celinelee/thestack_omp · Datasets at Hugging Face

source stringlengths 3 92	c stringlengths 26 2.25M
threshold.c	/* Copyright 2014. The Regents of the University of California. * Copyright 2015-2017. Martin Uecker. * All rights reserved. Use of this source code is governed by * a BSD-style license which can be found in the LICENSE file. * * Authors: * 2013-2017 Martin Uecker <martin.uecker@med.uni-goettingen.de> * 2015-2016 Jon Tamir <jtamir@eecs.berkeley.edu> * 2015 Frank Ong <frankong@berkeley.edu> / #include <stdbool.h> #include <complex.h> #include "num/flpmath.h" #include "num/multind.h" #include "num/init.h" #include "num/ops_p.h" #include "iter/prox.h" #include "iter/thresh.h" #include "misc/mmio.h" #include "misc/misc.h" #include "misc/debug.h" #include "misc/opts.h" #include "lowrank/lrthresh.h" #include "linops/waveop.h" #include "dfwavelet/prox_dfwavelet.h" // FIXME: lowrank interface should not be coupled to mri.h -- it should take D as an input #ifndef DIMS #define DIMS 16 #endif // FIXME: consider moving this to a more accessible location? static void wthresh(unsigned int D, const long dims[D], float lambda, unsigned int flags, complex float out, const complex float* in) { long minsize[D]; md_singleton_dims(D, minsize); long course_scale[3] = MD_INIT_ARRAY(3, 16); md_copy_dims(3, minsize, course_scale); unsigned int wflags = 7; // FIXME for (unsigned int i = 0; i < 3; i++) if (dims[i] < minsize[i]) wflags = MD_CLEAR(wflags, i); long strs[D]; md_calc_strides(D, strs, dims, CFL_SIZE); const struct linop_s* w = linop_wavelet_create(D, wflags, dims, strs, minsize, false); const struct operator_p_s* p = prox_unithresh_create(D, w, lambda, flags); operator_p_apply(p, 1., D, dims, out, D, dims, in); operator_p_free(p); } static void lrthresh(unsigned int D, const long dims[D], int llrblk, float lambda, unsigned int flags, complex float* out, const complex float* in) { long blkdims[MAX_LEV][D]; int levels = llr_blkdims(blkdims, ~flags, dims, llrblk); UNUSED(levels); const struct operator_p_s* p = lrthresh_create(dims, false, ~flags, (const long ()[])blkdims, lambda, false, false, false); operator_p_apply(p, 1., D, dims, out, D, dims, in); operator_p_free(p); } static void dfthresh(unsigned int D, const long dims[D], float lambda, complex float out, const complex float* in) { long minsize[3]; md_singleton_dims(3, minsize); long coarse_scale[3] = MD_INIT_ARRAY(3, 16); md_min_dims(3, ~0u, minsize, dims, coarse_scale); complex float res[3]; res[0] = 1.; res[1] = 1.; res[2] = 1.; assert(3 == dims[TE_DIM]); const struct operator_p_s* p = prox_dfwavelet_create(dims, minsize, res, TE_DIM, lambda, false); operator_p_apply(p, 1., D, dims, out, D, dims, in); operator_p_free(p); } static void hard_thresh(unsigned int D, const long dims[D], float lambda, complex float* out, const complex float* in) { long size = md_calc_size(DIMS, dims); #pragma omp parallel for for (long i = 0; i < size; i++) out[i] = (cabsf(in[i]) > lambda) ? in[i] : 0.; } static void binary_thresh(unsigned int D, const long dims[D], float lambda, complex float* out, const complex float* in) { long size = md_calc_size(DIMS, dims); #pragma omp parallel for for (long i = 0; i < size; i++) out[i] = (cabsf(in[i]) > lambda) ? 1. : 0.; } static const char help_str[] = "Perform (soft) thresholding with parameter lambda."; int main_threshold(int argc, char* argv[argc]) { float lambda = 0.; const char* in_file = NULL; const char* out_file = NULL; struct arg_s args[] = { ARG_FLOAT(true, &lambda, "lambda"), ARG_INFILE(true, &in_file, "input"), ARG_OUTFILE(true, &out_file, "output"), }; unsigned int flags = 0; enum th_type { NONE, WAV, LLR, DFW, MPDFW, HARD, BINARY } th_type = NONE; int llrblk = 8; const struct opt_s opts[] = { OPT_SELECT('H', enum th_type, &th_type, HARD, "hard thresholding"), OPT_SELECT('W', enum th_type, &th_type, WAV, "daubechies wavelet soft-thresholding"), OPT_SELECT('L', enum th_type, &th_type, LLR, "locally low rank soft-thresholding"), OPT_SELECT('D', enum th_type, &th_type, DFW, "divergence-free wavelet soft-thresholding"), OPT_SELECT('B', enum th_type, &th_type, BINARY, "thresholding with binary output"), OPT_UINT('j', &flags, "bitmask", "joint soft-thresholding"), OPT_INT('b', &llrblk, "blocksize", "locally low rank block size"), }; cmdline(&argc, argv, ARRAY_SIZE(args), args, help_str, ARRAY_SIZE(opts), opts); num_init(); const int N = DIMS; long dims[N]; complex float* idata = load_cfl(in_file, N, dims); complex float* odata = create_cfl(out_file, N, dims); switch (th_type) { case WAV: wthresh(N, dims, lambda, flags, odata, idata); break; case LLR: lrthresh(N, dims, llrblk, lambda, flags, odata, idata); break; case DFW: dfthresh(N, dims, lambda, odata, idata); break; case HARD: hard_thresh(N, dims, lambda, odata, idata); break; case BINARY: binary_thresh(N, dims, lambda, odata, idata); break; default: md_zsoftthresh(N, dims, lambda, flags, odata, idata); } unmap_cfl(N, dims, idata); unmap_cfl(N, dims, odata); return 0; }
TSDFVoxelGridImpl.h	// ---------------------------------------------------------------------------- // - Open3D: www.open3d.org - // ---------------------------------------------------------------------------- // The MIT License (MIT) // // Copyright (c) 2018 www.open3d.org // // Permission is hereby granted, free of charge, to any person obtaining a copy // of this software and associated documentation files (the "Software"), to deal // in the Software without restriction, including without limitation the rights // to use, copy, modify, merge, publish, distribute, sublicense, and/or sell // copies of the Software, and to permit persons to whom the Software is // furnished to do so, subject to the following conditions: // // The above copyright notice and this permission notice shall be included in // all copies or substantial portions of the Software. // // THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR // IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, // FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE // AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER // LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING // FROM, OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS // IN THE SOFTWARE. // ---------------------------------------------------------------------------- #include <atomic> #include <cmath> #include "open3d/core/Dispatch.h" #include "open3d/core/Dtype.h" #include "open3d/core/MemoryManager.h" #include "open3d/core/SizeVector.h" #include "open3d/core/Tensor.h" #include "open3d/t/geometry/Utility.h" #include "open3d/t/geometry/kernel/GeometryIndexer.h" #include "open3d/t/geometry/kernel/GeometryMacros.h" #include "open3d/t/geometry/kernel/TSDFVoxel.h" #include "open3d/t/geometry/kernel/TSDFVoxelGrid.h" #include "open3d/utility/Console.h" #include "open3d/utility/Timer.h" namespace open3d { namespace t { namespace geometry { namespace kernel { namespace tsdf { #if defined(__CUDACC__) void IntegrateCUDA #else void IntegrateCPU #endif (const core::Tensor& depth, const core::Tensor& color, const core::Tensor& indices, const core::Tensor& block_keys, core::Tensor& block_values, // Transforms const core::Tensor& intrinsics, const core::Tensor& extrinsics, // Parameters int64_t resolution, float voxel_size, float sdf_trunc, float depth_scale, float depth_max) { // Parameters int64_t resolution3 = resolution * resolution * resolution; // Shape / transform indexers, no data involved NDArrayIndexer voxel_indexer({resolution, resolution, resolution}); TransformIndexer transform_indexer(intrinsics, extrinsics, voxel_size); // Real data indexer NDArrayIndexer depth_indexer(depth, 2); NDArrayIndexer block_keys_indexer(block_keys, 1); NDArrayIndexer voxel_block_buffer_indexer(block_values, 4); // Optional color integration NDArrayIndexer color_indexer; bool integrate_color = false; if (color.NumElements() != 0) { color_indexer = NDArrayIndexer(color, 2); integrate_color = true; } // Plain arrays that does not require indexers const int64_t* indices_ptr = static_cast<const int64_t>(indices.GetDataPtr()); int64_t n = indices.GetLength() resolution3; #if defined(__CUDACC__) core::kernel::CUDALauncher launcher; #else core::kernel::CPULauncher launcher; #endif DISPATCH_BYTESIZE_TO_VOXEL( voxel_block_buffer_indexer.ElementByteSize(), [&]() { launcher.LaunchGeneralKernel(n, [=] OPEN3D_DEVICE( int64_t workload_idx) { // Natural index (0, N) -> (block_idx, voxel_idx) int64_t block_idx = indices_ptr[workload_idx / resolution3]; int64_t voxel_idx = workload_idx % resolution3; /// Coordinate transform // block_idx -> (x_block, y_block, z_block) int* block_key_ptr = block_keys_indexer.GetDataPtrFromCoord<int>( block_idx); int64_t xb = static_cast<int64_t>(block_key_ptr[0]); int64_t yb = static_cast<int64_t>(block_key_ptr[1]); int64_t zb = static_cast<int64_t>(block_key_ptr[2]); // voxel_idx -> (x_voxel, y_voxel, z_voxel) int64_t xv, yv, zv; voxel_indexer.WorkloadToCoord(voxel_idx, &xv, &yv, &zv); // coordinate in world (in voxel) int64_t x = (xb * resolution + xv); int64_t y = (yb * resolution + yv); int64_t z = (zb * resolution + zv); // coordinate in camera (in voxel -> in meter) float xc, yc, zc, u, v; transform_indexer.RigidTransform( static_cast<float>(x), static_cast<float>(y), static_cast<float>(z), &xc, &yc, &zc); // coordinate in image (in pixel) transform_indexer.Project(xc, yc, zc, &u, &v); if (!depth_indexer.InBoundary(u, v)) { return; } // Associate image workload and compute SDF and TSDF. float depth = depth_indexer.GetDataPtrFromCoord<float>( static_cast<int64_t>(u), static_cast<int64_t>(v)) / depth_scale; float sdf = (depth - zc); if (depth <= 0 \|\| depth > depth_max \|\| zc <= 0 \|\| sdf < -sdf_trunc) { return; } sdf = sdf < sdf_trunc ? sdf : sdf_trunc; sdf /= sdf_trunc; // Associate voxel workload and update TSDF/Weights voxel_t voxel_ptr = voxel_block_buffer_indexer .GetDataPtrFromCoord<voxel_t>( xv, yv, zv, block_idx); if (integrate_color) { float* color_ptr = color_indexer.GetDataPtrFromCoord<float>( static_cast<int64_t>(u), static_cast<int64_t>(v)); voxel_ptr->Integrate(sdf, color_ptr[0], color_ptr[1], color_ptr[2]); } else { voxel_ptr->Integrate(sdf); } }); }); #if defined(__CUDACC__) OPEN3D_CUDA_CHECK(cudaDeviceSynchronize()); #endif } #if defined(__CUDACC__) void ExtractSurfacePointsCUDA #else void ExtractSurfacePointsCPU #endif (const core::Tensor& indices, const core::Tensor& nb_indices, const core::Tensor& nb_masks, const core::Tensor& block_keys, const core::Tensor& block_values, core::Tensor& points, utility::optional<std::reference_wrapper<core::Tensor>> normals, utility::optional<std::reference_wrapper<core::Tensor>> colors, int64_t resolution, float voxel_size, float weight_threshold, int& valid_size) { // Parameters int64_t resolution3 = resolution * resolution * resolution; // Shape / transform indexers, no data involved NDArrayIndexer voxel_indexer({resolution, resolution, resolution}); // Real data indexer NDArrayIndexer voxel_block_buffer_indexer(block_values, 4); NDArrayIndexer block_keys_indexer(block_keys, 1); NDArrayIndexer nb_block_masks_indexer(nb_masks, 2); NDArrayIndexer nb_block_indices_indexer(nb_indices, 2); // Plain arrays that does not require indexers const int64_t* indices_ptr = static_cast<const int64_t>(indices.GetDataPtr()); int64_t n_blocks = indices.GetLength(); int64_t n = n_blocks resolution3; // Output #if defined(__CUDACC__) core::Tensor count(std::vector<int>{0}, {1}, core::Dtype::Int32, block_values.GetDevice()); int* count_ptr = count.GetDataPtr<int>(); #else std::atomic<int> count_atomic(0); std::atomic<int>* count_ptr = &count_atomic; #endif #if defined(__CUDACC__) core::kernel::CUDALauncher launcher; #else core::kernel::CPULauncher launcher; #endif if (valid_size < 0) { utility::LogWarning( "No estimated max point cloud size provided, using a 2-pass " "estimation. Surface extraction could be slow."); // This pass determines valid number of points. DISPATCH_BYTESIZE_TO_VOXEL( voxel_block_buffer_indexer.ElementByteSize(), [&]() { launcher.LaunchGeneralKernel( n, [=] OPEN3D_DEVICE(int64_t workload_idx) { auto GetVoxelAt = [&] OPEN3D_DEVICE( int xo, int yo, int zo, int curr_block_idx) -> voxel_t* { return DeviceGetVoxelAt<voxel_t>( xo, yo, zo, curr_block_idx, static_cast<int>(resolution), nb_block_masks_indexer, nb_block_indices_indexer, voxel_block_buffer_indexer); }; // Natural index (0, N) -> (block_idx, // voxel_idx) int64_t workload_block_idx = workload_idx / resolution3; int64_t block_idx = indices_ptr[workload_block_idx]; int64_t voxel_idx = workload_idx % resolution3; // voxel_idx -> (x_voxel, y_voxel, z_voxel) int64_t xv, yv, zv; voxel_indexer.WorkloadToCoord(voxel_idx, &xv, &yv, &zv); voxel_t* voxel_ptr = voxel_block_buffer_indexer .GetDataPtrFromCoord<voxel_t>( xv, yv, zv, block_idx); float tsdf_o = voxel_ptr->GetTSDF(); float weight_o = voxel_ptr->GetWeight(); if (weight_o <= weight_threshold) return; // Enumerate x-y-z directions for (int i = 0; i < 3; ++i) { voxel_t* ptr = GetVoxelAt( static_cast<int>(xv) + (i == 0), static_cast<int>(yv) + (i == 1), static_cast<int>(zv) + (i == 2), static_cast<int>( workload_block_idx)); if (ptr == nullptr) continue; float tsdf_i = ptr->GetTSDF(); float weight_i = ptr->GetWeight(); if (weight_i > weight_threshold && tsdf_i * tsdf_o < 0) { OPEN3D_ATOMIC_ADD(count_ptr, 1); } } }); }); #if defined(__CUDACC__) valid_size = count[0].Item<int>(); count[0] = 0; #else valid_size = (count_ptr).load(); (count_ptr) = 0; #endif } int max_count = valid_size; if (points.GetLength() == 0) { points = core::Tensor({max_count, 3}, core::Dtype::Float32, block_values.GetDevice()); } NDArrayIndexer point_indexer(points, 1); // Normals bool extract_normal = false; NDArrayIndexer normal_indexer; if (normals.has_value()) { extract_normal = true; if (normals.value().get().GetLength() == 0) { normals.value().get() = core::Tensor({max_count, 3}, core::Dtype::Float32, block_values.GetDevice()); } normal_indexer = NDArrayIndexer(normals.value().get(), 1); } // This pass extracts exact surface points. DISPATCH_BYTESIZE_TO_VOXEL( voxel_block_buffer_indexer.ElementByteSize(), [&]() { // Colors bool extract_color = false; NDArrayIndexer color_indexer; if (voxel_t::HasColor() && colors.has_value()) { extract_color = true; if (colors.value().get().GetLength() == 0) { colors.value().get() = core::Tensor( {max_count, 3}, core::Dtype::Float32, block_values.GetDevice()); } color_indexer = NDArrayIndexer(colors.value().get(), 1); } launcher.LaunchGeneralKernel(n, [=] OPEN3D_DEVICE( int64_t workload_idx) { auto GetVoxelAt = [&] OPEN3D_DEVICE( int xo, int yo, int zo, int curr_block_idx) -> voxel_t* { return DeviceGetVoxelAt<voxel_t>( xo, yo, zo, curr_block_idx, static_cast<int>(resolution), nb_block_masks_indexer, nb_block_indices_indexer, voxel_block_buffer_indexer); }; auto GetNormalAt = [&] OPEN3D_DEVICE(int xo, int yo, int zo, int curr_block_idx, float* n) { return DeviceGetNormalAt<voxel_t>( xo, yo, zo, curr_block_idx, n, static_cast<int>(resolution), voxel_size, nb_block_masks_indexer, nb_block_indices_indexer, voxel_block_buffer_indexer); }; // Natural index (0, N) -> (block_idx, voxel_idx) int64_t workload_block_idx = workload_idx / resolution3; int64_t block_idx = indices_ptr[workload_block_idx]; int64_t voxel_idx = workload_idx % resolution3; /// Coordinate transform // block_idx -> (x_block, y_block, z_block) int* block_key_ptr = block_keys_indexer.GetDataPtrFromCoord<int>( block_idx); int64_t xb = static_cast<int64_t>(block_key_ptr[0]); int64_t yb = static_cast<int64_t>(block_key_ptr[1]); int64_t zb = static_cast<int64_t>(block_key_ptr[2]); // voxel_idx -> (x_voxel, y_voxel, z_voxel) int64_t xv, yv, zv; voxel_indexer.WorkloadToCoord(voxel_idx, &xv, &yv, &zv); voxel_t* voxel_ptr = voxel_block_buffer_indexer .GetDataPtrFromCoord<voxel_t>( xv, yv, zv, block_idx); float tsdf_o = voxel_ptr->GetTSDF(); float weight_o = voxel_ptr->GetWeight(); if (weight_o <= weight_threshold) return; int64_t x = xb * resolution + xv; int64_t y = yb * resolution + yv; int64_t z = zb * resolution + zv; float no[3] = {0}, ni[3] = {0}; if (extract_normal) { GetNormalAt(static_cast<int>(xv), static_cast<int>(yv), static_cast<int>(zv), static_cast<int>(workload_block_idx), no); } // Enumerate x-y-z axis for (int i = 0; i < 3; ++i) { voxel_t* ptr = GetVoxelAt( static_cast<int>(xv) + (i == 0), static_cast<int>(yv) + (i == 1), static_cast<int>(zv) + (i == 2), static_cast<int>(workload_block_idx)); if (ptr == nullptr) continue; float tsdf_i = ptr->GetTSDF(); float weight_i = ptr->GetWeight(); if (weight_i > weight_threshold && tsdf_i * tsdf_o < 0) { float ratio = (0 - tsdf_o) / (tsdf_i - tsdf_o); int idx = OPEN3D_ATOMIC_ADD(count_ptr, 1); if (idx >= valid_size) { printf("Point cloud size larger than " "estimated, please increase the " "estimation!\n"); return; } float* point_ptr = point_indexer.GetDataPtrFromCoord<float>( idx); point_ptr[0] = voxel_size * (x + ratio * int(i == 0)); point_ptr[1] = voxel_size * (y + ratio * int(i == 1)); point_ptr[2] = voxel_size * (z + ratio * int(i == 2)); if (extract_color) { float* color_ptr = color_indexer .GetDataPtrFromCoord<float>( idx); float r_o = voxel_ptr->GetR(); float g_o = voxel_ptr->GetG(); float b_o = voxel_ptr->GetB(); float r_i = ptr->GetR(); float g_i = ptr->GetG(); float b_i = ptr->GetB(); color_ptr[0] = ((1 - ratio) * r_o + ratio * r_i) / 255.0f; color_ptr[1] = ((1 - ratio) * g_o + ratio * g_i) / 255.0f; color_ptr[2] = ((1 - ratio) * b_o + ratio * b_i) / 255.0f; } if (extract_normal) { GetNormalAt( static_cast<int>(xv) + (i == 0), static_cast<int>(yv) + (i == 1), static_cast<int>(zv) + (i == 2), static_cast<int>(workload_block_idx), ni); float* normal_ptr = normal_indexer .GetDataPtrFromCoord<float>( idx); float nx = (1 - ratio) * no[0] + ratio * ni[0]; float ny = (1 - ratio) * no[1] + ratio * ni[1]; float nz = (1 - ratio) * no[2] + ratio * ni[2]; float norm = static_cast<float>( sqrt(nx * nx + ny * ny + nz * nz) + 1e-5); normal_ptr[0] = nx / norm; normal_ptr[1] = ny / norm; normal_ptr[2] = nz / norm; } } } }); }); #if defined(__CUDACC__) int total_count = count.Item<int>(); #else int total_count = (count_ptr).load(); #endif utility::LogDebug("{} vertices extracted", total_count); valid_size = total_count; #if defined(BUILD_CUDA_MODULE) && defined(__CUDACC__) OPEN3D_CUDA_CHECK(cudaDeviceSynchronize()); #endif } #if defined(__CUDACC__) void ExtractSurfaceMeshCUDA #else void ExtractSurfaceMeshCPU #endif (const core::Tensor& indices, const core::Tensor& inv_indices, const core::Tensor& nb_indices, const core::Tensor& nb_masks, const core::Tensor& block_keys, const core::Tensor& block_values, core::Tensor& vertices, core::Tensor& triangles, core::Tensor& normals, core::Tensor& colors, int64_t resolution, float voxel_size, float weight_threshold) { int64_t resolution3 = resolution resolution * resolution; // Shape / transform indexers, no data involved NDArrayIndexer voxel_indexer({resolution, resolution, resolution}); // Output #if defined(__CUDACC__) core::CUDACachedMemoryManager::ReleaseCache(); #endif int n_blocks = static_cast<int>(indices.GetLength()); // Voxel-wise mesh info. 4 channels correspond to: // 3 edges' corresponding vertex index + 1 table index. core::Tensor mesh_structure; try { mesh_structure = core::Tensor::Zeros( {n_blocks, resolution, resolution, resolution, 4}, core::Dtype::Int32, block_keys.GetDevice()); } catch (const std::runtime_error&) { utility::LogError( "[MeshExtractionKernel] Unable to allocate assistance mesh " "structure for Marching " "Cubes with {} active voxel blocks. Please consider using a " "larger voxel size (currently {}) for TSDF " "integration, or using tsdf_volume.cpu() to perform mesh " "extraction on CPU.", n_blocks, voxel_size); } // Real data indexer NDArrayIndexer voxel_block_buffer_indexer(block_values, 4); NDArrayIndexer mesh_structure_indexer(mesh_structure, 4); NDArrayIndexer nb_block_masks_indexer(nb_masks, 2); NDArrayIndexer nb_block_indices_indexer(nb_indices, 2); // Plain arrays that does not require indexers const int64_t* indices_ptr = indices.GetDataPtr<int64_t>(); const int64_t* inv_indices_ptr = inv_indices.GetDataPtr<int64_t>(); int64_t n = n_blocks * resolution3; #if defined(__CUDACC__) core::kernel::CUDALauncher launcher; #else core::kernel::CPULauncher launcher; #endif // Pass 0: analyze mesh structure, set up one-on-one correspondences from // edges to vertices. DISPATCH_BYTESIZE_TO_VOXEL( voxel_block_buffer_indexer.ElementByteSize(), [&]() { launcher.LaunchGeneralKernel(n, [=] OPEN3D_DEVICE( int64_t workload_idx) { auto GetVoxelAt = [&] OPEN3D_DEVICE( int xo, int yo, int zo, int curr_block_idx) -> voxel_t* { return DeviceGetVoxelAt<voxel_t>( xo, yo, zo, curr_block_idx, static_cast<int>(resolution), nb_block_masks_indexer, nb_block_indices_indexer, voxel_block_buffer_indexer); }; // Natural index (0, N) -> (block_idx, voxel_idx) int64_t workload_block_idx = workload_idx / resolution3; int64_t voxel_idx = workload_idx % resolution3; // voxel_idx -> (x_voxel, y_voxel, z_voxel) int64_t xv, yv, zv; voxel_indexer.WorkloadToCoord(voxel_idx, &xv, &yv, &zv); // Check per-vertex sign in the cube to determine cube type int table_idx = 0; for (int i = 0; i < 8; ++i) { voxel_t* voxel_ptr_i = GetVoxelAt( static_cast<int>(xv) + vtx_shifts[i][0], static_cast<int>(yv) + vtx_shifts[i][1], static_cast<int>(zv) + vtx_shifts[i][2], static_cast<int>(workload_block_idx)); if (voxel_ptr_i == nullptr) return; float tsdf_i = voxel_ptr_i->GetTSDF(); float weight_i = voxel_ptr_i->GetWeight(); if (weight_i <= weight_threshold) return; table_idx \|= ((tsdf_i < 0) ? (1 << i) : 0); } int* mesh_struct_ptr = mesh_structure_indexer.GetDataPtrFromCoord<int>( xv, yv, zv, workload_block_idx); mesh_struct_ptr[3] = table_idx; if (table_idx == 0 \|\| table_idx == 255) return; // Check per-edge sign in the cube to determine cube type int edges_with_vertices = edge_table[table_idx]; for (int i = 0; i < 12; ++i) { if (edges_with_vertices & (1 << i)) { int64_t xv_i = xv + edge_shifts[i][0]; int64_t yv_i = yv + edge_shifts[i][1]; int64_t zv_i = zv + edge_shifts[i][2]; int edge_i = edge_shifts[i][3]; int dxb = static_cast<int>(xv_i / resolution); int dyb = static_cast<int>(yv_i / resolution); int dzb = static_cast<int>(zv_i / resolution); int nb_idx = (dxb + 1) + (dyb + 1) * 3 + (dzb + 1) * 9; int64_t block_idx_i = nb_block_indices_indexer .GetDataPtrFromCoord<int64_t>( workload_block_idx, nb_idx); int mesh_ptr_i = mesh_structure_indexer.GetDataPtrFromCoord< int>(xv_i - dxb * resolution, yv_i - dyb * resolution, zv_i - dzb * resolution, inv_indices_ptr[block_idx_i]); // Non-atomic write, but we are safe mesh_ptr_i[edge_i] = -1; } } }); }); // Pass 1: determine valid number of vertices. #if defined(__CUDACC__) core::Tensor vtx_count(std::vector<int>{0}, {}, core::Dtype::Int32, block_values.GetDevice()); int* vtx_count_ptr = vtx_count.GetDataPtr<int>(); #else std::atomic<int> vtx_count_atomic(0); std::atomic<int>* vtx_count_ptr = &vtx_count_atomic; #endif #if defined(__CUDACC__) core::kernel::CUDALauncher::LaunchGeneralKernel( n, [=] OPEN3D_DEVICE(int64_t workload_idx) { #else core::kernel::CPULauncher::LaunchGeneralKernel( n, [&](int64_t workload_idx) { #endif // Natural index (0, N) -> (block_idx, voxel_idx) int64_t workload_block_idx = workload_idx / resolution3; int64_t voxel_idx = workload_idx % resolution3; // voxel_idx -> (x_voxel, y_voxel, z_voxel) int64_t xv, yv, zv; voxel_indexer.WorkloadToCoord(voxel_idx, &xv, &yv, &zv); // Obtain voxel's mesh struct ptr int* mesh_struct_ptr = mesh_structure_indexer.GetDataPtrFromCoord<int>( xv, yv, zv, workload_block_idx); // Early quit -- no allocated vertex to compute if (mesh_struct_ptr[0] != -1 && mesh_struct_ptr[1] != -1 && mesh_struct_ptr[2] != -1) { return; } // Enumerate 3 edges in the voxel for (int e = 0; e < 3; ++e) { int vertex_idx = mesh_struct_ptr[e]; if (vertex_idx != -1) continue; OPEN3D_ATOMIC_ADD(vtx_count_ptr, 1); } }); // Reset count_ptr #if defined(__CUDACC__) int total_vtx_count = vtx_count.Item<int>(); vtx_count = core::Tensor(std::vector<int>{0}, {}, core::Dtype::Int32, block_values.GetDevice()); vtx_count_ptr = vtx_count.GetDataPtr<int>(); #else int total_vtx_count = (vtx_count_ptr).load(); (vtx_count_ptr) = 0; #endif utility::LogDebug("Total vertex count = {}", total_vtx_count); vertices = core::Tensor({total_vtx_count, 3}, core::Dtype::Float32, block_values.GetDevice()); normals = core::Tensor({total_vtx_count, 3}, core::Dtype::Float32, block_values.GetDevice()); NDArrayIndexer block_keys_indexer(block_keys, 1); NDArrayIndexer vertex_indexer(vertices, 1); NDArrayIndexer normal_indexer(normals, 1); // Pass 2: extract vertices. DISPATCH_BYTESIZE_TO_VOXEL( voxel_block_buffer_indexer.ElementByteSize(), [&]() { bool extract_color = false; NDArrayIndexer color_indexer; if (voxel_t::HasColor()) { extract_color = true; colors = core::Tensor({total_vtx_count, 3}, core::Dtype::Float32, block_values.GetDevice()); color_indexer = NDArrayIndexer(colors, 1); } launcher.LaunchGeneralKernel(n, [=] OPEN3D_DEVICE( int64_t workload_idx) { auto GetVoxelAt = [&] OPEN3D_DEVICE( int xo, int yo, int zo, int curr_block_idx) -> voxel_t* { return DeviceGetVoxelAt<voxel_t>( xo, yo, zo, curr_block_idx, static_cast<int>(resolution), nb_block_masks_indexer, nb_block_indices_indexer, voxel_block_buffer_indexer); }; auto GetNormalAt = [&] OPEN3D_DEVICE(int xo, int yo, int zo, int curr_block_idx, float* n) { return DeviceGetNormalAt<voxel_t>( xo, yo, zo, curr_block_idx, n, static_cast<int>(resolution), voxel_size, nb_block_masks_indexer, nb_block_indices_indexer, voxel_block_buffer_indexer); }; // Natural index (0, N) -> (block_idx, voxel_idx) int64_t workload_block_idx = workload_idx / resolution3; int64_t block_idx = indices_ptr[workload_block_idx]; int64_t voxel_idx = workload_idx % resolution3; // block_idx -> (x_block, y_block, z_block) int* block_key_ptr = block_keys_indexer.GetDataPtrFromCoord<int>( block_idx); int64_t xb = static_cast<int64_t>(block_key_ptr[0]); int64_t yb = static_cast<int64_t>(block_key_ptr[1]); int64_t zb = static_cast<int64_t>(block_key_ptr[2]); // voxel_idx -> (x_voxel, y_voxel, z_voxel) int64_t xv, yv, zv; voxel_indexer.WorkloadToCoord(voxel_idx, &xv, &yv, &zv); // global coordinate (in voxels) int64_t x = xb * resolution + xv; int64_t y = yb * resolution + yv; int64_t z = zb * resolution + zv; // Obtain voxel's mesh struct ptr int* mesh_struct_ptr = mesh_structure_indexer.GetDataPtrFromCoord<int>( xv, yv, zv, workload_block_idx); // Early quit -- no allocated vertex to compute if (mesh_struct_ptr[0] != -1 && mesh_struct_ptr[1] != -1 && mesh_struct_ptr[2] != -1) { return; } // Obtain voxel ptr voxel_t* voxel_ptr = voxel_block_buffer_indexer .GetDataPtrFromCoord<voxel_t>( xv, yv, zv, block_idx); float tsdf_o = voxel_ptr->GetTSDF(); float no[3] = {0}, ne[3] = {0}; GetNormalAt(static_cast<int>(xv), static_cast<int>(yv), static_cast<int>(zv), static_cast<int>(workload_block_idx), no); // Enumerate 3 edges in the voxel for (int e = 0; e < 3; ++e) { int vertex_idx = mesh_struct_ptr[e]; if (vertex_idx != -1) continue; voxel_t* voxel_ptr_e = GetVoxelAt( static_cast<int>(xv) + (e == 0), static_cast<int>(yv) + (e == 1), static_cast<int>(zv) + (e == 2), static_cast<int>(workload_block_idx)); float tsdf_e = voxel_ptr_e->GetTSDF(); float ratio = (0 - tsdf_o) / (tsdf_e - tsdf_o); int idx = OPEN3D_ATOMIC_ADD(vtx_count_ptr, 1); mesh_struct_ptr[e] = idx; float ratio_x = ratio * int(e == 0); float ratio_y = ratio * int(e == 1); float ratio_z = ratio * int(e == 2); float* vertex_ptr = vertex_indexer.GetDataPtrFromCoord<float>(idx); vertex_ptr[0] = voxel_size * (x + ratio_x); vertex_ptr[1] = voxel_size * (y + ratio_y); vertex_ptr[2] = voxel_size * (z + ratio_z); float* normal_ptr = normal_indexer.GetDataPtrFromCoord<float>(idx); GetNormalAt(static_cast<int>(xv) + (e == 0), static_cast<int>(yv) + (e == 1), static_cast<int>(zv) + (e == 2), static_cast<int>(workload_block_idx), ne); float nx = (1 - ratio) * no[0] + ratio * ne[0]; float ny = (1 - ratio) * no[1] + ratio * ne[1]; float nz = (1 - ratio) * no[2] + ratio * ne[2]; float norm = static_cast<float>( sqrt(nx * nx + ny * ny + nz * nz) + 1e-5); normal_ptr[0] = nx / norm; normal_ptr[1] = ny / norm; normal_ptr[2] = nz / norm; if (extract_color) { float* color_ptr = color_indexer.GetDataPtrFromCoord<float>( idx); float r_o = voxel_ptr->GetR(); float g_o = voxel_ptr->GetG(); float b_o = voxel_ptr->GetB(); float r_e = voxel_ptr_e->GetR(); float g_e = voxel_ptr_e->GetG(); float b_e = voxel_ptr_e->GetB(); color_ptr[0] = ((1 - ratio) * r_o + ratio * r_e) / 255.0f; color_ptr[1] = ((1 - ratio) * g_o + ratio * g_e) / 255.0f; color_ptr[2] = ((1 - ratio) * b_o + ratio * b_e) / 255.0f; } } }); }); // Pass 3: connect vertices and form triangles. #if defined(__CUDACC__) core::Tensor triangle_count(std::vector<int>{0}, {}, core::Dtype::Int32, block_values.GetDevice()); int* tri_count_ptr = triangle_count.GetDataPtr<int>(); #else std::atomic<int> tri_count_atomic(0); std::atomic<int>* tri_count_ptr = &tri_count_atomic; #endif triangles = core::Tensor({total_vtx_count * 3, 3}, core::Dtype::Int64, block_values.GetDevice()); NDArrayIndexer triangle_indexer(triangles, 1); #if defined(__CUDACC__) core::kernel::CUDALauncher::LaunchGeneralKernel( n, [=] OPEN3D_DEVICE(int64_t workload_idx) { #else core::kernel::CPULauncher::LaunchGeneralKernel( n, [&](int64_t workload_idx) { #endif // Natural index (0, N) -> (block_idx, // voxel_idx) int64_t workload_block_idx = workload_idx / resolution3; int64_t voxel_idx = workload_idx % resolution3; // voxel_idx -> (x_voxel, y_voxel, z_voxel) int64_t xv, yv, zv; voxel_indexer.WorkloadToCoord(voxel_idx, &xv, &yv, &zv); // Obtain voxel's mesh struct ptr int* mesh_struct_ptr = mesh_structure_indexer.GetDataPtrFromCoord<int>( xv, yv, zv, workload_block_idx); int table_idx = mesh_struct_ptr[3]; if (tri_count[table_idx] == 0) return; for (size_t tri = 0; tri < 16; tri += 3) { if (tri_table[table_idx][tri] == -1) return; int tri_idx = OPEN3D_ATOMIC_ADD(tri_count_ptr, 1); for (size_t vertex = 0; vertex < 3; ++vertex) { int edge = tri_table[table_idx][tri + vertex]; int64_t xv_i = xv + edge_shifts[edge][0]; int64_t yv_i = yv + edge_shifts[edge][1]; int64_t zv_i = zv + edge_shifts[edge][2]; int64_t edge_i = edge_shifts[edge][3]; int dxb = static_cast<int>(xv_i / resolution); int dyb = static_cast<int>(yv_i / resolution); int dzb = static_cast<int>(zv_i / resolution); int nb_idx = (dxb + 1) + (dyb + 1) * 3 + (dzb + 1) * 9; int64_t block_idx_i = nb_block_indices_indexer .GetDataPtrFromCoord<int64_t>( workload_block_idx, nb_idx); int mesh_struct_ptr_i = mesh_structure_indexer.GetDataPtrFromCoord<int>( xv_i - dxb * resolution, yv_i - dyb * resolution, zv_i - dzb * resolution, inv_indices_ptr[block_idx_i]); int64_t* triangle_ptr = triangle_indexer.GetDataPtrFromCoord<int64_t>( tri_idx); triangle_ptr[2 - vertex] = mesh_struct_ptr_i[edge_i]; } } }); #if defined(__CUDACC__) int total_tri_count = triangle_count.Item<int>(); #else int total_tri_count = (tri_count_ptr).load(); #endif utility::LogDebug("Total triangle count = {}", total_tri_count); triangles = triangles.Slice(0, 0, total_tri_count); } #if defined(__CUDACC__) void EstimateRangeCUDA #else void EstimateRangeCPU #endif (const core::Tensor& block_keys, core::Tensor& range_minmax_map, const core::Tensor& intrinsics, const core::Tensor& extrinsics, int h, int w, int down_factor, int64_t block_resolution, float voxel_size, float depth_min, float depth_max) { // TODO(wei): reserve it in a reusable buffer // Every 2 channels: (min, max) int h_down = h / down_factor; int w_down = w / down_factor; range_minmax_map = core::Tensor({h_down, w_down, 2}, core::Dtype::Float32, block_keys.GetDevice()); NDArrayIndexer range_map_indexer(range_minmax_map, 2); // Every 6 channels: (v_min, u_min, v_max, u_max, z_min, z_max) const int fragment_size = 16; const int frag_buffer_size = 65535; // TODO(wei): explicit buffer core::Tensor fragment_buffer = core::Tensor({frag_buffer_size, 6}, core::Dtype::Float32, block_keys.GetDevice()); NDArrayIndexer frag_buffer_indexer(fragment_buffer, 1); NDArrayIndexer block_keys_indexer(block_keys, 1); TransformIndexer w2c_transform_indexer(intrinsics, extrinsics); #if defined(__CUDACC__) core::Tensor count(std::vector<int>{0}, {1}, core::Dtype::Int32, block_keys.GetDevice()); int count_ptr = count.GetDataPtr<int>(); #else std::atomic<int> count_atomic(0); std::atomic<int>* count_ptr = &count_atomic; #endif #if defined(__CUDACC__) core::kernel::CUDALauncher launcher; #else core::kernel::CPULauncher launcher; using std::ceil; using std::floor; using std::max; using std::min; #endif // Pass 0: iterate over blocks, fill-in an rendering fragment array launcher.LaunchGeneralKernel( block_keys.GetLength(), [=] OPEN3D_DEVICE(int64_t workload_idx) { int* key = block_keys_indexer.GetDataPtrFromCoord<int>( workload_idx); int u_min = w_down - 1, v_min = h_down - 1, u_max = 0, v_max = 0; float z_min = depth_max, z_max = depth_min; float xc, yc, zc, u, v; // Project 8 corners to low-res image and form a rectangle for (int i = 0; i < 8; ++i) { float xw = (key[0] + ((i & 1) > 0)) * block_resolution * voxel_size; float yw = (key[1] + ((i & 2) > 0)) * block_resolution * voxel_size; float zw = (key[2] + ((i & 4) > 0)) * block_resolution * voxel_size; w2c_transform_indexer.RigidTransform(xw, yw, zw, &xc, &yc, &zc); if (zc <= 0) continue; // Project to the down sampled image buffer w2c_transform_indexer.Project(xc, yc, zc, &u, &v); u /= down_factor; v /= down_factor; v_min = min(static_cast<int>(floor(v)), v_min); v_max = max(static_cast<int>(ceil(v)), v_max); u_min = min(static_cast<int>(floor(u)), u_min); u_max = max(static_cast<int>(ceil(u)), u_max); z_min = min(z_min, zc); z_max = max(z_max, zc); } v_min = max(0, v_min); v_max = min(h_down - 1, v_max); u_min = max(0, u_min); u_max = min(w_down - 1, u_max); if (v_min >= v_max \|\| u_min >= u_max \|\| z_min >= z_max) return; // Divide the rectangle into small 16x16 fragments int frag_v_count = ceil(float(v_max - v_min + 1) / float(fragment_size)); int frag_u_count = ceil(float(u_max - u_min + 1) / float(fragment_size)); int frag_count = frag_v_count * frag_u_count; int frag_count_start = OPEN3D_ATOMIC_ADD(count_ptr, 1); int frag_count_end = frag_count_start + frag_count; if (frag_count_end >= frag_buffer_size) { printf("Fragment count exceeding buffer size, abort!\n"); } int offset = 0; for (int frag_v = 0; frag_v < frag_v_count; ++frag_v) { for (int frag_u = 0; frag_u < frag_u_count; ++frag_u, ++offset) { float* frag_ptr = frag_buffer_indexer.GetDataPtrFromCoord<float>( frag_count_start + offset); // zmin, zmax frag_ptr[0] = z_min; frag_ptr[1] = z_max; // vmin, umin frag_ptr[2] = v_min + frag_v * fragment_size; frag_ptr[3] = u_min + frag_u * fragment_size; // vmax, umax frag_ptr[4] = min(frag_ptr[2] + fragment_size - 1, static_cast<float>(v_max)); frag_ptr[5] = min(frag_ptr[3] + fragment_size - 1, static_cast<float>(u_max)); } } }); #if defined(__CUDACC__) int frag_count = count[0].Item<int>(); #else int frag_count = (count_ptr).load(); #endif // Pass 0.5: Fill in range map to prepare for atomic min/max launcher.LaunchGeneralKernel( h_down w_down, [=] OPEN3D_DEVICE(int64_t workload_idx) { int v = workload_idx / w_down; int u = workload_idx % w_down; float* range_ptr = range_map_indexer.GetDataPtrFromCoord<float>(u, v); range_ptr[0] = depth_max; range_ptr[1] = depth_min; }); // Pass 1: iterate over rendering fragment array, fill-in range launcher.LaunchGeneralKernel( frag_count * fragment_size * fragment_size, [=] OPEN3D_DEVICE(int64_t workload_idx) { int frag_idx = workload_idx / (fragment_size * fragment_size); int local_idx = workload_idx % (fragment_size * fragment_size); int dv = local_idx / fragment_size; int du = local_idx % fragment_size; float* frag_ptr = frag_buffer_indexer.GetDataPtrFromCoord<float>( frag_idx); int v_min = static_cast<int>(frag_ptr[2]); int u_min = static_cast<int>(frag_ptr[3]); int v_max = static_cast<int>(frag_ptr[4]); int u_max = static_cast<int>(frag_ptr[5]); int v = v_min + dv; int u = u_min + du; if (v > v_max \|\| u > u_max) return; float z_min = frag_ptr[0]; float z_max = frag_ptr[1]; float* range_ptr = range_map_indexer.GetDataPtrFromCoord<float>(u, v); #ifdef __CUDACC__ atomicMinf(&(range_ptr[0]), z_min); atomicMaxf(&(range_ptr[1]), z_max); #else #pragma omp critical { range_ptr[0] = min(z_min, range_ptr[0]); range_ptr[1] = max(z_max, range_ptr[1]); } #endif }); #if defined(__CUDACC__) OPEN3D_CUDA_CHECK(cudaDeviceSynchronize()); #endif } struct BlockCache { int x; int y; int z; int block_idx; inline int OPEN3D_DEVICE Check(int xin, int yin, int zin) { return (xin == x && yin == y && zin == z) ? block_idx : -1; } inline void OPEN3D_DEVICE Update(int xin, int yin, int zin, int block_idx_in) { x = xin; y = yin; z = zin; block_idx = block_idx_in; } }; #if defined(__CUDACC__) void RayCastCUDA #else void RayCastCPU #endif (std::shared_ptr<core::DeviceHashmap>& hashmap, const core::Tensor& block_values, const core::Tensor& range_map, core::Tensor& vertex_map, core::Tensor& depth_map, core::Tensor& color_map, core::Tensor& normal_map, const core::Tensor& intrinsics, const core::Tensor& extrinsics, int h, int w, int64_t block_resolution, float voxel_size, float sdf_trunc, float depth_scale, float depth_min, float depth_max, float weight_threshold) { using Key = core::Block<int, 3>; using Hash = core::BlockHash<int, 3>; #if defined(BUILD_CUDA_MODULE) && defined(__CUDACC__) auto cuda_hashmap = std::dynamic_pointer_cast<core::StdGPUHashmap<Key, Hash>>(hashmap); if (cuda_hashmap == nullptr) { utility::LogError( "Unsupported backend: CUDA raycasting only supports STDGPU."); } auto hashmap_impl = cuda_hashmap->GetImpl(); #else auto cpu_hashmap = std::dynamic_pointer_cast<core::TBBHashmap<Key, Hash>>(hashmap); auto hashmap_impl = cpu_hashmap->GetImpl(); #endif NDArrayIndexer voxel_block_buffer_indexer(block_values, 4); NDArrayIndexer range_map_indexer(range_map, 2); NDArrayIndexer vertex_map_indexer; NDArrayIndexer depth_map_indexer; NDArrayIndexer color_map_indexer; NDArrayIndexer normal_map_indexer; bool enable_vertex = (vertex_map.GetLength() != 0); bool enable_depth = (depth_map.GetLength() != 0); bool enable_color = (color_map.GetLength() != 0); bool enable_normal = (normal_map.GetLength() != 0); if (!enable_vertex && !enable_depth && !enable_color && !enable_normal) { utility::LogWarning("No output specified for ray casting, exit."); return; } if (enable_vertex) { vertex_map_indexer = NDArrayIndexer(vertex_map, 2); } if (enable_depth) { depth_map_indexer = NDArrayIndexer(depth_map, 2); } if (enable_color) { color_map_indexer = NDArrayIndexer(color_map, 2); } if (enable_normal) { normal_map_indexer = NDArrayIndexer(normal_map, 2); } TransformIndexer c2w_transform_indexer( intrinsics, t::geometry::InverseTransformation(extrinsics)); TransformIndexer w2c_transform_indexer(intrinsics, extrinsics); int64_t rows = h; int64_t cols = w; float block_size = voxel_size block_resolution; #if defined(BUILD_CUDA_MODULE) && defined(__CUDACC__) core::kernel::CUDALauncher launcher; #else core::kernel::CPULauncher launcher; using std::max; #endif DISPATCH_BYTESIZE_TO_VOXEL(voxel_block_buffer_indexer.ElementByteSize(), [&]() { launcher.LaunchGeneralKernel( rows * cols, [=] OPEN3D_DEVICE(int64_t workload_idx) { auto GetVoxelAtP = [&] OPEN3D_DEVICE( int x_b, int y_b, int z_b, int x_v, int y_v, int z_v, core::addr_t block_addr, BlockCache& cache) -> voxel_t* { int x_vn = (x_v + block_resolution) % block_resolution; int y_vn = (y_v + block_resolution) % block_resolution; int z_vn = (z_v + block_resolution) % block_resolution; int dx_b = sign(x_v - x_vn); int dy_b = sign(y_v - y_vn); int dz_b = sign(z_v - z_vn); if (dx_b == 0 && dy_b == 0 && dz_b == 0) { return voxel_block_buffer_indexer .GetDataPtrFromCoord<voxel_t>(x_v, y_v, z_v, block_addr); } else { Key key; key(0) = x_b + dx_b; key(1) = y_b + dy_b; key(2) = z_b + dz_b; int block_addr = cache.Check(key(0), key(1), key(2)); if (block_addr < 0) { auto iter = hashmap_impl.find(key); if (iter == hashmap_impl.end()) return nullptr; block_addr = iter->second; cache.Update(key(0), key(1), key(2), block_addr); } return voxel_block_buffer_indexer .GetDataPtrFromCoord<voxel_t>( x_vn, y_vn, z_vn, block_addr); } }; auto GetVoxelAtT = [&] OPEN3D_DEVICE( float x_o, float y_o, float z_o, float x_d, float y_d, float z_d, float t, BlockCache& cache) -> voxel_t* { float x_g = x_o + t * x_d; float y_g = y_o + t * y_d; float z_g = z_o + t * z_d; // Block coordinate and look up int x_b = static_cast<int>(floor(x_g / block_size)); int y_b = static_cast<int>(floor(y_g / block_size)); int z_b = static_cast<int>(floor(z_g / block_size)); Key key; key(0) = x_b; key(1) = y_b; key(2) = z_b; int block_addr = cache.Check(x_b, y_b, z_b); if (block_addr < 0) { auto iter = hashmap_impl.find(key); if (iter == hashmap_impl.end()) return nullptr; block_addr = iter->second; cache.Update(x_b, y_b, z_b, block_addr); } // Voxel coordinate and look up int x_v = int((x_g - x_b * block_size) / voxel_size); int y_v = int((y_g - y_b * block_size) / voxel_size); int z_v = int((z_g - z_b * block_size) / voxel_size); return voxel_block_buffer_indexer .GetDataPtrFromCoord<voxel_t>(x_v, y_v, z_v, block_addr); }; int64_t y = workload_idx / cols; int64_t x = workload_idx % cols; float depth_ptr = nullptr, vertex_ptr = nullptr, normal_ptr = nullptr, color_ptr = nullptr; if (enable_depth) { depth_ptr = depth_map_indexer.GetDataPtrFromCoord<float>(x, y); depth_ptr = 0; } if (enable_vertex) { vertex_ptr = vertex_map_indexer.GetDataPtrFromCoord<float>( x, y); vertex_ptr[0] = 0; vertex_ptr[1] = 0; vertex_ptr[2] = 0; } if (enable_color) { color_ptr = color_map_indexer.GetDataPtrFromCoord<float>(x, y); color_ptr[0] = 0; color_ptr[1] = 0; color_ptr[2] = 0; } if (enable_normal) { normal_ptr = normal_map_indexer.GetDataPtrFromCoord<float>( x, y); normal_ptr[0] = 0; normal_ptr[1] = 0; normal_ptr[2] = 0; } const float range = range_map_indexer.GetDataPtrFromCoord<float>(x / 8, y / 8); float t = range[0]; const float t_max = range[1]; if (t >= t_max) return; // Coordinates in camera and global float x_c = 0, y_c = 0, z_c = 0; float x_g = 0, y_g = 0, z_g = 0; float x_o = 0, y_o = 0, z_o = 0; // Iterative ray intersection check float t_prev = t; float tsdf_prev = -1.0f; float tsdf = 1.0; float w = 0.0; // Camera origin c2w_transform_indexer.RigidTransform(0, 0, 0, &x_o, &y_o, &z_o); // Direction c2w_transform_indexer.Unproject(static_cast<float>(x), static_cast<float>(y), 1.0f, &x_c, &y_c, &z_c); c2w_transform_indexer.RigidTransform(x_c, y_c, z_c, &x_g, &y_g, &z_g); float x_d = (x_g - x_o); float y_d = (y_g - y_o); float z_d = (z_g - z_o); BlockCache cache{0, 0, 0, -1}; bool surface_found = false; while (t < t_max) { voxel_t* voxel_ptr = GetVoxelAtT(x_o, y_o, z_o, x_d, y_d, z_d, t, cache); if (!voxel_ptr) { t_prev = t; t += block_size; } else { tsdf_prev = tsdf; tsdf = voxel_ptr->GetTSDF(); w = voxel_ptr->GetWeight(); if (tsdf_prev > 0 && w >= weight_threshold && tsdf <= 0) { surface_found = true; break; } t_prev = t; float delta = tsdf * sdf_trunc; t += delta < voxel_size ? voxel_size : delta; } } if (surface_found) { float t_intersect = (t * tsdf_prev - t_prev * tsdf) / (tsdf_prev - tsdf); x_g = x_o + t_intersect * x_d; y_g = y_o + t_intersect * y_d; z_g = z_o + t_intersect * z_d; // Trivial vertex assignment if (enable_depth) { depth_ptr = t_intersect depth_scale; } if (enable_vertex) { w2c_transform_indexer.RigidTransform( x_g, y_g, z_g, vertex_ptr + 0, vertex_ptr + 1, vertex_ptr + 2); } // Trilinear interpolation // TODO(wei): simplify the flow by splitting the // functions given what is enabled if (enable_color \|\| enable_normal) { int x_b = static_cast<int>(floor(x_g / block_size)); int y_b = static_cast<int>(floor(y_g / block_size)); int z_b = static_cast<int>(floor(z_g / block_size)); float x_v = (x_g - float(x_b) * block_size) / voxel_size; float y_v = (y_g - float(y_b) * block_size) / voxel_size; float z_v = (z_g - float(z_b) * block_size) / voxel_size; Key key; key(0) = x_b; key(1) = y_b; key(2) = z_b; int block_addr = cache.Check(x_b, y_b, z_b); if (block_addr < 0) { auto iter = hashmap_impl.find(key); if (iter == hashmap_impl.end()) return; block_addr = iter->second; cache.Update(x_b, y_b, z_b, block_addr); } int x_v_floor = static_cast<int>(floor(x_v)); int y_v_floor = static_cast<int>(floor(y_v)); int z_v_floor = static_cast<int>(floor(z_v)); float ratio_x = x_v - float(x_v_floor); float ratio_y = y_v - float(y_v_floor); float ratio_z = z_v - float(z_v_floor); float sum_weight_color = 0.0; float sum_weight_normal = 0.0; for (int k = 0; k < 8; ++k) { int dx_v = (k & 1) > 0 ? 1 : 0; int dy_v = (k & 2) > 0 ? 1 : 0; int dz_v = (k & 4) > 0 ? 1 : 0; float ratio = (dx_v * (ratio_x) + (1 - dx_v) * (1 - ratio_x)) * (dy_v * (ratio_y) + (1 - dy_v) * (1 - ratio_y)) * (dz_v * (ratio_z) + (1 - dz_v) * (1 - ratio_z)); voxel_t* voxel_ptr_k = GetVoxelAtP( x_b, y_b, z_b, x_v_floor + dx_v, y_v_floor + dy_v, z_v_floor + dz_v, block_addr, cache); if (enable_color && voxel_ptr_k && voxel_ptr_k->GetWeight() > 0) { sum_weight_color += ratio; color_ptr[0] += ratio * voxel_ptr_k->GetR(); color_ptr[1] += ratio * voxel_ptr_k->GetG(); color_ptr[2] += ratio * voxel_ptr_k->GetB(); } if (enable_normal) { for (int dim = 0; dim < 3; ++dim) { voxel_t* voxel_ptr_k_plus = GetVoxelAtP( x_b, y_b, z_b, x_v_floor + dx_v + (dim == 0), y_v_floor + dy_v + (dim == 1), z_v_floor + dz_v + (dim == 2), block_addr, cache); voxel_t* voxel_ptr_k_minus = GetVoxelAtP(x_b, y_b, z_b, x_v_floor + dx_v - (dim == 0), y_v_floor + dy_v - (dim == 1), z_v_floor + dz_v - (dim == 2), block_addr, cache); bool valid = false; if (voxel_ptr_k_plus && voxel_ptr_k_plus->GetWeight() > 0) { normal_ptr[dim] += ratio * voxel_ptr_k_plus ->GetTSDF() / (2 * voxel_size); valid = true; } if (voxel_ptr_k_minus && voxel_ptr_k_minus->GetWeight() > 0) { normal_ptr[dim] -= ratio * voxel_ptr_k_minus ->GetTSDF() / (2 * voxel_size); valid = true; } sum_weight_normal += valid ? ratio : 0; } } // if (enable_normal) } // loop over 8 neighbors if (enable_color && sum_weight_color > 0) { sum_weight_color = 255.0; color_ptr[0] /= sum_weight_color; color_ptr[1] /= sum_weight_color; color_ptr[2] /= sum_weight_color; } if (enable_normal && sum_weight_normal > 0) { normal_ptr[0] /= sum_weight_normal; normal_ptr[1] /= sum_weight_normal; normal_ptr[2] /= sum_weight_normal; float norm = sqrt(normal_ptr[0] normal_ptr[0] + normal_ptr[1] * normal_ptr[1] + normal_ptr[2] * normal_ptr[2]); w2c_transform_indexer.Rotate( normal_ptr[0] / norm, normal_ptr[1] / norm, normal_ptr[2] / norm, normal_ptr + 0, normal_ptr + 1, normal_ptr + 2); } } // if (color or normal) } // if (tsdf < 0) }); }); #if defined(__CUDACC__) OPEN3D_CUDA_CHECK(cudaDeviceSynchronize()); #endif } } // namespace tsdf } // namespace kernel } // namespace geometry } // namespace t } // namespace open3d
preprocess.c	/* * preprocess.c * * Created on: 2018-3-29 * Author: qiushuang * * This file preprocesses De Bruijn graph: removing one-directed edge, indexing vertices with their location index, * using new index to replace the neighbors of vertices, splitting and gathering vertices to junctions and linear vertices / #include <omp.h> #include "../include/dbgraph.h" #include "../include/graph.h" #include "../include/comm.h" #include "../include/hash.h" #include "../include/preprocess.h" #include "../include/bitkmer.h" #include "../include/hash.h" #include "../include/malloc.h" #include "../include/share.h" #define CPU_THREADS 128 // for debugging extern thread_function shift_dictionary[]; #ifdef LITTLE_ENDIAN static const ull zerotable[8] = { 0xffffffffffffff00, 0xffffffffffff00ff, 0xffffffffff00ffff, 0xffffffff00ffffff, 0xffffff00ffffffff, 0xffff00ffffffffff, 0xff00ffffffffffff, 0xffffffffffffff}; #else static const ull zerotable[8] = { 0xffffffffffffff, 0xff00ffffffffffff, 0xffff00ffffffffff, 0xffffff00ffffffff, 0xffffffff00ffffff, 0xffffffffff00ffff, 0xffffffffffff00ff, 0xffffffffffffff00}; #endif extern long cpu_threads; extern float elem_factor; extern voff_t max_ss; extern int cutoff; ull send_linear = 0; ull send_junction = 0; ull receive_linear = 0; ull receive_junction = 0; ull reverse_flag = 0; ull stride_true = 0; static uint size_prime_index; // for hash table lookup static goffset_t * id_offsets; // used to assign global id for each node in subgraphs static goffset_t * jid_offset; // junction vertex id offsets, used to calculate id of each vertex from its index static kmer_t * kmers; // temporary kmers for fast kmer binary search in assigning neighbor ids static vertex_t * vertices; // vertex structure static voff_t * jvalid; // freed after filtering static voff_t * lvalid; // freed after filtering static int * id2index; // partition id to the index of partition list static voff_t * send_offsets; // used to locate the write position of messages for each partition in send buffer static voff_t * receive_offsets; static voff_t * extra_send_offsets; static voff_t * send_offsets_th; static voff_t * tmp_send_offsets_th; static voff_t * index_offsets; extern int lock_flag[NUM_OF_PROCS]; extern float push_offset_time[NUM_OF_PROCS]; extern float push_time[NUM_OF_PROCS]; extern float pull_intra_time[NUM_OF_PROCS]; extern float pull_inter_time[NUM_OF_PROCS]; static void * send; static void * receive; // ********** the following are used for output junctions and linear vertices static kmer_t * jkmers; // for output sorted junction kmers //static kmer_t * lkmers; // for output sorted linear kmers static edge_type * post_edges; // for output sorted post edges of linear vertices static edge_type * pre_edges; // for output sorted pre edges of linear vertices static vid_t * posts; // for output post neighbor of a linear vertex static vid_t * pres; // for output pre neighbors of linear vertices static vid_t * adj_nbs[EDGE_DIC_SIZE]; // for output neigbhors of junctions static ull * spids; // for output shared pids of neighbors of kmers static ull * spidsr; // for output shared pids of neighbors of reverse complements static uint * spidlv; // for output shared pids of post and pre of linear vertices static ull * junct_edges; // for output edges of junctions static voff_t not_found[CPU_THREADS]; voff_t gmax_lsize = 0; voff_t gmax_jsize = 0; #define get_reverse_edge(edge, kmer) { \ edge = (kmer.x >> (KMER_UNIT_BITS - 2)) ^ 0x3; } static void set_globals_filter_cpu (dbmeta_t * dbm) { vertices = dbm->vs; jvalid = dbm->jvld; lvalid = dbm->lvld; jid_offset = dbm->jid_offset; id_offsets = dbm->id_offsets; send = dbm->comm.send; } static void set_kmer_for_host_pull (dbmeta_t * dbm) { kmers = dbm->nds.kmer; } static void set_pull_push_receive (comm_t * cm) { receive = cm->receive; } static void set_globals_preprocessing (dbmeta_t * dbm, int num_of_partitions) { send_offsets = dbm->comm.send_offsets; receive_offsets = dbm->comm.receive_offsets; send = dbm->comm.send; id2index = dbm->comm.id2index; index_offsets = dbm->comm.index_offsets; send_offsets_th = (voff_t) malloc (sizeof(voff_t) (num_of_partitions+1) * (cpu_threads+1)); CHECK_PTR_RETURN (send_offsets_th, "malloc local send offsets for multi-threads in push mssg offset error!\n"); memset (send_offsets_th, 0, sizeof(voff_t) * (num_of_partitions+1) * (cpu_threads+1)); tmp_send_offsets_th = (voff_t) malloc (sizeof(voff_t) (num_of_partitions+1) * (cpu_threads+1)); CHECK_PTR_RETURN (send_offsets_th, "malloc tmp send offsets for multi-threads in push mssg offset error!\n"); memset (tmp_send_offsets_th, 0, sizeof(voff_t) * (num_of_partitions+1) * (cpu_threads+1)); } void init_preprocessing_data_cpu (dbmeta_t * dbm, int num_of_partitions) { set_globals_preprocessing (dbm, num_of_partitions); } static void set_globals_gather (dbmeta_t * dbm) { int i; for (i=0; i<EDGE_DIC_SIZE; i++) { adj_nbs[i] = dbm->djs.nbs[i]; } posts = dbm->dls.posts; pres = dbm->dls.pres; jkmers = dbm->djs.kmers; // lkmers = dbm->dls.kmers; post_edges = dbm->dls.post_edges; pre_edges = dbm->dls.pre_edges; junct_edges = dbm->djs.edges; spids = dbm->djs.spids; spidsr = dbm->djs.spidsr; spidlv = dbm->dls.spids; } void reset_globals_gather_cpu (dbmeta_t * dbm) { set_globals_gather (dbm); } static void release_globals_cpu (void) { free(send_offsets_th); free(tmp_send_offsets_th); } void finalize_preprocessing_data_cpu (void) { release_globals_cpu(); } static void init_kmers (uint size, voff_t index_offset) { entry_t * buf = (entry_t ) send; int r; #pragma omp parallel for for (r=0; r<size; r++) { int index = r; if (buf[index].occupied) { lvalid[index+1] = 1; } } } static void gather_vs (uint size, voff_t index_offset, entry_t send) { entry_t * buf = (entry_t ) send; vertex_t vs = vertices + index_offset; int r; #pragma omp parallel for for (r=0; r<size; r++) { int index = r; if (buf[index].occupied) { vs[lvalid[index]].kmer = buf[index].kmer; vs[lvalid[index]].edge = buf[index].edge; vs[lvalid[index]].vid = buf[index].occupied;//2 } } } static void gather_vs_sorted (uint size, voff_t index_offset, entry_t * send) { entry_t * buf = send; vertex_t * vs = vertices + index_offset; int r; #pragma omp parallel for for (r=0; r<size; r++) { int index = r; vs[index].kmer = buf[index].kmer; vs[index].edge = buf[index].edge; vs[index].vid = buf[index].occupied;//2 } } static void set_mssg_offset_buffer (dbmeta_t * dbm) { extra_send_offsets = dbm->comm.extra_send_offsets; } void init_binary_data_cpu (int did, master_t * mst, dbmeta_t * dbm, dbtable_t * tbs) { int * num_partitions = mst->num_partitions; int * partition_list = mst->partition_list; int num_of_partitions = num_partitions[did+1]-num_partitions[did]; // number of partitions in this processor int total_num_partitions = mst->total_num_partitions; // total number of partitions in this compute node voff_t * index_offset = mst->index_offset[did]; int world_size = mst->world_size; int world_rank = mst->world_rank; int np_per_node = (total_num_partitions + world_size - 1)/world_size; int start_partition_id = np_per_nodeworld_rank; set_globals_filter_cpu (dbm); set_mssg_offset_buffer (dbm); int i; voff_t offset = 0; for (i=0; i<num_of_partitions; i++) { int poffset = num_partitions[did]; int pid = partition_list[poffset+i] - start_partition_id; // !!!be careful here, this pid is not the global partition id int pindex = mst->id2index[did][pid + start_partition_id]; if (pindex != i) { printf ("ERROR IN DISTRIBUTING PARTITIONS!!!!!!!!\n"); exit(0); } voff_t size = tbs[pid].size; memset (dbm->lvld, 0, sizeof(vid_t) (size+1)); memcpy(dbm->comm.send, tbs[pid].buf, sizeof(entry_t) * size); init_kmers (size, offset); // inclusive_prefix_sum (dbm->lvld, size+1); tbb_scan_uint (dbm->lvld, dbm->lvld, size+1); offset = dbm->lvld[size]; gather_vs (size, index_offset[i], (entry_t)(dbm->comm.send)); if (offset > max_ss) { printf ("error!!!!!!\n"); exit(0); } tbb_vertex_sort (dbm->vs + index_offset[i], offset); index_offset[i+1] = index_offset[i] + offset; free (tbs[pid].buf); } // printf ("index offset on CPU %d: \n", did); // print_offsets(index_offset, num_of_partitions); } void init_binary_data_cpu_sorted (int did, master_t mst, dbmeta_t * dbm, dbtable_t * tbs) { int * num_partitions = mst->num_partitions; int * partition_list = mst->partition_list; int num_of_partitions = num_partitions[did+1]-num_partitions[did]; // number of partitions in this processor int total_num_partitions = mst->total_num_partitions; // total number of partitions in this compute node voff_t * index_offset = mst->index_offset[did]; int world_size = mst->world_size; int world_rank = mst->world_rank; int np_per_node = (total_num_partitions + world_size - 1)/world_size; int start_partition_id = np_per_nodeworld_rank; set_globals_filter_cpu (dbm); set_mssg_offset_buffer (dbm); int i; for (i=0; i<num_of_partitions; i++) { int poffset = num_partitions[did]; int pid = partition_list[poffset+i] - start_partition_id; // !!!be careful here, this pid is not the global partition id int pindex = mst->id2index[did][pid + start_partition_id]; if (pindex != i) { printf ("ERROR IN DISTRIBUTING PARTITIONS!!!!!!!!\n"); exit(0); } voff_t size = tbs[pid].size; gather_vs_sorted (size, index_offset[i], tbs[pid].buf); index_offset[i+1] = index_offset[i] + size; free (tbs[pid].buf); } // printf ("index offset on CPU %d: \n", did); // print_offsets(index_offset, num_of_partitions+1); } static int binary_search_vertex (vertex_t vs, kmer_t * akmer, uint size) { int begin = 0; int end = size - 1; int index = (begin + end) / 2; int ret; while (begin <= end) { ret = compare_2kmers_cpu (&vs[index].kmer, akmer); if (ret == 0) return index; else if (ret < 0) { end = index - 1; } else if (ret > 0) { begin = index + 1; } index = (begin + end) / 2; } // printf ("!!!!!!!!!!!!! Error occurs here: %u, %u\n", akmer->x, akmer->y); return -1; } static int lookup_with_hash_cpu (hashval_t hashval, kmer_t * akmer, kmer_t * kmers, hashsize_t size, int pid) { hashval_t index, hash2; uint i; index = hashtab_mod_cpu (hashval, size_prime_index[pid]); if (index >= size) { printf ("index %u is larger than size %u\n", index, size); return -1; } kmer_t * entry = kmers + index; if (is_equal_kmer_cpu(entry, akmer)) { return index; } hash2 = hashtab_mod_m2_cpu (hashval, size_prime_index[pid]); for (i=0; i<size; i++) { index += hash2; if (index >= size) index -= size; entry = kmers + index; if (is_equal_kmer_cpu(entry, akmer)) { return index; } } return -1; } static int lookup_kmer_assign_source_id_binary (assid_t * mssg, vertex_t * vs, uint size, uint * not_found) { edge_type edge; int stride; edge = (mssg->code >> (82)) & 0xff; if (edge > 3) { printf ("Encoded edge error!!!!!!!!!! %u\n", edge); exit (0); } int index = binary_search_vertex (vs, &mssg->dst, size); if (mssg->code & REVERSE_FLAG) { stride = EDGE_DIC_SIZE / 2; } else { stride = 0; } if (index==-1) { return -1; } else { vs[index].nbs[edge + stride] = mssg->srcid; / int pid = query_partition_id_from_idoffsets(mssg->srcid, 32, id_offsets); if (mssg->srcid >= id_offsets[pid] && mssg->srcid < id_offsets[pid] + jid_offset[pid]) // a junction id receive_junction++; else receive_linear++;/ } return 0; } static int lookup_kmer_set_edge_zero_binary (shakehands_t mssg, vertex_t * vs, uint size, uint * not_found) { edge_type edge; int stride; edge = (mssg->code >> (82)) & 0xff; if (edge > 3) { printf ("Encoded edge error!!!!!!!!!! %u\n", edge); exit (0); } int index = binary_search_vertex (vs, &mssg->dst, size); if (mssg->code & REVERSE_FLAG) { stride = EDGE_DIC_SIZE / 2; } else { stride = 0; } if (index==-1) { return -1; } else { atomic_and (&vs[index].edge, zerotable[edge+stride]); } return 0; } static void init_hashtab_cpu (uint size, voff_t index_offset) { vertex_t vs = vertices + index_offset; entry_t * buf = (entry_t )send; kmer_t local_kmers = kmers + index_offset; int r; for (r = 0; r < size; r++) { int index = r; if (buf[index].occupied) { if (buf[index].occupied != 2) { printf ("ERROR IN INPUT DATA!!!!!!!!!!!!\n"); exit (0); } vs[index].kmer = buf[index].kmer; vs[index].edge = buf[index].edge; vs[index].vid = buf[index].occupied; local_kmers[index] = buf[index].kmer; } } } void init_hashtab_data_cpu (int did, master_t * mst, dbmeta_t * dbm, dbtable_t * tbs) { int * num_partitions = mst->num_partitions; int * partition_list = mst->partition_list; int num_of_partitions = num_partitions[did+1]-num_partitions[did]; // number of partitions in this processor int total_num_partitions = mst->total_num_partitions; // total number of partitions in this compute node voff_t * index_offset = mst->index_offset[did]; int world_size = mst->world_size; int world_rank = mst->world_rank; int np_per_node = (total_num_partitions + world_size - 1)/world_size; int start_partition_id = np_per_nodeworld_rank; size_prime_index = (uint ) malloc (sizeof(uint) * num_of_partitions); set_globals_filter_cpu (dbm); set_kmer_for_host_pull (dbm); int i; voff_t offset = 0; for (i=0; i<num_of_partitions; i++) { int poffset = num_partitions[did]; int pid = partition_list[poffset+i] - start_partition_id; int pindex = mst->id2index[did][pid+start_partition_id]; if (pindex != i) { printf ("ERROR IN DISTRIBUTING PARTITIONS!!!!!!!!\n"); // unsorted distribution // exit(0); } voff_t size = tbs[pid].size; // printf ("partition size of hash table %d: %u\n", pid+start_partition_id, size); memcpy(dbm->comm.send, tbs[pid].buf, sizeof(entry_t) * size); // init_hashtab (size, offset); init_hashtab_cpu (size, offset); index_offset[i] = offset; offset += size; uint num_of_elems = tbs[pid].num_elems; size_prime_index[i] = higher_prime_index (num_of_elems * elem_factor); // printf ("num_of_elems = %u, size_prime_index[%d]= %u\n", num_of_elems, i, size_prime_index[i]); free (tbs[pid].buf); } index_offset[i] = offset; // printf ("index offset on CPU %d: \n", did); // print_offsets(index_offset, num_of_partitions); } void finalize_hashtab_data_cpu (void) { free (size_prime_index); } static int lookup_kmer_assign_source_id_cpu2 (assid_t mssg, vertex_t * vs, kmer_t * kmers, uint size, int pindex, uint * not_found) { int edge; int stride; edge = (mssg.code >> (82)) && 0xff; if (edge > 3) { printf ("Encoded edge error!!!!!!!!!! %u\n", edge); exit (0); } hashval_t seed = DEFAULT_SEED; hashval_t hash = murmur_hash3_32 ((uint )&mssg.dst, seed); int index = lookup_with_hash_cpu (hash, &mssg.dst, kmers, size, pindex); if (mssg.code >> (83)) { stride = EDGE_DIC_SIZE / 2; } else { stride = 0; } if (index==-1) { (not_found)++; return -1; } else { vs[index].nbs[edge + stride] = mssg.srcid; } return 0; } static int get_adj_id_from_post (kmer_t * kmer, edge_type edge, int k, int p, int num_of_partitions) { if (edge>=4) printf("Error in getting adj id from post: edge must be a number in [0-3]!\n"); minstr_t minpstr = 0, rminpstr = 0; minstr_t curr = 0; minstr_t pstr = 0, rpstr = 0; unit_kmer_t * ptr; kmer_t node[2]; node[0].x = kmer->x; node[0].y = kmer->y; #ifdef LONG_KMER node[0].z = kmer->z; node[0].w = kmer->w; #endif kmer_32bit_left_shift (&node[0], 2); ptr = (unit_kmer_t )(&node[0]) + (k 2) / KMER_UNIT_BITS; ptr \|= ((unit_kmer_t)edge) << (KMER_UNIT_BITS - (k 2) % KMER_UNIT_BITS); get_reverse_kmer (&node[0], &node[1], k); /* get first minimum p-substring / get_first_pstr ((unit_kmer_t )&node[0], &pstr, p); get_first_pstr ((unit_kmer_t )&node[1], &rpstr, p); minpstr = pstr; rminpstr = rpstr; int j; for (j = 1; j < k - p + 1; j++) { right_shift_pstr ((unit_kmer_t )&node[0], &pstr, p, j); right_shift_pstr ((unit_kmer_t )&node[1], &rpstr, p, j); if (pstr < minpstr) minpstr = pstr; if (rpstr < rminpstr) rminpstr = rpstr; } curr = rminpstr < minpstr ? rminpstr : minpstr; msp_id_t mspid = get_partition_id_cpu (curr, p, num_of_partitions); return mspid; } static int get_adj_id_from_pre (kmer_t kmer, edge_type edge, int k, int p, int num_of_partitions) { if (edge>=4) printf("Error in getting adj id from post: edge must be a number in [0-3]!\n"); minstr_t minpstr = 0, rminpstr = 0; minstr_t curr = 0; minstr_t pstr = 0, rpstr = 0; unit_kmer_t * ptr; kmer_t node[2]; node[0].x = kmer->x; node[0].y = kmer->y; #ifdef LONG_KMER node[0].z = kmer->z; node[0].w = kmer->w; #endif get_reverse_kmer (&node[0], &node[1], k); kmer_32bit_left_shift (&node[1], 2); ptr = (unit_kmer_t )(&node[1]) + (k2)/KMER_UNIT_BITS; ptr \|= ((unit_kmer_t)edge) << (KMER_UNIT_BITS - (k2)%KMER_UNIT_BITS); get_reverse_kmer (&node[1], &node[0], k); /* get first minimum p-substring / get_first_pstr ((unit_kmer_t )&node[0], &pstr, p); get_first_pstr ((unit_kmer_t )&node[1], &rpstr, p); minpstr = pstr; rminpstr = rpstr; int j; for (j = 1; j < k - p + 1; j++) { right_shift_pstr ((unit_kmer_t )&node[0], &pstr, p, j); right_shift_pstr ((unit_kmer_t )&node[1], &rpstr, p, j); if (pstr < minpstr) minpstr = pstr; if (rpstr < rminpstr) rminpstr = rpstr; } curr = rminpstr < minpstr ? rminpstr : minpstr; msp_id_t mspid = get_partition_id_cpu (curr, p, num_of_partitions); return mspid; } static void get_adj_mssg_from_post (kmer_t kmer, edge_type edge, int k, assid_t * mssg, msp_id_t pid) { if (edge>=4) printf("Error in getting adj id from post: edge must be a number in [0-3]!\n"); uint seed = DEFAULT_SEED; unit_kmer_t * ptr; kmer_t node[2]; edge_type edges[2]; edges[0] = edge; // edges[0] from node[0] node[0].x = kmer->x; node[0].y = kmer->y; #ifdef LONG_KMER node[0].z = kmer->z; node[0].w = kmer->w; #endif get_reverse_edge (edges[1], node[0]); // edges[1] from node[1] kmer_32bit_left_shift (&node[0], 2); ptr = (unit_kmer_t )(&node[0]) + (k 2) / KMER_UNIT_BITS; ptr \|= ((unit_kmer_t)edge) << (KMER_UNIT_BITS - (k 2) % KMER_UNIT_BITS); get_reverse_kmer (&node[0], &node[1], k); int flag; hashval_t hash[2]; hash[0] = murmur_hash3_32 ((uint )&node[0], seed); hash[1] = murmur_hash3_32 ((uint )&node[1], seed); if (hash[0] == hash[1]) { int ret = compare_2kmers_cpu (&node[0], &node[1]); if (ret >= 0) flag = 0; else flag = 1; } else if (hash[0] < hash[1]) flag = 0; else flag = 1; mssg->dst = node[flag]; mssg->code = 0; if (flag == 0) { mssg->code = (((uint)edges[1]) << (82)) \| REVERSE_FLAG \| pid; reverse_flag++; } else mssg->code = (((uint)edges[1]) << (82)) \| pid; } static void get_adj_mssg_from_pre (kmer_t * kmer, edge_type edge, int k, assid_t * mssg, msp_id_t pid) { if (edge>=4) printf("Error in getting adj id from post: edge must be a number in [0-3]!\n"); uint seed = DEFAULT_SEED; unit_kmer_t * ptr; kmer_t node[2]; edge_type edges[2]; edges[1] = edge; // edges[1] from kmer - node[1] node[0].x = kmer->x; node[0].y = kmer->y; #ifdef LONG_KMER node[0].z = kmer->z; node[0].w = kmer->w; #endif get_reverse_kmer (&node[0], &node[1], k); get_reverse_edge (edges[0], node[1]); // edges[0] from kmer node[0] kmer_32bit_left_shift (&node[1], 2); ptr = (unit_kmer_t )(&node[1]) + (k2)/KMER_UNIT_BITS; ptr \|= ((unit_kmer_t)edge) << (KMER_UNIT_BITS - (k2)%KMER_UNIT_BITS); get_reverse_kmer (&node[1], &node[0], k); int flag; hashval_t hash[2]; hash[0] = murmur_hash3_32 ((uint )&node[0], seed); hash[1] = murmur_hash3_32 ((uint )&node[1], seed); if (hash[0] == hash[1]) { int ret = compare_2kmers_cpu (&node[0], &node[1]); if (ret >= 0) flag = 0; else flag = 1; } else if (hash[0] < hash[1]) flag = 0; else flag = 1; mssg->dst = node[flag]; mssg->code = 0; if (flag==1) { mssg->code = (((uint)edges[0]) << (82)) \| REVERSE_FLAG \| pid; reverse_flag++; } else mssg->code = (((uint)edges[0]) << (82)) \| pid; } static void push_mssg_offset_shakehands_cpu (voff_t size, int num_of_partitions, voff_t index_offset, int k, int p) { int nump = omp_get_num_procs(); #pragma omp parallel num_threads(cpu_threads) { int nth = omp_get_num_threads(); if (nth != cpu_threads) { printf ("warning: setting cpu threads failed! real number of threads: %d\n", nth); // exit(0); } voff_t size_per_th = (size + nth - 1)/nth; if (size_per_th <= nth) size_per_th = size/nth; voff_t size_th; int thid = omp_get_thread_num(); if (thid == nth-1) { size_th = size - size_per_th * (nth - 1); } else size_th = size_per_th; vertex_t * local_vs = vertices + index_offset + thid * size_per_th; voff_t * local_send_offsets = send_offsets_th + (thid+1) * (num_of_partitions+1); uint r; for(r = 0; r < size_th; r++) { int index = r; int pindex; int i; for (i = 0; i < EDGE_DIC_SIZE / 2; i++) { if ((local_vs[index].edge >> (i8) & 0xff) >= cutoff) { local_vs[index].nbs[i] = get_adj_id_from_post (&local_vs[index].kmer, (edge_type) i, k, p, num_of_partitions); if (local_vs[index].nbs[i] < 0 \|\| local_vs[index].nbs[i] >= num_of_partitions) { printf ("ERROR IN GETTING MSP ID!!!!!!\n"); } pindex = id2index[local_vs[index].nbs[i]]; local_send_offsets[pindex+1]++; } else local_vs[index].nbs[i] = DEADEND; if ((local_vs[index].edge >> ((EDGE_DIC_SIZE / 2 + i) 8) & 0xff) >= cutoff) { local_vs[index].nbs[EDGE_DIC_SIZE / 2 + i] = get_adj_id_from_pre (&local_vs[index].kmer, (edge_type) i, k, p, num_of_partitions); if (local_vs[index].nbs[EDGE_DIC_SIZE / 2 + i] < 0 \|\| local_vs[index].nbs[EDGE_DIC_SIZE / 2 + i] >= num_of_partitions) { printf ("ERROR IN GETTING MSP ID!!!!!!\n"); } pindex = id2index[local_vs[index].nbs[EDGE_DIC_SIZE / 2 + i]]; local_send_offsets[pindex+1]++; } else local_vs[index].nbs[EDGE_DIC_SIZE / 2 + i] = DEADEND; // dead end branch } } } } static void push_mssg_shakehands_cpu (voff_t size, int num_of_partitions, voff_t index_offset, int k, int p, int curr_id) { omp_set_num_threads(cpu_threads); #pragma omp parallel { int nth = omp_get_num_threads(); // printf ("PUSH MSSG OFFSET THREADS: %d!!!!!!!!!\n", nth); if (nth != cpu_threads) { printf ("warning: setting cpu threads failed! real number of threads: %d\n", nth); // exit(0); } uint size_per_th = (size + nth - 1)/nth; if (size_per_th <= nth) size_per_th = size/nth; uint size_th; int thid = omp_get_thread_num(); if (thid == nth-1) { size_th = size - size_per_th * (nth - 1); } else size_th = size_per_th; vertex_t * local_vs = vertices + index_offset + thid * size_per_th; voff_t * local_send_offsets = tmp_send_offsets_th + (thid+1) * (num_of_partitions+1); shakehands_t * buf = (shakehands_t ) send; uint r; for(r = 0; r < size_th; r++) { int index = r; int pindex; msp_id_t pid; voff_t local_offset; voff_t off; shakehands_t tmp; int i; for (i=0; i<EDGE_DIC_SIZE/2; i++) { if ((local_vs[index].edge >> (i8) & 0xff) >= cutoff) { pid = local_vs[index].nbs[i]; if (pid < 0 \|\| pid >= num_of_partitions) printf("ERRORRRRRRRRRRRR\n"); pindex = id2index[pid]; // local_offset = local_send_offsets[pindex+1]++; off = local_send_offsets[pindex+1] + send_offsets_th[thid(num_of_partitions+1)+(pindex+1)] + send_offsets[pindex]; local_send_offsets[pindex+1]++; get_adj_mssg_from_post (&local_vs[index].kmer, (edge_type)i, k, (assid_t)(&tmp), curr_id); buf[off] = tmp; } if ((local_vs[index].edge >> ((EDGE_DIC_SIZE / 2 + i) * 8) & 0xff) >= cutoff) { pid = local_vs[index].nbs[EDGE_DIC_SIZE / 2 + i]; if (pid < 0 \|\| pid >= num_of_partitions) printf("ERRORRRRRRRRRRRR\n"); pindex = id2index[pid]; // local_offset = local_send_offsets[pindex+1]++; off = local_send_offsets[pindex+1] + send_offsets_th[thid(num_of_partitions+1)+(pindex+1)] + send_offsets[pindex]; local_send_offsets[pindex+1]++; get_adj_mssg_from_pre (&local_vs[index].kmer, (edge_type)i, k, (assid_t)(&tmp), curr_id); buf[off] = tmp; } } } } } static void push_mssg_offset_respond_cpu (voff_t num_mssgs, int pid, voff_t psize, voff_t index_offset, int num_of_partitions, voff_t receive_start, bool intra_inter, int k, int p) { omp_set_num_threads(cpu_threads); #pragma omp parallel { int nth = omp_get_num_threads(); if (nth != cpu_threads) { printf ("warning: setting cpu thread number failed!\n"); // exit(0); } uint size_per_th = (num_mssgs + nth - 1)/nth; if (size_per_th <= nth) size_per_th = num_mssgs/nth; uint size_th; int thid = omp_get_thread_num(); if (thid == nth-1) { size_th = num_mssgs - size_per_th * (nth - 1); } else size_th = size_per_th; shakehands_t * buf; voff_t * local_send_offsets = send_offsets_th + (thid+1) * (num_of_partitions+1); if (intra_inter) { int pindex = id2index[pid]; buf = (shakehands_t )send + receive_start + send_offsets[pindex] + thid size_per_th; } else { int pindex = id2index[pid]; buf = (shakehands_t )send + receive_start + receive_offsets[pindex] + thid size_per_th; } vertex_t * local_vs = vertices + index_offset; voff_t r; for (r=0; r<size_th; r++) { int index=r; shakehands_t tmp = buf[index]; int thid = omp_get_thread_num (); int ret = binary_search_vertex (local_vs, &buf[index].dst, psize); int match = 0; if (ret != -1) { edge_type edge = (tmp.code >> (82)) & 0xff; int stride; if (tmp.code >> (83)) { stride = EDGE_DIC_SIZE / 2; } else { stride = 0; } if ((local_vs[ret].edge >> ((stride + edge) * 8) & 0xff) < cutoff) { match = -1; } } if (ret == -1 \|\| match == -1) { msp_id_t pid = tmp.code & ID_BITS; int pindex = id2index[pid]; local_send_offsets[pindex+1]++; } } } } static void push_mssg_respond_cpu (uint num_mssgs, int pid, voff_t psize, voff_t index_offset, int num_of_partitions, voff_t receive_start, bool intra_inter, int k, int p) { omp_set_num_threads(cpu_threads); #pragma omp parallel { int nth = omp_get_num_threads(); if (nth != cpu_threads) { printf ("warning: setting cpu thread number failed!\n"); // exit(0); } uint size_per_th = (num_mssgs + nth - 1)/nth; if (size_per_th <= nth) size_per_th = num_mssgs/nth; uint size_th; int thid = omp_get_thread_num(); if (thid == nth-1) { size_th = num_mssgs - size_per_th * (nth - 1); } else size_th = size_per_th; shakehands_t * buf; shakehands_t * vs = (shakehands_t )receive; voff_t local_offsets = extra_send_offsets; voff_t * local_send_offsets = tmp_send_offsets_th + (thid+1) * (num_of_partitions+1); if (intra_inter) { int pindex = id2index[pid]; buf = (shakehands_t )send + receive_start + send_offsets[pindex] + thid size_per_th; } else { int pindex = id2index[pid]; buf = (shakehands_t )send + receive_start + receive_offsets[pindex] + thid size_per_th; } vertex_t * local_vs = vertices + index_offset; voff_t r; for (r=0; r<size_th; r++) { int index=r; shakehands_t tmp = buf[index]; edge_type edge = (tmp.code >> (82)) & 0xff; int stride; if (tmp.code >> (83)) { stride = EDGE_DIC_SIZE / 2; } else { stride = 0; } int thid = omp_get_thread_num (); int mspid; int ret = binary_search_vertex (local_vs, &buf[index].dst, psize); int match = 0; if (ret != -1) { if ((local_vs[ret].edge >> ((stride + edge) * 8) & 0xff) < cutoff) { match = -1; } } if (ret == -1 \|\| match == -1) { mspid = tmp.code & ID_BITS; if (stride == 0) get_adj_mssg_from_post (&tmp.dst, edge, k, (assid_t)(&tmp), mspid); else get_adj_mssg_from_pre (&tmp.dst, edge, k, (assid_t)(&tmp), mspid); int pindex = id2index[mspid]; voff_t local_send_offset = local_send_offsets[pindex+1]++; off_t off = local_send_offset + send_offsets_th[thid(num_of_partitions+1)+(pindex+1)] + local_offsets[pindex]; vs[off] = tmp; } } } } static void pull_mssg_respond_cpu (uint num_mssgs, int pid, voff_t psize, voff_t index_offset, void local_receive, bool intra_inter) { int pindex = id2index[pid]; shakehands_t * buf; if (intra_inter) // true if intra partitions { buf = (shakehands_t )local_receive + extra_send_offsets[pindex]; } else { buf = (shakehands_t )local_receive + receive_offsets[pindex]; } vertex_t * local_vs = vertices + index_offset; int r; #pragma omp parallel for num_threads(cpu_threads) for (r=0; r<num_mssgs; r++) { int index = r; int thid = omp_get_thread_num (); if (lookup_kmer_set_edge_zero_binary (&buf[index], local_vs, psize, &not_found[thid]) == -1) { printf ("RESPOND ERROR WITH SOURCE KMER: %u, %u, pindex=%d, pid=%d\n", buf[index].dst.x, buf[index].dst.y, pindex, pid); } } } static void push_mssg_offset_assign_id_cpu (voff_t size, int num_of_partitions, voff_t index_offset, int k, int p) { omp_set_num_threads(cpu_threads); #pragma omp parallel { int nth = omp_get_num_threads(); if (nth != cpu_threads) { printf ("warning: setting cpu threads failed! real number of threads: %d\n", nth); } voff_t size_per_th = (size + nth - 1)/nth; if (size_per_th <= nth) size_per_th = size/nth; voff_t size_th; int thid = omp_get_thread_num(); if (thid == nth-1) { size_th = size - size_per_th * (nth - 1); } else size_th = size_per_th; vertex_t * local_vs = vertices + index_offset + thid * size_per_th; voff_t * local_send_offsets = send_offsets_th + (thid+1) * (num_of_partitions+1); uint r; for(r = 0; r < size_th; r++) { int index = r; int pindex; int i; for (i = 0; i < EDGE_DIC_SIZE / 2; i++) { if ((local_vs[index].edge >> (i8) & 0xff) >= cutoff) { // local_vs[index].nbs[i] = get_adj_id_from_post (&local_vs[index].kmer, (edge_type) i, k, p, num_of_partitions); if (local_vs[index].nbs[i] > num_of_partitions) { printf ("ERROR IN GETTING MSP ID!!!!!!\n"); } pindex = id2index[local_vs[index].nbs[i]]; local_send_offsets[pindex+1]++; } // else // local_vs[index].nbs[i] = DEADEND; if ((local_vs[index].edge >> ((EDGE_DIC_SIZE / 2 + i) 8) & 0xff) >= cutoff) { // local_vs[index].nbs[EDGE_DIC_SIZE / 2 + i] = get_adj_id_from_pre (&local_vs[index].kmer, (edge_type) i, k, p, num_of_partitions); if (local_vs[index].nbs[EDGE_DIC_SIZE / 2 + i] > num_of_partitions) { printf ("ERROR IN GETTING MSP ID!!!!!!\n"); } pindex = id2index[local_vs[index].nbs[EDGE_DIC_SIZE / 2 + i]]; local_send_offsets[pindex+1]++; } // else // local_vs[index].nbs[EDGE_DIC_SIZE / 2 + i] = DEADEND; // dead end branch } } } } static void push_mssg_assign_id_cpu (uint size, int num_of_partitions, voff_t index_offset, int k, int p, int curr_id) { omp_set_num_threads(cpu_threads); #pragma omp parallel { int nth = omp_get_num_threads(); if (nth != cpu_threads) { printf ("warning: setting cpu threads failed! real number of threads: %d\n", nth); } uint size_per_th = (size + nth - 1)/nth; if (size_per_th <= nth) size_per_th = size/nth; uint size_th; int thid = omp_get_thread_num(); if (thid == nth-1) { size_th = size - size_per_th * (nth - 1); } else size_th = size_per_th; vertex_t * local_vs = vertices + index_offset + thid * size_per_th; voff_t * local_send_offsets = tmp_send_offsets_th + (thid+1) * (num_of_partitions+1); assid_t * buf = (assid_t ) send; uint r; for(r = 0; r < size_th; r++) { int index = r; int pindex; msp_id_t pid; voff_t local_offset; voff_t off; assid_t tmp; kmer_t reverse; int i; for (i=0; i<EDGE_DIC_SIZE/2; i++) { if ((local_vs[index].edge >> (i8) & 0xff) >= cutoff) { pid = local_vs[index].nbs[i]; if (pid < 0 \|\| pid > num_of_partitions) printf("ERRORRRRRRRRRRRR\n"); pindex = id2index[pid]; // local_offset = local_send_offsets[pindex+1]++; off = local_send_offsets[pindex+1] + send_offsets_th[thid(num_of_partitions+1)+(pindex+1)] + send_offsets[pindex]; local_send_offsets[pindex+1]++; get_adj_mssg_from_post (&local_vs[index].kmer, (edge_type)i, k, &tmp, pid); tmp.srcid = local_vs[index].vid - 1; // ************************* BE CAREFUL HERE !!!!!!!!!!! ********************* if (tmp.srcid >= 0 && tmp.srcid < jid_offset[curr_id]) // junction send_junction++; else send_linear++; buf[off] = tmp; } if ((local_vs[index].edge >> ((EDGE_DIC_SIZE / 2 + i) * 8) & 0xff) >= cutoff) { pid = local_vs[index].nbs[EDGE_DIC_SIZE / 2 + i]; if (pid < 0 \|\| pid > num_of_partitions) printf("ERRORRRRRRRRRRRR\n"); pindex = id2index[pid]; // local_offset = local_send_offsets[pindex+1]++; off = local_send_offsets[pindex+1] + send_offsets_th[thid(num_of_partitions+1)+(pindex+1)] + send_offsets[pindex]; local_send_offsets[pindex+1]++; get_adj_mssg_from_pre (&local_vs[index].kmer, (edge_type)i, k, &tmp, pid); tmp.srcid = local_vs[index].vid - 1; // ************************* BE CAREFUL HERE !!!!!!!!!!! ********************* if (tmp.srcid >= 0 && tmp.srcid < jid_offset[curr_id]) // junction send_junction++; else send_linear++; buf[off] = tmp; } } } } } static void pull_mssg_assign_id_cpu (uint num_mssgs, int pid, uint psize, voff_t index_offset, int num_of_partitions, voff_t receive_start, bool intra_inter) { assid_t * buf; int pindex = id2index[pid]; if (intra_inter) buf = (assid_t )send + receive_start + send_offsets[pindex]; else buf = (assid_t )send + receive_start + receive_offsets[pindex]; vertex_t * local_vs = vertices + index_offset; // kmer_t * local_kmer = kmers + index_offset; int r; #pragma omp parallel for num_threads(cpu_threads) for (r=0; r<num_mssgs; r++) { int index = r; assid_t tmp = buf[index]; msp_id_t id = tmp.code & ID_BITS; // CHECK // if (id != pid) // printf ("ERROR IN ID ENCODING! id = %d, pid = %d\n", id, pid); int thid = omp_get_thread_num (); // lookup_kmer_assign_source_id_cpu (tmp, local_vs, psize, pindex, &not_found[thid]); // assign the neigbhor id for kmer tmp.dst // if (lookup_kmer_assign_source_id_cpu2 (tmp, local_vs, local_kmer, psize, pindex, &not_found[thid]) == -1) if (lookup_kmer_assign_source_id_binary (&buf[index], local_vs, psize, &not_found[thid]) == -1) { printf ("CPU KMER NOT FOUND: %u, %u, pindex=%d, pid=%d\n", tmp.dst.x, tmp.dst.y, pindex, pid); // exit(0); } } } void * neighbor_push_intra_pull_cpu (void * arg) { evaltime_t start, end; pre_arg * carg = (pre_arg ) arg; comm_t cm = &carg->dbm->comm; master_t * mst = carg->mst; int did = carg->did; int k = carg->k; int p = carg->p; // int total_num_partitions = mst->num_partitions[num_of_cpus+num_of_devices]; int total_num_partitions = mst->total_num_partitions; int num_of_partitions = mst->num_partitions[did + 1] - mst->num_partitions[did]; int poffset = mst->num_partitions[did]; voff_t * index_offset = mst->index_offset[did]; if (mst->world_rank == 0) printf ("WORLD RANK %d: Neighboring push intra pull cpu:\n", mst->world_rank); memset(cm->send_offsets, 0, sizeof(voff_t) * (total_num_partitions + 1)); memset (send_offsets_th, 0, sizeof(voff_t) * (total_num_partitions+1) * (cpu_threads+1)); #ifdef MEASURE_TIME_ gettimeofday (&start, NULL); #endif int i; for (i=0; i<num_of_partitions; i++) { int pid = mst->partition_list[poffset+i]; voff_t size = index_offset[i+1] - index_offset[i]; push_mssg_offset_assign_id_cpu (size, total_num_partitions, index_offset[i], k, p); // a better version than above } #ifdef MEASURE_TIME_ gettimeofday (&end, NULL); push_offset_time[did] += (float)((end.tv_sec * 1000000 + end.tv_usec) - (start.tv_sec * 1000000 + start.tv_usec)) / 1000; print_exec_time (start, end, "***************** PUSH MSSG OFFSET FOR CPU ASSIGNING ID INTRA PROCESSOR TIME: "); #endif get_global_offsets (cm->send_offsets, send_offsets_th, total_num_partitions, (cpu_threads+1)); inclusive_prefix_sum (cm->send_offsets, total_num_partitions + 1); memset (tmp_send_offsets_th, 0, sizeof(voff_t) * (total_num_partitions+1) * (cpu_threads+1)); #ifdef MEASURE_TIME_ gettimeofday (&start, NULL); #endif for (i=0; i<num_of_partitions; i++) { int pid = mst->partition_list[poffset+i]; voff_t size = index_offset[i+1] - index_offset[i]; push_mssg_assign_id_cpu (size, total_num_partitions, index_offset[i], k, p, i); // a better version than above } #ifdef MEASURE_TIME_ gettimeofday (&end, NULL); push_time[did] += (float)((end.tv_sec * 1000000 + end.tv_usec) - (start.tv_sec * 1000000 + start.tv_usec)) / 1000; print_exec_time (start, end, "***************** PUSH MSSG FOR CPU ASSIGNING ID INTRA PROCESSOR TIME: "); #endif memcpy(mst->roff[did], cm->send_offsets, sizeof(voff_t)(total_num_partitions + 1)); voff_t inter_start = mst->roff[did][num_of_partitions]; voff_t inter_end = mst->roff[did][total_num_partitions]; mst->receive[did] = (assid_t )cm->send+inter_start; #ifndef SYNC_ALL2ALL_ if (atomic_set_value (&lock_flag[did], 1, 0) == false) printf("!!!!!!!!!!!!!!!!!! CAREFUL, SETTING VALUE DOES NOT WORK FINE!\n"); #endif memset (not_found, 0, sizeof(uint) * cpu_threads); #ifdef MEASURE_TIME_ gettimeofday (&start, NULL); #endif for (i=0; i<num_of_partitions; i++) { int pid = mst->partition_list[poffset + i]; voff_t num_mssgs = cm->send_offsets[i+1] - cm->send_offsets[i]; voff_t size = index_offset[i+1] - index_offset[i]; pull_mssg_assign_id_cpu (num_mssgs, pid, size, index_offset[i], total_num_partitions, 0, 1); // a better version } #ifdef MEASURE_TIME_ gettimeofday (&end, NULL); pull_intra_time[did] += (float)((end.tv_sec * 1000000 + end.tv_usec) - (start.tv_sec * 1000000 + start.tv_usec)) / 1000; print_exec_time (start, end, "***************** PULL MSSG FOR CPU ASSIGNING ID INTRA PROCESSOR TIME: "); #endif return ((void) 0); } void neighbor_inter_pull_cpu (void * arg) { evaltime_t start, end; pre_arg * carg = (pre_arg ) arg; comm_t cm = &carg->dbm->comm; master_t * mst = carg->mst; int num_of_cpus = mst->num_of_cpus; int num_of_devices = mst->num_of_devices; int did = carg->did; int total_num_partitions = mst->total_num_partitions; int num_of_partitions = mst->num_partitions[did + 1] - mst->num_partitions[did]; voff_t * index_offset = mst->index_offset[did]; if (mst->world_rank == 0) printf ("WORLD RANK %d: Neighboring inter pull cpu:\n", mst->world_rank); voff_t receive_start = mst->roff[did][num_of_partitions]; memcpy(cm->receive_offsets, mst->soff[did], sizeof(voff_t) * (num_of_partitions + 1)); voff_t inter_size = mst->soff[did][num_of_partitions]; if(inter_size == 0) return ((void) 0); memcpy((assid_t)cm->send + receive_start, mst->send[did], sizeof(assid_t) * inter_size); int poffset = mst->num_partitions[did]; int i; #ifdef MEASURE_TIME_ gettimeofday (&start, NULL); #endif for (i=0; i<num_of_partitions; i++) { int pid = mst->partition_list[poffset + i]; voff_t num_mssgs = cm->receive_offsets[i+1] - cm->receive_offsets[i]; voff_t size = index_offset[i+1] - index_offset[i]; pull_mssg_assign_id_cpu (num_mssgs, pid, size, index_offset[i], total_num_partitions, receive_start, 0); } #ifdef MEASURE_TIME_ gettimeofday (&end, NULL); pull_inter_time[did] += (float)((end.tv_sec * 1000000 + end.tv_usec) - (start.tv_sec * 1000000 + start.tv_usec)) / 1000; print_exec_time (start, end, "***************** PULL MSSG FOR CPU NEIGHBORING INTER PROCESSORS TIME: "); #endif return ((void ) 0); } void shakehands_push_respond_intra_push_cpu (void * arg) { evaltime_t start, end; pre_arg * carg = (pre_arg ) arg; comm_t cm = &carg->dbm->comm; master_t * mst = carg->mst; int did = carg->did; int k = carg->k; int p = carg->p; int total_num_partitions = mst->total_num_partitions; int num_of_partitions = mst->num_partitions[did + 1] - mst->num_partitions[did]; int poffset = mst->num_partitions[did]; voff_t * index_offset = mst->index_offset[did]; if (mst->world_rank == 0) printf ("WORLD RANK %d: shakehands push respond intra push cpu:\n", mst->world_rank); memset(cm->send_offsets, 0, sizeof(voff_t) * (total_num_partitions + 1)); memset (send_offsets_th, 0, sizeof(voff_t) * (total_num_partitions+1) * (cpu_threads+1)); #ifdef MEASURE_TIME_ gettimeofday (&start, NULL); #endif int i; for (i=0; i<num_of_partitions; i++) { int pid = mst->partition_list[poffset+i]; voff_t size = index_offset[i+1] - index_offset[i]; push_mssg_offset_shakehands_cpu (size, total_num_partitions, index_offset[i], k, p); // a better version than above } #ifdef MEASURE_TIME_ gettimeofday (&end, NULL); push_offset_time[did] += (float)((end.tv_sec * 1000000 + end.tv_usec) - (start.tv_sec * 1000000 + start.tv_usec)) / 1000; print_exec_time (start, end, "***************** PUSH MSSG OFFSET FOR CPU SHAKEHANDS INTRA PROCESSOR TIME: "); #endif get_global_offsets (cm->send_offsets, send_offsets_th, total_num_partitions, (cpu_threads+1)); inclusive_prefix_sum (cm->send_offsets, total_num_partitions + 1); memset (tmp_send_offsets_th, 0, sizeof(voff_t) * (total_num_partitions+1) * (cpu_threads+1)); #ifdef MEASURE_TIME_ gettimeofday (&start, NULL); #endif for (i=0; i<num_of_partitions; i++) { int pid = mst->partition_list[poffset+i]; voff_t size = index_offset[i+1] - index_offset[i]; push_mssg_shakehands_cpu (size, total_num_partitions, index_offset[i], k, p, pid); // a better version than above } #ifdef MEASURE_TIME_ gettimeofday (&end, NULL); push_time[did] += (float)((end.tv_sec * 1000000 + end.tv_usec) - (start.tv_sec * 1000000 + start.tv_usec)) / 1000; print_exec_time (start, end, "***************** PUSH MSSG FOR CPU SHAKEHANDS INTRA PROCESSOR TIME: "); #endif memcpy(mst->roff[did], cm->send_offsets, sizeof(voff_t)(total_num_partitions + 1)); voff_t inter_start = mst->roff[did][num_of_partitions]; voff_t inter_end = mst->roff[did][total_num_partitions]; mst->receive[did] = (shakehands_t )cm->send+inter_start; #ifndef SYNC_ALL2ALL_ if (atomic_set_value (&lock_flag[did], 1, 0) == false) printf("!!!!!!!!!!!!!!!!!! CAREFUL, SETTING VALUE DOES NOT WORK FINE!\n"); #endif memset (cm->extra_send_offsets, 0, sizeof(voff_t) * (total_num_partitions+1)); memset (send_offsets_th, 0, sizeof(voff_t) * (total_num_partitions+1) * (cpu_threads+1)); memset (not_found, 0, sizeof(uint) * cpu_threads); #ifdef MEASURE_TIME_ gettimeofday (&start, NULL); #endif for (i=0; i<num_of_partitions; i++) { int pid = mst->partition_list[poffset + i]; voff_t num_mssgs = cm->send_offsets[i+1] - cm->send_offsets[i]; voff_t size = index_offset[i+1] - index_offset[i]; push_mssg_offset_respond_cpu (num_mssgs, pid, size, index_offset[i], total_num_partitions, 0, 1, k, p); // a better version } #ifdef MEASURE_TIME_ gettimeofday (&end, NULL); pull_intra_time[did] += (float)((end.tv_sec * 1000000 + end.tv_usec) - (start.tv_sec * 1000000 + start.tv_usec)) / 1000; print_exec_time (start, end, "***************** PUSH RESPOND OFFSET CPU INTRA PROCESSOR TIME: "); #endif return ((void) 0); } void shakehands_pull_respond_inter_push_intra_pull_cpu (void * arg) { evaltime_t start, end; pre_arg * carg = (pre_arg ) arg; comm_t cm = &carg->dbm->comm; master_t * mst = carg->mst; int num_of_cpus = mst->num_of_cpus; int num_of_devices = mst->num_of_devices; int did = carg->did; int k = carg->k; int p = carg->p; int total_num_partitions = mst->total_num_partitions; int num_of_partitions = mst->num_partitions[did + 1] - mst->num_partitions[did]; int poffset = mst->num_partitions[did]; voff_t * index_offset = mst->index_offset[did]; if (mst->world_rank == 0) printf ("WORLD RANK %d: Shakehands pull respond update inter push intra pull cpu:\n", mst->world_rank); voff_t receive_start = cm->send_offsets[num_of_partitions]; memcpy(cm->receive_offsets, mst->soff[did], sizeof(voff_t) * (num_of_partitions + 1)); voff_t inter_size = cm->receive_offsets[num_of_partitions]; memcpy((shakehands_t)(cm->send) + receive_start, mst->send[did], sizeof(shakehands_t) inter_size); #ifdef MEASURE_TIME_ gettimeofday (&start, NULL); #endif int i; for (i=0; i<num_of_partitions; i++) { int pid = mst->partition_list[poffset + i]; voff_t num_mssgs = cm->receive_offsets[i+1] - cm->receive_offsets[i]; voff_t size = index_offset[i+1] - index_offset[i]; push_mssg_offset_respond_cpu (num_mssgs, pid, size, index_offset[i], total_num_partitions, receive_start, 0, k, p); } #ifdef MEASURE_TIME_ gettimeofday (&end, NULL); pull_inter_time[did] += (float)((end.tv_sec * 1000000 + end.tv_usec) - (start.tv_sec * 1000000 + start.tv_usec)) / 1000; print_exec_time (start, end, "*********** PUSH RESPOND OFFSET CPU INTER PROCESSORS TIME: "); #endif get_global_offsets (cm->extra_send_offsets, send_offsets_th, total_num_partitions, (cpu_threads+1)); inclusive_prefix_sum (cm->extra_send_offsets, total_num_partitions + 1); // *************** malloc (send and) receive buffer for pull and push mode, this is for junctions??????? voff_t rcv_size = cm->extra_send_offsets[num_of_partitions]; if (rcv_size == 0) { printf ("WORLD RANK %d: CPU::: CCCCCCCCCcccareful:::::::::: receive size from intra junction update push is 0!!!!!!!!\n", mst->world_rank); rcv_size = 1000; } malloc_pull_push_receive_cpu (cm, sizeof(shakehands_t), did, rcv_size, 2(total_num_partitions+num_of_partitions-1)/num_of_partitions); set_pull_push_receive (cm); memset (tmp_send_offsets_th, 0, sizeof(voff_t) (total_num_partitions+1) * (cpu_threads+1)); #ifdef MEASURE_TIME_ gettimeofday (&start, NULL); #endif for (i=0; i<num_of_partitions; i++) { int pid = mst->partition_list[poffset+i]; voff_t num_mssgs = cm->send_offsets[i+1] - cm->send_offsets[i]; voff_t size = index_offset[i+1] - index_offset[i]; push_mssg_respond_cpu (num_mssgs, pid, size, index_offset[i], total_num_partitions, 0, 1, k, p); } #ifdef MEASURE_TIME_ gettimeofday (&end, NULL); push_time[did] += (float)((end.tv_sec * 1000000 + end.tv_usec) - (start.tv_sec * 1000000 + start.tv_usec)) / 1000; print_exec_time (start, end, "************** PUSH RESPOND MSSG CPU INTRA PROCESSOR TIME: "); #endif #ifdef MEASURE_TIME_ gettimeofday (&start, NULL); #endif for (i=0; i<num_of_partitions; i++) { int pid = mst->partition_list[poffset+i]; voff_t num_mssgs = cm->receive_offsets[i+1] - cm->receive_offsets[i]; voff_t size = index_offset[i+1] - index_offset[i]; push_mssg_respond_cpu (num_mssgs, pid, size, index_offset[i], total_num_partitions, receive_start, 0, k, p); } #ifdef MEASURE_TIME_ gettimeofday (&end, NULL); push_time[did] += (float)((end.tv_sec * 1000000 + end.tv_usec) - (start.tv_sec * 1000000 + start.tv_usec)) / 1000; print_exec_time (start, end, "************** PUSH RESPOND MSSG CPU INTER PROCESSORS TIME: "); #endif memcpy(mst->roff[did], cm->extra_send_offsets, sizeof(voff_t)(total_num_partitions + 1)); voff_t inter_start = cm->extra_send_offsets[num_of_partitions]; voff_t inter_end = cm->extra_send_offsets[total_num_partitions]; printf ("@@@@@@@@@@@@@@@@@@@@@ WORLD RANK %d:: total number of shakehands pushed in device %d: %lu\n", mst->world_rank, did, inter_end); printf ("############### WORLD RANK %d:: number of intra mssgs pulled for inter shakehands of device %d: %lu\n", mst->world_rank, did, inter_start); printf ("############### WORLD RANK %d:: number of slots malloced for receive buffer of device %d: %u\n", mst->world_rank, did, cm->temp_size/sizeof(shakehands_t)); mst->receive[did] = (shakehands_t)(cm->receive) + inter_start; #ifndef SYNC_ALL2ALL_ if (atomic_set_value (&lock_flag[did], 1, 0) == false) printf("!!!!!!!!!!!!!!!!!! CAREFUL, SETTING VALUE DOES NOT WORK FINE!\n"); #endif #ifdef MEASURE_TIME_ gettimeofday (&start, NULL); #endif for (i=0; i<num_of_partitions; i++) { int pid = mst->partition_list[poffset + i]; voff_t num_mssgs = cm->extra_send_offsets[i+1] - cm->extra_send_offsets[i]; voff_t size = index_offset[i+1] - index_offset[i]; pull_mssg_respond_cpu (num_mssgs, pid, size, index_offset[i], cm->receive, 1); } #ifdef MEASURE_TIME_ gettimeofday (&end, NULL); pull_intra_time[did] += (float)((end.tv_sec * 1000000 + end.tv_usec) - (start.tv_sec * 1000000 + start.tv_usec)) / 1000; print_exec_time (start, end, "WORLD RANK %d ***************** PULL RESPOND MSSG CPU INTRA PROCESSOR TIME: ", mst->world_rank); #endif return ((void ) 0); } void respond_inter_pull_cpu (void * arg) { evaltime_t start, end; pre_arg * carg = (pre_arg ) arg; comm_t cm = &carg->dbm->comm; master_t * mst = carg->mst; int num_of_cpus = mst->num_of_cpus; int num_of_devices = mst->num_of_devices; int did = carg->did; int total_num_partitions = mst->total_num_partitions; int num_of_partitions = mst->num_partitions[did + 1] - mst->num_partitions[did]; voff_t * index_offset = mst->index_offset[did]; if (mst->world_rank == 0) printf ("WORLD RANK %d: respond inter pull cpu:\n", mst->world_rank); voff_t receive_start = mst->roff[did][num_of_partitions]; //cm->extra_send_offsets[num_of_partitions]; memcpy(cm->receive_offsets, mst->soff[did], sizeof(voff_t) * (num_of_partitions + 1)); voff_t inter_size = mst->soff[did][num_of_partitions]; if(inter_size == 0) return ((void) 0); if (cm->temp_size <= (inter_size+receive_start)sizeof(shakehands_t)) { printf("WORLD RANK %d: CPU: Error:::::::: malloced receive buffer size smaller than actual receive buffer size!\n", mst->world_rank); exit(0); } memcpy((shakehands_t)(cm->receive) + receive_start, mst->send[did], sizeof(shakehands_t) inter_size); printf ("############### number of inter mssgs pulled for inter shakehands of device %d: %lu\n", did, inter_size); int poffset = mst->num_partitions[did]; int i; #ifdef MEASURE_TIME_ gettimeofday (&start, NULL); #endif for (i=0; i<num_of_partitions; i++) { int pid = mst->partition_list[poffset + i]; voff_t num_mssgs = cm->receive_offsets[i+1] - cm->receive_offsets[i]; voff_t size = index_offset[i+1] - index_offset[i]; pull_mssg_respond_cpu (num_mssgs, pid, size, index_offset[i], cm->receive + sizeof(shakehands_t) * receive_start, 0); } #ifdef MEASURE_TIME_ gettimeofday (&end, NULL); pull_inter_time[did] += (float)((end.tv_sec * 1000000 + end.tv_usec) - (start.tv_sec * 1000000 + start.tv_usec)) / 1000; print_exec_time (start, end, "***************** PULL RESPOND MSSG FOR CPU INTER PROCESSORS TIME: "); #endif // *************** free (send and) receive buffer for pull and push mode free_pull_push_receive_cpu(cm); return ((void ) 0); } static void label_vertex_with_flags_cpu (uint size, voff_t index_offset) { vertex_t local_vs = vertices + index_offset; voff_t * local_jvalid = jvalid + index_offset; voff_t * local_lvalid = lvalid + index_offset; uint r; #pragma omp parallel for num_threads(cpu_threads) for (r = 0; r < size; r++) { int ind = 0; int outd = 0; uint index = r; if (local_vs[index].vid == 0) continue; int i; for (i = 0; i < EDGE_DIC_SIZE / 2; i++) { if ((local_vs[index].edge >> ((EDGE_DIC_SIZE / 2 + i) * 8) & 0xff) >= cutoff) { ind++; } if ((local_vs[index].edge >> (i8) & 0xff) >= cutoff) { outd++; } } if (ind==0 && outd==0) // filter isolated vertices { local_vs[index].vid=0; continue; } if (ind > 1 \|\| outd > 1) { local_jvalid[index] = 1; // to pick out junction nodes } if (ind <= 1 && outd <= 1) { if (outd <= 1) { for (i = 0; i < EDGE_DIC_SIZE / 2; i++) { if ((local_vs[index].edge >> (i8) & 0xff) >= cutoff) { break; } } if (i == EDGE_DIC_SIZE / 2) { local_jvalid[index] = 1; // set a vertex with only one edge or no edge to be a junction } } if (ind <= 1) { for (i = EDGE_DIC_SIZE / 2; i < EDGE_DIC_SIZE; i++) { if ((local_vs[index].edge >> (i8) & 0xff) >= cutoff) { break; } } if (i == EDGE_DIC_SIZE) { local_jvalid[index] = 1; // set a vertex with only one edge or no edge to be a junction } } if (local_jvalid[index] != 1) local_lvalid[index] = 1; // a linear vertex } } } static void assid_vertex_with_flags_cpu (uint size, int pid, voff_t index_offset) { uint r; vertex_t local_vs = vertices + index_offset; voff_t * local_jvalid = jvalid + index_offset; voff_t * local_lvalid = lvalid + index_offset; #pragma omp parallel for num_threads(cpu_threads) for (r = 0; r < size; r++) { uint index = r; bool jflag, lflag; if (index==0) { if (local_jvalid[index]) jflag = true; else jflag = false; if (local_lvalid[index]) lflag = true; else lflag = false; } else { if (local_jvalid[index] - local_jvalid[index-1]) jflag = true; else jflag = false; if (local_lvalid[index] - local_lvalid[index-1]) lflag = true; else lflag = false; } if (jflag==false && lflag==false) // empty slot { local_vs[index].vid = 0; continue; } // ************************** BE CAREFUL HERE !!!!!!!!!!! ********************* if (jflag==true) // a junction local_vs[index].vid = local_jvalid[index]; else if (lflag) // a linear vertex local_vs[index].vid = jid_offset[pid] + local_lvalid[index]; } } void * identify_vertices_cpu (void * arg) { evaltime_t start, end; pre_arg * garg = (pre_arg ) arg; master_t mst = garg->mst; dbmeta_t * dbm = garg->dbm; int did = garg->did; if (mst->world_rank == 0) printf ("WORLD RANK %d: identifying vertices cpu %d:\n", mst->world_rank, did); int num_of_partitions = mst->num_partitions[did + 1] - mst->num_partitions[did]; voff_t * index_offset = mst->index_offset[did]; memset (dbm->lvld, 0, sizeof(vid_t) * (max_ss + 1)); int i; #ifdef MEASURE_TIME_ gettimeofday (&start, NULL); #endif for (i=0; i<num_of_partitions; i++) { int poffset = mst->num_partitions[did]; int pid = mst->partition_list[poffset+i]; voff_t size = index_offset[i+1] - index_offset[i]; label_vertex_with_flags_cpu (size, index_offset[i]); // inclusive_prefix_sum ((int )(dbm->jvld + index_offset[i]), size); tbb_scan_uint (dbm->jvld + index_offset[i], dbm->jvld + index_offset[i], size); // inclusive_prefix_sum ((int )(dbm->lvld + index_offset[i]), size); tbb_scan_uint (dbm->lvld + index_offset[i], dbm->lvld + index_offset[i], size); mst->jid_offset[pid] = (dbm->jvld + index_offset[i])[size-1]; mst->id_offsets[pid+1] = (dbm->jvld + index_offset[i])[size-1] + (dbm->lvld + index_offset[i])[size-1]; // pid+1, for prefix-sum later } #ifdef MEASURE_TIME_ gettimeofday (&end, NULL); print_exec_time (start, end, "&&&&&&&&&&&&&&&&&&&& IDENTIFYING IDS OF VERTICES TIME: "); #endif return ((void )0); } void assign_vertex_ids_cpu (void * arg) { evaltime_t start, end; pre_arg * garg = (pre_arg ) arg; master_t mst = garg->mst; int did = garg->did; if (mst->world_rank == 0) printf ("WORLD RANK %d: Assigning vertices cpu %d:\n", mst->world_rank, did); int num_of_partitions = mst->num_partitions[did + 1] - mst->num_partitions[did]; voff_t * index_offset = mst->index_offset[did]; int i; #ifdef MEASURE_TIME_ gettimeofday (&start, NULL); #endif for (i=0; i<num_of_partitions; i++) { int poffset = mst->num_partitions[did]; int pid = mst->partition_list[poffset+i]; voff_t size = index_offset[i+1] - index_offset[i]; // assid_vertex_with_flags (size, pid, index_offset[i]); assid_vertex_with_flags_cpu (size, pid, index_offset[i]); } #ifdef MEASURE_TIME_ gettimeofday (&end, NULL); print_exec_time (start, end, "&&&&&&&&&&&&&&&&&&&& ASSIGNING IDS OF VERTICES TIME: "); #endif return ((void )0); } static void gather_vertex_cpu (uint size, int pid, voff_t index_offset, int total_num_partitions) { vertex_t local_vs = vertices + index_offset; uint count=0; uint dead=0; uint r; #pragma omp parallel for num_threads(cpu_threads) firstprivate(pid, size, local_vs) for (r = 0; r < size; r++) { int i; uint index = r; if (local_vs[index].vid == 0) continue; voff_t off = local_vs[index].vid - id_offsets[pid] - 1; if (local_vs[index].vid < id_offsets[pid] + 1) { printf ("Gather vertex cpu: error in vertex id and id_offsets: local_vs[%u].vid=%lu, id_offsets[%d]=%lu!\n", \ index, local_vs[index].vid, pid, id_offsets[pid]); exit(0); } if (local_vs[index].vid - id_offsets[pid] <= jid_offset[pid]) // a junction here { for (i=0; i<EDGE_DIC_SIZE; i++) { adj_nbs[i][off] = local_vs[index].nbs[i]; if (local_vs[index].nbs[i] != DEADEND) { int ppid = query_partition_id_from_idoffsets (local_vs[index].nbs[i], total_num_partitions, id_offsets); if (local_vs[index].nbs[i] - id_offsets[ppid] <= jid_offset[ppid]) count++; } else dead++; } jkmers[off] = local_vs[index].kmer; junct_edges[off] = local_vs[index].edge; } else // a linear vertex { for (i = 0; i < EDGE_DIC_SIZE / 2; i++) { if ((local_vs[index].edge >> (i8) & 0xff) >= cutoff) { posts[off - jid_offset[pid]] = local_vs[index].nbs[i]; post_edges[off - jid_offset[pid]] = i; if (local_vs[index].nbs[i] != DEADEND) { int ppid = query_partition_id_from_idoffsets (local_vs[index].nbs[i], total_num_partitions, id_offsets); if (local_vs[index].nbs[i] - id_offsets[ppid] <= jid_offset[ppid]) count++; } else { dead++; printf ("error in gathering neighbors of linear vertices here!\n"); exit(0); } } } for (i = EDGE_DIC_SIZE / 2; i < EDGE_DIC_SIZE; i++) { if ((local_vs[index].edge >> (i8) & 0xff) >= cutoff) { pres[off - jid_offset[pid]] = local_vs[index].nbs[i]; pre_edges[off - jid_offset[pid]] = i - EDGE_DIC_SIZE/2; if (local_vs[index].nbs[i] != DEADEND) { int ppid = query_partition_id_from_idoffsets (local_vs[index].nbs[i], total_num_partitions, id_offsets); if (local_vs[index].nbs[i] - id_offsets[ppid] <= jid_offset[ppid]) count++; } else { dead++; printf ("error in gathering neighbors of linear vertices here!\n"); exit(0); } break; } } // lkmers[off - jid_offset[pid]] = local_vs[index].kmer; } } // printf ("partition %d: number of junctions in neighbors: %u, deadend = %u, size = %u\n", pid, count, dead, size); } static void gather_vertex_partitioned (uint size, int pid, voff_t index_offset, int total_num_partitions, int k, int p, voff_t max_jsize, voff_t max_lsize) { vertex_t * local_vs = vertices + index_offset; uint count=0; uint dead=0; uint r; memset (spids, 0, sizeof(ull) * max_jsize); memset (spidsr, 0, sizeof(ull) * max_jsize); memset (spidlv, 0, sizeof(uint) * max_lsize); #pragma omp parallel for num_threads(cpu_threads) firstprivate(pid, size, local_vs) for (r = 0; r < size; r++) { int i; uint index = r; if (local_vs[index].vid == 0) continue; voff_t off = local_vs[index].vid - 1; if (local_vs[index].vid <= jid_offset[pid]) // a junction here: do not use is_junction for its <= { for (i=0; i<EDGE_DIC_SIZE / 2; i++) { if ((local_vs[index].edge >> (i8) & 0xff) >= cutoff) { spids[off] \|= (ull)(get_adj_id_from_post (&local_vs[index].kmer, (edge_type) i, k, p, total_num_partitions)) << (iSPID_BITS); } adj_nbs[i][off] = local_vs[index].nbs[i]; } for (i=EDGE_DIC_SIZE / 2; i<EDGE_DIC_SIZE; i++) { if ((local_vs[index].edge >> (i8) & 0xff) >= cutoff) { spidsr[off] \|= (ull)(get_adj_id_from_pre (&local_vs[index].kmer, (edge_type) (i-EDGE_DIC_SIZE/2), k, p, total_num_partitions)) << ((i-EDGE_DIC_SIZE/2)SPID_BITS); } adj_nbs[i][off] = local_vs[index].nbs[i]; } jkmers[off] = local_vs[index].kmer; junct_edges[off] = local_vs[index].edge; } else // a linear vertex { for (i = 0; i < EDGE_DIC_SIZE / 2; i++) { if ((local_vs[index].edge >> (i8) & 0xff) >= cutoff) { spidlv[off - jid_offset[pid]] \|= (get_adj_id_from_post (&local_vs[index].kmer, (edge_type) i, k, p, total_num_partitions)); posts[off - jid_offset[pid]] = local_vs[index].nbs[i]; post_edges[off - jid_offset[pid]] = i; break; } } for (i = EDGE_DIC_SIZE / 2; i < EDGE_DIC_SIZE; i++) { if ((local_vs[index].edge >> (i8) & 0xff) >= cutoff) { spidlv[off - jid_offset[pid]] \|= get_adj_id_from_pre (&local_vs[index].kmer, (edge_type) (i-EDGE_DIC_SIZE/2), k, p, total_num_partitions) << SPID_BITS; pres[off - jid_offset[pid]] = local_vs[index].nbs[i]; pre_edges[off - jid_offset[pid]] = i - EDGE_DIC_SIZE/2; break; } } } } // printf ("partition %d: number of junctions in neighbors: %u, deadend = %u, size = %u\n", pid, count, dead, size); } void * gather_vertices_cpu (void * arg) { evaltime_t start, end; pre_arg * garg = (pre_arg ) arg; master_t mst = garg->mst; dbmeta_t * dbm = garg->dbm; d_jvs_t * js = garg->js; d_lvs_t * ls = garg->ls; int k = garg->k; int p = garg->p; subgraph_t * subgraph = garg->subgraph; int did = garg->did; if (mst->world_rank == 0) printf ("WORLD RANK %d: Assigning vertices cpu %d:\n", mst->world_rank, did); int total_num_partitions = mst->total_num_partitions; int num_of_partitions = mst->num_partitions[did + 1] - mst->num_partitions[did]; voff_t * index_offset = mst->index_offset[did]; int i; #ifdef MEASURE_TIME_ gettimeofday (&start, NULL); #endif for (i=0; i<num_of_partitions; i++) { int poffset = mst->num_partitions[did]; int pid = mst->partition_list[poffset+i]; voff_t size = index_offset[i+1] - index_offset[i]; // gather_vertex_cpu (size, pid, index_offset[i], total_num_partitions); gather_vertex_partitioned (size, pid, index_offset[i], total_num_partitions, k, p, gmax_jsize, gmax_lsize); uint jsize = mst->jid_offset[pid]; uint lsize = mst->id_offsets[pid+1] - mst->id_offsets[pid] - jsize; // write_junctions_cpu (dbm, mst, jsize, lsize, pid, total_num_partitions, did); // write_linear_vertices_cpu (dbm, mst, jsize, lsize, pid, total_num_partitions, did); output_vertices_cpu (dbm, mst, jsize, lsize, pid, total_num_partitions, did, js, ls, subgraph); write_kmers_edges_cpu (dbm, mst, jsize, lsize, pid, total_num_partitions, did); } #ifdef MEASURE_TIME_ gettimeofday (&end, NULL); print_exec_time (start, end, "CPU: &&&&&&&&&&&&&&&&&&&& ASSIGNING IDS OF VERTICES TIME: "); #endif if (mst->world_rank == 0 && mst->num_of_devices == 0) { printf ("CPU: NUMBER OF VERTICES PROCESSED: %u\n", index_offset[num_of_partitions]); printf ("CPU: number of messages sent by junction: %lu\n" "number of messages sent by linear vertices: %lu\n" "number of messages received from junction: %lu\n" "number of messages received from linear vertices: %lu\n",\ send_junction, send_linear, receive_junction, receive_linear); } // write_ids_cpu (dbm, mst, num_of_partitions, did); // print_offsets(mst->id_offsets, total_num_partitions+1); return ((void *)0); }
ark_heat1D_omp.c	/--------------------------------------------------------------- Programmer(s): Shelby Lockhart @ LLNL --------------------------------------------------------------- Based on the serial code ark_heat1D.c developed by * Daniel R. Reynolds @ SMU and parallelized with OpenMP --------------------------------------------------------------- SUNDIALS Copyright Start * Copyright (c) 2002-2022, Lawrence Livermore National Security * and Southern Methodist University. * All rights reserved. * * See the top-level LICENSE and NOTICE files for details. * * SPDX-License-Identifier: BSD-3-Clause * SUNDIALS Copyright End --------------------------------------------------------------- Example problem: * * The following test simulates a simple 1D heat equation, * u_t = ku_xx + f for t in [0, 10], x in [0, 1], with initial conditions * u(0,x) = 0 * Dirichlet boundary conditions, i.e. * u_t(t,0) = u_t(t,1) = 0, * and a point-source heating term, * f = 1 for x=0.5. * * The spatial derivatives are computed using second-order * centered differences, with the data distributed over N points * on a uniform spatial grid. * * This program solves the problem with either an ERK or DIRK * method. For the DIRK method, we use a Newton iteration with * the SUNPCG linear solver, and a user-supplied Jacobian-vector * product routine. * * 100 outputs are printed at equal intervals, and run statistics * are printed at the end. ---------------------------------------------------------------/ /* Header files / #include <stdio.h> #include <stdlib.h> #include <math.h> #include <arkode/arkode_arkstep.h> / prototypes for ARKStep fcts., consts / #include <nvector/nvector_openmp.h> / OpenMP N_Vector types, fcts., macros / #include <sunlinsol/sunlinsol_pcg.h> / access to PCG SUNLinearSolver / #include <sundials/sundials_types.h> / defs. of realtype, sunindextype, etc / #ifdef _OPENMP #include <omp.h> / OpenMP function defs. / #endif #if defined(SUNDIALS_EXTENDED_PRECISION) #define GSYM "Lg" #define ESYM "Le" #define FSYM "Lf" #else #define GSYM "g" #define ESYM "e" #define FSYM "f" #endif / user data structure / typedef struct { sunindextype N; / number of intervals / int nthreads; / number of OpenMP threads / realtype dx; / mesh spacing / realtype k; / diffusion coefficient / } UserData; /* User-supplied Functions Called by the Solver / static int f(realtype t, N_Vector y, N_Vector ydot, void user_data); static int Jac(N_Vector v, N_Vector Jv, realtype t, N_Vector y, N_Vector fy, void user_data, N_Vector tmp); / Private function to check function return values / static int check_flag(void flagvalue, const char funcname, int opt); / Main Program / int main(int argc, char argv[]) { /* general problem parameters / realtype T0 = RCONST(0.0); / initial time / realtype Tf = RCONST(1.0); / final time / int Nt = 10; / total number of output times / realtype rtol = 1.e-6; / relative tolerance / realtype atol = 1.e-10; / absolute tolerance / UserData udata = NULL; realtype data; sunindextype N = 201; /* spatial mesh size / realtype k = 0.5; / heat conductivity / sunindextype i; / general problem variables / int flag; / reusable error-checking flag / N_Vector y = NULL; / empty vector for storing solution / SUNLinearSolver LS = NULL; / empty linear solver object / void arkode_mem = NULL; /* empty ARKStep memory structure / FILE FID, UFID; realtype t, dTout, tout; int iout, num_threads; long int nst, nst_a, nfe, nfi, nsetups, nli, nJv, nlcf, nni, ncfn, netf; / Create the SUNDIALS context object for this simulation / SUNContext ctx; flag = SUNContext_Create(NULL, &ctx); if (check_flag(&flag, "SUNContext_Create", 1)) return 1; / set the number of threads to use / num_threads = 1; / default value / #ifdef _OPENMP num_threads = omp_get_max_threads(); / overwrite with OMP_NUM_THREADS environment variable / #endif if (argc > 1) / overwrite with command line value, if supplied / num_threads = (int) strtol(argv[1], NULL, 0); / allocate and fill udata structure / udata = (UserData) malloc(sizeof(udata)); udata->N = N; udata->k = k; udata->dx = RCONST(1.0)/(N-1); /* mesh spacing / udata->nthreads = num_threads; / Initial problem output / printf("\n1D Heat PDE test problem:\n"); printf(" N = %li\n", (long int) udata->N); printf(" diffusion coefficient: k = %"GSYM"\n", udata->k); / Initialize data structures / y = N_VNew_OpenMP(N, num_threads, ctx); / Create OpenMP vector for solution / if (check_flag((void ) y, "N_VNew_OpenMP", 0)) return 1; N_VConst(0.0, y); /* Set initial conditions / arkode_mem = ARKStepCreate(NULL, f, T0, y, ctx); / Create the solver memory / if (check_flag((void ) arkode_mem, "ARKStepCreate", 0)) return 1; /* Set routines / flag = ARKStepSetUserData(arkode_mem, (void ) udata); /* Pass udata to user functions / if (check_flag(&flag, "ARKStepSetUserData", 1)) return 1; flag = ARKStepSetMaxNumSteps(arkode_mem, 10000); / Increase max num steps / if (check_flag(&flag, "ARKStepSetMaxNumSteps", 1)) return 1; flag = ARKStepSetPredictorMethod(arkode_mem, 1); / Specify maximum-order predictor / if (check_flag(&flag, "ARKStepSetPredictorMethod", 1)) return 1; flag = ARKStepSStolerances(arkode_mem, rtol, atol); / Specify tolerances / if (check_flag(&flag, "ARKStepSStolerances", 1)) return 1; / Initialize PCG solver -- no preconditioning, with up to N iterations / LS = SUNLinSol_PCG(y, 0, (int) N, ctx); if (check_flag((void )LS, "SUNLinSol_PCG", 0)) return 1; /* Linear solver interface -- set user-supplied Jv routine (no 'jtsetup' required) / flag = ARKStepSetLinearSolver(arkode_mem, LS, NULL); /* Attach linear solver to ARKStep / if (check_flag(&flag, "ARKStepSetLinearSolver", 1)) return 1; flag = ARKStepSetJacTimes(arkode_mem, NULL, Jac); / Set the Jacobian routine / if (check_flag(&flag, "ARKStepSetJacTimes", 1)) return 1; / Specify linearly implicit RHS, with non-time-dependent Jacobian / flag = ARKStepSetLinear(arkode_mem, 0); if (check_flag(&flag, "ARKStepSetLinear", 1)) return 1; / output mesh to disk / FID=fopen("heat_mesh.txt","w"); for (i=0; i<N; i++) fprintf(FID," %.16"ESYM"\n", udata->dxi); fclose(FID); /* Open output stream for results, access data array / UFID=fopen("heat1D.txt","w"); data = N_VGetArrayPointer(y); / output initial condition to disk / for (i=0; i<N; i++) fprintf(UFID," %.16"ESYM"", data[i]); fprintf(UFID,"\n"); / Main time-stepping loop: calls ARKStep to perform the integration, then prints results. Stops when the final time has been reached / t = T0; dTout = (Tf-T0)/Nt; tout = T0+dTout; printf(" t \|\|u\|\|_rms\n"); printf(" -------------------------\n"); printf(" %10.6"FSYM" %10.6f\n", t, sqrt(N_VDotProd(y,y)/N)); for (iout=0; iout<Nt; iout++) { flag = ARKStepEvolve(arkode_mem, tout, y, &t, ARK_NORMAL); / call integrator / if (check_flag(&flag, "ARKStepEvolve", 1)) break; printf(" %10.6"FSYM" %10.6f\n", t, sqrt(N_VDotProd(y,y)/N)); / print solution stats / if (flag >= 0) { / successful solve: update output time / tout += dTout; tout = (tout > Tf) ? Tf : tout; } else { / unsuccessful solve: break / fprintf(stderr,"Solver failure, stopping integration\n"); break; } / output results to disk / for (i=0; i<N; i++) fprintf(UFID," %.16"ESYM"", data[i]); fprintf(UFID,"\n"); } printf(" -------------------------\n"); fclose(UFID); / Print some final statistics / flag = ARKStepGetNumSteps(arkode_mem, &nst); check_flag(&flag, "ARKStepGetNumSteps", 1); flag = ARKStepGetNumStepAttempts(arkode_mem, &nst_a); check_flag(&flag, "ARKStepGetNumStepAttempts", 1); flag = ARKStepGetNumRhsEvals(arkode_mem, &nfe, &nfi); check_flag(&flag, "ARKStepGetNumRhsEvals", 1); flag = ARKStepGetNumLinSolvSetups(arkode_mem, &nsetups); check_flag(&flag, "ARKStepGetNumLinSolvSetups", 1); flag = ARKStepGetNumErrTestFails(arkode_mem, &netf); check_flag(&flag, "ARKStepGetNumErrTestFails", 1); flag = ARKStepGetNumNonlinSolvIters(arkode_mem, &nni); check_flag(&flag, "ARKStepGetNumNonlinSolvIters", 1); flag = ARKStepGetNumNonlinSolvConvFails(arkode_mem, &ncfn); check_flag(&flag, "ARKStepGetNumNonlinSolvConvFails", 1); flag = ARKStepGetNumLinIters(arkode_mem, &nli); check_flag(&flag, "ARKStepGetNumLinIters", 1); flag = ARKStepGetNumJtimesEvals(arkode_mem, &nJv); check_flag(&flag, "ARKStepGetNumJtimesEvals", 1); flag = ARKStepGetNumLinConvFails(arkode_mem, &nlcf); check_flag(&flag, "ARKStepGetNumLinConvFails", 1); printf("\nFinal Solver Statistics:\n"); printf(" Internal solver steps = %li (attempted = %li)\n", nst, nst_a); printf(" Total RHS evals: Fe = %li, Fi = %li\n", nfe, nfi); printf(" Total linear solver setups = %li\n", nsetups); printf(" Total linear iterations = %li\n", nli); printf(" Total number of Jacobian-vector products = %li\n", nJv); printf(" Total number of linear solver convergence failures = %li\n", nlcf); printf(" Total number of Newton iterations = %li\n", nni); printf(" Total number of nonlinear solver convergence failures = %li\n", ncfn); printf(" Total number of error test failures = %li\n", netf); / Clean up and return with successful completion / N_VDestroy(y); / Free vectors / free(udata); / Free user data / ARKStepFree(&arkode_mem); / Free integrator memory / SUNLinSolFree(LS); / Free linear solver / SUNContext_Free(&ctx); / Free context / return 0; } /-------------------------------- * Functions called by the solver --------------------------------/ /* f routine to compute the ODE RHS function f(t,y). / static int f(realtype t, N_Vector y, N_Vector ydot, void user_data) { UserData udata = (UserData) user_data; /* access problem data / sunindextype N = udata->N; / set variable shortcuts / realtype k = udata->k; realtype dx = udata->dx; realtype Y=NULL, Ydot=NULL; realtype c1, c2; sunindextype i = 0; sunindextype isource; Y = N_VGetArrayPointer(y); / access data arrays / if (check_flag((void ) Y, "N_VGetArrayPointer", 0)) return 1; Ydot = N_VGetArrayPointer(ydot); if (check_flag((void ) Ydot, "N_VGetArrayPointer", 0)) return 1; N_VConst(0.0, ydot); / Initialize ydot to zero / / iterate over domain, computing all equations / c1 = k/dx/dx; c2 = -RCONST(2.0)k/dx/dx; isource = N/2; Ydot[0] = 0.0; /* left boundary condition / #pragma omp parallel for default(shared) private(i) schedule(static) num_threads(udata->nthreads) for (i=1; i<N-1; i++) Ydot[i] = c1Y[i-1] + c2Y[i] + c1Y[i+1]; Ydot[N-1] = 0.0; /* right boundary condition / Ydot[isource] += 0.01/dx; / source term / return 0; / Return with success / } / Jacobian routine to compute J(t,y) = df/dy. / static int Jac(N_Vector v, N_Vector Jv, realtype t, N_Vector y, N_Vector fy, void user_data, N_Vector tmp) { UserData udata = (UserData) user_data; /* variable shortcuts / sunindextype N = udata->N; realtype k = udata->k; realtype dx = udata->dx; realtype V=NULL, JV=NULL; realtype c1, c2; sunindextype i = 0; V = N_VGetArrayPointer(v); / access data arrays / if (check_flag((void ) V, "N_VGetArrayPointer", 0)) return 1; JV = N_VGetArrayPointer(Jv); if (check_flag((void ) JV, "N_VGetArrayPointer", 0)) return 1; N_VConst(0.0, Jv); / initialize Jv product to zero / / iterate over domain, computing all Jacobian-vector products / c1 = k/dx/dx; c2 = -RCONST(2.0)k/dx/dx; JV[0] = 0.0; #pragma omp parallel for default(shared) private(i) schedule(static) num_threads(udata->nthreads) for (i=1; i<N-1; i++) JV[i] = c1V[i-1] + c2V[i] + c1V[i+1]; JV[N-1] = 0.0; return 0; / Return with success / } /------------------------------- * Private helper functions -------------------------------/ /* Check function return value... opt == 0 means SUNDIALS function allocates memory so check if returned NULL pointer opt == 1 means SUNDIALS function returns a flag so check if flag >= 0 opt == 2 means function allocates memory so check if returned NULL pointer / static int check_flag(void flagvalue, const char funcname, int opt) { int errflag; /* Check if SUNDIALS function returned NULL pointer - no memory allocated / if (opt == 0 && flagvalue == NULL) { fprintf(stderr, "\nSUNDIALS_ERROR: %s() failed - returned NULL pointer\n\n", funcname); return 1; } / Check if flag < 0 / else if (opt == 1) { errflag = (int ) flagvalue; if (errflag < 0) { fprintf(stderr, "\nSUNDIALS_ERROR: %s() failed with flag = %d\n\n", funcname, errflag); return 1; }} /* Check if function returned NULL pointer - no memory allocated / else if (opt == 2 && flagvalue == NULL) { fprintf(stderr, "\nMEMORY_ERROR: %s() failed - returned NULL pointer\n\n", funcname); return 1; } return 0; } /---- end of file ----*/
otfft_eightstep.h	// Copyright (c) 2015, OK おじさん(岡久卓也) // Copyright (c) 2015, OK Ojisan(Takuya OKAHISA) // Copyright (c) 2017 to the present, DEWETRON GmbH // OTFFT Implementation Version 9.5 // based on Stockham FFT algorithm // from OK Ojisan(Takuya OKAHISA), source: http://www.moon.sannet.ne.jp/okahisa/stockham/stockham.html #pragma once #include "otfft_types.h" namespace OTFFT_NAMESPACE { namespace OTFFT_Eightstep { ///////////////////////////////////////////////////// using namespace OTFFT; using namespace OTFFT_MISC; using OTFFT_Sixstep::weight_t; using OTFFT_Sixstep::const_index_vector; static const int OMP_THRESHOLD1 = 1<<13; static const int OMP_THRESHOLD2 = 1<<16; /////////////////////////////////////////////////////////////////////////////// template <int log_N, int mode> struct fwdfftr { static const int N = 1 << log_N; static const int N0 = 0; static const int N1 = N/8; static const int N2 = N12; static const int N3 = N13; static const int N4 = N14; static const int N5 = N15; static const int N6 = N16; static const int N7 = N17; static inline void transpose_kernel( const int p, complex_vector x, complex_vector y) noexcept { const ymm aA = getpz2(x+p+N0); const ymm bB = getpz2(x+p+N1); const ymm cC = getpz2(x+p+N2); const ymm dD = getpz2(x+p+N3); const ymm eE = getpz2(x+p+N4); const ymm fF = getpz2(x+p+N5); const ymm gG = getpz2(x+p+N6); const ymm hH = getpz2(x+p+N7); const ymm ab = catlo(aA, bB); const ymm AB = cathi(aA, bB); const ymm cd = catlo(cC, dD); const ymm CD = cathi(cC, dD); const ymm ef = catlo(eE, fF); const ymm EF = cathi(eE, fF); const ymm gh = catlo(gG, hH); const ymm GH = cathi(gG, hH); setpz2(y+8p+ 0, ab); setpz2(y+8p+ 2, cd); setpz2(y+8p+ 4, ef); setpz2(y+8p+ 6, gh); setpz2(y+8p+ 8, AB); setpz2(y+8p+10, CD); setpz2(y+8p+12, EF); setpz2(y+8p+14, GH); } static inline void fft_and_mult_twiddle_factor_kernel( const int p, complex_vector x, complex_vector y, weight_t W) noexcept { const ymm w1p = getpz2(W+p); const ymm w2p = mulpz2(w1p, w1p); const ymm w3p = mulpz2(w1p, w2p); const ymm w4p = mulpz2(w2p, w2p); const ymm w5p = mulpz2(w2p, w3p); const ymm w6p = mulpz2(w3p, w3p); const ymm w7p = mulpz2(w3p, w4p); const ymm x0 = scalepz2<N,mode>(getpz2(x+p+N0)); const ymm x1 = scalepz2<N,mode>(getpz2(x+p+N1)); const ymm x2 = scalepz2<N,mode>(getpz2(x+p+N2)); const ymm x3 = scalepz2<N,mode>(getpz2(x+p+N3)); const ymm x4 = scalepz2<N,mode>(getpz2(x+p+N4)); const ymm x5 = scalepz2<N,mode>(getpz2(x+p+N5)); const ymm x6 = scalepz2<N,mode>(getpz2(x+p+N6)); const ymm x7 = scalepz2<N,mode>(getpz2(x+p+N7)); const ymm a04 = addpz2(x0, x4); const ymm s04 = subpz2(x0, x4); const ymm a26 = addpz2(x2, x6); const ymm js26 = jxpz2(subpz2(x2, x6)); const ymm a15 = addpz2(x1, x5); const ymm s15 = subpz2(x1, x5); const ymm a37 = addpz2(x3, x7); const ymm js37 = jxpz2(subpz2(x3, x7)); const ymm a04_p1_a26 = addpz2(a04, a26); const ymm s04_mj_s26 = subpz2(s04, js26); const ymm a04_m1_a26 = subpz2(a04, a26); const ymm s04_pj_s26 = addpz2(s04, js26); const ymm a15_p1_a37 = addpz2(a15, a37); const ymm w8_s15_mj_s37 = w8xpz2(subpz2(s15, js37)); const ymm j_a15_m1_a37 = jxpz2(subpz2(a15, a37)); const ymm v8_s15_pj_s37 = v8xpz2(addpz2(s15, js37)); setpz2(y+p+N0, addpz2(a04_p1_a26, a15_p1_a37)); setpz2(y+p+N1, mulpz2(w1p, addpz2(s04_mj_s26, w8_s15_mj_s37))); setpz2(y+p+N2, mulpz2(w2p, subpz2(a04_m1_a26, j_a15_m1_a37))); setpz2(y+p+N3, mulpz2(w3p, subpz2(s04_pj_s26, v8_s15_pj_s37))); setpz2(y+p+N4, mulpz2(w4p, subpz2(a04_p1_a26, a15_p1_a37))); setpz2(y+p+N5, mulpz2(w5p, subpz2(s04_mj_s26, w8_s15_mj_s37))); setpz2(y+p+N6, mulpz2(w6p, addpz2(a04_m1_a26, j_a15_m1_a37))); setpz2(y+p+N7, mulpz2(w7p, addpz2(s04_pj_s26, v8_s15_pj_s37))); } void operator()(const_index_vector ip, complex_vector x, complex_vector y, weight_t W, weight_t Ws) const noexcept { if (N < OMP_THRESHOLD1) { for (int p = 0; p < N1; p += 2) { fft_and_mult_twiddle_factor_kernel(p, x, y, W); } OTFFT_Sixstep::fwdffts8<log_N-3,scale_1,1>()(ip, y+N0, x+N0, W, Ws); OTFFT_Sixstep::fwdffts8<log_N-3,scale_1,1>()(ip, y+N1, x+N1, W, Ws); OTFFT_Sixstep::fwdffts8<log_N-3,scale_1,1>()(ip, y+N2, x+N2, W, Ws); OTFFT_Sixstep::fwdffts8<log_N-3,scale_1,1>()(ip, y+N3, x+N3, W, Ws); OTFFT_Sixstep::fwdffts8<log_N-3,scale_1,1>()(ip, y+N4, x+N4, W, Ws); OTFFT_Sixstep::fwdffts8<log_N-3,scale_1,1>()(ip, y+N5, x+N5, W, Ws); OTFFT_Sixstep::fwdffts8<log_N-3,scale_1,1>()(ip, y+N6, x+N6, W, Ws); OTFFT_Sixstep::fwdffts8<log_N-3,scale_1,1>()(ip, y+N7, x+N7, W, Ws); for (int p = 0; p < N1; p += 2) { transpose_kernel(p, y, x); } } else if (N < OMP_THRESHOLD2) #pragma omp parallel firstprivate(x,y,W,Ws) { #pragma omp for schedule(guided) for (int p = 0; p < N1; p += 2) { fft_and_mult_twiddle_factor_kernel(p, x, y, W); } #pragma omp for schedule(static) for (int i = 0; i < 8; i++) { OTFFT_Sixstep::fwdffts8<log_N-3,scale_1,1>()(ip, y+iN1, x+iN1, W, Ws); } #pragma omp for schedule(static) for (int p = 0; p < N1; p += 2) { transpose_kernel(p, y, x); } } else { #pragma omp parallel for schedule(guided) firstprivate(x,y,W) for (int p = 0; p < N1; p += 2) { fft_and_mult_twiddle_factor_kernel(p, x, y, W); } OTFFT_Sixstep::fwdffts8<log_N-3,scale_1>()(ip, y+N0, x+N0, W, Ws); OTFFT_Sixstep::fwdffts8<log_N-3,scale_1>()(ip, y+N1, x+N1, W, Ws); OTFFT_Sixstep::fwdffts8<log_N-3,scale_1>()(ip, y+N2, x+N2, W, Ws); OTFFT_Sixstep::fwdffts8<log_N-3,scale_1>()(ip, y+N3, x+N3, W, Ws); OTFFT_Sixstep::fwdffts8<log_N-3,scale_1>()(ip, y+N4, x+N4, W, Ws); OTFFT_Sixstep::fwdffts8<log_N-3,scale_1>()(ip, y+N5, x+N5, W, Ws); OTFFT_Sixstep::fwdffts8<log_N-3,scale_1>()(ip, y+N6, x+N6, W, Ws); OTFFT_Sixstep::fwdffts8<log_N-3,scale_1>()(ip, y+N7, x+N7, W, Ws); #pragma omp parallel for schedule(static) firstprivate(x,y) for (int p = 0; p < N1; p += 2) { transpose_kernel(p, y, x); } } } }; /////////////////////////////////////////////////////////////////////////////// template <int log_N, int mode> struct invfftr { static const int N = 1 << log_N; static const int N0 = 0; static const int N1 = N/8; static const int N2 = N12; static const int N3 = N13; static const int N4 = N14; static const int N5 = N15; static const int N6 = N16; static const int N7 = N17; static inline void transpose_kernel( const int p, complex_vector x, complex_vector y) noexcept { fwdfftr<log_N,mode>::transpose_kernel(p, x, y); } static inline void fft_and_mult_twiddle_factor_kernel( const int p, complex_vector x, complex_vector y, weight_t W) noexcept { const ymm w1p = cnjpz2(getpz2(W+p)); const ymm w2p = mulpz2(w1p, w1p); const ymm w3p = mulpz2(w1p, w2p); const ymm w4p = mulpz2(w2p, w2p); const ymm w5p = mulpz2(w2p, w3p); const ymm w6p = mulpz2(w3p, w3p); const ymm w7p = mulpz2(w3p, w4p); const ymm x0 = scalepz2<N,mode>(getpz2(x+p+N0)); const ymm x1 = scalepz2<N,mode>(getpz2(x+p+N1)); const ymm x2 = scalepz2<N,mode>(getpz2(x+p+N2)); const ymm x3 = scalepz2<N,mode>(getpz2(x+p+N3)); const ymm x4 = scalepz2<N,mode>(getpz2(x+p+N4)); const ymm x5 = scalepz2<N,mode>(getpz2(x+p+N5)); const ymm x6 = scalepz2<N,mode>(getpz2(x+p+N6)); const ymm x7 = scalepz2<N,mode>(getpz2(x+p+N7)); const ymm a04 = addpz2(x0, x4); const ymm s04 = subpz2(x0, x4); const ymm a26 = addpz2(x2, x6); const ymm js26 = jxpz2(subpz2(x2, x6)); const ymm a15 = addpz2(x1, x5); const ymm s15 = subpz2(x1, x5); const ymm a37 = addpz2(x3, x7); const ymm js37 = jxpz2(subpz2(x3, x7)); const ymm a04_p1_a26 = addpz2(a04, a26); const ymm s04_pj_s26 = addpz2(s04, js26); const ymm a04_m1_a26 = subpz2(a04, a26); const ymm s04_mj_s26 = subpz2(s04, js26); const ymm a15_p1_a37 = addpz2(a15, a37); const ymm v8_s15_pj_s37 = v8xpz2(addpz2(s15, js37)); const ymm j_a15_m1_a37 = jxpz2(subpz2(a15, a37)); const ymm w8_s15_mj_s37 = w8xpz2(subpz2(s15, js37)); setpz2(y+p+N0, addpz2(a04_p1_a26, a15_p1_a37)); setpz2(y+p+N1, mulpz2(w1p, addpz2(s04_pj_s26, v8_s15_pj_s37))); setpz2(y+p+N2, mulpz2(w2p, addpz2(a04_m1_a26, j_a15_m1_a37))); setpz2(y+p+N3, mulpz2(w3p, subpz2(s04_mj_s26, w8_s15_mj_s37))); setpz2(y+p+N4, mulpz2(w4p, subpz2(a04_p1_a26, a15_p1_a37))); setpz2(y+p+N5, mulpz2(w5p, subpz2(s04_pj_s26, v8_s15_pj_s37))); setpz2(y+p+N6, mulpz2(w6p, subpz2(a04_m1_a26, j_a15_m1_a37))); setpz2(y+p+N7, mulpz2(w7p, addpz2(s04_mj_s26, w8_s15_mj_s37))); } void operator()(const_index_vector ip, complex_vector x, complex_vector y, weight_t W, weight_t Ws) const noexcept { if (N < OMP_THRESHOLD1) { for (int p = 0; p < N1; p += 2) { fft_and_mult_twiddle_factor_kernel(p, x, y, W); } OTFFT_Sixstep::invffts8<log_N-3,scale_1,1>()(ip, y+N0, x+N0, W, Ws); OTFFT_Sixstep::invffts8<log_N-3,scale_1,1>()(ip, y+N1, x+N1, W, Ws); OTFFT_Sixstep::invffts8<log_N-3,scale_1,1>()(ip, y+N2, x+N2, W, Ws); OTFFT_Sixstep::invffts8<log_N-3,scale_1,1>()(ip, y+N3, x+N3, W, Ws); OTFFT_Sixstep::invffts8<log_N-3,scale_1,1>()(ip, y+N4, x+N4, W, Ws); OTFFT_Sixstep::invffts8<log_N-3,scale_1,1>()(ip, y+N5, x+N5, W, Ws); OTFFT_Sixstep::invffts8<log_N-3,scale_1,1>()(ip, y+N6, x+N6, W, Ws); OTFFT_Sixstep::invffts8<log_N-3,scale_1,1>()(ip, y+N7, x+N7, W, Ws); for (int p = 0; p < N1; p += 2) { transpose_kernel(p, y, x); } } else if (N < OMP_THRESHOLD2) #pragma omp parallel firstprivate(x,y,W,Ws) { #pragma omp for schedule(guided) for (int p = 0; p < N1; p += 2) { fft_and_mult_twiddle_factor_kernel(p, x, y, W); } #pragma omp for schedule(static) for (int i = 0; i < 8; i++) { OTFFT_Sixstep::invffts8<log_N-3,scale_1,1>()(ip, y+iN1, x+iN1, W, Ws); } #pragma omp for schedule(static) for (int p = 0; p < N1; p += 2) { transpose_kernel(p, y, x); } } else { #pragma omp parallel for schedule(guided) firstprivate(x,y,W) for (int p = 0; p < N1; p += 2) { fft_and_mult_twiddle_factor_kernel(p, x, y, W); } OTFFT_Sixstep::invffts8<log_N-3,scale_1>()(ip, y+N0, x+N0, W, Ws); OTFFT_Sixstep::invffts8<log_N-3,scale_1>()(ip, y+N1, x+N1, W, Ws); OTFFT_Sixstep::invffts8<log_N-3,scale_1>()(ip, y+N2, x+N2, W, Ws); OTFFT_Sixstep::invffts8<log_N-3,scale_1>()(ip, y+N3, x+N3, W, Ws); OTFFT_Sixstep::invffts8<log_N-3,scale_1>()(ip, y+N4, x+N4, W, Ws); OTFFT_Sixstep::invffts8<log_N-3,scale_1>()(ip, y+N5, x+N5, W, Ws); OTFFT_Sixstep::invffts8<log_N-3,scale_1>()(ip, y+N6, x+N6, W, Ws); OTFFT_Sixstep::invffts8<log_N-3,scale_1>()(ip, y+N7, x+N7, W, Ws); #pragma omp parallel for schedule(static) firstprivate(x,y) for (int p = 0; p < N1; p += 2) { transpose_kernel(p, y, x); } } } }; } ///////////////////////////////////////////////////////////////////////////// }
laplace.c	#include <stdlib.h> #include <stdio.h> #include <math.h> #include <sys/time.h> #define WIDTH 1000 #define HEIGHT 1000 #define TEMP_TOLERANCE 0.01 double Temperature[HEIGHT+2][WIDTH+2]; double Temperature_previous[HEIGHT+2][WIDTH+2]; void initialize(); void track_progress(int iter); int main(int argc, char argv[]) { int i, j; int iteration = 1; double worst_dt = 100; struct timeval start_time, stop_time, elapsed_time; gettimeofday(&start_time, NULL); initialize(); while (worst_dt > TEMP_TOLERANCE) { #pragma omp parallel for private(i, j) for (i = 1; i <= HEIGHT; i++) { for (j = 1; j <= WIDTH; j++) { Temperature[i][j] = 0.25 (Temperature_previous[i+1][j] + Temperature_previous[i-1][j] + Temperature_previous[i][j+1] + Temperature_previous[i][j-1]); } } worst_dt = 0.0; #pragma omp parallel for reduction(max:worst_dt) private(i,j) for (i = 1; i <= HEIGHT; i++) { for (j = 1; j <= WIDTH; j++) { worst_dt = fmax(fabs(Temperature[i][j] - Temperature_previous[i][j]), worst_dt); Temperature_previous[i][j] = Temperature[i][j]; } } if ((iteration % 100) == 0) { track_progress(iteration); } iteration++; } gettimeofday(&stop_time, NULL); timersub(&stop_time, &start_time, &elapsed_time); printf("\nMax error at iteration %d was %f\n", iteration-1, worst_dt); printf("Total time was %f seconds.\n", elapsed_time.tv_sec+elapsed_time.tv_usec/1000000.0); } void initialize() { int i, j; for (i = 0; i < HEIGHT+1; i++) { for (j = 0; j < WIDTH+1; j++) { Temperature_previous[i][j] = 0.0; } } for (i = 0; i < HEIGHT+1; i++) { Temperature_previous[i][0] = 0.0; Temperature_previous[i][WIDTH+1] = (100.0/HEIGHT) * i; } for (j = 0; j < WIDTH+1; j++) { Temperature_previous[0][j] = 0; Temperature_previous[HEIGHT+1][j] = (100.0/WIDTH)*j; } } void track_progress(int iteration) { int i; printf("---------- Iteration number: %d ----------\n", iteration); for (i = HEIGHT-5; i <= HEIGHT; i++) { printf("[%d,%d]: %5.2f ", i, i, Temperature[i][i]); } printf("\n"); }
spgsolver.h	/* Algorithm for Steiner Problem in Graphs Copyright (c) Microsoft Corporation All rights reserved. MIT License Permission is hereby granted, free of charge, to any person obtaining a copy of this software and associated documentation files (the "Software"), to deal in the Software without restriction, including without limitation the rights to use, copy, modify, merge, publish, distribute, sublicense, and/or sell copies of the Software, and to permit persons to whom the Software is furnished to do so, subject to the following conditions: The above copyright notice and this permission notice shall be included in all copies or substantial portions of the Software. THE SOFTWARE IS PROVIDED AS IS, WITHOUT WARRANTY OF ANY KIND, EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE. / #pragma once #include <cstdint> #include <cstdio> #include <cstdlib> #include <iostream> #include <iomanip> #include <fstream> #include <vector> #include <algorithm> #include "binheap.h" #include "graph.h" #include "solution.h" #include "rfw_timer.h" #include "uf.h" #include "uset.h" #include "voronoi.h" #include "rfw_random.h" #include "rfw_stack.h" #include "drawer.h" #include "dual.h" #include "stedgelinear.h" #include "pairheap.h" #include "buckets.h" #include <cstring> #include <cmath> #include "elite.h" #include "spgconfig.h" #include <omp.h> #include "constructive.h" #include "execution_log.h" #include "LSVertexInsertion.h" #include "LSVertexElimination.h" #include "LSBasics.h" #include "LSKeyPath.h" #include "BranchBound.h" #include "perturbation.h" #include "preprocess.h" using namespace std; class SPGSolver { private: static void fatal (const string &msg) { fprintf (stderr, "ERROR: %s.\n", msg.c_str()); fflush(stderr); exit(-1); } static void warning (const string &msg) { fprintf (stderr, "%s", msg.c_str()); fflush(stderr); } / static void ShowUsage() { fprintf (stderr, "Usage: steiner <filename> <upper bound> [-prep 1] [-seed <s>]\n"); }/ static void ExtractFilename (char filename, char name) { strcpy (name, filename); //fprintf (stderr, "<%s> ", name); //exit(-1); char lastsep = NULL; char lastdot = NULL; char end = &name[strlen(name)]; char p = name; for (p=name; p<=end; p++) { if (p=='/' \|\| p=='\\') lastsep = p; if (p=='.') lastdot = p; } if (lastsep == NULL) { lastsep = name; } else { lastsep ++; } if (lastdot == NULL) { lastdot = end; } // avoid weird cases if (lastdot <= lastsep) { lastdot = end; lastsep = name; } lastdot = 0; int i = 0; while (1) { name[i] = lastsep; if (name[i] == 0) break; i++; lastsep ++; } //fprintf (file, "graph %s\n", lastsep); //fprintf (file, "graph %s\n", name); //delete [] name; } static void OutputGraphStats (FILE file, Graph &g, char filename) { fprintf (file, "file %s\n", filename); fprintf (file, "nvertices %d\n", g.VertexCount()); fprintf (file, "nedges %d\n", g.EdgeCount()); fprintf (file, "nterminals %d\n", g.TerminalCount()); } public: static EdgeCost ReadBound(FILE logfile, char graphname) { EdgeCost answer = -1; FILE file = fopen ("bounds.txt", "r"); if (!file) { fprintf (stderr, "Could not find bounds file.\n"); fflush (stderr); return answer; } fprintf (stderr, "Reading bounds file... "); fflush (stderr); double solution; const int BUFSIZE = 65534; //1048574; char buffer [BUFSIZE+2]; char bufseries [BUFSIZE+2]; char bufclass [BUFSIZE+2]; char bufinstance [BUFSIZE+2]; sprintf (bufseries, "undefined"); sprintf (bufclass, "undefined"); while (fgets(buffer, BUFSIZE, file)!=0) { //fprintf (stderr, "<%s> ", buffer); if (sscanf (buffer, "#series %s", bufseries) > 0) { continue; } if (sscanf (buffer, "#class %s", bufclass) > 0) { continue; } if (sscanf (buffer, "%s %lg", bufinstance, &solution)>0) { if (strcmp (bufinstance, graphname) == 0) { answer = (EdgeCost)solution; fprintf (logfile, "instance %s\n", graphname); fprintf (logfile, "series %s\n", bufseries); fprintf (logfile, "class %s\n", bufclass); fprintf (logfile, "bestknown %.20f\n", (double)solution); } } } fclose(file); //fprintf (stderr, "done (solution is %.0f).\n", (double)answer); //fflush (stderr); return answer; } typedef enum { MS_PLAIN, MS_COMBINATION, MS_BINARY, MS_MULTILEVEL, MS_TIMEBOUNDEDCOMBINATION, MS_TIMEBOUNDEDMULTILEVEL, MS_TIMEBOUNDEDADAPTIVE, MS_NUMBER } MSType; static void ShowUsage () { fprintf (stderr, "Usage: steiner <stp_file> [-bb] [-ub] [-prep] [-msit] [-seed] [-mstype]\n"); fprintf (stderr, "Valid types: plain(%d) combination(%d) binary(%d) multilevel(%d)\n", MS_PLAIN, MS_COMBINATION, MS_BINARY, MS_MULTILEVEL); exit (-1); } static void RunMultistart(Graph &g, int mstype, int msit, EdgeCost &gbestfound, EdgeCost &bestknown, SteinerConfig &config, char name, GlobalInfo ginfo, ExecutionLog executionLogPtr, SteinerSolution outSolution) { double mstime = 0; EdgeCost mscost = g.GetFixedCost(); int elite = -1; EdgeCost bestfound = gbestfound; if (g.EdgeCount()>0 && g.TerminalCount()>1) { fprintf(stderr, "MULTISTARTING WITH %d\n", mstype); mscost = INFINITE_COST; // If the multistart type is the time bounded combination multistart type, do not do the // incremental number of iterations. if (mstype == MS_TIMEBOUNDEDCOMBINATION \|\| mstype == MS_TIMEBOUNDEDMULTILEVEL \|\| mstype == MS_TIMEBOUNDEDADAPTIVE) { SteinerSolution solution(&g); RFWTimer mstimer(true); TimeBoundedMultistart(solution, mstype, msit, config.OUTPUT_INCUMBENT ? name : NULL, -1, &config, ginfo, executionLogPtr); mstime = mstimer.getTime(); if (outSolution != nullptr) { outSolution->CopyFrom(&solution); mscost = solution.GetCost(); } } else { int doneit = 0; for (int maxit = (config.TIME_LIMIT <= 0 ? (msit <= 0 ? 2 : msit) : 2); (msit <= 0 \|\| doneit < msit) && (config.TIME_LIMIT <= 0 \|\| executionLogPtr->timerPtr->getTime() < config.TIME_LIMIT); maxit = 2) { SteinerSolution solution(&g); int curit = maxit; if (msit > 0 && doneit + maxit > msit) curit = msit - doneit; fprintf(stderr, "RUNNING %d ITERATIONS (%d ALREADY DONE IN %.2f SEC).\n", curit, doneit, executionLogPtr->timerPtr->getTime()); RFWTimer mstimer(true); switch (mstype) { case MS_PLAIN: PlainMultistart(solution, curit, -1, &config); break; case MS_COMBINATION: CombinationMultistart(solution, curit, elite, config.OUTPUT_INCUMBENT ? name : NULL, -1, &config, ginfo, executionLogPtr); break; case MS_BINARY: BinaryMultistart(solution, curit, name, &config); break; case MS_MULTILEVEL: MultilevelMultistart(solution, curit, curit, elite, config.OUTPUT_INCUMBENT ? name : NULL, -1, &config); break; }; doneit += curit; mstime += mstimer.getTime(); if (solution.GetCost() < mscost) { fprintf(stderr, "FOUND BETTER SOLUTION. IMPROVING COST FROM %.0f TO %.0f.\n", mscost, solution.GetCost()); mscost = solution.GetCost(); if (outSolution != nullptr && (outSolution->GetCost() > solution.GetCost() \|\| outSolution->EdgeCount() == 0)) { outSolution->CopyFrom(&solution); } } //if (outSolution != nullptr && (outSolution->GetCost() > solution.GetCost() \|\| outSolution->EdgeCount() == 0)) { // outSolution->CopyFrom(&solution); // fprintf(stderr, "FOUND BETTER SOLUTION. IMPROVING COST FROM %.0f TO %.0f.\n", mscost, solution.GetCost()); // mscost = solution.GetCost(); //} } } } if (mscost < bestfound) bestfound = mscost; fprintf (stderr, "Solution is %.12f.\n", (double)mscost); /* double ratio = (double)mscost / (double)bestknown; double error = ratio - 1; fprintf (stdout, "ratio %.12f\n", ratio); fprintf (stdout, "error %.12f\n", error); fprintf (stdout, "pcterror %.12f\n", 100.0 * error); / Basics::ReportResults(stdout, "ms", mstime, mscost, bestknown); fprintf (stdout, "msiterations %d\n", msit); fprintf(stdout, "mstype %d\n", mstype); //fprintf (stdout, "mssolution %.0f\n", mscost); //fprintf (stdout, "mstimeseconds %.12f\n", mstime); gbestfound = bestfound; } static void Solve (int argc, char argv) { const uint64_t version = 201706010852; cout << "version " << version << endl << "precision " << fixed << setprecision(20) << EDGE_COST_PRECISION << endl; if (argc < 2) ShowUsage(); Graph g; g.ReadSTP(argv[1]); char filename = argv[1]; char name = new char[strlen(filename)+1]; ExtractFilename(filename, name); OutputGraphStats (stdout, g, argv[1]); fprintf (stdout, "graph %s\n", name); EdgeCost bestknown = ReadBound(stdout, name); EdgeCost bestfound = INFINITE_COST; //ReadBound("bounds.txt", ); EdgeCost solcost = 0; bool MSTPRUNE = false; bool PREPROCESS = false; bool SAFE_PREPROCESS = false; bool DUALASCENT = false; bool BRANCHBOUND = false; bool LOCALSEARCH = false; bool MULTISTART = false; bool BINARYMULTISTART = true; int mstype = MS_COMBINATION; int msit = 0; int seed = 17; EdgeCost primal = INFINITE_COST; //fprintf (stderr, "ARGC is %d\n", argc); SteinerConfig config; for (int i=2; i<argc; i+=2) { if (i == argc-1) ShowUsage(); if (strcmp(argv[i], "-ub")==0) { primal = atoi(argv[i+1]); fprintf (stderr, "Setting upper bound to %.0f.\n", primal); continue; } if (strcmp(argv[i], "-bb")==0) { if (atoi(argv[i+1])==0) { BRANCHBOUND = false; } else { BRANCHBOUND = true; } continue; } if (strcmp(argv[i], "-prep")==0) { if (atoi(argv[i+1])!=0) { fprintf (stderr, "Will do preprocessing.\n"); PREPROCESS = true; if (atoi(argv[i + 1]) > 1) SAFE_PREPROCESS = true; } continue; } if (strcmp(argv[i], "-ls")==0) { if (atoi(argv[i+1])!=0) { fprintf (stderr, "Will do localsearch.\n"); LOCALSEARCH = true; } continue; } if (strcmp(argv[i], "-bms")==0) { if (atoi(argv[i+1])!=0) { fprintf (stderr, "Will do binary.\n"); BINARYMULTISTART = true; } continue; } if (strcmp(argv[i], "-msit")==0) { msit = (atoi(argv[i+1])); fprintf (stderr, "Will run %d multistart iterations.\n", msit); continue; } if (strcmp(argv[i], "-mstype")==0) { mstype = (atoi(argv[i+1])); fprintf (stderr, "Will run multistart type %d.\n", mstype); assert(mstype != 14); // This is corrupt (BB with TimeBoundedMultistart) continue; } if (strcmp(argv[i], "-seed")==0) { seed = atoi(argv[i+1]); fprintf (stderr, "Set seed to %d.\n", seed); continue; } //maybe config knows what to do with this parameter config.ReadParameter (argv[i], argv[i+1]); } fflush (stderr); if (config.EARLY_STOP_BOUND < 0) {config.EARLY_STOP_BOUND = bestknown;} bestfound = primal; config.Output(stdout); fprintf (stdout, "seed %d\n", seed); // if there is a best known solution, output it whenever we find it if (config.OUTPUT_THRESHOLD<0 && bestknown>=0) { config.OUTPUT_THRESHOLD = bestknown; } RFWTimer timer(true); // solution cost log. ExecutionLog executionLog(&g, &timer, config.TIME_LIMIT); MULTISTART = (msit != 0); RFWRandom::randomize(seed); bool APPLY_PERTURBATION = false; if (APPLY_PERTURBATION) { fprintf (stderr, "Applying perturbation... "); int m = g.EdgeCount(); vector<EdgeCost> pertcost (m+1,-1); RFWLocalRandom random(seed+17); PerturbationTools::ApplyPerturbation(g, pertcost, random, 1, 1.0001); g.ApplyCosts(pertcost); for (int i=1; i<std::min(10, m); i++) { fprintf (stderr, "%.5f ", (double)g.GetCost(i)); } fprintf (stderr, "done.\n"); } if (PREPROCESS) { fprintf (stderr, "Should be preprocessing.\n"); RFWTimer preptime(true); Preprocessing::RunPreprocessing(g, !SAFE_PREPROCESS); fprintf (stdout, "preptime %.6f\n", preptime.getTime()); fprintf (stdout, "prepfixed %.6f\n", g.GetFixedCost()); //PrepBottleneck(g); //exit(-1); } bool GUARDED_MULTISTART = false; if (mstype > MS_NUMBER) { GUARDED_MULTISTART = true; mstype = mstype % 10; fprintf (stderr, "Will run guarded mode %d.\n", mstype); } double second_time = 0; double first_time; SteinerSolution bestSolution(&g); if (MULTISTART && GUARDED_MULTISTART) { fprintf (stderr, "There are %d threads, %d processes.\n", omp_get_max_threads(), omp_get_num_procs()); GlobalInfo ginfo; ginfo.fixed = g.GetFixedCost(); config.DEPTH_LIMIT = 128; fprintf (stderr, "Setting depth limit to %d.\n", config.DEPTH_LIMIT); omp_set_num_threads(2); RFWTimer ftimer(true); #pragma omp parallel { Graph thread_g = g; EdgeCost thread_bestfound = bestfound; fprintf (stderr, "<%d> ", omp_get_thread_num()); if (omp_get_thread_num() == 0) { RunMultistart(thread_g, mstype, msit, thread_bestfound, bestknown, config, name, &ginfo, &executionLog, nullptr); fprintf (stderr, "DONE RUNNING MULTISTART AND FOUND %.3f\n", thread_bestfound); ginfo.MakeSolved(); } else if (omp_get_thread_num() == 1) { RFWTimer stimer(true); fprintf (stderr, "Should be running something smarter here.\n"); int bbseed = seed; if (bbseed > 0) bbseed = -bbseed; BranchBound::RunBranchAndBound(thread_g, bbseed, thread_bestfound, thread_bestfound, bestknown, config, &ginfo, &executionLog); second_time += stimer.getTime(); fprintf (stderr, "DONE RUNNING BRANCHING-AND-BOUND!\n"); if (!ginfo.bbpruned) ginfo.MakeSolved(); else fprintf (stderr, "Did not find the optimal solution, though.\n"); } #pragma omp critical { if (thread_bestfound < bestfound) { bestfound = thread_bestfound; fprintf (stderr, "THREAD %d UPDATED TO %.3f\n", omp_get_thread_num(), bestfound); } } } #pragma omp barrier { fprintf (stderr, "Done with this.\n"); } first_time = ftimer.getTime(); fprintf (stdout, "bbpruned %d\n", ginfo.bbpruned); MULTISTART = false; BRANCHBOUND = false; } if (MULTISTART) { RunMultistart(g, mstype, msit, bestfound, bestknown, config, name, NULL, &executionLog, &bestSolution); } if (LOCALSEARCH) { int maxit = 10; for (int m=0; m<5; m++) { double besttime = 99999999; fprintf (stderr, "Running %d... ", m); fflush(stderr); if (m==3) { fprintf (stderr, "WARNING! SKIPPING METHOD 3.\n"); continue; } //if (m != 2) continue; for (int i=0; i<maxit; i++) { RFWTimer timer(true); SteinerSolution solution(&g); switch (m) { case 0: MSTPrim (g, solution); break; case 1: MSTKruskal (g, solution); break; case 2: ConstructiveAlgorithms::SPH (g, solution, NULL, 1); break; case 3: FullBoruvka (g, solution); break; case 4: TestLocalSearch (g, solution); break; } if (m>=2 && MSTPRUNE) { MSTPrune(g,solution); } solcost = solution.GetCost(); double t = timer.getTime(); if (t < besttime) besttime = t; } fprintf (stderr, "Method %d found solution of cost %d in %.3f milliseconds (best of %d runs).\n", m, solcost, besttime 1000.0, maxit); fflush(stderr); } } if (BRANCHBOUND) { BranchBound::RunBranchAndBound(g, seed, primal, bestfound, bestknown, config, NULL, &executionLog); } double walltime = timer.getTime(); fprintf (stdout, "totalwalltimeseconds %.12f\n", walltime); //fprintf (stdout, "totaltimeseconds %.12f\n", walltime + second_time); //fprintf (stdout, "bestsolution %.0f\n", bestfound); Basics::ReportResults(stdout, "total", walltime + first_time, bestfound, bestknown); Basics::ReportResults(stdout, "totalcpu", walltime + second_time, bestfound, bestknown); // Dump official output logs. if (!config.LOG_FILENAME.empty()) { ofstream logFile(config.LOG_FILENAME.c_str()); if (logFile.is_open()) { logFile << "SECTION Comment" << endl << "Name \"" << name << "\"" << endl << "Problem \"SPG\"" << endl << "Program \"puw\"" << endl << "Version \"" << version << "\"" << endl << "End" << endl << endl << "SECTION Solutions" << endl; for (size_t i = 0; i < executionLog.solCost.size(); ++i) { logFile << "Solution " << fixed << executionLog.solCost[i].second << " " << fixed << executionLog.solCost[i].first << endl; } logFile << "End" << endl << endl << "SECTION Run" << endl << "Threads 1" << endl << "Time " << fixed << walltime << endl << "Dual 0" << endl; if (executionLog.solCost.empty()) logFile << "Primal inf" << endl; else logFile << "Primal " << fixed << executionLog.bestSolution.GetCost() << endl; logFile << "End" << endl << endl; if (!executionLog.solCost.empty()) { logFile << "SECTION Finalsolution" << endl; size_t numVertices = 0; for (int v = 1; v <= g.VertexCount(); ++v) { if (executionLog.bestSolution.GetDegree(v) > 0 \|\| g.IsTerminal(v)) ++numVertices; } logFile << "Vertices " << numVertices << endl; for (int v = 1; v <= g.VertexCount(); ++v) { if (executionLog.bestSolution.GetDegree(v) > 0 \|\| g.IsTerminal(v)) logFile << "V " << v << endl; } logFile << "Edges " << executionLog.bestSolution.EdgeCount() << endl; for (size_t e = 1; e <= g.EdgeCount(); ++e) { if (executionLog.bestSolution.Contains(e)) logFile << "E " << g.GetFirstEndpoint(e) << " " << g.GetSecondEndpoint(e) << endl; } logFile << "End" << endl; } logFile.close(); } } delete [] name; } static void CombineSolutions(SteinerSolution &target, SteinerSolution &sa, SteinerSolution &sb, RFWLocalRandom &random, SteinerConfig config) { Graph &g = sa.g; int n = g.VertexCount(); int m = g.EdgeCount(); const bool verbose = false; /* UniverseSet baselist = new UniverseSet(n); VoronoiData voronoi = new VoronoiData(n); UnionFind uf = new UnionFind(n); SteinerSolution solution = new SteinerSolution(g); BinaryHeap<ArcCost> heap = new BinaryHeap<ArcCost>(n); ArcCost [] pertcost = new ArcCost [m+1]; SteinerSolution target = new SteinerSolution(g); Console.Error.Write("{0} x {1}:", sa.GetCost(), sb.GetCost()); / vector<EdgeCost> pertcost(m+1,-1); //was: 1000, (100,500), 1 for (int e = 1; e <= m; e++) { int tcount = 0; if (sa.Contains(e)) tcount++; if (sb.Contains(e)) tcount++; int mult = 1; if (tcount == 0) mult = 1000; //random.GetInteger(200,300); //edge in neither solution: very expensive else if (tcount == 1) mult = random.GetInteger(100, 500); //split edge: intermediate cost else { mult = 1; } //random.GetInteger(100,200); } //edge in both: keep it pertcost[e] = g.GetCost(e) mult; // g.GetCost(a); } int root = Basics::PickRandomTerminal(g, random); ConstructiveAlgorithms::SPH (g, target, &pertcost[0], root); MSTPrune(g,target); RunLocalSearch(g, target, random, -1, config); if (verbose) fprintf (stderr, "%d x %d -> %d\n", sa.GetCost(), sb.GetCost(), target.GetCost()); /* baselist.Reset(); for (int v = 1; v <= n; v++) {if (g.IsTerminal(v)) baselist.Insert(v);} ComputeVoronoi(voronoi, baselist, heap, pertcost); uf.Reset(); target.Reset(); Boruvka(target, voronoi, uf, pertcost); ArcCost borcost = target.GetCost(); FullLocalSearch(target); ArcCost newcost = target.GetCost(); Console.Error.WriteLine(" {0}", newcost); return target; }/ } static void BinaryMultistart (SteinerSolution &solution, int maxit, char outprefix, SteinerConfig config) { int nlevels = 32; vector<SteinerSolution> levelsol (nlevels, NULL); //solution[i]: solution obtained by combining 2^i solutions Graph &g = solution.g; int n = g.VertexCount(); int m = g.EdgeCount(); RFWTimer timer(true); RFWLocalRandom random (RFWRandom::getInteger(1,999999999)); EdgeCost bestcost = 999999999; const bool verbose =false; bool USE_PERTURBATION = true; bool ADAPTIVE_PERTURBATION = false; fprintf (stderr, "Running multistart for %d iterations and %d levels (perturbation=%d).\n", maxit, nlevels, USE_PERTURBATION); fflush(stderr); vector<EdgeCost> pertcost (m+1,-1); //bool USE_PERTURBATION = true; //bool ADAPTIVE_PERTURBATION = false; SteinerSolution cursol(&g); SteinerSolution bestsol(&g); SteinerSolution combsol(&g); //EdgeCost bestcost = 999999999; for (int i=0 ; i<maxit; i++) { int root = random.GetInteger(1,n); //PickRandomTerminal(g, random); if (USE_PERTURBATION) { PerturbationTools::InitPerturbation(g, pertcost, random, config); } ConstructiveAlgorithms::SPH (g, cursol, USE_PERTURBATION ? &pertcost[0] : NULL, root); MSTPrune(g,cursol); RunLocalSearch(g, cursol, random, -1, config); if (cursol.GetCost() < bestcost) { bestcost = cursol.GetCost(); bestsol.CopyFrom(&cursol); } int j; for (j=0; j<nlevels; j++) { fprintf (stderr, "%10d : %2d : %.0f : ", (int)i, j, bestcost); if (levelsol[j] == NULL) { fprintf (stderr, "+%.0f\n", cursol.GetCost()); levelsol[j] = new SteinerSolution(&cursol); break; } // so there is a solution at level j //SteinerSolution refsol = elite.GetReference(random.GetInteger(1, elite.Count())); int maxtries = 5; int t; for (t=0; t<maxtries; t++) { CombineSolutions(combsol, cursol, levelsol[j], random, config); //fprintf (stderr, "%.0f x %.0f -> %.0f\n", cursol.GetCost(), levelsol[j]->GetCost(), combsol.GetCost()); if (combsol.GetCost() < cursol.GetCost() && combsol.GetCost() < levelsol[j]->GetCost()) { break; //cursol.CopyFrom(&combsol); } } fprintf (stderr, "<%d>", t); if (combsol.GetCost() > cursol.GetCost()) { combsol.CopyFrom(&cursol); fprintf (stderr, "a"); //fprintf (stderr, "!"); } if (combsol.GetCost() > levelsol[j]->GetCost()) { combsol.CopyFrom(levelsol[j]); fprintf (stderr, "b"); } cursol.CopyFrom(&combsol); delete levelsol[j]; levelsol[j] = NULL; //if (cursol.GetCost() < cursol. if (cursol.GetCost() < bestcost) { bestcost = cursol.GetCost(); bestsol.CopyFrom(&cursol); } } if (i%10==0) fflush(stderr); if (j==nlevels) { fprintf (stderr, "Ran out of levels!\n"); break; } } for (int i=0; i<nlevels; i++) { if (levelsol[i]) delete levelsol[i]; } solution.CopyFrom(&bestsol); } static void EliteMultistart (SteinerSolution &solution, int maxit, int capacity, char outprefix, SteinerConfig config) { Graph &g = solution.g; SteinerSolution bestsol(&g); SteinerSolution combsol(&g); EdgeCost bestcost = INFINITE_COST; RFWLocalRandom random (RFWRandom::getInteger(1,999999999)); SolutionPool elite(maxit); for (int i=0; i<999999; i++) { CombinationMultistart(solution, maxit, capacity, NULL, 0); EdgeCost curcost = solution.GetCost(); fprintf (stderr, "Should be adding solution %.0f to capacity %d.\n", (double)curcost, capacity); fflush(stderr); int pos1 = elite.Add(&solution); //int pos1 = -1; CascadedCombination(solution, combsol, elite, -1, random, config); curcost = solution.GetCost(); int pos2 = elite.Add(&solution); fprintf (stderr, "[%d,%d:%.0f] ", pos1, pos2, (double)solution.GetCost()); if (curcost < bestcost) { bestsol.CopyFrom(&solution); bestcost = curcost; } fprintf (stderr, "Iteration %d: %.0f\n", i, (double)bestsol.GetCost()); elite.Output(stderr, 8); } solution.CopyFrom(&bestsol); } //-------------------------- // Repeatedly combine initial solution with others from the elite set, then add the result to elite set itself. // Combinations continue until the algorithm fails to improve 'maxfail' times. static void CascadedCombination(SteinerSolution &solution, SteinerSolution &combsol, SolutionPool &elite, int maxfail, RFWLocalRandom &random, SteinerConfig config) { if (maxfail < 0) maxfail = config->MAX_COMB_FAIL; int failures_to_go = maxfail; const bool verbose = false; if (verbose) fprintf (stderr, "%d->", solution.GetCost()); while (failures_to_go > 0) { SteinerSolution refsol = elite.GetReference(random.GetInteger(1, elite.Count())); CombineSolutions(combsol, solution, refsol, random, config); if (!combsol.IsBetter(&solution)) { failures_to_go --; } else { solution.CopyFrom(&combsol); } } if (verbose) fprintf (stderr, "%d\n", solution.GetCost()); elite.Add(&solution); } static void AddSmallPerturbation (Graph &g) { fatal ("deprecated function"); int m = g.EdgeCount(); vector<EdgeCost> pertcost(m+1); for (int e=1; e<=m; e++) { EdgeCost c = 10000 g.GetCost(e) + RFWRandom::getInteger(0,10); pertcost[e] = c; } g.ApplyCosts(pertcost); } struct DistancePair { int source; EdgeCost distance; }; class ClosenessData { private: int k; int maxid; void GetBounds (int v, int &first, int &last) { first = vmaxid; last = (v+1)maxid; } public: vector<DistancePair> data; ClosenessData(int _k, int _maxid) { k = _k; maxid = _maxid; data.resize(kmaxid+1); } }; static void FindKClosest (Graph &g, int k, vector<int> sources, ClosenessData &cdata) { int n = g.VertexCount(); for (int v=1; v<=n; v++) { //cdata[ } } static void KeyVertexInsertion (SteinerSolution &solution, RFWLocalRandom &random) { //return; Graph &g = solution.g; int n = g.VertexCount(); SteinerSolution tempsol(&g); RFWStack<int,true> tempterm(n+1); //fprintf (stderr, "Should be finding improvements!\n"); fprintf (stderr, "k"); const bool MOVE_SIDEWAYS = true; vector<int> perm(n+1); for (int v=1; v<=n; v++) {perm[v] = v;} for (int i=1; i<n; i++) { int j = random.GetInteger(i,n); std::swap(perm[i], perm[j]); } int improvements = 1; while (improvements > 0) { improvements = 0; //for (int v=1; v<=n; v++) { for (int p=1; p<=n; p++) { int v = perm[p]; //RFWRandom::getInteger(1,n); //warning! Should have a real permutation. //fprintf (stderr, "%d ", v); if (g.IsTerminal(v)) continue; //if (!solution.Contains(v)) continue; //MUCH WEAKER VERSION OF THE SEARCH /* if (solution.GetDegree(v) <= 2) { //fprintf (stderr, "."); continue; //WARNING: THIS IS FOR TESTING ONLY }/ //fprintf (stderr, "v%d ", v); tempterm.reset(); //fflush (stderr); // push all current terminals for (int w=1; w<=n; w++) { if (g.IsTerminal(w)) continue; if (solution.GetDegree(w) <= 2) continue; //fprintf (stderr, "t%d:%d ", w, solution.GetDegree(w)); tempterm.push(w); } //fprintf (stderr, "Created %d new terminals.\n", tempterm.getNElements()); // push v itself (if not already pushed) //if (solution.GetDegree(v) <= 2) tempterm.push(v); int oldt = g.TerminalCount(); //fprintf (stderr, "oldt=%d ", g.TerminalCount()); for (int i=1; i<=tempterm.getNElements(); i++) { int w = tempterm.peek(i); //fprintf (stderr, "x"); if (g.IsTerminal(w)) fatal ("something wrong!\n"); g.MakeTerminal(w); if (g.TerminalCount() == oldt) fatal ("insertion did nothing"); } //fprintf (stderr, "newt=%d ", g.TerminalCount()); tempsol.Reset(); //fprintf (stderr, "%.0f+%.0f = ", solution.GetCost(), tempsol.GetCost()); ConstructiveAlgorithms::SPH(g, tempsol, NULL, v); //fprintf (stderr, "%.0f>>%.0f ", oldcost, newcost); for (int i=1; i<=tempterm.getNElements(); i++) { int w = tempterm.peek(i); g.UnmakeTerminal(w); } MSTPrune(g, tempsol); EdgeCost oldcost = solution.GetCost(); EdgeCost newcost = tempsol.GetCost(); //if (newcost - oldcost > 0) fprintf (stderr, "%.0f ", newcost - oldcost); //fflush(stderr); double improvement = oldcost - newcost; // remember the new solution if there is an improvement or a tie (if MOVE_SIDEWAYS is true) if (improvement > EDGE_COST_PRECISION \|\| (MOVE_SIDEWAYS && (improvement > -EDGE_COST_PRECISION))) { solution.CopyFrom(&tempsol); if (improvement > EDGE_COST_PRECISION) { fprintf (stderr, "."); improvements ++; fprintf (stderr, "i%.0f ", newcost); fflush(stderr); return; } } } } } static void DecayLocalSearch (SteinerSolution &solution, vector<EdgeCost> &original, RFWLocalRandom &random, int decaysteps, double exponent, SteinerConfig config, ExecutionLog executionLogPtr = nullptr) { Graph &g = solution.g; int m = g.EdgeCount(); vector<EdgeCost> current(m+1); const bool verbose = true; double precision = EDGE_COST_PRECISION; // run a few iterations of the local search while decaying the perturbation (towards unperturbed solution) int decaytogo = decaysteps; for (;;) { EdgeCost prevcost = solution.GetCost(); // run one round of local seach MSTPrune(g,solution); RunLocalSearch(g, solution, random, 1, config, executionLogPtr); EdgeCost newcost = solution.GetCost(); if (decaytogo == 0) break; if (prevcost - newcost <= precision) { fprintf (stderr, "<%d> ", decaysteps - decaytogo); break; } decaytogo --; g.RetrieveCosts(current); for (int e=1; e<=m; e++) { //current[e] = original[e] + (current[e] - original[e]) * exponent; //NOT REALLY AN EXPONENT current[e] = original[e] + (current[e] - original[e]) * exponent; //NOT REALLY AN EXPONENT } g.ApplyCosts(current); solution.UpdateCost(); } g.ApplyCosts(original); //restore original edge costs solution.UpdateCost(); //recost the existing solution EdgeCost before = solution.GetCost(); // this is the original cost //fprintf (stderr, "d%.0f->", solution.GetCost()); //SPH (g, solution, NULL, root); //fprintf (stderr, "[%d->", solution.GetCost()); // run local search on current solution using original costs MSTPrune(g,solution); RunLocalSearch(g, solution, random, -1, config); EdgeCost after = solution.GetCost(); if (verbose) { fprintf (stderr, " %.0f", after); //fprintf (stderr, " %3.0f", before - after); } //fprintf (stderr, "%d]", solution.GetCost()); } /** * Generate randomized solution from scratch by perturbing edge weights, runing a constructive algorithm, then applying local search. * The local search is applied to the perturbed graph initially, but the perturbation may be gradually dampened (removed). * / static void GenerateRandomizedSolution(SteinerSolution &solution, int root, vector<EdgeCost> &pertcost, RFWLocalRandom &random, SteinerConfig config, ExecutionLog executionLogPtr = nullptr) { Graph &g = solution.g; int m = g.EdgeCount(); const bool VERBOSE_STEP = false; vector<EdgeCost> original (m+1); //remember original costs g.RetrieveCosts(original); // find local optimum with perturbed costs g.ApplyCosts(pertcost); ConstructiveAlgorithms::SPH (g, solution, NULL, root); if (executionLogPtr != nullptr) { fprintf(stderr, "ADDING SPH SOLUTION WITH COST %f.\n", solution.GetCost()); executionLogPtr->AddSolution(solution); } if (VERBOSE_STEP) { fprintf (stderr, "Done after SPH (%d).\n", solution.GetCost()); fflush(stderr); } int LS_PERT_ROUNDS= std::max(999,g.VertexCount()); double LS_PERT_EXPONENT = 1.0; //no decay if (config) { LS_PERT_ROUNDS = config->LS_PERT_ROUNDS; LS_PERT_EXPONENT = config->LS_PERT_EXPONENT; } if (LS_PERT_EXPONENT <= 0) fatal ("invalid perturbation exponent"); bool DECAY_LOCAL_SEARCH = (LS_PERT_EXPONENT <= 0.999999); if (DECAY_LOCAL_SEARCH) { DecayLocalSearch(solution, original, random, LS_PERT_ROUNDS, LS_PERT_EXPONENT, config, executionLogPtr); } else { MSTPrune(g,solution); if (VERBOSE_STEP) { fprintf (stderr, "Done after MSTPrune (%d).\n", solution.GetCost()); fflush(stderr); } RunLocalSearch(g, solution, random, LS_PERT_ROUNDS, config, executionLogPtr); //, 2); if (VERBOSE_STEP) { fprintf (stderr, "Done after LocalSearch (%d).\n", solution.GetCost()); fflush(stderr); } // find real local optimum g.ApplyCosts(original); solution.UpdateCost(); //SPH (g, solution, NULL, root); //fprintf (stderr, "[%d->", solution.GetCost()); MSTPrune(g,solution); RunLocalSearch(g, solution, random, -1, config); //fprintf (stderr, "%d]", solution.GetCost()); } } static int ComputeCapacity(int maxit, SteinerConfig config) { double denominator = 1.0; if (config) denominator = config->ELITE_DENOMINATOR; int capacity = (int)ceil(sqrt((double)maxit / denominator)); return capacity; } static void PlainMultistart (SteinerSolution &solution, int maxit, int capacity, SteinerConfig config) { if (capacity<0) capacity = ComputeCapacity(maxit, config); SolutionPool elite (capacity); RFWLocalRandom random (RFWRandom::getInteger(1,999999999)); FlexibleMultistart (solution, maxit, elite, NULL, maxit, config); //CombinationMultistart (solution, maxit, capacity, NULL, maxit, config); SolutionPool children (capacity); SolutionPool a, b; a = &elite; b = &children; fprintf (stderr, "There are %d elite solutions.\n", elite.GetCount()); int maxfail = 100; int failures = maxfail; EdgeCost curbest = elite.FindBestCost(); //fprintf (stderr, "Initial best is %.0f\n", curbest); //exit(-1); while (1) { fprintf (stderr, "HERE!\n"); fflush(stderr); RecombineGeneration(a, b, random, config); //if (b->FindBestCost() >= a->FindBestCost()) break; //fprintf (stderr, "Doing stuff now.\n"); //fflush (stderr); //EdgeCost newbest = curbest +1; EdgeCost newbest = b->FindBestCost(); if (newbest >= curbest) { failures --; if (failures == 0) break; } else { failures = maxfail; curbest = newbest; } fprintf (stderr, "New best solution is %.0f\n", curbest); //break; //fprintf (stderr, "Swapping (%d,%d)...\n", a->GetCount(), b->GetCount()); //fflush(stderr); std::swap(a,b); //fprintf (stderr, "Resetting...\n"); //fflush(stderr); b->HardReset(); } fprintf (stderr, "Ended with solution with cost %.0f\n", curbest); } static void CombinationMultistart(SteinerSolution &solution, int maxit, int capacity, char outprefix, int COMBINATION_THRESHOLD = -1, SteinerConfig config = NULL, GlobalInfo ginfo = NULL, ExecutionLog executionLogPtr = nullptr) { if (capacity<0) capacity = ComputeCapacity(maxit, config); SolutionPool elite (capacity); if (!config->AGGRESSIVE_COMBINATION) COMBINATION_THRESHOLD = capacity; fprintf (stderr, "<<<<< %p >>>>>>\n", ginfo); FlexibleMultistart (solution, maxit, elite, outprefix, COMBINATION_THRESHOLD, config, ginfo, executionLogPtr); } static void TimeBoundedMultistart(SteinerSolution &solution, int mstype, int maxitupper, char outprefix, int COMBINATION_THRESHOLD = -1, SteinerConfig config = NULL, GlobalInfo ginfo = NULL, ExecutionLog executionLogPtr = nullptr) { SolutionPool tentativeElite(2); RFWTimer tentativeTimer(true); FlexibleMultistart(solution, 1, tentativeElite, outprefix, COMBINATION_THRESHOLD, config, ginfo, executionLogPtr, false, false); double tentativeTime = tentativeTimer.getTime(); int maxit = maxitupper; const double blowupFactor = 2.5; // this fell from the sky after careful consideration if (tentativeTime > 0 && config->TIME_LIMIT > 0) maxit = static_cast<int>(ceil(config->TIME_LIMIT / tentativeTime / blowupFactor)); if (maxit > maxitupper) maxit = maxitupper; fprintf(stderr, "TENTATIVE TIME: %.3f SEC; WILL COMPUTE %d ITERATIONS (UPPER BOUND = %d).\n", tentativeTime, maxit, maxitupper); int capacity = ComputeCapacity(maxit, config); SolutionPool elite(capacity); if (!config->AGGRESSIVE_COMBINATION) COMBINATION_THRESHOLD = capacity; // Determine which multistart to call depending on mstype. int localtype = mstype; if (mstype == MS_TIMEBOUNDEDADAPTIVE) { localtype = maxit > 2048 ? MS_TIMEBOUNDEDMULTILEVEL : MS_TIMEBOUNDEDCOMBINATION; } if (localtype == MS_TIMEBOUNDEDCOMBINATION) { FlexibleMultistart(solution, maxitupper, elite, outprefix, COMBINATION_THRESHOLD, config, ginfo, executionLogPtr); } else if (localtype == MS_TIMEBOUNDEDMULTILEVEL) { MultilevelMultistart(solution, maxit, maxitupper, capacity, outprefix, COMBINATION_THRESHOLD, config, ginfo, executionLogPtr); } else { fatal("Not supported."); } if (tentativeElite.FindBestCost() < solution.GetCost()) { solution.CopyFrom(tentativeElite.GetReference(tentativeElite.FindBestPosition())); fprintf(stderr, "USING SOLUTION FROM FIRST TENTATIVE ITERATION.\n"); } fprintf(stdout, "actualmstype %d\n", localtype); } template<class T> static void Permute(vector<T> &array, RFWLocalRandom &random) { int s = (int)array.size(); for (int i=0; i<s-1; i++) { int j = random.GetInteger(i,s-1); std::swap(array[i], array[j]); } } static void MultilevelMultistart(SteinerSolution &solution, int maxit, int maxitupper, int capacity, char outprefix, int COMBINATION_THRESHOLD = -1, SteinerConfig config = NULL, GlobalInfo ginfo = NULL, ExecutionLog executionLogPtr = nullptr) { fprintf (stderr, "SHOULD BE RUNNING MMS FROM SOLUTION %.0f\n", solution.GetCost()); fflush(stderr); if (capacity<0) capacity = ComputeCapacity(maxit, config); const int SUBCOUNT = 4; SolutionPool subelite[SUBCOUNT]; if (!config->AGGRESSIVE_COMBINATION) COMBINATION_THRESHOLD = capacity; int localit = maxit / (2SUBCOUNT); int subcapacity = ComputeCapacity(localit, config); int restit = maxit - SUBCOUNTlocalit; int restcap = ComputeCapacity(restit, config); SolutionPool elite(restcap); // Only do phase one of the algorithm if there are enough iterations. if (localit > 0) { for (int i = 0; i < SUBCOUNT; i++) { subelite[i] = new SolutionPool(subcapacity); } // Runs subcount independent multistarts using half the total number of iterations. for (int i = 0; i < SUBCOUNT; i++) { fprintf(stderr, "SUBPROBLEM %d\n", i); FlexibleMultistart(solution, localit, subelite[i], outprefix, COMBINATION_THRESHOLD, config, ginfo, executionLogPtr); fprintf(stderr, "\n\n"); } vector<SteinerSolution> solpointers; for (int i = 0; i < SUBCOUNT; i++) { subelite[i]->Output(stderr, 8); fprintf(stderr, "\n"); int count = subelite[i]->GetCount(); for (int j = 1; j <= count; j++) solpointers.push_back(subelite[i]->GetReference(j)); } RFWLocalRandom random(RFWRandom::getInteger(1, 1000000)); Permute(solpointers, random); //std::sort(solpointers.begin(), solpointers.end(), [&](SteinerSolution x, SteinerSolution y) {return x->GetCost() >= y->GetCost();}); //sort (&perm[0], &perm[perm.size()], [&](int x, int y) {return totalbound[x]/count[x] > totalbound[y]/count[y];}); for (int i = 0; i < (int)solpointers.size(); i++) { SteinerSolution sol = solpointers[i]; if (sol->GetCost() < solution.GetCost()) { solution.CopyFrom(sol); } elite.Add(sol); } for (int i = 0; i<SUBCOUNT; i++) { delete subelite[i]; } /* for (int i=0; i<SUBCOUNT; i++) { subelite[i]->Output(stderr, 8); fprintf (stderr, "\n"); int count = subelite[i]->GetCount(); for (int j=1; j<=count; j++) { SteinerSolution sol = subelite[i]->GetReference(j); if (sol->GetCost() < solution.GetCost()) {solution.CopyFrom(sol);} elite.Add(sol); } }/ elite.Output(stderr, 8); } fprintf (stderr, "SUPERPROBLEM (from solution %.0f):\n", solution.GetCost()); FlexibleMultistart(solution, maxitupper - SUBCOUNTlocalit, elite, outprefix, COMBINATION_THRESHOLD, config, ginfo, executionLogPtr); } static void RecombineGeneration (SolutionPool &parents, SolutionPool &children, RFWLocalRandom &random, SteinerConfig config) { int pcount = parents.GetCount(); if (pcount == 0) return; fprintf (stderr, "Should be combining.\n"); Graph &g = (parents.GetReference(1)->g); SteinerSolution newsol(&g); SteinerSolution bestsol(&g); bestsol.CopyFrom(parents.GetReference(parents.FindBestPosition())); //fprintf (stderr, "WARNING: THIS IS VERY WRONG.\n"); for (int i=1; i<pcount; i++) { SteinerSolution a = parents.GetReference(i); fprintf (stderr, " %.0f", a->GetCost()); for (int j=i+1; j<=pcount; j++) { SteinerSolution b = parents.GetReference(j); CombineSolutions(newsol, a, b, random, config); //fprintf (stderr, "%.0f x %.0f: %.0f\t", a->GetCost(), b->GetCost(), newsol.GetCost()); if (newsol.GetCost() < bestsol.GetCost()) { bestsol.CopyFrom(&newsol); } children.Add(&newsol); } } // make sure the best solution (even if from a previous iteration) is preserved children.Add(&bestsol); fprintf (stderr, "Best solution is %.0f\n", bestsol.GetCost()); } static void FlexibleMultistart(SteinerSolution &solution, int maxit, SolutionPool &elite, char outprefix, int COMBINATION_THRESHOLD = -1, SteinerConfig config = NULL, GlobalInfo ginfo = NULL, ExecutionLog executionLogPtr = nullptr, bool USE_PERTURBATION = true, bool outputStats = true) { Graph &g = solution.g; //AddSmallPerturbation(g); int itbits = 6; //int maxit = 1 << itbits; //int capacity = 1 << (itbits / 2); /* if (capacity < 0) { double denominator = 1.0; if (config) denominator = config->ELITE_DENOMINATOR; capacity = (int)ceil(sqrt((double)maxit / denominator)); }/ int n = g.VertexCount(); SteinerSolution bestsol(&g); //best solution found so far SteinerSolution combsol(&g); //combined solution bestsol.CopyFrom(&solution); //SolutionPool elite (capacity); int capacity = elite.GetCapacity(); //Graph &g = solution.g; int m = g.EdgeCount(); RFWTimer timer(true); RFWLocalRandom random (RFWRandom::getInteger(1,999999999)); EdgeCost bestcost = INFINITE_COST; if (elite.GetCount() > 0) { int p = elite.FindBestPosition(); bestsol.CopyFrom(elite.GetReference(p)); bestcost = bestsol.GetCost(); } const bool verbose = false; //bool = perturbation; bool ADAPTIVE_PERTURBATION = false; bool RESILIENT_PERTURBATION = USE_PERTURBATION; if (config) { int confpert = config->RESILIENT_PERTURBATION; if (confpert == 0) {RESILIENT_PERTURBATION = false;} else if (confpert == 1) {RESILIENT_PERTURBATION = true;} } fprintf (stderr, "Using resilient perturbation? %d\n", RESILIENT_PERTURBATION); //int COMBINATION_THRESHOLD = -1; //capacity; fprintf (stderr, "Running multistart for %d iterations and %d elite solutions (perturbation=%d).\n", maxit, capacity, USE_PERTURBATION); //fflush (stderr); vector<EdgeCost> pertcost (m+1,-1); const bool VERBOSE_STEP = false; int i; for (i=0; i<maxit; i++) { //if (ginfo) fprintf (stderr, "THERE IS A GINFO.\n"); if (ginfo && ginfo->IsSolved()) { fprintf (stderr, "Stopping at iteration %d.\n", i); break; } if (config->TIME_LIMIT > 0 && executionLogPtr->timerPtr->getTime() >= config->TIME_LIMIT) { fprintf(stderr, "Stopping at iteration %d because of time limit of %2.f sec (%.2f sec passed).\n", i, config->TIME_LIMIT, executionLogPtr->timerPtr->getTime()); break; } int root = random.GetInteger(1,n); //PickRandomTerminal(g, random); if (USE_PERTURBATION) { ADAPTIVE_PERTURBATION = false; //((i % 2) == 1); //random.GetInteger(0,1)==0; //ADAPTIVE_PERTURBATION = true; if (ADAPTIVE_PERTURBATION) { PerturbationTools::AdaptivePerturbation(g, pertcost, elite, random); } else { //fprintf (stderr, "Here!\n"); PerturbationTools::InitPerturbation(g, pertcost, random, config); //fflush (stderr); } } if (RESILIENT_PERTURBATION) { // both constructive and the local search use perturbation GenerateRandomizedSolution (solution, root, pertcost, random, config); } else { // non-resilient perturbation: ConstructiveAlgorithms::SPH (g, solution, USE_PERTURBATION ? &pertcost[0] : NULL, root); if (executionLogPtr != nullptr) executionLogPtr->AddSolution(solution); MSTPrune(g,solution); RunLocalSearch(g, solution, random, -1, config, executionLogPtr); } if (executionLogPtr != nullptr) { executionLogPtr->AddSolution(solution); } //fprintf (stderr, "Adding original solution...\n"); elite.Add(&solution); //add initial solution to the pool //global.UpdateSolution(solution.GetCost()); //make sure we remember it's the best if (i >= COMBINATION_THRESHOLD) { CascadedCombination(solution, combsol, elite, -1, random, config); } else { fprintf (stderr, "! "); } EdgeCost solcost = solution.GetCost(); //fprintf (stderr, "Found solution costing %d.\n", solcost); if (solcost < bestcost) { if (executionLogPtr != nullptr) { executionLogPtr->AddSolution(solution); } bestcost = solcost; bestsol.CopyFrom(&solution); //fprintf (stderr, "HERE (%.2f %p %p %.2f).\n", bestcost, outprefix, config, config->OUTPUT_THRESHOLD); if (outprefix) { if (config && bestcost < config->OUTPUT_THRESHOLD) { fprintf (stderr, "\n<outputting solution with value %0f>\n", bestcost); config->OUTPUT_THRESHOLD = bestcost; bestsol.Output(outprefix); } } if (ginfo) ginfo->UpdateBestFound(bestcost); } bool localverbose = ((i % 10) == 0); if (localverbose) { fprintf (stderr, "%6d : %6d : %10.0f : %10.5f\n", i, root, (double)solcost, (double)bestcost); fflush(stderr); } if (config && bestcost <= config->EARLY_STOP_BOUND) { fprintf (stderr, "Early stop!\n"); break; } //elite.Output(stderr); //if (i % 10 == 0) fflush (stderr); } if (outputStats) { //fprintf (stdout, "msiterations %d\n", maxit); fprintf(stdout, "actualiterations %d\n", i); fprintf(stdout, "earlystop %d\n", maxit != i); fprintf(stdout, "mselite %d\n", capacity); //fprintf (stdout, "totaltimeseconds %.8f\n", timer.getTime()); //fprintf (stdout, "mssolution %.0f\n", (double)bestcost); } fflush (stderr); solution.CopyFrom(&bestsol); } static void Multistart (SteinerSolution &solution, SteinerConfig config) { int maxit = 9999; Graph &g = solution.g; int m = g.EdgeCount(); RFWTimer timer(true); RFWLocalRandom random (RFWRandom::getInteger(1,999999999)); EdgeCost bestcost = INFINITE_COST; bool USE_PERTURBATION = true; fprintf (stderr, "Running multistart for %d iterations with perturbation=%d.\n", maxit, USE_PERTURBATION); vector<EdgeCost> pertcost (m+1,-1); for (int i=0; i<maxit; i++) { int root = Basics::PickRandomTerminal(g, random); if (USE_PERTURBATION) PerturbationTools::InitPerturbation(g, pertcost, random, NULL); ConstructiveAlgorithms::SPH (g, solution, USE_PERTURBATION ? &pertcost[0] : NULL, root); MSTPrune(g,solution); RunLocalSearch(g, solution, random, -1, config); EdgeCost solcost = solution.GetCost(); if (solcost < bestcost) { bestcost = solcost; } if (i % 10 == 0) { fprintf (stderr, "%6d : %6d : %6d : %6d\n", i, root, solcost, bestcost); fflush(stderr); } //if (i % 10 == 0) fflush (stderr); } fflush (stderr); fprintf (stderr, "totaltimeseconds %.8f\n", timer.getTime()); fprintf (stderr, "solution %d\n", bestcost); /* if (LOCALSEARCH) { int maxit = 10; for (int m=0; m<5; m++) { double besttime = 99999999; fprintf (stderr, "Running %d... ", m); fflush(stderr); if (m==3) { fprintf (stderr, "WARNING! SKIPPING METHOD 3.\n"); continue; } //if (m != 2) continue; for (int i=0; i<maxit; i++) { RFWTimer timer(true); SteinerSolution solution(&g); switch (m) { case 0: MSTPrim (g, solution); break; case 1: MSTKruskal (g, solution); break; case 2: SPH (g, solution, NULL, 1); break; case 3: FullBoruvka (g, solution); break; case 4: TestLocalSearch (g, solution); break; } if (m>=2 && MSTPRUNE) { MSTPrune(g,solution); } solcost = solution.GetCost(); double t = timer.getTime(); if (t < besttime) besttime = t; } fprintf (stderr, "Method %d found solution of cost %d in %.3f milliseconds (best of %d runs).\n", m, solcost, besttime * 1000.0, maxit); fflush(stderr); } }/ } static void RunLocalSearch (Graph &g, SteinerSolution &solution, RFWLocalRandom &random, int maxrounds, SteinerConfig config, ExecutionLog executionLogPtr = nullptr) { bool RUN_Q = false; bool RUN_V = false; bool RUN_U = false; bool RUN_K = false; bool RESTRICT_K = false; // bool verbose = false; static bool first = true; char lstype = config->LSTYPE; bool wait = false; for (int i=0; ;i++) { char c = lstype[i]; if (c==0) break; if (c=='w') { wait = true; continue; } switch (c) { case 'k': RUN_K = true; RESTRICT_K = wait; break; case 'v': RUN_V = true; break; case 'u': RUN_U = true; break; case 'q': RUN_Q = true; break; default: fprintf (stderr, "WARNING: invalid local search parameter (%c).\n", c); } wait = false; } //fprintf (stderr, "<%d%d>", RUN_K, RESTRICT_K); //return; //int maxrounds = 999; if (maxrounds < 0) maxrounds = 999; //999; //large number if (first) { fprintf (stderr, "Running with maxrounds %d.\n", maxrounds); } //SPH (g, solution, NULL, PickRandomTerminal(g,random)); //if (verbose) fprintf (stderr, "SPH found solution %d.\n", solution.GetCost()); int n = g.VertexCount(); EdgeCost oldcost = solution.GetCost(); RFWTimer timer(true); int rounds = 0; int i=0; for (i=0; i<maxrounds; i++) { rounds ++; if (RUN_V) { LSVertexInsertion::VertexInsertion(g, solution, n, random); MSTPrune(g, solution); if (verbose) fprintf (stderr, " v%d ", solution.GetCost()); } //fprintf (stderr, "Starting key vertex elimination!\n"); //fflush (stderr); if (RUN_Q) { LSKeyPath::KeyVertexElimination(g, solution, random); //fprintf (stderr, "Ending key vertex elimination!\n"); if (verbose) fprintf (stderr, " q%d ", solution.GetCost()); } if (RUN_U) { LSVertexElimination::VertexElimination(g, solution, random); if (verbose) fprintf (stderr, " u%d ", solution.GetCost()); } if (RUN_K) { if (!RESTRICT_K \|\| solution.GetCost() == oldcost) { KeyVertexInsertion(solution, random); } } EdgeCost newcost = solution.GetCost(); if (newcost > oldcost + EDGE_COST_PRECISION) fatal ("invalid result"); if (newcost > oldcost - EDGE_COST_PRECISION) break; //stop if result did not improve if (executionLogPtr != nullptr) executionLogPtr->AddSolution(solution); oldcost = newcost; } const bool VERBOSE_ROUNDS = false; if (VERBOSE_ROUNDS) fprintf (stderr, "%d ", i); //fprintf (stderr, "%d ", rounds); if (verbose) fprintf (stderr, "\n\nDone with local search: %d (%.2f ms, %.2f ms average)\n", solution.GetCost(), 1000 * timer.getTime(), 1000 * timer.getTime() / (double)rounds); //exit(-1); first = false; } static void TestLocalSearch (Graph &g, SteinerSolution &solution) { RFWLocalRandom random(RFWRandom::getInteger(1,999999999)); bool RUN_Q = true; bool RUN_V = true; bool RUN_U = false; bool verbose = false; ConstructiveAlgorithms::SPH (g, solution, NULL, Basics::PickRandomTerminal(g,random)); if (verbose) fprintf (stderr, "SPH found solution %d.\n", solution.GetCost()); int n = g.VertexCount(); EdgeCost oldcost = solution.GetCost(); RFWTimer timer(true); int rounds = 0; for (int i=0; i<10; i++) { rounds ++; if (RUN_V) { LSVertexInsertion::VertexInsertion(g, solution, n, random); MSTPrune(g, solution); if (verbose) fprintf (stderr, " v%d ", solution.GetCost()); } //fprintf (stderr, "Starting key vertex elimination!\n"); //fflush (stderr); if (RUN_Q) { LSKeyPath::KeyVertexElimination(g, solution, random); //fprintf (stderr, "Ending key vertex elimination!\n"); if (verbose) fprintf (stderr, " q%d ", solution.GetCost()); } if (RUN_U) { LSVertexElimination::VertexElimination(g, solution, random); if (verbose) fprintf (stderr, " u%d ", solution.GetCost()); } EdgeCost newcost = solution.GetCost(); if (newcost > oldcost) fatal ("invalid result"); if (newcost == oldcost) break; oldcost = newcost; } if (verbose) fprintf (stderr, "\n\nDone with local search: %d (%.2f ms, %.2f ms average)\n", solution.GetCost(), 1000 * timer.getTime(), 1000 * timer.getTime() / (double)rounds); //exit(-1); } // Comput minimum spanning tree of the graph g using Prim's algorithm (ignores terminals) // 'solution' will contain the MST edges static void MSTPrim (Graph &g, SteinerSolution &solution) { bool verbose = false; int n = g.VertexCount(); BinaryHeap<EdgeCost> heap(n); // = new BinaryHeap<ArcCost>(n); vector<int> parc (n+1); //not need to initialize unsigned int r = Basics::PickRandomTerminal(g); parc[r] = 0; int nscanned = 0; solution.Reset(); //int inscount = 0; heap.Insert(r, 0); while (!heap.IsEmpty()) { unsigned int v; EdgeCost acost; heap.RemoveFirst(v,acost); //v, out acost); if (v!=r) solution.Insert(parc[v]); //add parent edge to the solution //scan outgoing arcs nscanned ++; SPGArc a, end; for (g.GetBounds(v,a,end); a<end; a++) { int w = a->head; //neighbor if (solution.GetDegree(w) > 0) continue; //ignore if already in solution if (heap.Insert(w, a->cost)) { parc[w] = a->label; //inscount ++; } } } //fprintf (stderr, "%.3f ", (double)inscount / (double)n); //if (nscanned != n) fprintf (stderr, "Warning: graph is not connected"); } //-------------------------------------------------------------- // Kruskal's algorithm to compute the MST of the full graph. // (Could be made faster for some instances with partial sort.) //-------------------------------------------------------------- static void MSTKruskal (Graph &g, SteinerSolution &solution) { // create list of all edges sorted in increasing order of weight const bool verbose = false; int i, m = g.EdgeCount(); vector<int> elist(m+1); for (i=0; i<m; i++) {elist[i] = i+1;} sort(&elist[0], &elist[m], [&](int x, int y) {return g.GetCost(x)<g.GetCost(y);}); // create empty solution and union find with singletons solution.Reset(); int n = g.VertexCount(); UnionFind uf(n); int togo = n-1; //number of unions left // process all edges in order for (i=0; i<m; i++) { int e = elist[i]; int v, w; g.GetEndpoints(e,v,w); if (uf.Union(v,w)) { //if successfully joined... solution.Insert(e); //...we have a new edge in the tree if (--togo==0) break; } } if (verbose) fprintf (stderr, "%.3f ", (double)i/(double)m); } /// Compute the MST of the distance network of the subgraph induced /// by the vertices in bases. /// <param name="solution">Final solution (output)</param> /// <param name="bases">Set of bases (key vertices)</param> /* static void DNH(Graph &g, SteinerSolution &solution, UniverseSet &baselist) { int n = g.VertexCount(); int m = g.EdgeCount(); VoronoiData voronoi = new VoronoiData(n); UnionFind uf = new UnionFind(n); BinaryHeap<ArcCost> heap = new BinaryHeap<ArcCost>(n); ArcCost [] pertcost = null; ComputeVoronoi(voronoi, baselist, heap, pertcost); solution.Reset(); Boruvka(solution, voronoi, uf, pertcost); //Console.Error.WriteLine("DNH"); } / /// Boruvka-based implementation of DNH (given a Voronoi diagram and the associated union-find data structure). /// Traverses a list of edge IDs in each pass, eliminating those that are no longer boundary. /// Seems to be worse than the version that actually traverses graphs. static void Boruvka(Graph &g, SteinerSolution &solution, VoronoiData &voronoi, UnionFind &uf, EdgeCost pertcost) { int v, n = g.VertexCount(); int m = g.EdgeCount(); EdgeCost solvalue = 0; const bool verbose = false; //count boundary regions in the current diagram int nregions = 0; for (v=1; v<=n; v++) { // it's not clear find is needed, unless some merges happened before if (uf.Find(voronoi.GetBase(v))==v) nregions ++; } //Boruvka's algorithm int minarc = new int[n+1]; //minimum outgoing edge from the region based in v EdgeCost minvalue = new EdgeCost[n+1]; //value associated with the neighbor int elist = new int [m]; //list of all potential boundary edges for (int i=0; i<m; i++) elist[i] = (i+1); int ecount = m; //number of edges in edge list int rounds = 0; bool changes = true; while (changes && nregions > 1) { rounds ++; //if (rounds > 3) break; changes = false; //initially, we don't know what are the arcs out of each component for (v=1; v<=n; v++) { minarc[v] = -1; minvalue[v] = 0; } int nextpos = 0; //fprintf (stderr, "%d ", ecount); for (int i=0; i<ecount; i++) { int e = elist[i]; //get edge in the current position int v, w; g.GetEndpoints(e,v,w); int bv = voronoi.GetBase(v); int bw = voronoi.GetBase(w); if (bv == bw) continue; //same base bv = uf.Find(bv); bw = uf.Find(bw); if (bv == bw) continue; //same component //found a boundary edge: move it forward in the list if (i!=nextpos) elist[nextpos++] = e; // get length of actual edge EdgeCost cost = (pertcost!=NULL) ? pertcost[e] : g.GetCost(e); cost += voronoi.GetDistance(v) + voronoi.GetDistance(w); //update bv and bw if better if (minarc[bv]==-1 \|\| (cost<minvalue[bv])) {minarc[bv]=e; minvalue[bv]=cost;} if (minarc[bw]==-1 \|\| (cost<minvalue[bw])) {minarc[bw]=e; minvalue[bw]=cost;} } ecount = nextpos; //fewer edges for next round //join each region to its best neighbor int bvisited = 0; int b; for (b=1; b<=n; b++) { if (minarc[b] >= 0) { //best neighbor defined... bvisited ++; int w = 0; g.GetEndpoints(minarc[b], v, w); int bv = voronoi.GetBase(v); int bw = voronoi.GetBase(w); if (uf.Union(bv,bw)) { // if they were not already joined... changes = true; nregions--; solution.Insert(minarc[b]); while (v != bv) { int f = voronoi.GetParentArc(v); if (!solution.Insert(f)) break; v = g.GetOther(f, v); } while (w != bw) { int f = voronoi.GetParentArc(w); if (!solution.Insert(f)) break; w = g.GetOther(f, w); } } } } } if (verbose) fprintf(stderr, "\n"); delete [] minvalue; delete [] minarc; delete [] elist; } static void DNHPrim (Graph &g, SteinerSolution &solution, VoronoiData &voronoi, UnionFind &uf) { int n = g.VertexCount(); int m = g.EdgeCount(); vector <int> new2old (m+1,-1); Graph dg; dg.SetVertices(n); dg.SetEdges(m); //maximum tentative number of edges // build appropriate subgraph of the distance network int ecount = 0; for (int v=1; v<=n; v++) { int bv = uf.Find(voronoi.GetBase(v)); EdgeCost vdist = -1; SPGArc a, end; for (g.GetBounds(v,a,end); a<end; a++) { int w = a->head; if (v>=w) continue; int bw = uf.Find(voronoi.GetBase(w)); if (bv == bw) continue; dg.MakeTerminal(bv); dg.MakeTerminal(bw); if (vdist<0) vdist = voronoi.GetDistance(v); EdgeCost cost = a->cost + vdist + voronoi.GetDistance(w); dg.AddEdge(bv,bw,cost); new2old[++ecount] = a->label; } } dg.Commit(); //create actual graph // find a solution in the new graph SteinerSolution ds(&dg); MSTPrim(dg,ds); // transform into solution in the new graph solution.Reset(); int newm = dg.EdgeCount(); for (int e=1; e<=newm; e++) { if (!ds.Contains(e)) continue; int orige = new2old[e]; //original boundary edge if (orige<1 \|\| orige>m) {fatal ("Edge out of range.\n");} int v,w; g.GetEndpoints(orige,v,w); solution.Insert(orige); for (;;) { int f = voronoi.GetParentArc(v); if (f<1 \|\| !solution.Insert(f)) break; v = g.GetOther(f,v); } for (;;) { int f = voronoi.GetParentArc(w); if (f<1 \|\| !solution.Insert(f)) break; w = g.GetOther(f,w); } } } /// Run DNH (Boruvka implementation) to create a solution from scratch. /// If 'r' is null, uses the original edge weights; otherwise, perturbs /// edge weights before running the algorithm. /// <param name="solution">The output solution (will be deleted).</param> /// <param name="r">Random number generator.</param> static void FullBoruvka(Graph &g, SteinerSolution &solution) { //, OptRandom r) { int n = g.VertexCount(); int m = g.EdgeCount(); UniverseSet baselist(n); // = new UniverseSet(n); VoronoiData voronoi(n); // = new VoronoiData(n); UnionFind uf(n); // = new UnionFind(n); BinaryHeap<EdgeCost> heap(n); // = new BinaryHeap<ArcCost>(n); / ArcCost [] pertcost = null; if (r != null) { pertcost = new ArcCost[m + 1]; InitPerturbation(pertcost, r); } / baselist.Reset(); for (int v = 1; v <= n; v++) { if (g.IsTerminal(v)) baselist.Insert(v); } //fprintf (stderr, "Should be computing Voronoi.\n"); Basics::ComputeVoronoi(g, voronoi, baselist, heap, NULL); //pertcost); solution.Reset(); // return; //fprintf (stderr, "Missing boruvka!\n"); //Boruvka(g, solution, voronoi, uf, NULL); Preprocessing::BoruvkaGraph(g, solution, voronoi, uf, NULL); //DNHPrim(g,solution,voronoi,uf); //Console.Error.WriteLine("t3:{0} ", timer.GetTime()); } /// Modifies a solution by computing the MST of the subgraph induced by its vertices /// and removing all vertices of degree one. Changes the solution. /// <param name="svertices">Vertices in the solution (doesn't change).</param> /// <param name="solution">Edges in the solution (may change).</param> static bool MSTPrune(Graph &g, SteinerSolution &solution) { //return 0; EdgeCost original = solution.GetCost(); int n = g.VertexCount(); UniverseSet svertices(n); Basics::MarkSolutionNodes(g, solution, svertices); MST(g,solution,svertices); Basics::Prune(g,solution); //fprintf (stderr, "Solution costs %d, gain is %d.\n", solution.GetCost(), original - solution.GetCost()); //Prune(g,solution); //fprintf (stderr, "g%d ", original - solution.GetCost()); return (solution.GetCost() < original) ? 1 : 0; } static int VeryOldPickTerminal(Graph &g, RFWLocalRandom &random) { int t = 0; int count = 0; int n = g.VertexCount(); for (int v=1; v<=n; v++) { if (g.IsTerminal(v)) { if (t==0 \|\| g.GetDegree(v) < g.GetDegree(t)) { t = v; } } } return t; } /// <summary> /// Compute the MST of the subgraph induced by svertices /// (assumed to contain all terminals---DO I NEED THIS?) /// </summary> /// <param name="svertices">list of vertices to be spanned</param> /// <param name="solution">solution in which the MST will be stored</param> /// <returns>Number of vertices scanned.</returns> static int MST (Graph &g, SteinerSolution &solution, UniverseSet &svertices) { bool verbose = false; int n = g.VertexCount(); BinaryHeap<EdgeCost> heap(n); vector<int> parc (n+1); int r = Basics::PickRandomTerminal(g); if (!svertices.Contains(r)) fatal ("Terminal does not appear to belong to the solution."); parc[r] = 0; int nscanned = 0; //run Prim's algorithm solution.Reset(); heap.Insert(r, 0); while (!heap.IsEmpty()) { unsigned int v; EdgeCost acost; heap.RemoveFirst(v,acost); if (v!=r) solution.Insert(parc[v]); //add edge (p(v),v) to solution //scan vertices nscanned ++; SPGArc a, *end; for (g.GetBounds(v,a,end); a<end; a++) { int w = a->head; if (!svertices.Contains(w)) continue; //we only care about svertex if (solution.GetDegree(w) > 0) continue; //vertex already in the new tree if (heap.Insert(w, a->cost)) parc[w] = a->label; } } //if (solution.Count() < g.TerminalCount() - 1) {fatal ("solution does not have enough vertices");} return nscanned; } };
declare_simd_ast_print.c	// RUN: %clang_cc1 -verify -fopenmp -ast-print %s \| FileCheck %s // RUN: %clang_cc1 -fopenmp -emit-pch -o %t %s // RUN: %clang_cc1 -fopenmp -include-pch %t -fsyntax-only -verify %s -ast-print \| FileCheck %s // RUN: %clang_cc1 -verify -fopenmp-simd -ast-print %s \| FileCheck %s // RUN: %clang_cc1 -fopenmp-simd -emit-pch -o %t %s // RUN: %clang_cc1 -fopenmp-simd -include-pch %t -fsyntax-only -verify %s -ast-print \| FileCheck %s // expected-no-diagnostics #ifndef HEADER #define HEADER #pragma omp declare simd aligned(b : 64) #pragma omp declare simd simdlen(32) aligned(d, b) #pragma omp declare simd inbranch, uniform(d) linear(val(s1, s2) : 32) #pragma omp declare simd notinbranch simdlen(2), uniform(s1, s2) linear(d: s1) void add_1(float d, int s1, float s2, double b[]) __attribute__((cold)); // CHECK: #pragma omp declare simd notinbranch simdlen(2) uniform(s1, s2) linear(val(d): s1){{$}} // CHECK-NEXT: #pragma omp declare simd inbranch uniform(d) linear(val(s1): 32) linear(val(s2): 32){{$}} // CHECK-NEXT: #pragma omp declare simd simdlen(32) aligned(d) aligned(b){{$}} // CHECK-NEXT: #pragma omp declare simd aligned(b: 64){{$}} // CHECK-NEXT: void add_1(float d, int s1, float s2, double b[]) __attribute__((cold)) #endif
DRB049-fprintf-orig-no.c	/* Copyright (c) 2017, Lawrence Livermore National Security, LLC. Produced at the Lawrence Livermore National Laboratory Written by Chunhua Liao, Pei-Hung Lin, Joshua Asplund, Markus Schordan, and Ian Karlin (email: liao6@llnl.gov, lin32@llnl.gov, asplund1@llnl.gov, schordan1@llnl.gov, karlin1@llnl.gov) LLNL-CODE-732144 All rights reserved. This file is part of DataRaceBench. For details, see https://github.com/LLNL/dataracebench. Please also see the LICENSE file for our additional BSD notice. Redistribution and use in source and binary forms, with or without modification, are permitted provided that the following conditions are met: * Redistributions of source code must retain the above copyright notice, this list of conditions and the disclaimer below. * Redistributions in binary form must reproduce the above copyright notice, this list of conditions and the disclaimer (as noted below) in the documentation and/or other materials provided with the distribution. * Neither the name of the LLNS/LLNL nor the names of its contributors may be used to endorse or promote products derived from this software without specific prior written permission. THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL LAWRENCE LIVERMORE NATIONAL SECURITY, LLC, THE U.S. DEPARTMENT OF ENERGY OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. / #include <stdio.h> #include <stdlib.h> / Example use of fprintf / #include <stdio.h> int main(int argc, char argv[]) { int i; int ret; FILE* pfile; int len=1000; int A[1000]; #pragma omp parallel for simd for (i=0; i<len; i++) A[i]=i; pfile = fopen("mytempfile.txt","a+"); if (pfile ==NULL) { fprintf(stderr,"Error in fopen()\n"); } #pragma omp parallel for simd ordered for (i=0; i<len; ++i) { #pragma omp ordered simd fprintf(pfile, "%d\n", A[i] ); } fclose(pfile); ret = remove("mytempfile.txt"); if (ret != 0) { fprintf(stderr, "Error: unable to delete mytempfile.txt\n"); } return 0; }
laplace.h	#ifndef LAPLACE_H #define LAPLACE_H void laplace(const Storage3D& in, Storage3D& out) { for (int64_t i = 0; i < domain_size; ++i) { for (int64_t j = 0; j < domain_size; ++j) { for (int64_t k = 0; k < domain_height; ++k) { out(i, j, k) = -4.0 * in(i, j, k) + ((in(i - 1, j, k) + in(i + 1, j, k)) + (in(i, j + 1, k) + in(i, j - 1, k))); } } } } void laplace_fullfusion(const Storage3D& in, Storage3D& out) { for (int64_t i = 0; i < domain_size; ++i) { for (int64_t j = 0; j < domain_size; ++j) { for (int64_t k = 0; k < domain_height; ++k) { out(i, j, k) = -4.0 * in(i, j, k) + ((in(i - 1, j, k) + in(i + 1, j, k)) + (in(i, j + 1, k) + in(i, j - 1, k))); } } } } void laplace_partialfusion(const Storage3D& in, Storage3D& out) { for (int64_t i = 0; i < domain_size; ++i) { for (int64_t j = 0; j < domain_size; ++j) { for (int64_t k = 0; k < domain_height; ++k) { out(i, j, k) = -4.0 * in(i, j, k) + ((in(i - 1, j, k) + in(i + 1, j, k)) + (in(i, j + 1, k) + in(i, j - 1, k))); } } } } void laplace_openmp(const Storage3D& in, Storage3D& out) { #pragma omp parallel for for (int64_t i = 0; i < domain_size; ++i) { for (int64_t j = 0; j < domain_size; ++j) { for (int64_t k = 0; k < domain_height; ++k) { out(i, j, k) = -4.0 * in(i, j, k) + ((in(i - 1, j, k) + in(i + 1, j, k)) + (in(i, j + 1, k) + in(i, j - 1, k))); } } } } #endif // LAPLACE_H
openmp.c	#include <stdio.h> #include <omp.h> int main(int argc, char **argv) { #pragma omp parallel for for (int i = 0; i < argc; i++) { printf("Thread %d/%d: %s\n", omp_get_thread_num(), omp_get_num_threads(), argv[i]); } }
LAGraph_pagerank3b.c	//------------------------------------------------------------------------------ // LAGraph_pagerank3b: pagerank using a real semiring //------------------------------------------------------------------------------ /* LAGraph: graph algorithms based on GraphBLAS Copyright 2019 LAGraph Contributors. (see Contributors.txt for a full list of Contributors; see ContributionInstructions.txt for information on how you can Contribute to this project). All Rights Reserved. NO WARRANTY. THIS MATERIAL IS FURNISHED ON AN "AS-IS" BASIS. THE LAGRAPH CONTRIBUTORS MAKE NO WARRANTIES OF ANY KIND, EITHER EXPRESSED OR IMPLIED, AS TO ANY MATTER INCLUDING, BUT NOT LIMITED TO, WARRANTY OF FITNESS FOR PURPOSE OR MERCHANTABILITY, EXCLUSIVITY, OR RESULTS OBTAINED FROM USE OF THE MATERIAL. THE CONTRIBUTORS DO NOT MAKE ANY WARRANTY OF ANY KIND WITH RESPECT TO FREEDOM FROM PATENT, TRADEMARK, OR COPYRIGHT INFRINGEMENT. Released under a BSD license, please see the LICENSE file distributed with this Software or contact permission@sei.cmu.edu for full terms. Created, in part, with funding and support from the United States Government. (see Acknowledgments.txt file). This program includes and/or can make use of certain third party source code, object code, documentation and other files ("Third Party Software"). See LICENSE file for more details. / // LAGraph_pagerank3b: Alternative PageRank implementation using a real // semiring. // // This algorithm follows the specification given in the GAP Benchmark Suite: // https://arxiv.org/abs/1508.03619 // For fastest results, the input matrix should be GrB_FP32, stored in // GxB_BY_COL format. #include "LAGraph.h" #define LAGRAPH_FREE_ALL { \ GrB_free(&transpose_desc); \ GrB_free(&invmask_desc); \ GrB_free(&A); \ GrB_free(&G); \ GrB_free(&grb_d_out); \ GrB_free(&importance_vec); \ GrB_free(&grb_pr); \ }; // uncomment this to see the intermidiate resluts; lots of prints!! //#undef NDEBUG // uncomment this to see the timing info #define PRINT_TIMING_INFO GrB_Info LAGraph_pagerank3b // PageRank definition ( GrB_Vector result, // output: array of LAGraph_PageRank structs GrB_Matrix A_input, // binary input graph, not modified float damping_factor, // damping factor unsigned long itermax, // maximum number of iterations int* iters // output: number of iterations taken ) { GrB_Info info; GrB_Index n; GrB_Descriptor invmask_desc = NULL ; GrB_Descriptor transpose_desc = NULL ; GrB_Vector grb_d_out = NULL ; GrB_Matrix A = NULL ; #ifdef PRINT_TIMING_INFO // start the timer double tic [2] ; LAGraph_tic (tic) ; #endif GrB_Vector importance_vec = NULL ; GrB_Vector grb_pr = NULL; GrB_Matrix G = NULL ; // a dense row of zeros zeroes(1,n) GrB_Index ncols ; //number of columnns LAGRAPH_OK(GrB_Matrix_ncols(&ncols , A_input)); LAGRAPH_OK(GrB_Matrix_nrows(&n, A_input)); GrB_Index nvals; LAGRAPH_OK(GrB_Matrix_nvals(&nvals, A_input)); if (ncols != n) { return (GrB_DIMENSION_MISMATCH) ; } LAGRAPH_OK(GrB_Matrix_new (&G, GrB_FP32, n, n)); LAGRAPH_OK(GrB_Matrix_new (&A, GrB_FP32, n, n)); LAGRAPH_OK(GxB_set (A, GxB_FORMAT, GxB_BY_COL)); // G is zeros in last row for (GrB_Index c = 0; c < n; c++){ LAGRAPH_OK(GrB_Matrix_setElement (G, 0.0, n-1, c)); } #ifndef NDEBUG int print_size = 5; //number of entries get printed print_size = (print_size > n)? n : print_size; // GxB_print (G, 3) ; #endif // A = A_input + G; LAGRAPH_OK(GrB_eWiseAdd (A, NULL, NULL, GrB_PLUS_FP32, A_input, G, NULL)); GrB_free (&G) ; #ifndef NDEBUG // GxB_print (A, 3) ; #endif // Create complement descriptor LAGRAPH_OK(GrB_Descriptor_new(&invmask_desc)); LAGRAPH_OK(GrB_Descriptor_set(invmask_desc, GrB_MASK, GrB_SCMP)); // Create transpose descriptor LAGRAPH_OK(GrB_Descriptor_new(&transpose_desc)); LAGRAPH_OK(GrB_Descriptor_set(transpose_desc, GrB_INP0, GrB_TRAN)); LAGRAPH_OK(GrB_Descriptor_set(transpose_desc, GrB_OUTP, GrB_REPLACE)); // Matrix A row sum // Stores the outbound degrees of all vertices LAGRAPH_OK(GrB_Vector_new(&grb_d_out, GrB_FP32, n)); LAGRAPH_OK(GrB_reduce( grb_d_out, NULL, NULL, GxB_PLUS_FP32_MONOID, A, NULL )); #ifndef NDEBUG GxB_print (grb_d_out, 1) ; // GxB_print (A, 3) ; #endif // Iteration // Initialize PR vector LAGRAPH_OK(GrB_Vector_new(&grb_pr, GrB_FP32, n)); LAGRAPH_OK(GrB_Vector_new(&importance_vec, GrB_FP32, n)); // Teleport value const float teleport = (1 - damping_factor) / n; float tol = 1e-4; float rdiff = 1 ; // first iteration is always done GrB_Type type = GrB_FP32 ; GrB_Index dI = NULL ; float d_sp= NULL ; GrB_Index d_nvals; GrB_Index d_n; // d_sp <----- grb_d_out \|\| export LAGRAPH_OK (GxB_Vector_export (&grb_d_out, &type, &d_n, &d_nvals, &dI, (void *) (&d_sp), NULL)) ; // dens d_out float d_out = (float ) LAGraph_calloc (n, sizeof(float)); int nthreads = LAGraph_get_nthreads ( ) ; nthreads = LAGRAPH_MIN (n , nthreads) ; nthreads = LAGRAPH_MAX (nthreads, 1) ; #pragma omp parallel for num_threads(nthreads) schedule(static) for (int64_t i = 0 ; i < d_nvals; i++){ GrB_Index ind = (GrB_Index) dI[i]; d_out [ind] = d_sp [i]; } free (d_sp); free (dI); #ifndef NDEBUG for (int i = 0 ; i < print_size; i++){ printf("d_out [%d]=%ld\n", i, d_out [i]); } #endif // initializing pr float pr = (float ) malloc (nsizeof(float)); #pragma omp parallel for num_threads(nthreads) schedule(static) for (int i = 0; i < n ; i++){ pr [i] = 1.0/n; } #ifndef NDEBUG for (int i = 0 ; i < print_size ; i++){ printf("pr[%d]=%f\n", i, pr [i]); } #endif float oldpr = (float ) malloc (nsizeof(float)); //initailze the dense indices GrB_Index I = LAGraph_malloc(n, sizeof(GrB_Index)); #pragma omp parallel for num_threads(nthreads) schedule(static) for (GrB_Index j = 0; j < n; j++){ I[j] = j; } #ifdef PRINT_TIMING_INFO // stop the timer double t1 = LAGraph_toc (tic); printf ("\ninitialization time: %12.6e (sec)\n",t1); LAGraph_tic (tic); #endif for ((iters) = 0 ; (iters) < itermax && rdiff > tol ; (iters)++) { // oldpr = pr; deep copy //GrB_Vector_dup(&oldpr, pr); #pragma omp parallel for num_threads(nthreads) schedule(static) for (int i = 0; i < n ; i++){ oldpr [i] = pr [i]; } // Importance calculation #pragma omp parallel for num_threads(nthreads) schedule(static) for (int i = 0 ; i < n; i++){ if (d_out [i] != 0){ pr [i] = damping_factor pr [i] / d_out [i]; } else{ pr [i] = 0; } } #ifndef NDEBUG for (int i = 0 ; i < print_size; i++){ printf (" pr [%d] = %f\n", i, pr [i]); } #endif // importance_vec <----- pr LAGRAPH_OK (GxB_Vector_import (&importance_vec, GrB_FP32, n, n, &I, (void *) (&pr), NULL)) ; #ifndef NDEBUG printf ("after importance_vec import\n"); GxB_print (importance_vec, 2) ; #endif // Calculate total PR of all inbound vertices // importance_vec = A' importance_vec LAGRAPH_OK(GrB_mxv( importance_vec, NULL, NULL, GxB_PLUS_TIMES_FP32, A, importance_vec, transpose_desc )); #ifndef NDEBUG printf ("==============2\n"); printf ("after mxv\n"); GxB_print (importance_vec, 1) ; #endif GrB_Index nvals_exp; // pr <----- importance_vec GrB_Type ivtype; LAGRAPH_OK (GxB_Vector_export (&importance_vec, &ivtype, &n, &nvals_exp, &I, (void *) (&pr), NULL)) ; // assert (nvals_exp == n ); // PageRank summarization // Add teleport, importance_vec, and dangling_vec components together // pr = (1-df)/n + pr #pragma omp parallel for num_threads(nthreads) schedule(static) for (int i = 0 ; i < n; i++){ pr [i] += teleport; } #ifndef NDEBUG for (int i = 0 ; i < print_size; i++){ printf (" pr [%d] = %f\n", i, pr [i]); } #endif //---------------------------------------------------------------------- // rdiff = sum ((oldpr-pr).^2) //---------------------------------------------------------------------- rdiff = 0; // norm (oldpr pr, 1) #pragma omp parallel for num_threads(nthreads) reduction(+:rdiff) for (int i = 0 ; i < n; i++){ float d = (oldpr [i] - pr [i]); d = (d > 0 ? d : -d); //abs(d) rdiff += d; } #ifndef NDEBUG printf("---------------------------iters %d rdiff=%f\n",iters, rdiff); #endif } #ifdef PRINT_TIMING_INFO // stop the timer double t2 = LAGraph_toc (tic); printf ("compuatatin time: %12.6e (sec) ratio (comp/init): %f\n\n", t2, t2/t1); #endif GrB_Index prI = LAGraph_malloc(n, sizeof(GrB_Index)); // grb_pr<----- pr \|\| import back LAGRAPH_OK (GxB_Vector_import (&grb_pr, GrB_FP32, n, n, &I, (void ) (&pr), NULL)) ; (result) = grb_pr; free(I); free (oldpr); return (GrB_SUCCESS); }
serial_tree_learner.h	/! Copyright (c) 2016 Microsoft Corporation. All rights reserved. * Licensed under the MIT License. See LICENSE file in the project root for license information. / #ifndef LIGHTGBM_TREELEARNER_SERIAL_TREE_LEARNER_H_ #define LIGHTGBM_TREELEARNER_SERIAL_TREE_LEARNER_H_ #include <LightGBM/dataset.h> #include <LightGBM/tree.h> #include <LightGBM/tree_learner.h> #include <LightGBM/utils/array_args.h> #include <LightGBM/utils/json11.h> #include <LightGBM/utils/random.h> #include <string> #include <cmath> #include <cstdio> #include <memory> #include <random> #include <vector> #include "col_sampler.hpp" #include "data_partition.hpp" #include "feature_histogram.hpp" #include "leaf_splits.hpp" #include "monotone_constraints.hpp" #include "split_info.hpp" #ifdef USE_GPU // Use 4KBytes aligned allocator for ordered gradients and ordered hessians when GPU is enabled. // This is necessary to pin the two arrays in memory and make transferring faster. #include <boost/align/aligned_allocator.hpp> #endif namespace LightGBM { using json11::Json; /! \brief forward declaration / class CostEfficientGradientBoosting; /! * \brief Used for learning a tree by single machine / class SerialTreeLearner: public TreeLearner { public: friend CostEfficientGradientBoosting; explicit SerialTreeLearner(const Config config); ~SerialTreeLearner(); void Init(const Dataset* train_data, bool is_constant_hessian) override; void ResetTrainingData(const Dataset* train_data, bool is_constant_hessian) override { ResetTrainingDataInner(train_data, is_constant_hessian, true); } void ResetIsConstantHessian(bool is_constant_hessian) override { share_state_->is_constant_hessian = is_constant_hessian; } virtual void ResetTrainingDataInner(const Dataset* train_data, bool is_constant_hessian, bool reset_multi_val_bin); void ResetConfig(const Config* config) override; inline void SetForcedSplit(const Json* forced_split_json) override { if (forced_split_json != nullptr && !forced_split_json->is_null()) { forced_split_json_ = forced_split_json; } else { forced_split_json_ = nullptr; } } Tree* Train(const score_t* gradients, const score_t hessians) override; Tree FitByExistingTree(const Tree* old_tree, const score_t* gradients, const score_t* hessians) const override; Tree* FitByExistingTree(const Tree* old_tree, const std::vector<int>& leaf_pred, const score_t* gradients, const score_t* hessians) override; void SetBaggingData(const Dataset* subset, const data_size_t* used_indices, data_size_t num_data) override { if (subset == nullptr) { data_partition_->SetUsedDataIndices(used_indices, num_data); share_state_->is_use_subrow = false; } else { ResetTrainingDataInner(subset, share_state_->is_constant_hessian, false); share_state_->is_use_subrow = true; share_state_->is_subrow_copied = false; share_state_->bagging_use_indices = used_indices; share_state_->bagging_indices_cnt = num_data; } } void AddPredictionToScore(const Tree* tree, double* out_score) const override { if (tree->num_leaves() <= 1) { return; } CHECK_LE(tree->num_leaves(), data_partition_->num_leaves()); #pragma omp parallel for schedule(static, 1) for (int i = 0; i < tree->num_leaves(); ++i) { double output = static_cast<double>(tree->LeafOutput(i)); data_size_t cnt_leaf_data = 0; auto tmp_idx = data_partition_->GetIndexOnLeaf(i, &cnt_leaf_data); for (data_size_t j = 0; j < cnt_leaf_data; ++j) { out_score[tmp_idx[j]] += output; } } } void RenewTreeOutput(Tree* tree, const ObjectiveFunction* obj, std::function<double(const label_t, int)> residual_getter, data_size_t total_num_data, const data_size_t bag_indices, data_size_t bag_cnt) const override; protected: void ComputeBestSplitForFeature(FeatureHistogram* histogram_array_, int feature_index, int real_fidx, bool is_feature_used, int num_data, const LeafSplits* leaf_splits, SplitInfo* best_split); void GetShareStates(const Dataset* dataset, bool is_constant_hessian, bool is_first_time); void RecomputeBestSplitForLeaf(int leaf, SplitInfo* split); /! \brief Some initial works before training / virtual void BeforeTrain(); /! * \brief Some initial works before FindBestSplit / virtual bool BeforeFindBestSplit(const Tree tree, int left_leaf, int right_leaf); virtual void FindBestSplits(const Tree* tree); virtual void ConstructHistograms(const std::vector<int8_t>& is_feature_used, bool use_subtract); virtual void FindBestSplitsFromHistograms(const std::vector<int8_t>& is_feature_used, bool use_subtract, const Tree); /! * \brief Partition tree and data according best split. * \param tree Current tree, will be splitted on this function. * \param best_leaf The index of leaf that will be splitted. * \param left_leaf The index of left leaf after splitted. * \param right_leaf The index of right leaf after splitted. / inline virtual void Split(Tree tree, int best_leaf, int* left_leaf, int* right_leaf) { SplitInner(tree, best_leaf, left_leaf, right_leaf, true); } void SplitInner(Tree* tree, int best_leaf, int* left_leaf, int* right_leaf, bool update_cnt); /* Force splits with forced_split_json dict and then return num splits forced./ int32_t ForceSplits(Tree tree, int* left_leaf, int* right_leaf, int* cur_depth); /! \brief Get the number of data in a leaf * \param leaf_idx The index of leaf * \return The number of data in the leaf_idx leaf / inline virtual data_size_t GetGlobalDataCountInLeaf(int leaf_idx) const; /! \brief number of data / data_size_t num_data_; /! \brief number of features / int num_features_; /! \brief training data / const Dataset train_data_; /! \brief gradients of current iteration / const score_t* gradients_; /! \brief hessians of current iteration / const score_t* hessians_; /! \brief training data partition on leaves / std::unique_ptr<DataPartition> data_partition_; /! \brief pointer to histograms array of parent of current leaves / FeatureHistogram* parent_leaf_histogram_array_; /! \brief pointer to histograms array of smaller leaf / FeatureHistogram* smaller_leaf_histogram_array_; /! \brief pointer to histograms array of larger leaf / FeatureHistogram* larger_leaf_histogram_array_; /! \brief store best split points for all leaves / std::vector<SplitInfo> best_split_per_leaf_; /! \brief store best split per feature for all leaves / std::vector<SplitInfo> splits_per_leaf_; /! \brief stores minimum and maximum constraints for each leaf / std::unique_ptr<LeafConstraintsBase> constraints_; /! \brief stores best thresholds for all feature for smaller leaf / std::unique_ptr<LeafSplits> smaller_leaf_splits_; /! \brief stores best thresholds for all feature for larger leaf / std::unique_ptr<LeafSplits> larger_leaf_splits_; #ifdef USE_GPU /! \brief gradients of current iteration, ordered for cache optimized, aligned to 4K page / std::vector<score_t, boost::alignment::aligned_allocator<score_t, 4096>> ordered_gradients_; /! \brief hessians of current iteration, ordered for cache optimized, aligned to 4K page / std::vector<score_t, boost::alignment::aligned_allocator<score_t, 4096>> ordered_hessians_; #else /! \brief gradients of current iteration, ordered for cache optimized / std::vector<score_t, Common::AlignmentAllocator<score_t, kAlignedSize>> ordered_gradients_; /! \brief hessians of current iteration, ordered for cache optimized / std::vector<score_t, Common::AlignmentAllocator<score_t, kAlignedSize>> ordered_hessians_; #endif /! \brief used to cache historical histogram to speed up/ HistogramPool histogram_pool_; /! \brief config of tree learner/ const Config* config_; ColSampler col_sampler_; const Json* forced_split_json_; std::unique_ptr<TrainingShareStates> share_state_; std::unique_ptr<CostEfficientGradientBoosting> cegb_; }; inline data_size_t SerialTreeLearner::GetGlobalDataCountInLeaf(int leaf_idx) const { if (leaf_idx >= 0) { return data_partition_->leaf_count(leaf_idx); } else { return 0; } } } // namespace LightGBM #endif // LightGBM_TREELEARNER_SERIAL_TREE_LEARNER_H_
PeptideIndexing.h	// -------------------------------------------------------------------------- // OpenMS -- Open-Source Mass Spectrometry // -------------------------------------------------------------------------- // Copyright The OpenMS Team -- Eberhard Karls University Tuebingen, // ETH Zurich, and Freie Universitaet Berlin 2002-2017. // // This software is released under a three-clause BSD license: // * Redistributions of source code must retain the above copyright // notice, this list of conditions and the following disclaimer. // * Redistributions in binary form must reproduce the above copyright // notice, this list of conditions and the following disclaimer in the // documentation and/or other materials provided with the distribution. // * Neither the name of any author or any participating institution // may be used to endorse or promote products derived from this software // without specific prior written permission. // For a full list of authors, refer to the file AUTHORS. // -------------------------------------------------------------------------- // THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" // AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE // IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE // ARE DISCLAIMED. IN NO EVENT SHALL ANY OF THE AUTHORS OR THE CONTRIBUTING // INSTITUTIONS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, // EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, // PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; // OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, // WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR // OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF // ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. // // -------------------------------------------------------------------------- // $Maintainer: Chris Bielow $ // $Authors: Andreas Bertsch, Chris Bielow $ // -------------------------------------------------------------------------- #ifndef OPENMS_ANALYSIS_ID_PEPTIDEINDEXING_H #define OPENMS_ANALYSIS_ID_PEPTIDEINDEXING_H #include <OpenMS/ANALYSIS/ID/AhoCorasickAmbiguous.h> #include <OpenMS/CHEMISTRY/ProteaseDigestion.h> #include <OpenMS/CHEMISTRY/ProteaseDB.h> #include <OpenMS/CONCEPT/LogStream.h> #include <OpenMS/CONCEPT/ProgressLogger.h> #include <OpenMS/DATASTRUCTURES/DefaultParamHandler.h> #include <OpenMS/DATASTRUCTURES/FASTAContainer.h> #include <OpenMS/DATASTRUCTURES/ListUtils.h> #include <OpenMS/DATASTRUCTURES/SeqanIncludeWrapper.h> #include <OpenMS/FORMAT/FASTAFile.h> #include <OpenMS/KERNEL/StandardTypes.h> #include <OpenMS/METADATA/PeptideEvidence.h> #include <OpenMS/METADATA/PeptideIdentification.h> #include <OpenMS/METADATA/ProteinIdentification.h> #include <OpenMS/SYSTEM/StopWatch.h> #include <OpenMS/SYSTEM/SysInfo.h> #include <atomic> #include <algorithm> #include <fstream> namespace OpenMS { /** @brief Refreshes the protein references for all peptide hits in a vector of PeptideIdentifications and adds target/decoy information. All peptide and protein hits are annotated with target/decoy information, using the meta value "target_decoy". For proteins the possible values are "target" and "decoy", depending on whether the protein accession contains the decoy pattern (parameter @p decoy_string) as a suffix or prefix, respectively (see parameter @p prefix). For peptides, the possible values are "target", "decoy" and "target+decoy", depending on whether the peptide sequence is found only in target proteins, only in decoy proteins, or in both. The target/decoy information is crucial for the @ref TOPP_FalseDiscoveryRate tool. (For FDR calculations, "target+decoy" peptide hits count as target hits.) @note Make sure that your protein names in the database contain a correctly formatted decoy string. This can be ensured by using @ref UTILS_DecoyDatabase. If the decoy identifier is not recognized successfully all proteins will be assumed to stem from the target-part of the query.<br> E.g., "sw\|P33354_DECOY\|YEHR_ECOLI Uncharacterized lipop..." is <b>invalid</b>, since the tool has no knowledge of how SwissProt entries are build up. A correct identifier could be "DECOY_sw\|P33354\|YEHR_ECOLI Uncharacterized li ..." or "sw\|P33354\|YEHR_ECOLI_DECOY Uncharacterized li", depending on whether you are using prefix or suffix annotation.<br> This tool will also report some helpful target/decoy statistics when it is done. By default this tool will fail if an unmatched peptide occurs, i.e. if the database does not contain the corresponding protein. You can force it to return successfully in this case by using the flag @p allow_unmatched. Search engines (such as Mascot) will replace ambiguous amino acids ('B', 'J', 'Z' and 'X') in the protein database with unambiguous amino acids in the reported peptides, e.g. exchange 'X' with 'H'. This will cause such peptides to not be found by exactly matching their sequences to the protein database. However, we can recover these cases by using tolerant search for ambiguous amino acids in the protein sequence. This is done by default with up to four amino acids per peptide hit. If you only want exact matches, set @p aaa_max to zero (but expect that unmatched peptides might occur)! Leucine/Isoleucine: Further complications can arise due to the presence of the isobaric amino acids isoleucine ('I') and leucine ('L') in protein sequences. Since the two have the exact same chemical composition and mass, they generally cannot be distinguished by mass spectrometry. If a peptide containing 'I' was reported as a match for a spectrum, a peptide containing 'L' instead would be an equally good match (and vice versa). To account for this inherent ambiguity, setting the flag @p IL_equivalent causes 'I' and 'L' to be considered as indistinguishable.@n For example, if the sequence "PEPTIDE" (matching "Protein1") was identified as a search hit, but the database additionally contained "PEPTLDE" (matching "Protein2"), running PeptideIndexer with the @p IL_equivalent option would report both "Protein1" and "Protein2" as accessions for "PEPTIDE". (This is independent of ambiguous matching via @p aaa_max.) Additionally, setting this flag will convert all 'J's in any protein sequence to 'I'. This way, no tolerant search is required for 'J' (but is still possible for all the other ambiguous amino acids). If @p write_protein_sequences is requested and @p IL_equivalent is set as well, both the I/L-version and unmodified protein sequences need to be stored internally. This requires some extra memory, roughly equivalent to the size of the FASTA database file itself. Enzyme specificity: Once a peptide sequence is found in a protein sequence, this does <b>not</b> imply that the hit is valid! This is where enzyme specificity comes into play. By default, we demand that the peptide is fully tryptic (i.e. the enzyme parameter is set to "trypsin" and specificity is "full"). So unless the peptide coincides with C- and/or N-terminus of the protein, the peptide's cleavage pattern should fulfill the trypsin cleavage rule [KR][^P]. We make two exceptions to the specificity constraints: 1) for peptides starting at the second or third position of a protein are still considered N-terminally specific, since the residues can be cleaved off in vivo; X!Tandem reports these peptides. For example, the two peptides ABAR and LABAR would both match a protein starting with MLABAR. 2) adventitious cleavage at Asp\|Pro (Aspartate/D \| Proline/P) is allowed for all enzymes (as supported by X!Tandem), i.e. counts as a proper cleavage site (see http://www.thegpm.org/tandem/release.html). You can relax the requirements further by choosing <tt>semi-tryptic</tt> (only one of two "internal" termini must match requirements) or <tt>none</tt> (essentially allowing all hits, no matter their context). These settings should not be used (due to high risk of reporting false positives), unless the search engine was instructed to search peptides in the same way. Threading: This tool support multiple threads (@p threads option) to speed up computation, at the cost of little extra memory. / class OPENMS_DLLAPI PeptideIndexing : public DefaultParamHandler, public ProgressLogger { public: /// Exit codes enum ExitCodes { EXECUTION_OK, DATABASE_EMPTY, PEPTIDE_IDS_EMPTY, DATABASE_CONTAINS_MULTIPLES, ILLEGAL_PARAMETERS, UNEXPECTED_RESULT }; /// Default constructor PeptideIndexing(); /// Default destructor ~PeptideIndexing() override; /// forward for old interface and pyOpenMS; use run<T>() for more control inline ExitCodes run(std::vector<FASTAFile::FASTAEntry>& proteins, std::vector<ProteinIdentification>& prot_ids, std::vector<PeptideIdentification>& pep_ids) { FASTAContainer<TFI_Vector> protein_container(proteins); return run<TFI_Vector>(protein_container, prot_ids, pep_ids); } /* @brief Re-index peptide identifications honoring enzyme cutting rules, ambiguous amino acids and target/decoy hits. Template parameter 'T' can be either TFI_File or TFI_Vector. If the data is already available, use TFI_Vector and pass the vector. If the data is still in a FASTA file and its not needed afterwards for additional processing, use TFI_File and pass the filename. PeptideIndexer refreshes target/decoy information and mapping of peptides to proteins. The target/decoy information is crucial for the @ref TOPP_FalseDiscoveryRate tool. (For FDR calculations, "target+decoy" peptide hits count as target hits.) PeptideIndexer allows for ambiguous amino acids (B\|J\|Z\|X) in the protein database, but not in the peptide sequences. For the latter only I/L can be treated as equivalent (see 'IL_equivalent' flag), but 'J' is not allowed. Enzyme cutting rules and partial specificity can be specified. Resulting protein hits appear in the order of the FASTA file, except for orphaned proteins, which will appear first with an empty target_decoy metavalue. Duplicate protein accessions & sequences will not raise a warning, but create multiple hits (PeptideIndexer scans over the FASTA file once for efficiency reasons, and thus might not see all accessions & sequences at once). All peptide and protein hits are annotated with target/decoy information, using the meta value "target_decoy". For proteins the possible values are "target" and "decoy", depending on whether the protein accession contains the decoy pattern (parameter @p decoy_string) as a suffix or prefix, respectively (see parameter @p prefix). Peptide hits are annotated with metavalue 'protein_references', and if matched to at least one protein also with metavalue 'target_decoy'. The possible values for 'target_decoy' are "target", "decoy" and "target+decoy", depending on whether the peptide sequence is found only in target proteins, only in decoy proteins, or in both. The metavalue is not present, if the peptide is unmatched. Runtime: PeptideIndexer is usually very fast (loading and storing the data takes the most time) and search speed can be further improved (linearly), but using more threads. Avoid allowing too many (>=4) ambiguous amino acids if your database contains long stretches of 'X' (exponential search space). @param proteins A list of proteins -- either read piecewise from a FASTA file or as existing vector of FASTAEntries. @param prot_ids Resulting protein identifications associated to pep_ids (will be re-written completely) @param pep_ids Peptide identifications which should be search within @p proteins and then linked to @p prot_ids @return Exit status codes. / template<typename T> ExitCodes run(FASTAContainer<T>& proteins, std::vector<ProteinIdentification>& prot_ids, std::vector<PeptideIdentification>& pep_ids) { //------------------------------------------------------------- // parsing parameters //------------------------------------------------------------- ProteaseDigestion enzyme; enzyme.setEnzyme(enzyme_name_); enzyme.setSpecificity(enzyme.getSpecificityByName(enzyme_specificity_)); const size_t PROTEIN_CACHE_SIZE = 4e5; // 400k should be enough for most DB's and is not too hard on memory either (~200 MB FASTA) //------------------------------------------------------------- // calculations //------------------------------------------------------------- // cache the first proteins proteins.cacheChunk(PROTEIN_CACHE_SIZE); if (proteins.empty()) // we do not allow an empty database { LOG_ERROR << "Error: An empty database was provided. Mapping makes no sense. Aborting..." << std::endl; return DATABASE_EMPTY; } if (pep_ids.empty()) // Aho-Corasick requires non-empty input; but we allow this case, since the TOPP tool should not crash when encountering a bad raw file (with no PSMs) { LOG_WARN << "Warning: An empty set of peptide identifications was provided. Output will be empty as well." << std::endl; if (!keep_unreferenced_proteins_) { // delete only protein hits, not whole ID runs incl. meta data: for (std::vector<ProteinIdentification>::iterator it = prot_ids.begin(); it != prot_ids.end(); ++it) { it->getHits().clear(); } } return PEPTIDE_IDS_EMPTY; } FoundProteinFunctor func(enzyme); // store the matches Map<String, Size> acc_to_prot; // map: accessions --> FASTA protein index std::vector<bool> protein_is_decoy; // protein index -> is decoy? std::vector<std::string> protein_accessions; // protein index -> accession bool invalid_protein_sequence = false; // check for proteins with modifications, i.e. '[' or '(', and throw an exception { // new scope - forget data after search / BUILD Peptide DB / bool has_illegal_AAs(false); AhoCorasickAmbiguous::PeptideDB pep_DB; for (std::vector<PeptideIdentification>::const_iterator it1 = pep_ids.begin(); it1 != pep_ids.end(); ++it1) { //String run_id = it1->getIdentifier(); const std::vector<PeptideHit>& hits = it1->getHits(); for (std::vector<PeptideHit>::const_iterator it2 = hits.begin(); it2 != hits.end(); ++it2) { // // Warning: // do not skip over peptides here, since the results are iterated in the same way // String seq = it2->getSequence().toUnmodifiedString().remove(''); // make a copy, i.e. do NOT change the peptide sequence! if (seqan::isAmbiguous(seqan::AAString(seq.c_str()))) { // do not quit here, to show the user all sequences .. only quit after loop LOG_ERROR << "Peptide sequence '" << it2->getSequence() << "' contains one or more ambiguous amino acids (B\|J\|Z\|X).\n"; has_illegal_AAs = true; } if (IL_equivalent_) // convert L to I; { seq.substitute('L', 'I'); } appendValue(pep_DB, seq.c_str()); } } if (has_illegal_AAs) { LOG_ERROR << "One or more peptides contained illegal amino acids. This is not allowed!" << "\nPlease either remove the peptide or replace it with one of the unambiguous ones (while allowing for ambiguous AA's to match the protein)." << std::endl;; } LOG_INFO << "Mapping " << length(pep_DB) << " peptides to " << (proteins.size() == PROTEIN_CACHE_SIZE ? "? (unknown number of)" : String(proteins.size())) << " proteins." << std::endl; if (length(pep_DB) == 0) { // Aho-Corasick will crash if given empty needles as input LOG_WARN << "Warning: Peptide identifications have no hits inside! Output will be empty as well." << std::endl; return PEPTIDE_IDS_EMPTY; } /* Aho Corasick (fast) / LOG_INFO << "Searching with up to " << aaa_max_ << " ambiguous amino acid(s) and " << mm_max_ << " mismatch(es)!" << std::endl; SysInfo::MemUsage mu; LOG_INFO << "Building trie ..."; StopWatch s; s.start(); AhoCorasickAmbiguous::FuzzyACPattern pattern; AhoCorasickAmbiguous::initPattern(pep_DB, aaa_max_, mm_max_, pattern); s.stop(); LOG_INFO << " done (" << int(s.getClockTime()) << "s)" << std::endl; s.reset(); uint16_t count_j_proteins(0); bool has_active_data = true; // becomes false if end of FASTA file is reached const std::string jumpX(aaa_max_ + mm_max_ + 1, 'X'); // jump over stretches of 'X' which cost a lot of time; +1 because AXXA is a valid hit for aaa_max == 2 (cannot split it) this->startProgress(0, proteins.size(), "Aho-Corasick"); std::atomic<int> progress_prots(0); #ifdef _OPENMP #pragma omp parallel #endif { FoundProteinFunctor func_threads(enzyme); Map<String, Size> acc_to_prot_thread; // map: accessions --> FASTA protein index AhoCorasickAmbiguous fuzzyAC; String prot; while (true) { #pragma omp barrier // all threads need to be here, since we are about to swap protein data #pragma omp single { DEBUG_ONLY std::cerr << " activating cache ...\n"; has_active_data = proteins.activateCache(); // swap in last cache protein_accessions.resize(proteins.getChunkOffset() + proteins.chunkSize()); } // implicit barrier here if (!has_active_data) break; // leave while-loop SignedSize prot_count = (SignedSize)proteins.chunkSize(); #pragma omp master { DEBUG_ONLY std::cerr << "Filling Protein Cache ..."; proteins.cacheChunk(PROTEIN_CACHE_SIZE); protein_is_decoy.resize(proteins.getChunkOffset() + prot_count); for (SignedSize i = 0; i < prot_count; ++i) { // do this in master only, to avoid false sharing const String& seq = proteins.chunkAt(i).identifier; protein_is_decoy[i + proteins.getChunkOffset()] = (prefix_ ? seq.hasPrefix(decoy_string_) : seq.hasSuffix(decoy_string_)); } DEBUG_ONLY std::cerr << " done" << std::endl; } DEBUG_ONLY std::cerr << " starting for loop \n"; // search all peptides in each protein #pragma omp for schedule(dynamic, 100) nowait for (SignedSize i = 0; i < prot_count; ++i) { ++progress_prots; // atomic if (omp_get_thread_num() == 0) { this->setProgress(progress_prots); } prot = proteins.chunkAt(i).sequence; prot.remove(''); // check for invalid sequences with modifications if (prot.has('[') \|\| prot.has('(')) { invalid_protein_sequence = true; // not omp-critical because its write-only // we cannot throw an exception here, since we'd need to catch it within the parallel region } // convert L/J to I; also replace 'J' in proteins if (IL_equivalent_) { prot.substitute('L', 'I'); prot.substitute('J', 'I'); } else { // warn if 'J' is found (it eats into aaa_max) if (prot.has('J')) { #pragma omp atomic ++count_j_proteins; } } Size prot_idx = i + proteins.getChunkOffset(); // test if protein was a hit Size hits_total = func_threads.filter_passed + func_threads.filter_rejected; // check if there are stretches of 'X' if (prot.has('X')) { // create chunks of the protein (splitting it at stretches of 'X..X') and feed them to AC one by one size_t offset = -1, start = 0; while ((offset = prot.find(jumpX, offset + 1)) != std::string::npos) { //std::cout << "found X..X at " << offset << " in protein " << proteins[i].identifier << "\n"; addHits_(fuzzyAC, pattern, pep_DB, prot.substr(start, offset + jumpX.size() - start), prot, prot_idx, (int)start, func_threads); // skip ahead while we encounter more X... while (offset + jumpX.size() < prot.size() && prot[offset + jumpX.size()] == 'X') ++offset; start = offset; //std::cout << " new start: " << start << "\n"; } // last chunk if (start < prot.size()) { addHits_(fuzzyAC, pattern, pep_DB, prot.substr(start), prot, prot_idx, (int)start, func_threads); } } else { addHits_(fuzzyAC, pattern, pep_DB, prot, prot, prot_idx, 0, func_threads); } // was protein found? if (hits_total < func_threads.filter_passed + func_threads.filter_rejected) { protein_accessions[prot_idx] = proteins.chunkAt(i).identifier; acc_to_prot_thread[protein_accessions[prot_idx]] = prot_idx; } } // end parallel FOR // join results again DEBUG_ONLY std::cerr << " critical now \n"; #ifdef _OPENMP #pragma omp critical(PeptideIndexer_joinAC) #endif { s.start(); // hits func.merge(func_threads); // accession -> index acc_to_prot.insert(acc_to_prot_thread.begin(), acc_to_prot_thread.end()); acc_to_prot_thread.clear(); s.stop(); } // OMP end critical } // end readChunk } // OMP end parallel this->endProgress(); std::cout << "Merge took: " << s.toString() << "\n"; mu.after(); std::cout << mu.delta("Aho-Corasick") << "\n\n"; LOG_INFO << "\nAho-Corasick done:\n found " << func.filter_passed << " hits for " << func.pep_to_prot.size() << " of " << length(pep_DB) << " peptides.\n"; // write some stats LOG_INFO << "Peptide hits passing enzyme filter: " << func.filter_passed << "\n" << " ... rejected by enzyme filter: " << func.filter_rejected << std::endl; if (count_j_proteins) { LOG_WARN << "PeptideIndexer found " << count_j_proteins << " protein sequences in your database containing the amino acid 'J'." << "To match 'J' in a protein, an ambiguous amino acid placeholder for I/L will be used.\n" << "This costs runtime and eats into the 'aaa_max' limit, leaving less opportunity for B/Z/X matches.\n" << "If you want 'J' to be treated as unambiguous, enable '-IL_equivalent'!" << std::endl; } } // end local scope // // do mapping // // index existing proteins Map<String, Size> runid_to_runidx; // identifier to index for (Size run_idx = 0; run_idx < prot_ids.size(); ++run_idx) { runid_to_runidx[prot_ids[run_idx].getIdentifier()] = run_idx; } // for peptides --> proteins Size stats_matched_unique(0); Size stats_matched_multi(0); Size stats_unmatched(0); // no match to DB Size stats_count_m_t(0); // match to Target DB Size stats_count_m_d(0); // match to Decoy DB Size stats_count_m_td(0); // match to T+D DB Map<Size, std::set<Size> > runidx_to_protidx; // in which protID do appear which proteins (according to mapped peptides) Size pep_idx(0); for (std::vector<PeptideIdentification>::iterator it1 = pep_ids.begin(); it1 != pep_ids.end(); ++it1) { // which ProteinIdentification does the peptide belong to? Size run_idx = runid_to_runidx[it1->getIdentifier()]; std::vector<PeptideHit>& hits = it1->getHits(); for (std::vector<PeptideHit>::iterator it2 = hits.begin(); it2 != hits.end(); ++it2) { // clear protein accessions it2->setPeptideEvidences(std::vector<PeptideEvidence>()); // // is this a decoy hit? // bool matches_target(false); bool matches_decoy(false); std::set<Size> prot_indices; /// protein hits of this peptide // add new protein references for (std::set<PeptideProteinMatchInformation>::const_iterator it_i = func.pep_to_prot[pep_idx].begin(); it_i != func.pep_to_prot[pep_idx].end(); ++it_i) { prot_indices.insert(it_i->protein_index); const String& accession = protein_accessions[it_i->protein_index]; PeptideEvidence pe(accession, it_i->position, it_i->position + (int)it2->getSequence().size() - 1, it_i->AABefore, it_i->AAAfter); it2->addPeptideEvidence(pe); runidx_to_protidx[run_idx].insert(it_i->protein_index); // fill protein hits if (protein_is_decoy[it_i->protein_index]) { matches_decoy = true; } else { matches_target = true; } } if (matches_decoy && matches_target) { it2->setMetaValue("target_decoy", "target+decoy"); ++stats_count_m_td; } else if (matches_target) { it2->setMetaValue("target_decoy", "target"); ++stats_count_m_t; } else if (matches_decoy) { it2->setMetaValue("target_decoy", "decoy"); ++stats_count_m_d; } // else: could match to no protein (i.e. both are false) //else ... // not required (handled below; see stats_unmatched); if (prot_indices.size() == 1) { it2->setMetaValue("protein_references", "unique"); ++stats_matched_unique; } else if (prot_indices.size() > 1) { it2->setMetaValue("protein_references", "non-unique"); ++stats_matched_multi; } else { it2->setMetaValue("protein_references", "unmatched"); ++stats_unmatched; if (stats_unmatched < 15) LOG_INFO << "Unmatched peptide: " << it2->getSequence() << "\n"; else if (stats_unmatched == 15) LOG_INFO << "Unmatched peptide: ...\n"; } ++pep_idx; // next hit } } Size total_peptides = stats_count_m_t + stats_count_m_d + stats_count_m_td + stats_unmatched; LOG_INFO << "-----------------------------------\n"; LOG_INFO << "Peptide statistics\n"; LOG_INFO << "\n"; LOG_INFO << " unmatched : " << stats_unmatched << " (" << stats_unmatched * 100 / total_peptides << " %)\n"; LOG_INFO << " target/decoy:\n"; LOG_INFO << " match to target DB only: " << stats_count_m_t << " (" << stats_count_m_t * 100 / total_peptides << " %)\n"; LOG_INFO << " match to decoy DB only : " << stats_count_m_d << " (" << stats_count_m_d * 100 / total_peptides << " %)\n"; LOG_INFO << " match to both : " << stats_count_m_td << " (" << stats_count_m_td * 100 / total_peptides << " %)\n"; LOG_INFO << "\n"; LOG_INFO << " mapping to proteins:\n"; LOG_INFO << " no match (to 0 protein) : " << stats_unmatched << "\n"; LOG_INFO << " unique match (to 1 protein) : " << stats_matched_unique << "\n"; LOG_INFO << " non-unique match (to >1 protein): " << stats_matched_multi << std::endl; /// for proteins --> peptides Size stats_matched_proteins(0), stats_matched_new_proteins(0), stats_orphaned_proteins(0), stats_proteins_target(0), stats_proteins_decoy(0); // all peptides contain the correct protein hit references, now update the protein hits for (Size run_idx = 0; run_idx < prot_ids.size(); ++run_idx) { std::set<Size> masterset = runidx_to_protidx[run_idx]; // all protein matches from above std::vector<ProteinHit>& phits = prot_ids[run_idx].getHits(); { // go through existing protein hits and count orphaned proteins (with no peptide hits) std::vector<ProteinHit> orphaned_hits; for (std::vector<ProteinHit>::iterator p_hit = phits.begin(); p_hit != phits.end(); ++p_hit) { const String& acc = p_hit->getAccession(); if (!acc_to_prot.has(acc)) // acc_to_prot only contains found proteins from current run { // old hit is orphaned ++stats_orphaned_proteins; if (keep_unreferenced_proteins_) { p_hit->setMetaValue("target_decoy", ""); orphaned_hits.push_back(p_hit); } } } // only keep orphaned hits (if any) phits = orphaned_hits; } // add new protein hits FASTAFile::FASTAEntry fe; phits.reserve(phits.size() + masterset.size()); for (std::set<Size>::const_iterator it = masterset.begin(); it != masterset.end(); ++it) { ProteinHit hit; hit.setAccession(protein_accessions[it]); if (write_protein_sequence_ \|\| write_protein_description_) { proteins.readAt(fe, it); if (write_protein_sequence_) { hit.setSequence(fe.sequence); } // no else, since sequence is empty by default if (write_protein_description_) { hit.setDescription(fe.description); } // no else, since description is empty by default } if (protein_is_decoy[it]) { hit.setMetaValue("target_decoy", "decoy"); ++stats_proteins_decoy; } else { hit.setMetaValue("target_decoy", "target"); ++stats_proteins_target; } phits.push_back(hit); ++stats_matched_new_proteins; } stats_matched_proteins += phits.size(); } LOG_INFO << "-----------------------------------\n"; LOG_INFO << "Protein statistics\n"; LOG_INFO << "\n"; LOG_INFO << " total proteins searched: " << proteins.size() << "\n"; LOG_INFO << " matched proteins : " << stats_matched_proteins << " (" << stats_matched_new_proteins << " new)\n"; if (stats_matched_proteins) { // prevent Division-by-0 Exception LOG_INFO << " matched target proteins: " << stats_proteins_target << " (" << stats_proteins_target * 100 / stats_matched_proteins << " %)\n"; LOG_INFO << " matched decoy proteins : " << stats_proteins_decoy << " (" << stats_proteins_decoy * 100 / stats_matched_proteins << " %)\n"; } LOG_INFO << " orphaned proteins : " << stats_orphaned_proteins << (keep_unreferenced_proteins_ ? " (all kept)" : " (all removed)\n"); LOG_INFO << "-----------------------------------" << std::endl; /// exit if no peptides were matched to decoy bool has_error = false; if (invalid_protein_sequence) { LOG_ERROR << "Error: One or more protein sequences contained the characters '[' or '(', which are illegal in protein sequences." << "\nPeptide hits might be masked by these characters (which usually indicate presence of modifications).\n"; has_error = true; } if ((stats_count_m_d + stats_count_m_td) == 0) { String msg("No peptides were matched to the decoy portion of the database! Did you provide the correct concatenated database? Are your 'decoy_string' (=" + String(decoy_string_) + ") and 'decoy_string_position' (=" + String(param_.getValue("decoy_string_position")) + ") settings correct?"); if (missing_decoy_action_ == "error") { LOG_ERROR << "Error: " << msg << "\nSet 'missing_decoy_action' to 'warn' if you are sure this is ok!\nAborting ..." << std::endl; has_error = true; } else if (missing_decoy_action_ == "warn") { LOG_WARN << "Warn: " << msg << "\nSet 'missing_decoy_action' to 'error' if you want to elevate this to an error!" << std::endl; } else // silent { } } if ((!allow_unmatched_) && (stats_unmatched > 0)) { LOG_ERROR << "PeptideIndexer found unmatched peptides, which could not be associated to a protein.\n" << "Potential solutions:\n" << " - check your FASTA database for completeness\n" << " - set 'enzyme:specificity' to match the identification parameters of the search engine\n" << " - some engines (e.g. X! Tandem) employ loose cutting rules generating non-tryptic peptides;\n" << " if you trust them, disable enzyme specificity\n" << " - increase 'aaa_max' to allow more ambiguous amino acids\n" << " - as a last resort: use the 'allow_unmatched' option to accept unmatched peptides\n" << " (note that unmatched peptides cannot be used for FDR calculation or quantification)\n"; has_error = true; } if (has_error) { LOG_ERROR << "Result files will be written, but PeptideIndexer will exit with an error code." << std::endl; return UNEXPECTED_RESULT; } return EXECUTION_OK; } protected: struct PeptideProteinMatchInformation { /// index of the protein the peptide is contained in OpenMS::Size protein_index; /// the position of the peptide in the protein OpenMS::Int position; /// the amino acid after the peptide in the protein char AABefore; /// the amino acid before the peptide in the protein char AAAfter; bool operator<(const PeptideProteinMatchInformation& other) const { if (protein_index != other.protein_index) { return protein_index < other.protein_index; } else if (position != other.position) { return position < other.position; } else if (AABefore != other.AABefore) { return AABefore < other.AABefore; } else if (AAAfter != other.AAAfter) { return AAAfter < other.AAAfter; } return false; } bool operator==(const PeptideProteinMatchInformation& other) const { return protein_index == other.protein_index && position == other.position && AABefore == other.AABefore && AAAfter == other.AAAfter; } }; struct FoundProteinFunctor { public: typedef std::map<OpenMS::Size, std::set<PeptideProteinMatchInformation> > MapType; /// peptide index --> protein indices MapType pep_to_prot; /// number of accepted hits (passing addHit() constraints) OpenMS::Size filter_passed; /// number of rejected hits (not passing addHit()) OpenMS::Size filter_rejected; private: ProteaseDigestion enzyme_; public: explicit FoundProteinFunctor(const ProteaseDigestion& enzyme) : pep_to_prot(), filter_passed(0), filter_rejected(0), enzyme_(enzyme) { } void merge(FoundProteinFunctor& other) { if (pep_to_prot.empty()) { // first merge is easy pep_to_prot.swap(other.pep_to_prot); } else { for (FoundProteinFunctor::MapType::const_iterator it = other.pep_to_prot.begin(); it != other.pep_to_prot.end(); ++it) { // augment set this->pep_to_prot[it->first].insert(other.pep_to_prot[it->first].begin(), other.pep_to_prot[it->first].end()); } other.pep_to_prot.clear(); } // cheap members this->filter_passed += other.filter_passed; other.filter_passed = 0; this->filter_rejected += other.filter_rejected; other.filter_rejected = 0; } void addHit(const OpenMS::Size idx_pep, const OpenMS::Size idx_prot, const OpenMS::Size len_pep, const OpenMS::String& seq_prot, OpenMS::Int position) { if (enzyme_.isValidProduct(seq_prot, position, len_pep, true, true)) { PeptideProteinMatchInformation match; match.protein_index = idx_prot; match.position = position; match.AABefore = (position == 0) ? PeptideEvidence::N_TERMINAL_AA : seq_prot[position - 1]; match.AAAfter = (position + len_pep >= seq_prot.size()) ? PeptideEvidence::C_TERMINAL_AA : seq_prot[position + len_pep]; pep_to_prot[idx_pep].insert(match); ++filter_passed; } else { //std::cerr << "REJECTED Peptide " << seq_pep << " with hit to protein " // << seq_prot << " at position " << position << std::endl; ++filter_rejected; } } }; inline void addHits_(AhoCorasickAmbiguous& fuzzyAC, const AhoCorasickAmbiguous::FuzzyACPattern& pattern, const AhoCorasickAmbiguous::PeptideDB& pep_DB, const String& prot, const String& full_prot, SignedSize idx_prot, Int offset, FoundProteinFunctor& func_threads) const { fuzzyAC.setProtein(prot); while (fuzzyAC.findNext(pattern)) { const seqan::Peptide& tmp_pep = pep_DB[fuzzyAC.getHitDBIndex()]; func_threads.addHit(fuzzyAC.getHitDBIndex(), idx_prot, length(tmp_pep), full_prot, fuzzyAC.getHitProteinPosition() + offset); } } void updateMembers_() override; String decoy_string_; bool prefix_; String missing_decoy_action_; String enzyme_name_; String enzyme_specificity_; bool write_protein_sequence_; bool write_protein_description_; bool keep_unreferenced_proteins_; bool allow_unmatched_; bool IL_equivalent_; Int aaa_max_; Int mm_max_; }; } #endif // OPENMS_ANALYSIS_ID_PEPTIDEINDEXING_H
par_nongalerkin.c	/BHEADER********************************************************************* * Copyright (c) 2008, Lawrence Livermore National Security, LLC. * Produced at the Lawrence Livermore National Laboratory. * This file is part of HYPRE. See file COPYRIGHT for details. * * HYPRE is free software; you can redistribute it and/or modify it under the * terms of the GNU Lesser General Public License (as published by the Free * Software Foundation) version 2.1 dated February 1999. * * $Revision: 2.14 $ **********************************************************************EHEADER/ #include "_hypre_parcsr_ls.h" #include "../HYPRE.h" /* This file contains the routines for constructing non-Galerkin coarse grid * operators, based on the original Galerkin coarse grid / / Take all of the indices from indices[start, start+1, start+2, ..., end] * and take the corresponding entries in array and place them in-order in output. * Assumptions: * output is of length end-start+1 * indices never contains an index that goes out of bounds in array * / HYPRE_Int hypre_GrabSubArray(HYPRE_Int indices, HYPRE_Int start, HYPRE_Int end, HYPRE_BigInt * array, HYPRE_Int * output) { HYPRE_Int i, length; length = end - start + 1; for(i = 0; i < length; i++) { output[i] = array[ indices[start + i] ]; } return 0; } /* Quick Sort based on magnitude on w (HYPRE_Real), move v / void hypre_qsort2_abs( HYPRE_Int v, HYPRE_Real w, HYPRE_Int left, HYPRE_Int right ) { HYPRE_Int i, last; if (left >= right) return; hypre_swap2( v, w, left, (left+right)/2); last = left; for (i = left+1; i <= right; i++) if (fabs(w[i]) < fabs(w[left])) { hypre_swap2(v, w, ++last, i); } hypre_swap2(v, w, left, last); hypre_qsort2_abs(v, w, left, last-1); hypre_qsort2_abs(v, w, last+1, right); } / Compute the intersection of x and y, placing * the intersection in z. Additionally, the array * x_data is associated with x, i.e., the entries * that we grab from x, we also grab from x_data. * If x[k] is placed in z[m], then x_data[k] goes to * output_x_data[m]. * * Assumptions: * z is of length min(x_length, y_length) * x and y are sorted * x_length and y_length are similar in size, otherwise, * looping over the smaller array and doing binary search * in the longer array is faster. * / HYPRE_Int hypre_IntersectTwoArrays(HYPRE_Int x, HYPRE_Real x_data, HYPRE_Int x_length, HYPRE_Int y, HYPRE_Int y_length, HYPRE_Int z, HYPRE_Real output_x_data, HYPRE_Int intersect_length) { HYPRE_Int x_index = 0; HYPRE_Int y_index = 0; intersect_length = 0; /* Compute Intersection, looping over each array / while ( (x_index < x_length) && (y_index < y_length) ) { if (x[x_index] > y[y_index]) { y_index = y_index + 1; } else if (x[x_index] < y[y_index]) { x_index = x_index + 1; } else { z[intersect_length] = x[x_index]; output_x_data[intersect_length] = x_data[x_index]; x_index = x_index + 1; y_index = y_index + 1; intersect_length = intersect_length + 1; } } return 1; } / Copy CSR matrix A to CSR matrix B. The column indices are * assumed to be sorted, and the sparsity pattern of B is a subset * of the sparsity pattern of A. * * Assumptions: * Column indices of A and B are sorted * Sparsity pattern of B is a subset of A's * A and B are the same size and have same data layout */ HYPRE_Int hypre_SortedCopyParCSRData(hypre_ParCSRMatrix A, hypre_ParCSRMatrix B) { / Grab off A and B's data structures / hypre_CSRMatrix A_diag = hypre_ParCSRMatrixDiag(A); HYPRE_Int A_diag_i = hypre_CSRMatrixI(A_diag); HYPRE_Int A_diag_j = hypre_CSRMatrixJ(A_diag); HYPRE_Real A_diag_data = hypre_CSRMatrixData(A_diag); hypre_CSRMatrix A_offd = hypre_ParCSRMatrixOffd(A); HYPRE_Int A_offd_i = hypre_CSRMatrixI(A_offd); HYPRE_Int A_offd_j = hypre_CSRMatrixJ(A_offd); HYPRE_Real A_offd_data = hypre_CSRMatrixData(A_offd); hypre_CSRMatrix B_diag = hypre_ParCSRMatrixDiag(B); HYPRE_Int B_diag_i = hypre_CSRMatrixI(B_diag); HYPRE_Int B_diag_j = hypre_CSRMatrixJ(B_diag); HYPRE_Real B_diag_data = hypre_CSRMatrixData(B_diag); hypre_CSRMatrix B_offd = hypre_ParCSRMatrixOffd(B); HYPRE_Int B_offd_i = hypre_CSRMatrixI(B_offd); HYPRE_Int B_offd_j = hypre_CSRMatrixJ(B_offd); HYPRE_Real B_offd_data = hypre_CSRMatrixData(B_offd); HYPRE_Int num_variables = hypre_CSRMatrixNumRows(A_diag); HYPRE_Int temp_int_array = NULL; HYPRE_Int temp_int_array_length=0; HYPRE_Int i, length, offset_A, offset_B; for(i = 0; i < num_variables; i++) { /* Deal with the first row entries, which may be diagonal elements / if( A_diag_j[A_diag_i[i]] == i) { offset_A = 1; } else { offset_A = 0; } if( B_diag_j[B_diag_i[i]] == i) { offset_B = 1; } else { offset_B = 0; } if( (offset_B == 1) && (offset_A == 1) ) { B_diag_data[B_diag_i[i]] = A_diag_data[A_diag_i[i]]; } / This finds the intersection of the column indices, and * also copies the matching data in A to the data array in B */ if( (A_diag_i[i+1] - A_diag_i[i] - offset_A) > temp_int_array_length ) { hypre_TFree(temp_int_array, HYPRE_MEMORY_HOST); temp_int_array_length = (A_diag_i[i+1] - A_diag_i[i] - offset_A); temp_int_array = hypre_CTAlloc(HYPRE_Int, temp_int_array_length, HYPRE_MEMORY_HOST); } hypre_IntersectTwoArrays(&(A_diag_j[A_diag_i[i] + offset_A]), &(A_diag_data[A_diag_i[i] + offset_A]), A_diag_i[i+1] - A_diag_i[i] - offset_A, &(B_diag_j[B_diag_i[i] + offset_B]), B_diag_i[i+1] - B_diag_i[i] - offset_B, temp_int_array, &(B_diag_data[B_diag_i[i] + offset_B]), &length); if( (A_offd_i[i+1] - A_offd_i[i]) > temp_int_array_length ) { hypre_TFree(temp_int_array, HYPRE_MEMORY_HOST); temp_int_array_length = (A_offd_i[i+1] - A_offd_i[i]); temp_int_array = hypre_CTAlloc(HYPRE_Int, temp_int_array_length, HYPRE_MEMORY_HOST); } hypre_IntersectTwoArrays(&(A_offd_j[A_offd_i[i]]), &(A_offd_data[A_offd_i[i]]), A_offd_i[i+1] - A_offd_i[i], &(B_offd_j[B_offd_i[i]]), B_offd_i[i+1] - B_offd_i[i], temp_int_array, &(B_offd_data[B_offd_i[i]]), &length); } if(temp_int_array) { hypre_TFree(temp_int_array, HYPRE_MEMORY_HOST); } return 1; } / * Equivalent to hypre_BoomerAMGCreateS, except, the data array of S * is not Null and contains the data entries from A. / HYPRE_Int hypre_BoomerAMG_MyCreateS(hypre_ParCSRMatrix A, HYPRE_Real strength_threshold, HYPRE_Real max_row_sum, HYPRE_Int num_functions, HYPRE_Int dof_func, hypre_ParCSRMatrix S_ptr) { MPI_Comm comm = hypre_ParCSRMatrixComm(A); hypre_ParCSRCommPkg comm_pkg = hypre_ParCSRMatrixCommPkg(A); hypre_ParCSRCommHandle comm_handle; hypre_CSRMatrix A_diag = hypre_ParCSRMatrixDiag(A); HYPRE_Int A_diag_i = hypre_CSRMatrixI(A_diag); HYPRE_Real A_diag_data = hypre_CSRMatrixData(A_diag); hypre_CSRMatrix A_offd = hypre_ParCSRMatrixOffd(A); HYPRE_Int A_offd_i = hypre_CSRMatrixI(A_offd); HYPRE_Real A_offd_data = NULL; HYPRE_Int A_diag_j = hypre_CSRMatrixJ(A_diag); HYPRE_Int A_offd_j = hypre_CSRMatrixJ(A_offd); HYPRE_BigInt row_starts = hypre_ParCSRMatrixRowStarts(A); HYPRE_Int num_variables = hypre_CSRMatrixNumRows(A_diag); HYPRE_BigInt global_num_vars = hypre_ParCSRMatrixGlobalNumRows(A); HYPRE_Int num_nonzeros_diag; HYPRE_Int num_nonzeros_offd = 0; HYPRE_Int num_cols_offd = 0; hypre_ParCSRMatrix S; hypre_CSRMatrix S_diag; HYPRE_Int S_diag_i; HYPRE_Int S_diag_j; HYPRE_Real S_diag_data; hypre_CSRMatrix S_offd; HYPRE_Int S_offd_i = NULL; HYPRE_Int S_offd_j = NULL; HYPRE_Real S_offd_data; HYPRE_Real diag, row_scale, row_sum; HYPRE_Int i, jA, jS; HYPRE_Int ierr = 0; HYPRE_Int dof_func_offd; HYPRE_Int num_sends; HYPRE_Int int_buf_data; HYPRE_Int index, start, j; /-------------------------------------------------------------- * Compute a ParCSR strength matrix, S. * * For now, the "strength" of dependence/influence is defined in * the following way: i depends on j if * aij > hypre_max (k != i) aik, aii < 0 * or * aij < hypre_min (k != i) aik, aii >= 0 * Then S_ij = aij, else S_ij = 0. * * NOTE: the entries are negative initially, corresponding * to "unaccounted-for" dependence. ----------------------------------------------------------------/ num_nonzeros_diag = A_diag_i[num_variables]; num_cols_offd = hypre_CSRMatrixNumCols(A_offd); A_offd_i = hypre_CSRMatrixI(A_offd); num_nonzeros_offd = A_offd_i[num_variables]; /* Initialize S / S = hypre_ParCSRMatrixCreate(comm, global_num_vars, global_num_vars, row_starts, row_starts, num_cols_offd, num_nonzeros_diag, num_nonzeros_offd); / row_starts is owned by A, col_starts = row_starts / hypre_ParCSRMatrixSetRowStartsOwner(S,0); S_diag = hypre_ParCSRMatrixDiag(S); hypre_CSRMatrixI(S_diag) = hypre_CTAlloc(HYPRE_Int, num_variables+1, HYPRE_MEMORY_HOST); hypre_CSRMatrixJ(S_diag) = hypre_CTAlloc(HYPRE_Int, num_nonzeros_diag, HYPRE_MEMORY_HOST); hypre_CSRMatrixData(S_diag) = hypre_CTAlloc(HYPRE_Real, num_nonzeros_diag, HYPRE_MEMORY_HOST); S_offd = hypre_ParCSRMatrixOffd(S); hypre_CSRMatrixI(S_offd) = hypre_CTAlloc(HYPRE_Int, num_variables+1, HYPRE_MEMORY_HOST); S_diag_i = hypre_CSRMatrixI(S_diag); S_diag_j = hypre_CSRMatrixJ(S_diag); S_diag_data = hypre_CSRMatrixData(S_diag); S_offd_i = hypre_CSRMatrixI(S_offd); dof_func_offd = NULL; if (num_cols_offd) { A_offd_data = hypre_CSRMatrixData(A_offd); hypre_CSRMatrixJ(S_offd) = hypre_CTAlloc(HYPRE_Int, num_nonzeros_offd, HYPRE_MEMORY_HOST); hypre_CSRMatrixData(S_offd) = hypre_CTAlloc(HYPRE_Real, num_nonzeros_offd, HYPRE_MEMORY_HOST); S_offd_j = hypre_CSRMatrixJ(S_offd); S_offd_data = hypre_CSRMatrixData(S_offd); hypre_ParCSRMatrixColMapOffd(S) = hypre_CTAlloc(HYPRE_BigInt, num_cols_offd, HYPRE_MEMORY_HOST); if (num_functions > 1) dof_func_offd = hypre_CTAlloc(HYPRE_Int, num_cols_offd, HYPRE_MEMORY_HOST); } /------------------------------------------------------------------- * Get the dof_func data for the off-processor columns -------------------------------------------------------------------/ if (!comm_pkg) { hypre_MatvecCommPkgCreate(A); comm_pkg = hypre_ParCSRMatrixCommPkg(A); } num_sends = hypre_ParCSRCommPkgNumSends(comm_pkg); if (num_functions > 1) { int_buf_data = hypre_CTAlloc(HYPRE_Int, hypre_ParCSRCommPkgSendMapStart(comm_pkg, num_sends), HYPRE_MEMORY_HOST); index = 0; for (i = 0; i < num_sends; i++) { start = hypre_ParCSRCommPkgSendMapStart(comm_pkg, i); for (j=start; j < hypre_ParCSRCommPkgSendMapStart(comm_pkg, i+1); j++) int_buf_data[index++] = dof_func[hypre_ParCSRCommPkgSendMapElmt(comm_pkg,j)]; } comm_handle = hypre_ParCSRCommHandleCreate( 11, comm_pkg, int_buf_data, dof_func_offd); hypre_ParCSRCommHandleDestroy(comm_handle); hypre_TFree(int_buf_data, HYPRE_MEMORY_HOST); } /* give S same nonzero structure as A / hypre_ParCSRMatrixCopy(A,S,1); #ifdef HYPRE_USING_OPENMP #pragma omp parallel for private(i,diag,row_scale,row_sum,jA) HYPRE_SMP_SCHEDULE #endif for (i = 0; i < num_variables; i++) { diag = A_diag_data[A_diag_i[i]]; / compute scaling factor and row sum / row_scale = 0.0; row_sum = diag; if (num_functions > 1) { if (diag < 0) { for (jA = A_diag_i[i]+1; jA < A_diag_i[i+1]; jA++) { if (dof_func[i] == dof_func[A_diag_j[jA]]) { row_scale = hypre_max(row_scale, A_diag_data[jA]); row_sum += A_diag_data[jA]; } } for (jA = A_offd_i[i]; jA < A_offd_i[i+1]; jA++) { if (dof_func[i] == dof_func_offd[A_offd_j[jA]]) { row_scale = hypre_max(row_scale, A_offd_data[jA]); row_sum += A_offd_data[jA]; } } } else { for (jA = A_diag_i[i]+1; jA < A_diag_i[i+1]; jA++) { if (dof_func[i] == dof_func[A_diag_j[jA]]) { row_scale = hypre_min(row_scale, A_diag_data[jA]); row_sum += A_diag_data[jA]; } } for (jA = A_offd_i[i]; jA < A_offd_i[i+1]; jA++) { if (dof_func[i] == dof_func_offd[A_offd_j[jA]]) { row_scale = hypre_min(row_scale, A_offd_data[jA]); row_sum += A_offd_data[jA]; } } } } else { if (diag < 0) { for (jA = A_diag_i[i]+1; jA < A_diag_i[i+1]; jA++) { row_scale = hypre_max(row_scale, A_diag_data[jA]); row_sum += A_diag_data[jA]; } for (jA = A_offd_i[i]; jA < A_offd_i[i+1]; jA++) { row_scale = hypre_max(row_scale, A_offd_data[jA]); row_sum += A_offd_data[jA]; } } else { for (jA = A_diag_i[i]+1; jA < A_diag_i[i+1]; jA++) { row_scale = hypre_min(row_scale, A_diag_data[jA]); row_sum += A_diag_data[jA]; } for (jA = A_offd_i[i]; jA < A_offd_i[i+1]; jA++) { row_scale = hypre_min(row_scale, A_offd_data[jA]); row_sum += A_offd_data[jA]; } } } / compute row entries of S / S_diag_j[A_diag_i[i]] = -1; if ((fabs(row_sum) > fabs(diag)max_row_sum) && (max_row_sum < 1.0)) { /* make all dependencies weak / for (jA = A_diag_i[i]+1; jA < A_diag_i[i+1]; jA++) { S_diag_j[jA] = -1; } for (jA = A_offd_i[i]; jA < A_offd_i[i+1]; jA++) { S_offd_j[jA] = -1; } } else { if (num_functions > 1) { if (diag < 0) { for (jA = A_diag_i[i]+1; jA < A_diag_i[i+1]; jA++) { if (A_diag_data[jA] <= strength_threshold row_scale \|\| dof_func[i] != dof_func[A_diag_j[jA]]) { S_diag_j[jA] = -1; } } for (jA = A_offd_i[i]; jA < A_offd_i[i+1]; jA++) { if (A_offd_data[jA] <= strength_threshold * row_scale \|\| dof_func[i] != dof_func_offd[A_offd_j[jA]]) { S_offd_j[jA] = -1; } } } else { for (jA = A_diag_i[i]+1; jA < A_diag_i[i+1]; jA++) { if (A_diag_data[jA] >= strength_threshold * row_scale \|\| dof_func[i] != dof_func[A_diag_j[jA]]) { S_diag_j[jA] = -1; } } for (jA = A_offd_i[i]; jA < A_offd_i[i+1]; jA++) { if (A_offd_data[jA] >= strength_threshold * row_scale \|\| dof_func[i] != dof_func_offd[A_offd_j[jA]]) { S_offd_j[jA] = -1; } } } } else { if (diag < 0) { for (jA = A_diag_i[i]+1; jA < A_diag_i[i+1]; jA++) { if (A_diag_data[jA] <= strength_threshold * row_scale) { S_diag_j[jA] = -1; } } for (jA = A_offd_i[i]; jA < A_offd_i[i+1]; jA++) { if (A_offd_data[jA] <= strength_threshold * row_scale) { S_offd_j[jA] = -1; } } } else { for (jA = A_diag_i[i]+1; jA < A_diag_i[i+1]; jA++) { if (A_diag_data[jA] >= strength_threshold * row_scale) { S_diag_j[jA] = -1; } } for (jA = A_offd_i[i]; jA < A_offd_i[i+1]; jA++) { if (A_offd_data[jA] >= strength_threshold * row_scale) { S_offd_j[jA] = -1; } } } } } } /-------------------------------------------------------------- "Compress" the strength matrix. * * NOTE: S has NO DIAGONAL ELEMENT on any row. Caveat Emptor! * * NOTE: This "compression" section of code may not be removed, the * non-Galerkin routine depends on it. ----------------------------------------------------------------/ /* RDF: not sure if able to thread this loop / jS = 0; for (i = 0; i < num_variables; i++) { S_diag_i[i] = jS; for (jA = A_diag_i[i]; jA < A_diag_i[i+1]; jA++) { if (S_diag_j[jA] > -1) { S_diag_j[jS] = S_diag_j[jA]; S_diag_data[jS] = S_diag_data[jA]; jS++; } } } S_diag_i[num_variables] = jS; hypre_CSRMatrixNumNonzeros(S_diag) = jS; / RDF: not sure if able to thread this loop / jS = 0; for (i = 0; i < num_variables; i++) { S_offd_i[i] = jS; for (jA = A_offd_i[i]; jA < A_offd_i[i+1]; jA++) { if (S_offd_j[jA] > -1) { S_offd_j[jS] = S_offd_j[jA]; S_offd_data[jS] = S_offd_data[jA]; jS++; } } } S_offd_i[num_variables] = jS; hypre_CSRMatrixNumNonzeros(S_offd) = jS; hypre_ParCSRMatrixCommPkg(S) = NULL; S_ptr = S; hypre_TFree(dof_func_offd, HYPRE_MEMORY_HOST); return (ierr); } /** * Initialize the IJBuffer counters */ HYPRE_Int hypre_NonGalerkinIJBufferInit( HYPRE_Int ijbuf_cnt, /* See NonGalerkinIJBufferWrite for parameter descriptions / HYPRE_Int ijbuf_rowcounter, HYPRE_Int ijbuf_numcols ) { HYPRE_Int ierr = 0; (ijbuf_cnt) = 0; (ijbuf_rowcounter) = 1; /Always points to the next row/ ijbuf_numcols[0] = 0; return ierr; } /* * Initialize the IJBuffer counters */ HYPRE_Int hypre_NonGalerkinIJBigBufferInit( HYPRE_Int ijbuf_cnt, /* See NonGalerkinIJBufferWrite for parameter descriptions / HYPRE_Int ijbuf_rowcounter, HYPRE_BigInt ijbuf_numcols ) { HYPRE_Int ierr = 0; (ijbuf_cnt) = 0; (ijbuf_rowcounter) = 1; /Always points to the next row/ ijbuf_numcols[0] = 0; return ierr; } /* * Update the buffer counters */ HYPRE_Int hypre_NonGalerkinIJBufferNewRow(HYPRE_BigInt ijbuf_rownums, /* See NonGalerkinIJBufferWrite for parameter descriptions / HYPRE_Int ijbuf_numcols, HYPRE_Int ijbuf_rowcounter, HYPRE_BigInt new_row) { HYPRE_Int ierr = 0; / First check to see if the previous row was empty, and if so, overwrite that row / if( ijbuf_numcols[(ijbuf_rowcounter)-1] == 0 ) { ijbuf_rownums[(ijbuf_rowcounter)-1] = new_row; } else { / Move to the next row / ijbuf_rownums[(ijbuf_rowcounter)] = new_row; ijbuf_numcols[(ijbuf_rowcounter)] = 0; (ijbuf_rowcounter)++; } return ierr; } /** * Compress the current row in an IJ Buffer by removing duplicate entries */ HYPRE_Int hypre_NonGalerkinIJBufferCompressRow( HYPRE_Int ijbuf_cnt, /* See NonGalerkinIJBufferWrite for parameter descriptions / HYPRE_Int ijbuf_rowcounter, HYPRE_Real ijbuf_data, HYPRE_BigInt ijbuf_cols, HYPRE_BigInt ijbuf_rownums, HYPRE_Int ijbuf_numcols) { HYPRE_Int ierr = 0; HYPRE_Int nentries, i, nduplicate; / Compress the current row by removing any repeat entries, * making sure to decrement ijbuf_cnt by nduplicate / nentries = ijbuf_numcols[ ijbuf_rowcounter-1 ]; nduplicate = 0; hypre_BigQsort1(ijbuf_cols, ijbuf_data, (ijbuf_cnt)-nentries, (ijbuf_cnt)-1 ); for(i =(ijbuf_cnt)-nentries+1; i <= (ijbuf_cnt)-1; i++) { if( ijbuf_cols[i] == ijbuf_cols[i-1] ) { / Shift duplicate entry down / nduplicate++; ijbuf_data[i - nduplicate] += ijbuf_data[i]; } else if(nduplicate > 0) { ijbuf_data[i - nduplicate] = ijbuf_data[i]; ijbuf_cols[i - nduplicate] = ijbuf_cols[i]; } } (ijbuf_cnt) -= nduplicate; ijbuf_numcols[ ijbuf_rowcounter-1 ] -= nduplicate; return ierr; } /** * Compress the entire buffer, removing duplicate rows */ HYPRE_Int hypre_NonGalerkinIJBufferCompress( HYPRE_Int ijbuf_size, HYPRE_Int ijbuf_cnt, /* See NonGalerkinIJBufferWrite for parameter descriptions / HYPRE_Int ijbuf_rowcounter, HYPRE_Real ijbuf_data, HYPRE_BigInt ijbuf_cols, HYPRE_BigInt ijbuf_rownums, HYPRE_Int ijbuf_numcols) { HYPRE_Int ierr = 0; HYPRE_Int indys = hypre_CTAlloc(HYPRE_Int, (ijbuf_rowcounter) , HYPRE_MEMORY_HOST); HYPRE_Int i, j, duplicate, cnt_new, rowcounter_new, prev_row; HYPRE_Int row_loc; HYPRE_BigInt row_start, row_stop, row; HYPRE_Real data_new; HYPRE_BigInt cols_new; HYPRE_BigInt rownums_new; HYPRE_Int numcols_new; /* Do a sort on rownums, but store the original order in indys. * Then see if there are any duplicate rows / for(i = 0; i < (ijbuf_rowcounter); i++) { indys[i] = i; } hypre_BigQsortbi((ijbuf_rownums), indys, 0, (ijbuf_rowcounter)-1); duplicate = 0; for(i = 1; i < (ijbuf_rowcounter); i++) { if(indys[i] != (indys[i-1]+1)) { duplicate = 1; break; } } / Compress duplicate rows / if(duplicate) { / Accumulate numcols, so that it functions like a CSR row-pointer / for(i = 1; i < (ijbuf_rowcounter); i++) { (ijbuf_numcols)[i] += (ijbuf_numcols)[i-1]; } /* Initialize new buffer / prev_row = -1; rowcounter_new = 0; cnt_new = 0; data_new = hypre_CTAlloc(HYPRE_Real, ijbuf_size, HYPRE_MEMORY_HOST); cols_new = hypre_CTAlloc(HYPRE_BigInt, ijbuf_size, HYPRE_MEMORY_HOST); rownums_new = hypre_CTAlloc(HYPRE_BigInt, ijbuf_size, HYPRE_MEMORY_HOST); numcols_new = hypre_CTAlloc(HYPRE_Int, ijbuf_size, HYPRE_MEMORY_HOST); numcols_new[0] = 0; / Cycle through each row / for(i = 0; i < (ijbuf_rowcounter); i++) { /* Find which row this is in local and global numberings, and where * this row's data starts and stops in the buffer/ row_loc = indys[i]; row = (ijbuf_rownums)[i]; if(row_loc > 0) { row_start = (ijbuf_numcols)[row_loc-1]; row_stop = (ijbuf_numcols)[row_loc]; } else { row_start = 0; row_stop = (ijbuf_numcols)[row_loc]; } / Is this a new row? If so, compress previous row, and add a new * one. Noting that prev_row = -1 is a special value / if(row != prev_row) { if(prev_row != -1) { / Compress previous row / hypre_NonGalerkinIJBufferCompressRow(&cnt_new, rowcounter_new, data_new, cols_new, rownums_new, numcols_new); } prev_row = row; numcols_new[rowcounter_new] = 0; rownums_new[rowcounter_new] = row; rowcounter_new++; } / Copy row into new buffer / for(j = row_start; j < row_stop; j++) { data_new[cnt_new] = (ijbuf_data)[j]; cols_new[cnt_new] = (ijbuf_cols)[j]; numcols_new[rowcounter_new-1]++; cnt_new++; } } / Compress the final row / if(i > 1) { hypre_NonGalerkinIJBufferCompressRow(&cnt_new, rowcounter_new, data_new, cols_new, rownums_new, numcols_new); } ijbuf_cnt = cnt_new; ijbuf_rowcounter = rowcounter_new; / Point to the new buffer / hypre_TFree(ijbuf_data, HYPRE_MEMORY_HOST); hypre_TFree(ijbuf_cols, HYPRE_MEMORY_HOST); hypre_TFree(ijbuf_rownums, HYPRE_MEMORY_HOST); hypre_TFree(ijbuf_numcols, HYPRE_MEMORY_HOST); (ijbuf_data) = data_new; (ijbuf_cols) = cols_new; (ijbuf_rownums) = rownums_new; (ijbuf_numcols) = numcols_new; } hypre_TFree(indys, HYPRE_MEMORY_HOST); return ierr; } /* * Do a buffered write to an IJ matrix. * That is, write to the buffer, until the buffer is full. Then when the * buffer is full, write to the IJ matrix and reset the buffer counters * In effect, this buffers this operation * A[row_to_write, col_to_write] += val_to_write */ HYPRE_Int hypre_NonGalerkinIJBufferWrite( HYPRE_IJMatrix B, / Unassembled matrix to add an entry to / HYPRE_Int ijbuf_cnt, /* current buffer size / HYPRE_Int ijbuf_size, / max buffer size / HYPRE_Int ijbuf_rowcounter, /* num of rows in rownums, (i.e., size of rownums) / / This counter will increase as you call this function for multiple rows / HYPRE_Real ijbuf_data, / Array of values, of size ijbuf_size / HYPRE_BigInt ijbuf_cols, / Array of col indices, of size ijbuf_size / HYPRE_BigInt ijbuf_rownums, / Holds row-indices that with numcols makes for a CSR-like data structure/ HYPRE_Int ijbuf_numcols, / rownums[i] is the row num, and numcols holds the number of entries being added / / for that row. Note numcols is not cumulative like an actual CSR data structure/ HYPRE_BigInt row_to_write, / Entry to add to the buffer / HYPRE_BigInt col_to_write, / Ditto / HYPRE_Real val_to_write ) / Ditto / { HYPRE_Int ierr = 0; if( (ijbuf_cnt) == 0 ) { /* brand new buffer: increment buffer structures for the new row / hypre_NonGalerkinIJBufferNewRow((ijbuf_rownums), (ijbuf_numcols), ijbuf_rowcounter, row_to_write); } else if((ijbuf_rownums)[ (ijbuf_rowcounter)-1 ] != row_to_write) { / If this is a new row, compress the previous row / hypre_NonGalerkinIJBufferCompressRow(ijbuf_cnt, (ijbuf_rowcounter), (ijbuf_data), (ijbuf_cols), (ijbuf_rownums), (ijbuf_numcols)); /* increment buffer structures for the new row / hypre_NonGalerkinIJBufferNewRow( (ijbuf_rownums), (ijbuf_numcols), ijbuf_rowcounter, row_to_write); } / Add new entry to buffer / (ijbuf_cols)[(ijbuf_cnt)] = col_to_write; (ijbuf_data)[(ijbuf_cnt)] = val_to_write; (ijbuf_numcols)[ (ijbuf_rowcounter)-1 ]++; (ijbuf_cnt)++; /* Buffer is full, write to the matrix object / if ( (ijbuf_cnt) == (ijbuf_size-1) ) { /* If the last row is empty, decrement rowcounter / if( (ijbuf_numcols)[ (ijbuf_rowcounter)-1 ] == 0) { (ijbuf_rowcounter)--; } /* Compress and Add Entries / hypre_NonGalerkinIJBufferCompressRow(ijbuf_cnt, (ijbuf_rowcounter), (ijbuf_data), (ijbuf_cols), (ijbuf_rownums), (ijbuf_numcols)); hypre_NonGalerkinIJBufferCompress(ijbuf_size, ijbuf_cnt, ijbuf_rowcounter, ijbuf_data, ijbuf_cols, ijbuf_rownums, ijbuf_numcols); ierr += HYPRE_IJMatrixAddToValues(B, ijbuf_rowcounter, (ijbuf_numcols), (ijbuf_rownums), (ijbuf_cols), (ijbuf_data)); / Reinitialize the buffer / hypre_NonGalerkinIJBufferInit( ijbuf_cnt, ijbuf_rowcounter, (ijbuf_numcols)); hypre_NonGalerkinIJBufferNewRow((ijbuf_rownums), (ijbuf_numcols), ijbuf_rowcounter, row_to_write); } return ierr; } /** * Empty the IJ Buffer with a final AddToValues. */ HYPRE_Int hypre_NonGalerkinIJBufferEmpty(HYPRE_IJMatrix B, / See NonGalerkinIJBufferWrite for parameter descriptions / HYPRE_Int ijbuf_size, HYPRE_Int ijbuf_cnt, HYPRE_Int ijbuf_rowcounter, HYPRE_Real ijbuf_data, HYPRE_BigInt ijbuf_cols, HYPRE_BigInt ijbuf_rownums, HYPRE_Int ijbuf_numcols) { HYPRE_Int ierr = 0; if( (ijbuf_cnt) > 0) { / Compress the last row and then write / hypre_NonGalerkinIJBufferCompressRow(ijbuf_cnt, ijbuf_rowcounter, (ijbuf_data), (ijbuf_cols), (ijbuf_rownums), (ijbuf_numcols)); hypre_NonGalerkinIJBufferCompress(ijbuf_size, ijbuf_cnt, &ijbuf_rowcounter, ijbuf_data, ijbuf_cols, ijbuf_rownums, ijbuf_numcols); ierr += HYPRE_IJMatrixAddToValues(B, ijbuf_rowcounter, (ijbuf_numcols), (ijbuf_rownums), (ijbuf_cols), (ijbuf_data)); } (ijbuf_cnt = 0); return ierr; } /* * Construct sparsity pattern based on R_I A P, plus entries required by drop tolerance / hypre_ParCSRMatrix hypre_NonGalerkinSparsityPattern(hypre_ParCSRMatrix R_IAP, hypre_ParCSRMatrix RAP, HYPRE_Int * CF_marker, HYPRE_Real droptol, HYPRE_Int sym_collapse, HYPRE_Int collapse_beta ) { /* MPI Communicator / MPI_Comm comm = hypre_ParCSRMatrixComm(RAP); / Declare R_IAP / hypre_CSRMatrix R_IAP_diag = hypre_ParCSRMatrixDiag(R_IAP); HYPRE_Int R_IAP_diag_i = hypre_CSRMatrixI(R_IAP_diag); HYPRE_Int R_IAP_diag_j = hypre_CSRMatrixJ(R_IAP_diag); hypre_CSRMatrix R_IAP_offd = hypre_ParCSRMatrixOffd(R_IAP); HYPRE_Int R_IAP_offd_i = hypre_CSRMatrixI(R_IAP_offd); HYPRE_Int R_IAP_offd_j = hypre_CSRMatrixJ(R_IAP_offd); HYPRE_BigInt col_map_offd_R_IAP = hypre_ParCSRMatrixColMapOffd(R_IAP); /* Declare RAP / hypre_CSRMatrix RAP_diag = hypre_ParCSRMatrixDiag(RAP); HYPRE_Int RAP_diag_i = hypre_CSRMatrixI(RAP_diag); HYPRE_Real RAP_diag_data = hypre_CSRMatrixData(RAP_diag); HYPRE_Int RAP_diag_j = hypre_CSRMatrixJ(RAP_diag); HYPRE_BigInt first_col_diag_RAP = hypre_ParCSRMatrixFirstColDiag(RAP); HYPRE_Int num_cols_diag_RAP = hypre_CSRMatrixNumCols(RAP_diag); HYPRE_BigInt last_col_diag_RAP = first_col_diag_RAP + (HYPRE_BigInt)num_cols_diag_RAP - 1; hypre_CSRMatrix RAP_offd = hypre_ParCSRMatrixOffd(RAP); HYPRE_Int RAP_offd_i = hypre_CSRMatrixI(RAP_offd); HYPRE_Real RAP_offd_data = NULL; HYPRE_Int RAP_offd_j = hypre_CSRMatrixJ(RAP_offd); HYPRE_BigInt col_map_offd_RAP = hypre_ParCSRMatrixColMapOffd(RAP); HYPRE_Int num_cols_RAP_offd = hypre_CSRMatrixNumCols(RAP_offd); HYPRE_Int num_variables = hypre_CSRMatrixNumRows(RAP_diag); /* Declare A / HYPRE_Int num_fine_variables = hypre_CSRMatrixNumRows(R_IAP_diag); / Declare IJ matrices / HYPRE_IJMatrix Pattern; hypre_ParCSRMatrix Pattern_CSR = NULL; /* Buffered IJAddToValues / HYPRE_Int ijbuf_cnt, ijbuf_size, ijbuf_rowcounter; HYPRE_Real ijbuf_data; HYPRE_BigInt ijbuf_cols, ijbuf_rownums; HYPRE_Int ijbuf_numcols; / Buffered IJAddToValues for Symmetric Entries / HYPRE_Int ijbuf_sym_cnt, ijbuf_sym_rowcounter; HYPRE_Real ijbuf_sym_data; HYPRE_BigInt ijbuf_sym_cols, ijbuf_sym_rownums; HYPRE_Int ijbuf_sym_numcols; / Other Declarations / HYPRE_Int ierr = 0; HYPRE_Real max_entry = 0.0; HYPRE_Real max_entry_offd = 0.0; HYPRE_Int rownz = NULL; HYPRE_Int i, j, Cpt; HYPRE_BigInt row_start, row_end, global_row, global_col; /* Other Setup / if (num_cols_RAP_offd) { RAP_offd_data = hypre_CSRMatrixData(RAP_offd); } / * Initialize the IJ matrix, leveraging our rough knowledge of the * nonzero structure of Pattern based on RAP * * ilower, iupper, jlower, jupper / ierr += HYPRE_IJMatrixCreate(comm, first_col_diag_RAP, last_col_diag_RAP, first_col_diag_RAP, last_col_diag_RAP, &Pattern); ierr += HYPRE_IJMatrixSetObjectType(Pattern, HYPRE_PARCSR); rownz = hypre_CTAlloc(HYPRE_Int, num_variables, HYPRE_MEMORY_HOST); for(i = 0; i < num_variables; i++) { rownz[i] = 1.2(RAP_diag_i[i+1] - RAP_diag_i[i]) + 1.2(RAP_offd_i[i+1] - RAP_offd_i[i]); } HYPRE_IJMatrixSetRowSizes(Pattern, rownz); ierr += HYPRE_IJMatrixInitialize(Pattern); hypre_TFree(rownz, HYPRE_MEMORY_HOST); / For efficiency, we do a buffered IJAddToValues. Here, we initialize the buffer and then initialize the buffer counters / ijbuf_size = 1000; ijbuf_data = hypre_CTAlloc(HYPRE_Real, ijbuf_size, HYPRE_MEMORY_HOST); ijbuf_cols = hypre_CTAlloc(HYPRE_BigInt, ijbuf_size, HYPRE_MEMORY_HOST); ijbuf_rownums = hypre_CTAlloc(HYPRE_BigInt, ijbuf_size, HYPRE_MEMORY_HOST); ijbuf_numcols = hypre_CTAlloc(HYPRE_Int, ijbuf_size, HYPRE_MEMORY_HOST); hypre_NonGalerkinIJBigBufferInit( &ijbuf_cnt, &ijbuf_rowcounter, ijbuf_cols ); if(sym_collapse) { ijbuf_sym_data = hypre_CTAlloc(HYPRE_Real, ijbuf_size, HYPRE_MEMORY_HOST); ijbuf_sym_cols = hypre_CTAlloc(HYPRE_BigInt, ijbuf_size, HYPRE_MEMORY_HOST); ijbuf_sym_rownums= hypre_CTAlloc(HYPRE_BigInt, ijbuf_size, HYPRE_MEMORY_HOST); ijbuf_sym_numcols= hypre_CTAlloc(HYPRE_Int, ijbuf_size, HYPRE_MEMORY_HOST); hypre_NonGalerkinIJBigBufferInit( &ijbuf_sym_cnt, &ijbuf_sym_rowcounter, ijbuf_sym_cols ); } / * Place entries in R_IAP into Pattern / Cpt = -1; / Cpt contains the fine grid index of the i-th Cpt / for(i = 0; i < num_variables; i++) { global_row = i+first_col_diag_RAP; / Find the next Coarse Point in CF_marker / for(j = Cpt+1; j < num_fine_variables; j++) { if(CF_marker[j] == 1) / Found Next C-point / { Cpt = j; break; } } / Diag Portion / row_start = R_IAP_diag_i[Cpt]; row_end = R_IAP_diag_i[Cpt+1]; for(j = row_start; j < row_end; j++) { global_col = R_IAP_diag_j[j] + first_col_diag_RAP; / This call adds a 1 x 1 to i j data / hypre_NonGalerkinIJBufferWrite( Pattern, &ijbuf_cnt, ijbuf_size, &ijbuf_rowcounter, &ijbuf_data, &ijbuf_cols, &ijbuf_rownums, &ijbuf_numcols, global_row, global_col, 1.0); if (sym_collapse) { hypre_NonGalerkinIJBufferWrite( Pattern, &ijbuf_sym_cnt, ijbuf_size, &ijbuf_sym_rowcounter, &ijbuf_sym_data, &ijbuf_sym_cols, &ijbuf_sym_rownums, &ijbuf_sym_numcols, global_col, global_row, 1.0); } } / Offdiag Portion / row_start = R_IAP_offd_i[Cpt]; row_end = R_IAP_offd_i[Cpt+1]; for(j = row_start; j < row_end; j++) { global_col = col_map_offd_R_IAP[ R_IAP_offd_j[j] ]; / This call adds a 1 x 1 to i j data / hypre_NonGalerkinIJBufferWrite( Pattern, &ijbuf_cnt, ijbuf_size, &ijbuf_rowcounter, &ijbuf_data, &ijbuf_cols, &ijbuf_rownums, &ijbuf_numcols, global_row, global_col, 1.0); if (sym_collapse) { hypre_NonGalerkinIJBufferWrite( Pattern, &ijbuf_sym_cnt, ijbuf_size, &ijbuf_sym_rowcounter, &ijbuf_sym_data, &ijbuf_sym_cols, &ijbuf_sym_rownums, &ijbuf_sym_numcols, global_col, global_row, 1.0); } } } / * Use drop-tolerance to compute new entries for sparsity pattern / /#ifdef HYPRE_USING_OPENMP #pragma omp parallel for private(i,j,max_entry,max_entry_offd,global_col,global_row) HYPRE_SMP_SCHEDULE #endif/ for(i = 0; i < num_variables; i++) { global_row = i+first_col_diag_RAP; / Compute the drop tolerance for this row, which is just * abs(max of row i)droptol / max_entry = -1.0; for(j = RAP_diag_i[i]; j < RAP_diag_i[i+1]; j++) { if( (RAP_diag_j[j] != i) && (max_entry < fabs(RAP_diag_data[j]) ) ) { max_entry = fabs(RAP_diag_data[j]); } } for(j = RAP_offd_i[i]; j < RAP_offd_i[i+1]; j++) { { if( max_entry < fabs(RAP_offd_data[j]) ) { max_entry = fabs(RAP_offd_data[j]); } } } max_entry = droptol; max_entry_offd = max_entrycollapse_beta; /* Loop over diag portion, adding all entries that are "strong" / for(j = RAP_diag_i[i]; j < RAP_diag_i[i+1]; j++) { if( fabs(RAP_diag_data[j]) > max_entry ) { global_col = RAP_diag_j[j] + first_col_diag_RAP; /#ifdef HYPRE_USING_OPENMP #pragma omp critical (IJAdd) #endif {/ / For efficiency, we do a buffered IJAddToValues * A[global_row, global_col] += 1.0 / hypre_NonGalerkinIJBufferWrite( Pattern, &ijbuf_cnt, ijbuf_size, &ijbuf_rowcounter, &ijbuf_data, &ijbuf_cols, &ijbuf_rownums, &ijbuf_numcols, global_row, global_col, 1.0 ); if(sym_collapse) { hypre_NonGalerkinIJBufferWrite( Pattern, &ijbuf_sym_cnt, ijbuf_size, &ijbuf_sym_rowcounter, &ijbuf_sym_data, &ijbuf_sym_cols, &ijbuf_sym_rownums, &ijbuf_sym_numcols, global_col, global_row, 1.0 ); } /}/ } } / Loop over offd portion, adding all entries that are "strong" / for(j = RAP_offd_i[i]; j < RAP_offd_i[i+1]; j++) { if( fabs(RAP_offd_data[j]) > max_entry_offd ) { global_col = col_map_offd_RAP[ RAP_offd_j[j] ]; /#ifdef HYPRE_USING_OPENMP #pragma omp critical (IJAdd) #endif {/ / For efficiency, we do a buffered IJAddToValues * A[global_row, global_col] += 1.0 / hypre_NonGalerkinIJBufferWrite( Pattern, &ijbuf_cnt, ijbuf_size, &ijbuf_rowcounter, &ijbuf_data, &ijbuf_cols, &ijbuf_rownums, &ijbuf_numcols, global_row, global_col, 1.0 ); if(sym_collapse) { hypre_NonGalerkinIJBufferWrite( Pattern, &ijbuf_sym_cnt, ijbuf_size, &ijbuf_sym_rowcounter, &ijbuf_sym_data, &ijbuf_sym_cols, &ijbuf_sym_rownums, &ijbuf_sym_numcols, global_col, global_row, 1.0 ); } /}/ } } } / For efficiency, we do a buffered IJAddToValues. * This empties the buffer of any remaining values / hypre_NonGalerkinIJBufferEmpty(Pattern, ijbuf_size, &ijbuf_cnt, ijbuf_rowcounter, &ijbuf_data, &ijbuf_cols, &ijbuf_rownums, &ijbuf_numcols); if(sym_collapse) hypre_NonGalerkinIJBufferEmpty(Pattern, ijbuf_size, &ijbuf_sym_cnt, ijbuf_sym_rowcounter, &ijbuf_sym_data, &ijbuf_sym_cols, &ijbuf_sym_rownums, &ijbuf_sym_numcols); / Finalize Construction of Pattern / ierr += HYPRE_IJMatrixAssemble(Pattern); ierr += HYPRE_IJMatrixGetObject( Pattern, (void) &Pattern_CSR ); / Deallocate / ierr += HYPRE_IJMatrixSetObjectType(Pattern, -1); ierr += HYPRE_IJMatrixDestroy(Pattern); hypre_TFree(ijbuf_data, HYPRE_MEMORY_HOST); hypre_TFree(ijbuf_cols, HYPRE_MEMORY_HOST); hypre_TFree(ijbuf_rownums, HYPRE_MEMORY_HOST); hypre_TFree(ijbuf_numcols, HYPRE_MEMORY_HOST); if(sym_collapse) { hypre_TFree(ijbuf_sym_data, HYPRE_MEMORY_HOST); hypre_TFree(ijbuf_sym_cols, HYPRE_MEMORY_HOST); hypre_TFree(ijbuf_sym_rownums, HYPRE_MEMORY_HOST); hypre_TFree(ijbuf_sym_numcols, HYPRE_MEMORY_HOST); } return Pattern_CSR; } HYPRE_Int hypre_BoomerAMGBuildNonGalerkinCoarseOperator( hypre_ParCSRMatrix RAP_ptr, hypre_ParCSRMatrix AP, HYPRE_Real strong_threshold, HYPRE_Real max_row_sum, HYPRE_Int num_functions, HYPRE_Int * dof_func_value, HYPRE_Real S_commpkg_switch, HYPRE_Int * CF_marker, HYPRE_Real droptol, HYPRE_Int sym_collapse, HYPRE_Real lump_percent, HYPRE_Int collapse_beta ) { /* Initializations / MPI_Comm comm = hypre_ParCSRMatrixComm(RAP_ptr); hypre_ParCSRMatrix S = NULL; hypre_ParCSRMatrix RAP = RAP_ptr; HYPRE_Int col_offd_S_to_A = NULL; HYPRE_Int i, j, k, row_start, row_end, value, num_cols_offd_Sext, num_procs; HYPRE_Int S_ext_diag_size, S_ext_offd_size, last_col_diag_RAP, cnt_offd, cnt_diag, cnt; HYPRE_Int col_indx_Pattern, current_Pattern_j, col_indx_RAP; /* HYPRE_Real start_time = hypre_MPI_Wtime(); / / HYPRE_Real end_time; / HYPRE_BigInt temp = NULL; HYPRE_Int ierr = 0; char filename[256]; /* Lumping related variables / HYPRE_IJMatrix ijmatrix; HYPRE_Int Pattern_offd_indices = NULL; HYPRE_Int * S_offd_indices = NULL; HYPRE_Int * offd_intersection = NULL; HYPRE_Real * offd_intersection_data = NULL; HYPRE_Int * diag_intersection = NULL; HYPRE_Real * diag_intersection_data = NULL; HYPRE_Int Pattern_offd_indices_len = 0; HYPRE_Int Pattern_offd_indices_allocated_len= 0; HYPRE_Int S_offd_indices_len = 0; HYPRE_Int S_offd_indices_allocated_len = 0; HYPRE_Int offd_intersection_len = 0; HYPRE_Int offd_intersection_allocated_len = 0; HYPRE_Int diag_intersection_len = 0; HYPRE_Int diag_intersection_allocated_len = 0; HYPRE_Real intersection_len = 0; HYPRE_Int * Pattern_indices_ptr = NULL; HYPRE_Int Pattern_diag_indices_len = 0; HYPRE_Int global_row = 0; HYPRE_Int has_row_ended = 0; HYPRE_Real lump_value = 0.; HYPRE_Real diagonal_lump_value = 0.; HYPRE_Real neg_lump_value = 0.; HYPRE_Real sum_strong_neigh = 0.; HYPRE_Int * rownz = NULL; /* offd and diag portions of RAP / hypre_CSRMatrix RAP_diag = hypre_ParCSRMatrixDiag(RAP); HYPRE_Int RAP_diag_i = hypre_CSRMatrixI(RAP_diag); HYPRE_Real RAP_diag_data = hypre_CSRMatrixData(RAP_diag); HYPRE_Int RAP_diag_j = hypre_CSRMatrixJ(RAP_diag); HYPRE_BigInt first_col_diag_RAP = hypre_ParCSRMatrixFirstColDiag(RAP); HYPRE_Int num_cols_diag_RAP = hypre_CSRMatrixNumCols(RAP_diag); hypre_CSRMatrix RAP_offd = hypre_ParCSRMatrixOffd(RAP); HYPRE_Int RAP_offd_i = hypre_CSRMatrixI(RAP_offd); HYPRE_Real RAP_offd_data = NULL; HYPRE_Int RAP_offd_j = hypre_CSRMatrixJ(RAP_offd); HYPRE_BigInt col_map_offd_RAP = hypre_ParCSRMatrixColMapOffd(RAP); HYPRE_Int num_cols_RAP_offd = hypre_CSRMatrixNumCols(RAP_offd); HYPRE_Int num_variables = hypre_CSRMatrixNumRows(RAP_diag); HYPRE_BigInt global_num_vars = hypre_ParCSRMatrixGlobalNumRows(RAP); /* offd and diag portions of S / hypre_CSRMatrix S_diag = NULL; HYPRE_Int S_diag_i = NULL; HYPRE_Real S_diag_data = NULL; HYPRE_Int S_diag_j = NULL; hypre_CSRMatrix S_offd = NULL; HYPRE_Int S_offd_i = NULL; HYPRE_Real S_offd_data = NULL; HYPRE_Int S_offd_j = NULL; HYPRE_BigInt col_map_offd_S = NULL; HYPRE_Int num_cols_offd_S; /* HYPRE_Int num_nonzeros_S_diag; / / off processor portions of S / hypre_CSRMatrix S_ext = NULL; HYPRE_Int S_ext_i = NULL; HYPRE_Real S_ext_data = NULL; HYPRE_BigInt S_ext_j = NULL; HYPRE_Int S_ext_diag_i = NULL; HYPRE_Real S_ext_diag_data = NULL; HYPRE_Int S_ext_diag_j = NULL; HYPRE_Int S_ext_offd_i = NULL; HYPRE_Real S_ext_offd_data = NULL; HYPRE_Int S_ext_offd_j = NULL; HYPRE_BigInt col_map_offd_Sext = NULL; /* HYPRE_Int num_nonzeros_S_ext_diag; HYPRE_Int num_nonzeros_S_ext_offd; HYPRE_Int num_rows_Sext = 0; / HYPRE_Int row_indx_Sext = 0; / offd and diag portions of Pattern / hypre_ParCSRMatrix Pattern = NULL; hypre_CSRMatrix Pattern_diag = NULL; HYPRE_Int Pattern_diag_i = NULL; HYPRE_Real Pattern_diag_data = NULL; HYPRE_Int Pattern_diag_j = NULL; hypre_CSRMatrix Pattern_offd = NULL; HYPRE_Int Pattern_offd_i = NULL; HYPRE_Real Pattern_offd_data = NULL; HYPRE_Int Pattern_offd_j = NULL; HYPRE_BigInt col_map_offd_Pattern = NULL; HYPRE_Int num_cols_Pattern_offd; HYPRE_Int my_id; / Buffered IJAddToValues / HYPRE_Int ijbuf_cnt, ijbuf_size, ijbuf_rowcounter; HYPRE_Real ijbuf_data; HYPRE_BigInt ijbuf_cols, ijbuf_rownums; HYPRE_Int ijbuf_numcols; / Buffered IJAddToValues for Symmetric Entries / HYPRE_Int ijbuf_sym_cnt, ijbuf_sym_rowcounter; HYPRE_Real ijbuf_sym_data; HYPRE_BigInt ijbuf_sym_cols, ijbuf_sym_rownums; HYPRE_Int ijbuf_sym_numcols; / Further Initializations / if (num_cols_RAP_offd) { RAP_offd_data = hypre_CSRMatrixData(RAP_offd); } hypre_MPI_Comm_size(comm, &num_procs); hypre_MPI_Comm_rank(comm, &my_id); / Compute Sparsity Pattern / Pattern = hypre_NonGalerkinSparsityPattern(AP, RAP, CF_marker, droptol, sym_collapse, collapse_beta); Pattern_diag = hypre_ParCSRMatrixDiag(Pattern); Pattern_diag_i = hypre_CSRMatrixI(Pattern_diag); Pattern_diag_data = hypre_CSRMatrixData(Pattern_diag); Pattern_diag_j = hypre_CSRMatrixJ(Pattern_diag); Pattern_offd = hypre_ParCSRMatrixOffd(Pattern); Pattern_offd_i = hypre_CSRMatrixI(Pattern_offd); Pattern_offd_j = hypre_CSRMatrixJ(Pattern_offd); col_map_offd_Pattern = hypre_ParCSRMatrixColMapOffd(Pattern); num_cols_Pattern_offd = hypre_CSRMatrixNumCols(Pattern_offd); if (num_cols_Pattern_offd) { Pattern_offd_data = hypre_CSRMatrixData(Pattern_offd); } /* * Fill in the entries of Pattern with entries from RAP */ / First, sort column indices in RAP and Pattern / for(i = 0; i < num_variables; i++) { / The diag matrices store the diagonal as first element in each row. * We maintain that for the case of Pattern and RAP, because the * strength of connection routine relies on it and we need to ignore * diagonal entries in Pattern later during set intersections. * / / Sort diag portion of RAP / row_start = RAP_diag_i[i]; if( RAP_diag_j[row_start] == i) { row_start = row_start + 1; } row_end = RAP_diag_i[i+1]; hypre_qsort1(RAP_diag_j, RAP_diag_data, row_start, row_end-1 ); / Sort diag portion of Pattern / row_start = Pattern_diag_i[i]; if( Pattern_diag_j[row_start] == i) { row_start = row_start + 1; } row_end = Pattern_diag_i[i+1]; hypre_qsort1(Pattern_diag_j, Pattern_diag_data, row_start, row_end-1 ); / Sort offd portion of RAP / row_start = RAP_offd_i[i]; row_end = RAP_offd_i[i+1]; hypre_qsort1(RAP_offd_j, RAP_offd_data, row_start, row_end-1 ); / Sort offd portion of Pattern / / Be careful to map coarse dof i with CF_marker into Pattern / row_start = Pattern_offd_i[i]; row_end = Pattern_offd_i[i+1]; hypre_qsort1(Pattern_offd_j, Pattern_offd_data, row_start, row_end-1 ); } / Create Strength matrix based on RAP or Pattern. If Pattern is used, * then the SortedCopyParCSRData(...) function call must also be commented * back in / / hypre_SortedCopyParCSRData(RAP, Pattern); / if(0) { / hypre_BoomerAMG_MyCreateS(Pattern, strong_threshold, max_row_sum, / hypre_BoomerAMG_MyCreateS(RAP, strong_threshold, max_row_sum, num_functions, dof_func_value, &S); } else { / Passing in "1, NULL" because dof_array is not needed * because we assume that the number of functions is 1 / / hypre_BoomerAMG_MyCreateS(Pattern, strong_threshold, max_row_sum,/ hypre_BoomerAMG_MyCreateS(RAP, strong_threshold, max_row_sum, 1, NULL, &S); } /if (0)/ /(strong_threshold > S_commpkg_switch)/ /{ hypre_BoomerAMG_MyCreateSCommPkg(RAP, S, &col_offd_S_to_A); }/ / Grab diag and offd parts of S / S_diag = hypre_ParCSRMatrixDiag(S); S_diag_i = hypre_CSRMatrixI(S_diag); S_diag_j = hypre_CSRMatrixJ(S_diag); S_diag_data = hypre_CSRMatrixData(S_diag); S_offd = hypre_ParCSRMatrixOffd(S); S_offd_i = hypre_CSRMatrixI(S_offd); S_offd_j = hypre_CSRMatrixJ(S_offd); S_offd_data = hypre_CSRMatrixData(S_offd); col_map_offd_S = hypre_ParCSRMatrixColMapOffd(S); num_cols_offd_S = hypre_CSRMatrixNumCols(S_offd); / num_nonzeros_S_diag = S_diag_i[num_variables]; / / Grab part of S that is distance one away from the local rows * This is needed later for the stencil collapsing. This section * of the code mimics par_rap.c when it extracts Ps_ext. * When moving from par_rap.c, the variable name changes were: * A --> RAP * P --> S * Ps_ext --> S_ext * P_ext_diag --> S_ext_diag * P_ext_offd --> S_ext_offd * * The data layout of S_ext as returned by ExtractBExt gives you only global * column indices, and must be converted to the local numbering. This code * section constructs S_ext_diag and S_ext_offd, which are the distance 1 * couplings in S based on the sparsity structure in RAP. * --> S_ext_diag corresponds to the same column slice that RAP_diag * corresponds to. Thus, the column indexing is the same as in * RAP_diag such that S_ext_diag_j[k] just needs to be offset by * the RAP_diag first global dof offset. * --> S_ext_offd column indexing is a little more complicated, and * requires the computation below of col_map_S_ext_offd, which * maps the local 0,1,2,... column indexing in S_ext_offd to global * dof numbers. Note, that the num_cols_RAP_offd is NOT equal to * num_cols_offd_S_ext * --> The row indexing of S_ext_diag\|offd is as follows. Use * col_map_offd_RAP, where the first index corresponds to the * first global row index in S_ext_diag\|offd. Remember that ExtractBExt * grabs the information from S required for locally computing * (RAPS)[proc_k row slice, :] / if (num_procs > 1) { S_ext = hypre_ParCSRMatrixExtractBExt(S,RAP,1); S_ext_data = hypre_CSRMatrixData(S_ext); S_ext_i = hypre_CSRMatrixI(S_ext); S_ext_j = hypre_CSRMatrixBigJ(S_ext); } /* This uses the num_cols_RAP_offd to set S_ext_diag\|offd_i, because S_ext * is the off-processor information needed to compute RAPS. That is, num_cols_RAP_offd represents the number of rows needed from S_ext for * the multiplication / S_ext_diag_i = hypre_CTAlloc(HYPRE_Int, num_cols_RAP_offd+1, HYPRE_MEMORY_HOST); S_ext_offd_i = hypre_CTAlloc(HYPRE_Int, num_cols_RAP_offd+1, HYPRE_MEMORY_HOST); S_ext_diag_size = 0; S_ext_offd_size = 0; / num_rows_Sext = num_cols_RAP_offd; / last_col_diag_RAP = first_col_diag_RAP + num_cols_diag_RAP - 1; / construct the S_ext_diag and _offd row-pointer arrays by counting elements * This looks to create offd and diag blocks related to the local rows belonging * to this processor...we may not need to split up S_ext this way...or we could. * It would make for faster binary searching and set intersecting later...this will * be the bottle neck so LETS SPLIT THIS UP Between offd and diag/ for (i=0; i < num_cols_RAP_offd; i++) { for (j=S_ext_i[i]; j < S_ext_i[i+1]; j++) if (S_ext_j[j] < first_col_diag_RAP \|\| S_ext_j[j] > last_col_diag_RAP) S_ext_offd_size++; else S_ext_diag_size++; S_ext_diag_i[i+1] = S_ext_diag_size; S_ext_offd_i[i+1] = S_ext_offd_size; } if (S_ext_diag_size) { S_ext_diag_j = hypre_CTAlloc(HYPRE_Int, S_ext_diag_size, HYPRE_MEMORY_HOST); S_ext_diag_data = hypre_CTAlloc(HYPRE_Real, S_ext_diag_size, HYPRE_MEMORY_HOST); } if (S_ext_offd_size) { S_ext_offd_j = hypre_CTAlloc(HYPRE_Int, S_ext_offd_size, HYPRE_MEMORY_HOST); S_ext_offd_data = hypre_CTAlloc(HYPRE_Real, S_ext_offd_size, HYPRE_MEMORY_HOST); } / This copies over the column indices into the offd and diag parts. * The diag portion has it's local column indices shifted to start at 0. * The offd portion requires more work to construct the col_map_offd array * and a local column ordering. / cnt_offd = 0; cnt_diag = 0; cnt = 0; for (i=0; i < num_cols_RAP_offd; i++) { for (j=S_ext_i[i]; j < S_ext_i[i+1]; j++) if (S_ext_j[j] < first_col_diag_RAP \|\| S_ext_j[j] > last_col_diag_RAP) { S_ext_offd_data[cnt_offd] = S_ext_data[j]; //S_ext_offd_j[cnt_offd++] = S_ext_j[j]; S_ext_j[cnt_offd++] = S_ext_j[j]; } else { S_ext_diag_data[cnt_diag] = S_ext_data[j]; S_ext_diag_j[cnt_diag++] = (HYPRE_Int)(S_ext_j[j] - first_col_diag_RAP); } } / This creates col_map_offd_Sext / if (S_ext_offd_size \|\| num_cols_offd_S) { temp = hypre_CTAlloc(HYPRE_BigInt, S_ext_offd_size+num_cols_offd_S, HYPRE_MEMORY_HOST); for (i=0; i < S_ext_offd_size; i++) temp[i] = S_ext_j[i]; cnt = S_ext_offd_size; for (i=0; i < num_cols_offd_S; i++) temp[cnt++] = col_map_offd_S[i]; } if (cnt) { / after this, the first so many entries of temp will hold the * unique column indices in S_ext_offd_j unioned with the indices * in col_map_offd_S / hypre_BigQsort0(temp, 0, cnt-1); num_cols_offd_Sext = 1; value = temp[0]; for (i=1; i < cnt; i++) { if (temp[i] > value) { value = temp[i]; temp[num_cols_offd_Sext++] = value; } } } else { num_cols_offd_Sext = 0; } / num_nonzeros_S_ext_diag = cnt_diag; num_nonzeros_S_ext_offd = S_ext_offd_size; / if (num_cols_offd_Sext) col_map_offd_Sext = hypre_CTAlloc(HYPRE_BigInt, num_cols_offd_Sext, HYPRE_MEMORY_HOST); for (i=0; i < num_cols_offd_Sext; i++) col_map_offd_Sext[i] = temp[i]; if (S_ext_offd_size \|\| num_cols_offd_S) hypre_TFree(temp, HYPRE_MEMORY_HOST); / look for S_ext_offd_j[i] in col_map_offd_Sext, and set S_ext_offd_j[i] * to the index of that column value in col_map_offd_Sext / for (i=0 ; i < S_ext_offd_size; i++) S_ext_offd_j[i] = hypre_BigBinarySearch(col_map_offd_Sext, S_ext_j[i], num_cols_offd_Sext); if (num_procs > 1) { hypre_CSRMatrixDestroy(S_ext); S_ext = NULL; } / Need to sort column indices in S and S_ext / for(i = 0; i < num_variables; i++) { / Re-Sort diag portion of Pattern, placing the diagonal entry in a * sorted position / row_start = Pattern_diag_i[i]; row_end = Pattern_diag_i[i+1]; hypre_qsort1(Pattern_diag_j, Pattern_diag_data, row_start, row_end-1 ); / Sort diag portion of S, noting that no diagonal entry / / S has not "data" array...it's just NULL / row_start = S_diag_i[i]; row_end = S_diag_i[i+1]; hypre_qsort1(S_diag_j, S_diag_data, row_start, row_end-1 ); / Sort offd portion of S / / S has no "data" array...it's just NULL / row_start = S_offd_i[i]; row_end = S_offd_i[i+1]; hypre_qsort1(S_offd_j, S_offd_data, row_start, row_end-1 ); } / Sort S_ext * num_cols_RAP_offd equals num_rows for S_ext/ for(i = 0; i < num_cols_RAP_offd; i++) { / Sort diag portion of S_ext / row_start = S_ext_diag_i[i]; row_end = S_ext_diag_i[i+1]; hypre_qsort1(S_ext_diag_j, S_ext_diag_data, row_start, row_end-1 ); / Sort offd portion of S_ext / row_start = S_ext_offd_i[i]; row_end = S_ext_offd_i[i+1]; hypre_qsort1(S_ext_offd_j, S_ext_offd_data, row_start, row_end-1 ); } / * Now, for the fun stuff -- Computing the Non-Galerkin Operator / / Initialize the ijmatrix, leveraging our knowledge of the nonzero * structure in Pattern / ierr += HYPRE_IJMatrixCreate(comm, first_col_diag_RAP, last_col_diag_RAP, first_col_diag_RAP, last_col_diag_RAP, &ijmatrix); ierr += HYPRE_IJMatrixSetObjectType(ijmatrix, HYPRE_PARCSR); rownz = hypre_CTAlloc(HYPRE_Int, num_variables, HYPRE_MEMORY_HOST); for(i = 0; i < num_variables; i++) { rownz[i] = 1.2(Pattern_diag_i[i+1] - Pattern_diag_i[i]) + 1.2(Pattern_offd_i[i+1] - Pattern_offd_i[i]); } HYPRE_IJMatrixSetRowSizes(ijmatrix, rownz); ierr += HYPRE_IJMatrixInitialize(ijmatrix); hypre_TFree(rownz, HYPRE_MEMORY_HOST); / For efficiency, we do a buffered IJAddToValues. Here, we initialize the buffer and then initialize the buffer counters / ijbuf_size = 1000; ijbuf_data = hypre_CTAlloc(HYPRE_Real, ijbuf_size, HYPRE_MEMORY_HOST); ijbuf_cols = hypre_CTAlloc(HYPRE_BigInt, ijbuf_size, HYPRE_MEMORY_HOST); ijbuf_rownums = hypre_CTAlloc(HYPRE_BigInt, ijbuf_size, HYPRE_MEMORY_HOST); ijbuf_numcols = hypre_CTAlloc(HYPRE_Int, ijbuf_size, HYPRE_MEMORY_HOST); hypre_NonGalerkinIJBigBufferInit( &ijbuf_cnt, &ijbuf_rowcounter, ijbuf_cols ); if(sym_collapse) { ijbuf_sym_data = hypre_CTAlloc(HYPRE_Real, ijbuf_size, HYPRE_MEMORY_HOST); ijbuf_sym_cols = hypre_CTAlloc(HYPRE_BigInt, ijbuf_size, HYPRE_MEMORY_HOST); ijbuf_sym_rownums= hypre_CTAlloc(HYPRE_BigInt, ijbuf_size, HYPRE_MEMORY_HOST); ijbuf_sym_numcols= hypre_CTAlloc(HYPRE_Int, ijbuf_size, HYPRE_MEMORY_HOST); hypre_NonGalerkinIJBigBufferInit( &ijbuf_sym_cnt, &ijbuf_sym_rowcounter, ijbuf_sym_cols ); } / * Eliminate Entries In RAP_diag * / for(i = 0; i < num_variables; i++) { global_row = i+first_col_diag_RAP; row_start = RAP_diag_i[i]; row_end = RAP_diag_i[i+1]; has_row_ended = 0; / Only do work if row has nonzeros / if( row_start < row_end) { / Grab pointer to current entry in Pattern_diag / current_Pattern_j = Pattern_diag_i[i]; col_indx_Pattern = Pattern_diag_j[current_Pattern_j]; / Grab this row's indices out of Pattern offd and diag. This will * be for computing index set intersections for lumping / / Ensure adequate length / Pattern_offd_indices_len = Pattern_offd_i[i+1] - Pattern_offd_i[i]; if(Pattern_offd_indices_allocated_len < Pattern_offd_indices_len) { hypre_TFree(Pattern_offd_indices, HYPRE_MEMORY_HOST); Pattern_offd_indices = hypre_CTAlloc(HYPRE_Int, Pattern_offd_indices_len, HYPRE_MEMORY_HOST); Pattern_offd_indices_allocated_len = Pattern_offd_indices_len; } / Grab sub array from col_map, corresponding to the slice of Pattern_offd_j / hypre_GrabSubArray(Pattern_offd_j, Pattern_offd_i[i], Pattern_offd_i[i+1]-1, col_map_offd_Pattern, Pattern_offd_indices); / No need to grab info out of Pattern_diag_j[...], here we just start from * Pattern_diag_i[i] and end at index Pattern_diag_i[i+1] - 1. We do need to * ignore the diagonal entry in Pattern, because we don't lump entries there / if( Pattern_diag_j[Pattern_diag_i[i]] == i ) { Pattern_indices_ptr = &( Pattern_diag_j[Pattern_diag_i[i]+1]); Pattern_diag_indices_len = Pattern_diag_i[i+1] - Pattern_diag_i[i] - 1; } else { Pattern_indices_ptr = &( Pattern_diag_j[Pattern_diag_i[i]]); Pattern_diag_indices_len = Pattern_diag_i[i+1] - Pattern_diag_i[i]; } } for(j = row_start; j < row_end; j++) { col_indx_RAP = RAP_diag_j[j]; / Ignore zero entries in RAP / if( RAP_diag_data[j] != 0.0) { / Don't change the diagonal, just write it / if(col_indx_RAP == i) { /#ifdef HY PRE_USING_OPENMP #pragma omp critical (IJAdd) #endif {/ / For efficiency, we do a buffered IJAddToValues. * A[global_row, global_row] += RAP_diag_data[j] / hypre_NonGalerkinIJBufferWrite( ijmatrix, &ijbuf_cnt, ijbuf_size, &ijbuf_rowcounter, &ijbuf_data, &ijbuf_cols, &ijbuf_rownums, &ijbuf_numcols, global_row, global_row, RAP_diag_data[j] ); /}/ } / The entry in RAP does not appear in Pattern, so LUMP it / else if( (col_indx_RAP < col_indx_Pattern) \|\| has_row_ended) { / Lump entry (i, col_indx_RAP) in RAP / / Grab the indices for row col_indx_RAP of S_offd and diag. This will * be for computing lumping locations / S_offd_indices_len = S_offd_i[col_indx_RAP+1] - S_offd_i[col_indx_RAP]; if(S_offd_indices_allocated_len < S_offd_indices_len) { hypre_TFree(S_offd_indices, HYPRE_MEMORY_HOST); S_offd_indices = hypre_CTAlloc(HYPRE_Int, S_offd_indices_len, HYPRE_MEMORY_HOST); S_offd_indices_allocated_len = S_offd_indices_len; } / Grab sub array from col_map, corresponding to the slice of S_offd_j / hypre_GrabSubArray(S_offd_j, S_offd_i[col_indx_RAP], S_offd_i[col_indx_RAP+1]-1, col_map_offd_S, S_offd_indices); / No need to grab info out of S_diag_j[...], here we just start from * S_diag_i[col_indx_RAP] and end at index S_diag_i[col_indx_RAP+1] - 1 / / Intersect the diag and offd pieces, remembering that the * diag array will need to have the offset +first_col_diag_RAP / cnt = hypre_max(S_offd_indices_len, Pattern_offd_indices_len); if(offd_intersection_allocated_len < cnt) { hypre_TFree(offd_intersection, HYPRE_MEMORY_HOST); hypre_TFree(offd_intersection_data, HYPRE_MEMORY_HOST); offd_intersection = hypre_CTAlloc(HYPRE_Int, cnt, HYPRE_MEMORY_HOST); offd_intersection_data = hypre_CTAlloc(HYPRE_Real, cnt, HYPRE_MEMORY_HOST); offd_intersection_allocated_len = cnt; } / This intersection also tracks S_offd_data and assumes that * S_offd_indices is the first argument here / hypre_IntersectTwoArrays(S_offd_indices, &(S_offd_data[ S_offd_i[col_indx_RAP] ]), S_offd_indices_len, Pattern_offd_indices, Pattern_offd_indices_len, offd_intersection, offd_intersection_data, &offd_intersection_len); / Now, intersect the indices for the diag block. Note that S_diag_j does * not have a diagonal entry, so no lumping occurs to the diagonal. / cnt = hypre_max(Pattern_diag_indices_len, S_diag_i[col_indx_RAP+1] - S_diag_i[col_indx_RAP] ); if(diag_intersection_allocated_len < cnt) { hypre_TFree(diag_intersection, HYPRE_MEMORY_HOST); hypre_TFree(diag_intersection_data, HYPRE_MEMORY_HOST); diag_intersection = hypre_CTAlloc(HYPRE_Int, cnt, HYPRE_MEMORY_HOST); diag_intersection_data = hypre_CTAlloc(HYPRE_Real, cnt, HYPRE_MEMORY_HOST); diag_intersection_allocated_len = cnt; } / There is no diagonal entry in first position of S / hypre_IntersectTwoArrays( &(S_diag_j[S_diag_i[col_indx_RAP]]), &(S_diag_data[ S_diag_i[col_indx_RAP] ]), S_diag_i[col_indx_RAP+1] - S_diag_i[col_indx_RAP], Pattern_indices_ptr, Pattern_diag_indices_len, diag_intersection, diag_intersection_data, &diag_intersection_len); / Loop over these intersections, and lump a constant fraction of * RAP_diag_data[j] to each entry / intersection_len = diag_intersection_len + offd_intersection_len; if(intersection_len > 0) { / Sum the strength-of-connection values from row * col_indx_RAP in S, corresponding to the indices we are * collapsing to in row i This will give us our collapsing * weights. / sum_strong_neigh = 0.0; for(k = 0; k < diag_intersection_len; k++) { sum_strong_neigh += fabs(diag_intersection_data[k]); } for(k = 0; k < offd_intersection_len; k++) { sum_strong_neigh += fabs(offd_intersection_data[k]); } sum_strong_neigh = RAP_diag_data[j]/sum_strong_neigh; / When lumping with the diag_intersection, must offset column index / for(k = 0; k < diag_intersection_len; k++) { lump_value = lump_percent fabs(diag_intersection_data[k])sum_strong_neigh; diagonal_lump_value = (1.0 - lump_percent) fabs(diag_intersection_data[k])sum_strong_neigh; neg_lump_value = -1.0 lump_value; cnt = diag_intersection[k]+first_col_diag_RAP; /#ifdef HY PRE_USING_OPENMP #pragma omp critical (IJAdd) #endif {/ /* For efficiency, we do a buffered IJAddToValues. * A[global_row, cnt] += RAP_diag_data[j] / hypre_NonGalerkinIJBufferWrite( ijmatrix, &ijbuf_cnt, ijbuf_size, &ijbuf_rowcounter, &ijbuf_data, &ijbuf_cols, &ijbuf_rownums, &ijbuf_numcols, global_row, cnt, lump_value ); if (lump_percent < 1.0) { / Preserve row sum by updating diagonal / hypre_NonGalerkinIJBufferWrite( ijmatrix, &ijbuf_cnt, ijbuf_size, &ijbuf_rowcounter, &ijbuf_data, &ijbuf_cols, &ijbuf_rownums, &ijbuf_numcols, global_row, global_row, diagonal_lump_value ); } / Update mirror entries, if symmetric collapsing / if(sym_collapse) { / Update mirror entry / hypre_NonGalerkinIJBufferWrite( ijmatrix, &ijbuf_sym_cnt, ijbuf_size, &ijbuf_sym_rowcounter, &ijbuf_sym_data, &ijbuf_sym_cols, &ijbuf_sym_rownums, &ijbuf_sym_numcols, cnt, global_row, lump_value ); / Update mirror entry diagonal / hypre_NonGalerkinIJBufferWrite( ijmatrix, &ijbuf_sym_cnt, ijbuf_size, &ijbuf_sym_rowcounter, &ijbuf_sym_data, &ijbuf_sym_cols, &ijbuf_sym_rownums, &ijbuf_sym_numcols, cnt, cnt, neg_lump_value ); } /}/ } / The offd_intersection has global column indices, i.e., the * col_map arrays contain global indices / for(k = 0; k < offd_intersection_len; k++) { lump_value = lump_percent fabs(offd_intersection_data[k])sum_strong_neigh; diagonal_lump_value = (1.0 - lump_percent) fabs(offd_intersection_data[k])sum_strong_neigh; neg_lump_value = -1.0 lump_value; hypre_NonGalerkinIJBufferWrite( ijmatrix, &ijbuf_cnt, ijbuf_size, &ijbuf_rowcounter, &ijbuf_data, &ijbuf_cols, &ijbuf_rownums, &ijbuf_numcols, global_row, offd_intersection[k], lump_value ); if (lump_percent < 1.0) { hypre_NonGalerkinIJBufferWrite( ijmatrix, &ijbuf_cnt, ijbuf_size, &ijbuf_rowcounter, &ijbuf_data, &ijbuf_cols, &ijbuf_rownums, &ijbuf_numcols, global_row, global_row, diagonal_lump_value ); } /* Update mirror entries, if symmetric collapsing / if (sym_collapse) { hypre_NonGalerkinIJBufferWrite( ijmatrix, &ijbuf_sym_cnt, ijbuf_size, &ijbuf_sym_rowcounter, &ijbuf_sym_data, &ijbuf_sym_cols, &ijbuf_sym_rownums, &ijbuf_sym_numcols, offd_intersection[k], global_row, lump_value ); hypre_NonGalerkinIJBufferWrite( ijmatrix, &ijbuf_sym_cnt, ijbuf_size, &ijbuf_sym_rowcounter, &ijbuf_sym_data, &ijbuf_sym_cols, &ijbuf_sym_rownums, &ijbuf_sym_numcols, offd_intersection[k], offd_intersection[k], neg_lump_value ); } } } / If intersection is empty, do not eliminate entry / else { / Don't forget to update mirror entry if collapsing symmetrically / if (sym_collapse) { lump_value = 0.5RAP_diag_data[j]; } else { lump_value = RAP_diag_data[j]; } cnt = col_indx_RAP+first_col_diag_RAP; hypre_NonGalerkinIJBufferWrite( ijmatrix, &ijbuf_cnt, ijbuf_size, &ijbuf_rowcounter, &ijbuf_data, &ijbuf_cols, &ijbuf_rownums, &ijbuf_numcols, global_row, cnt, lump_value ); if (sym_collapse) { hypre_NonGalerkinIJBufferWrite( ijmatrix, &ijbuf_sym_cnt, ijbuf_size, &ijbuf_sym_rowcounter, &ijbuf_sym_data, &ijbuf_sym_cols, &ijbuf_sym_rownums, &ijbuf_sym_numcols, cnt, global_row, lump_value ); } } } /* The entry in RAP appears in Pattern, so keep it / else if(col_indx_RAP == col_indx_Pattern) { cnt = col_indx_RAP+first_col_diag_RAP; hypre_NonGalerkinIJBufferWrite( ijmatrix, &ijbuf_cnt, ijbuf_size, &ijbuf_rowcounter, &ijbuf_data, &ijbuf_cols, &ijbuf_rownums, &ijbuf_numcols, global_row, cnt, RAP_diag_data[j] ); / Only go to the next entry in Pattern, if this is not the end of a row / if( current_Pattern_j < Pattern_diag_i[i+1]-1 ) { current_Pattern_j += 1; col_indx_Pattern = Pattern_diag_j[current_Pattern_j]; } else { has_row_ended = 1;} } / Increment col_indx_Pattern, and repeat this loop iter for current * col_ind_RAP value / else if(col_indx_RAP > col_indx_Pattern) { for(; current_Pattern_j < Pattern_diag_i[i+1]; current_Pattern_j++) { col_indx_Pattern = Pattern_diag_j[current_Pattern_j]; if(col_indx_RAP <= col_indx_Pattern) { break;} } / If col_indx_RAP is still greater (i.e., we've reached a row end), then * we need to lump everything else in this row / if(col_indx_RAP > col_indx_Pattern) { has_row_ended = 1; } / Decrement j, in order to repeat this loop iteration for the current * col_indx_RAP value / j--; } } } } / * Eliminate Entries In RAP_offd * Structure of this for-loop is very similar to the RAP_diag for-loop * But, not so similar that these loops should be combined into a single fuction. * / if(num_cols_RAP_offd) { for(i = 0; i < num_variables; i++) { global_row = i+first_col_diag_RAP; row_start = RAP_offd_i[i]; row_end = RAP_offd_i[i+1]; has_row_ended = 0; / Only do work if row has nonzeros / if( row_start < row_end) { current_Pattern_j = Pattern_offd_i[i]; Pattern_offd_indices_len = Pattern_offd_i[i+1] - Pattern_offd_i[i]; if( (Pattern_offd_j != NULL) && (Pattern_offd_indices_len > 0) ) { col_indx_Pattern = col_map_offd_Pattern[ Pattern_offd_j[current_Pattern_j] ]; } else { / if Pattern_offd_j is not allocated or this is a zero length row, then all entries need to be lumped. This is an analagous situation to has_row_ended=1. / col_indx_Pattern = -1; has_row_ended = 1; } / Grab this row's indices out of Pattern offd and diag. This will * be for computing index set intersections for lumping. The above * loop over RAP_diag ensures adequate length of Pattern_offd_indices / / Ensure adequate length / hypre_GrabSubArray(Pattern_offd_j, Pattern_offd_i[i], Pattern_offd_i[i+1]-1, col_map_offd_Pattern, Pattern_offd_indices); / No need to grab info out of Pattern_diag_j[...], here we just start from * Pattern_diag_i[i] and end at index Pattern_diag_i[i+1] - 1. We do need to * ignore the diagonal entry in Pattern, because we don't lump entries there / if( Pattern_diag_j[Pattern_diag_i[i]] == i ) { Pattern_indices_ptr = &( Pattern_diag_j[Pattern_diag_i[i]+1]); Pattern_diag_indices_len = Pattern_diag_i[i+1] - Pattern_diag_i[i] - 1; } else { Pattern_indices_ptr = &( Pattern_diag_j[Pattern_diag_i[i]]); Pattern_diag_indices_len = Pattern_diag_i[i+1] - Pattern_diag_i[i]; } } for(j = row_start; j < row_end; j++) { / Ignore zero entries in RAP / if( RAP_offd_data[j] != 0.0) { / In general for all the offd_j arrays, we have to indirectly * index with the col_map_offd array to get a global index / col_indx_RAP = col_map_offd_RAP[ RAP_offd_j[j] ]; / The entry in RAP does not appear in Pattern, so LUMP it / if( (col_indx_RAP < col_indx_Pattern) \|\| has_row_ended) { / The row_indx_Sext would be found with: row_indx_Sext = hypre_BinarySearch(col_map_offd_RAP, col_indx_RAP, num_cols_RAP_offd); But, we already know the answer to this with, / row_indx_Sext = RAP_offd_j[j]; / Grab the indices for row row_indx_Sext from the offd and diag parts. This will * be for computing lumping locations / S_offd_indices_len = S_ext_offd_i[row_indx_Sext+1] - S_ext_offd_i[row_indx_Sext]; if(S_offd_indices_allocated_len < S_offd_indices_len) { hypre_TFree(S_offd_indices, HYPRE_MEMORY_HOST); S_offd_indices = hypre_CTAlloc(HYPRE_Int, S_offd_indices_len, HYPRE_MEMORY_HOST); S_offd_indices_allocated_len = S_offd_indices_len; } / Grab sub array from col_map, corresponding to the slice of S_ext_offd_j / hypre_GrabSubArray(S_ext_offd_j, S_ext_offd_i[row_indx_Sext], S_ext_offd_i[row_indx_Sext+1]-1, col_map_offd_Sext, S_offd_indices); / No need to grab info out of S_ext_diag_j[...], here we just start from * S_ext_diag_i[row_indx_Sext] and end at index S_ext_diag_i[row_indx_Sext+1] - 1 / / Intersect the diag and offd pieces, remembering that the * diag array will need to have the offset +first_col_diag_RAP / cnt = hypre_max(S_offd_indices_len, Pattern_offd_indices_len); if(offd_intersection_allocated_len < cnt) { hypre_TFree(offd_intersection, HYPRE_MEMORY_HOST); hypre_TFree(offd_intersection_data, HYPRE_MEMORY_HOST); offd_intersection = hypre_CTAlloc(HYPRE_Int, cnt, HYPRE_MEMORY_HOST); offd_intersection_data = hypre_CTAlloc(HYPRE_Real, cnt, HYPRE_MEMORY_HOST); offd_intersection_allocated_len = cnt; } hypre_IntersectTwoArrays(S_offd_indices, &(S_ext_offd_data[ S_ext_offd_i[row_indx_Sext] ]), S_offd_indices_len, Pattern_offd_indices, Pattern_offd_indices_len, offd_intersection, offd_intersection_data, &offd_intersection_len); / Now, intersect the indices for the diag block. / cnt = hypre_max(Pattern_diag_indices_len, S_ext_diag_i[row_indx_Sext+1] - S_ext_diag_i[row_indx_Sext] ); if(diag_intersection_allocated_len < cnt) { hypre_TFree(diag_intersection, HYPRE_MEMORY_HOST); hypre_TFree(diag_intersection_data, HYPRE_MEMORY_HOST); diag_intersection = hypre_CTAlloc(HYPRE_Int, cnt, HYPRE_MEMORY_HOST); diag_intersection_data = hypre_CTAlloc(HYPRE_Real, cnt, HYPRE_MEMORY_HOST); diag_intersection_allocated_len = cnt; } hypre_IntersectTwoArrays( &(S_ext_diag_j[S_ext_diag_i[row_indx_Sext]]), &(S_ext_diag_data[ S_ext_diag_i[row_indx_Sext] ]), S_ext_diag_i[row_indx_Sext+1] - S_ext_diag_i[row_indx_Sext], Pattern_indices_ptr, Pattern_diag_indices_len, diag_intersection, diag_intersection_data, &diag_intersection_len); / Loop over these intersections, and lump a constant fraction of * RAP_offd_data[j] to each entry / intersection_len = diag_intersection_len + offd_intersection_len; if(intersection_len > 0) { / Sum the strength-of-connection values from row * row_indx_Sext in S, corresponding to the indices we are * collapsing to in row i. This will give us our collapsing * weights. / sum_strong_neigh = 0.0; for(k = 0; k < diag_intersection_len; k++) { sum_strong_neigh += fabs(diag_intersection_data[k]); } for(k = 0; k < offd_intersection_len; k++) { sum_strong_neigh += fabs(offd_intersection_data[k]); } sum_strong_neigh = RAP_offd_data[j]/sum_strong_neigh; / When lumping with the diag_intersection, must offset column index / for(k = 0; k < diag_intersection_len; k++) { lump_value = lump_percent fabs(diag_intersection_data[k])sum_strong_neigh; diagonal_lump_value = (1.0 - lump_percent) fabs(diag_intersection_data[k])sum_strong_neigh; neg_lump_value = -1.0 lump_value; cnt = diag_intersection[k]+first_col_diag_RAP; hypre_NonGalerkinIJBufferWrite( ijmatrix, &ijbuf_cnt, ijbuf_size, &ijbuf_rowcounter, &ijbuf_data, &ijbuf_cols, &ijbuf_rownums, &ijbuf_numcols, global_row, cnt, lump_value ); if (lump_percent < 1.0) { hypre_NonGalerkinIJBufferWrite( ijmatrix, &ijbuf_cnt, ijbuf_size, &ijbuf_rowcounter, &ijbuf_data, &ijbuf_cols, &ijbuf_rownums, &ijbuf_numcols, global_row, global_row, diagonal_lump_value ); } /* Update mirror entries, if symmetric collapsing / if (sym_collapse) { hypre_NonGalerkinIJBufferWrite( ijmatrix, &ijbuf_sym_cnt, ijbuf_size, &ijbuf_sym_rowcounter, &ijbuf_sym_data, &ijbuf_sym_cols, &ijbuf_sym_rownums, &ijbuf_sym_numcols, cnt, global_row, lump_value); hypre_NonGalerkinIJBufferWrite( ijmatrix, &ijbuf_sym_cnt, ijbuf_size, &ijbuf_sym_rowcounter, &ijbuf_sym_data, &ijbuf_sym_cols, &ijbuf_sym_rownums, &ijbuf_sym_numcols, cnt, cnt, neg_lump_value ); } } / The offd_intersection has global column indices, i.e., the * col_map arrays contain global indices / for(k = 0; k < offd_intersection_len; k++) { lump_value = lump_percent fabs(offd_intersection_data[k])sum_strong_neigh; diagonal_lump_value = (1.0 - lump_percent) fabs(offd_intersection_data[k])sum_strong_neigh; neg_lump_value = -1.0 lump_value; hypre_NonGalerkinIJBufferWrite( ijmatrix, &ijbuf_cnt, ijbuf_size, &ijbuf_rowcounter, &ijbuf_data, &ijbuf_cols, &ijbuf_rownums, &ijbuf_numcols, global_row, offd_intersection[k], lump_value ); if (lump_percent < 1.0) { hypre_NonGalerkinIJBufferWrite( ijmatrix, &ijbuf_cnt, ijbuf_size, &ijbuf_rowcounter, &ijbuf_data, &ijbuf_cols, &ijbuf_rownums, &ijbuf_numcols, global_row, global_row, diagonal_lump_value ); } /* Update mirror entries, if symmetric collapsing / if (sym_collapse) { hypre_NonGalerkinIJBufferWrite( ijmatrix, &ijbuf_sym_cnt, ijbuf_size, &ijbuf_sym_rowcounter, &ijbuf_sym_data, &ijbuf_sym_cols, &ijbuf_sym_rownums, &ijbuf_sym_numcols, offd_intersection[k], global_row, lump_value ); hypre_NonGalerkinIJBufferWrite( ijmatrix, &ijbuf_sym_cnt, ijbuf_size, &ijbuf_sym_rowcounter, &ijbuf_sym_data, &ijbuf_sym_cols, &ijbuf_sym_rownums, &ijbuf_sym_numcols, offd_intersection[k], offd_intersection[k], neg_lump_value ); } } } / If intersection is empty, do not eliminate entry / else { / Don't forget to update mirror entry if collapsing symmetrically / if (sym_collapse) { lump_value = 0.5RAP_offd_data[j]; } else { lump_value = RAP_offd_data[j]; } hypre_NonGalerkinIJBufferWrite( ijmatrix, &ijbuf_cnt, ijbuf_size, &ijbuf_rowcounter, &ijbuf_data, &ijbuf_cols, &ijbuf_rownums, &ijbuf_numcols, global_row, col_indx_RAP, lump_value ); if (sym_collapse) { hypre_NonGalerkinIJBufferWrite( ijmatrix, &ijbuf_sym_cnt, ijbuf_size, &ijbuf_sym_rowcounter, &ijbuf_sym_data, &ijbuf_sym_cols, &ijbuf_sym_rownums, &ijbuf_sym_numcols, col_indx_RAP, global_row, lump_value ); } } } /* The entry in RAP appears in Pattern, so keep it / else if (col_indx_RAP == col_indx_Pattern) { / For the offd structure, col_indx_RAP is a global dof number / hypre_NonGalerkinIJBufferWrite( ijmatrix, &ijbuf_cnt, ijbuf_size, &ijbuf_rowcounter, &ijbuf_data, &ijbuf_cols, &ijbuf_rownums, &ijbuf_numcols, global_row, col_indx_RAP, RAP_offd_data[j]); / Only go to the next entry in Pattern, if this is not the end of a row / if( current_Pattern_j < Pattern_offd_i[i+1]-1 ) { current_Pattern_j += 1; col_indx_Pattern = col_map_offd_Pattern[ Pattern_offd_j[current_Pattern_j] ]; } else { has_row_ended = 1;} } / Increment col_indx_Pattern, and repeat this loop iter for current * col_ind_RAP value / else if(col_indx_RAP > col_indx_Pattern) { for(; current_Pattern_j < Pattern_offd_i[i+1]; current_Pattern_j++) { col_indx_Pattern = col_map_offd_Pattern[ Pattern_offd_j[current_Pattern_j] ]; if(col_indx_RAP <= col_indx_Pattern) { break;} } / If col_indx_RAP is still greater (i.e., we've reached a row end), then * we need to lump everything else in this row / if(col_indx_RAP > col_indx_Pattern) { has_row_ended = 1; } / Decrement j, in order to repeat this loop iteration for the current * col_indx_RAP value / j--; } } } } } / For efficiency, we do a buffered IJAddToValues. * This empties the buffer of any remaining values / hypre_NonGalerkinIJBufferEmpty(ijmatrix, ijbuf_size, &ijbuf_cnt, ijbuf_rowcounter, &ijbuf_data, &ijbuf_cols, &ijbuf_rownums, &ijbuf_numcols); if(sym_collapse) hypre_NonGalerkinIJBufferEmpty(ijmatrix, ijbuf_size, &ijbuf_sym_cnt, ijbuf_sym_rowcounter, &ijbuf_sym_data, &ijbuf_sym_cols, &ijbuf_sym_rownums, &ijbuf_sym_numcols); / Assemble non-Galerkin Matrix, and overwrite current RAP/ ierr += HYPRE_IJMatrixAssemble (ijmatrix); ierr += HYPRE_IJMatrixGetObject( ijmatrix, (void) RAP_ptr); / Optional diagnostic matrix printing / if (0) { hypre_sprintf(filename, "Pattern_%d.ij", global_num_vars); hypre_ParCSRMatrixPrintIJ(Pattern, 0, 0, filename); hypre_sprintf(filename, "Strength_%d.ij", global_num_vars); hypre_ParCSRMatrixPrintIJ(S, 0, 0, filename); hypre_sprintf(filename, "RAP_%d.ij", global_num_vars); hypre_ParCSRMatrixPrintIJ(RAP, 0, 0, filename); hypre_sprintf(filename, "RAPc_%d.ij", global_num_vars); hypre_ParCSRMatrixPrintIJ(RAP_ptr, 0, 0, filename); hypre_sprintf(filename, "AP_%d.ij", global_num_vars); hypre_ParCSRMatrixPrintIJ(AP, 0, 0, filename); } /* Free matrices and variables and arrays / hypre_TFree(ijbuf_data, HYPRE_MEMORY_HOST); hypre_TFree(ijbuf_cols, HYPRE_MEMORY_HOST); hypre_TFree(ijbuf_rownums, HYPRE_MEMORY_HOST); hypre_TFree(ijbuf_numcols, HYPRE_MEMORY_HOST); if(sym_collapse) { hypre_TFree(ijbuf_sym_data, HYPRE_MEMORY_HOST); hypre_TFree(ijbuf_sym_cols, HYPRE_MEMORY_HOST); hypre_TFree(ijbuf_sym_rownums, HYPRE_MEMORY_HOST); hypre_TFree(ijbuf_sym_numcols, HYPRE_MEMORY_HOST); } hypre_TFree(Pattern_offd_indices, HYPRE_MEMORY_HOST); hypre_TFree(S_ext_diag_i, HYPRE_MEMORY_HOST); hypre_TFree(S_ext_offd_i, HYPRE_MEMORY_HOST); hypre_TFree(S_offd_indices, HYPRE_MEMORY_HOST); hypre_TFree(offd_intersection, HYPRE_MEMORY_HOST); hypre_TFree(offd_intersection_data, HYPRE_MEMORY_HOST); hypre_TFree(diag_intersection, HYPRE_MEMORY_HOST); hypre_TFree(diag_intersection_data, HYPRE_MEMORY_HOST); if (S_ext_diag_size) { hypre_TFree(S_ext_diag_j, HYPRE_MEMORY_HOST); hypre_TFree(S_ext_diag_data, HYPRE_MEMORY_HOST); } if (S_ext_offd_size) { hypre_TFree(S_ext_offd_j, HYPRE_MEMORY_HOST); hypre_TFree(S_ext_offd_data, HYPRE_MEMORY_HOST); } if (num_cols_offd_Sext) { hypre_TFree(col_map_offd_Sext, HYPRE_MEMORY_HOST); } if (0) /(strong_threshold > S_commpkg_switch)/ { hypre_TFree(col_offd_S_to_A, HYPRE_MEMORY_HOST); } ierr += hypre_ParCSRMatrixDestroy(Pattern); ierr += hypre_ParCSRMatrixDestroy(RAP); ierr += hypre_ParCSRMatrixDestroy(S); ierr += HYPRE_IJMatrixSetObjectType(ijmatrix, -1); ierr += HYPRE_IJMatrixDestroy(ijmatrix); /end_time = hypre_MPI_Wtime(); if(my_id == 0) { fprintf(stdout, "NonGalerkin Time: %1.2e\n", end_time-start_time); } */ return ierr; }
random.c	/* Copyright (c) 2013, Intel Corporation Redistribution and use in source and binary forms, with or without modification, are permitted provided that the following conditions are met: * Redistributions of source code must retain the above copyright notice, this list of conditions and the following disclaimer. * Redistributions in binary form must reproduce the above copyright notice, this list of conditions and the following disclaimer in the documentation and/or other materials provided with the distribution. * Neither the name of Intel Corporation nor the names of its contributors may be used to endorse or promote products derived from this software without specific prior written permission. THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. / /********************************************************** Copyright (c) 2013 The University of Tennessee. All rights reserved. Redistribution and use in source and binary forms, with or without modification, are permitted provided that the following conditions are met: - Redistributions of source code must retain the above copyright notice, this list of conditions and the following disclaimer. - Redistributions in binary form must reproduce the above copyright notice, this list of conditions and the following disclaimer listed in this license in the documentation and/or other materials provided with the distribution. - Neither the name of the copyright holders nor the names of its contributors may be used to endorse or promote products derived from this software without specific prior written permission. This software is provided by the copyright holders and contributors "as is" and any express or implied warranties, including, but not limited to, the implied warranties of merchantability and fitness for a particular purpose are disclaimed. in no event shall the copyright owner or contributors be liable for any direct, indirect, incidental, special, exemplary, or consequential damages (including, but not limited to, procurement of substitute goods or services; loss of use, data, or profits; or business interruption) however caused and on any theory of liability, whether in contract, strict liability, or tort (including negligence or otherwise) arising in any way out of the use of this software, even if advised of the possibility of such damage. *********************************************************/ /*************************************************************** NAME: RandomAccess PURPOSE: This program tests the efficiency of the memory subsystem to update elements of an array with irregular stride. USAGE: The program takes as input the number of threads involved, the 2log of the size of the table that gets updated, the ratio of table size over number of updates, and the vector length of simultaneously updatable table elements. When multiple threads participate, they all share the same table. This can lead to conflicts in memory accesses. Setting the ATOMICFLAG variable in the Makefile will avoid conflicts, but at a large price, because the atomic directive is currently not implemented on IA for the type of update operation used here. Instead, a critical section is used, serializing the main loop. If the CHUNKFLAG variable is set, contiguous, non-overlapping chunks of the array are assigned to individual threads. Each thread computes all pseudo-random indices into the table, but only updates table elements that fall inside its chunk. Hence, this version is safe, and there is no false sharing. It is also non-scalable. <progname> <# threads> <log2 tablesize> <#update ratio> <vector length> FUNCTIONS CALLED: Other than OpenMP or standard C functions, the following functions are used in this program: wtime() bail_out() PRK_starts() poweroftwo() NOTES: This program is derived from HPC Challenge Random Access. The random number generator computes successive powers of 0x2, modulo the primitive polynomial x^63+x^2+x+1. The principal differences between this code and the HPCC version are: - we start the stream of random numbers not with seed 0x1, but the SEQSEED-th element in the stream of powers of 0x2. - the timed code applies the RandomAccess operator twice to the table of computed resuls (starting with the same seed(s) for "ran" in both iterations. The second pass makes sure that any update to any table element that sets high-order bits in the first pass resets those bits to zero. - the verification test now simply constitutes checking whether table element j equals j. - the number of independent streams (vector length) can be changed by the user. We note that the vectorized version of this code (i.e. nstarts unequal to 1), does not feature exactly the same sequence of accesses and intermediate update values in the table as the scalar version. The reason for this is twofold. 1. the elements in the stream of powers of 0x2 that get computed outside the main timed loop as seeds for independent streams in the vectorized version, using the jump-ahead function PRK_starts, are computed inside the timed loop for the scalar version. However, since both versions do the same number of timed random accesses, the vectorized version must progress further in the sequence of powers of 0x2. 2. The independent streams of powers of 0x2 computed in the vectorized version can (and will) cause updates of the same elements of the table in an order that is not consistent with the scalar version. That is, distinct values of "ran" can refer to the same table element "ran&(tablesize-1)," but the operation Table[ran&(tablesize-1)] ^= ran will deposit different values in that table element for different values of ran. At the end of each pass over the data set, the table will contain the same values in the vector and scalar version (ignoring the small differences caused by 1.) because of commutativity of the XOR operator. If the update operator had been non-commutative, the vector and scalar version would have yielded different results. HISTORY: Written by Rob Van der Wijngaart, June 2006. Histogram code (verbose mode) courtesy Roger Golliver Shared table version derived from random.c by Michael Frumkin, October 2006 *********************************************************************************/ #include <par-res-kern_general.h> #include <par-res-kern_omp.h> / Define constants / / PERIOD = (2^63-1)/7 = 77312733792737649657 / #if LONG_IS_64BITS #define POLY 0x0000000000000007UL #define PERIOD 1317624576693539401L /* sequence number in stream of random numbers to be used as initial value / #define SEQSEED 834568137686317453L #else #define POLY 0x0000000000000007ULL #define PERIOD 1317624576693539401LL / sequence number in stream of random numbers to be used as initial value / #define SEQSEED 834568137686317453LL #endif #if HPCC #undef ATOMIC #undef CHUNKED #undef ERRORPERCENT #define ERRORPERCENT 1 #else #if CHUNKED #undef ATOMIC #endif #endif static u64Int PRK_starts(s64Int); #if UNUSED static int poweroftwo(int); #endif int main(int argc, char argv) { int my_ID; / thread ID / int update_ratio; / multiplier of tablesize for # updates / int nstarts; / vector length / s64Int i, j, round, oldsize; / dummies / s64Int error; / number of incorrect table elements / s64Int tablesize; / aggregate table size (all threads / s64Int nupdate; / number of updates per thread / size_t tablespace; / bytes per thread required for table / u64Int ran; /* vector of random numbers / s64Int index; / index into Table / #if VERBOSE u64Int RESTRICT Hist; /* histogram of # updates to table elements / unsigned int HistHist; /* histogram of update frequencies / #endif u64Int RESTRICT Table; /* (pseudo-)randomly accessed array / double random_time; int nthread_input; / thread parameters / int nthread; int log2tablesize; / log2 of aggregate table size / int num_error=0; / flag that signals that requested and obtained numbers of threads are the same / printf("Parallel Research Kernels version %s\n", PRKVERSION); printf("OpenMP Random Access test\n"); #if LONG_IS_64BITS if (sizeof(long) != 8) { printf("ERROR: Makefile says \"long\" is 8 bytes, but it is %d bytes\n", sizeof(long)); exit(EXIT_FAILURE); } #endif /****************************************************************** process and test input parameters ********************************************************************/ if (argc != 5){ printf("Usage: %s <# threads> <log2 tablesize> <#update ratio> ", argv); printf("<vector length>\n"); exit(EXIT_FAILURE); } nthread_input = atoi(++argv); / test whether number of threads is positive / if (nthread_input <1) { printf("ERROR: Invalid number of threads: %d, must be positive\n", nthread_input); exit(EXIT_FAILURE); } omp_set_num_threads(nthread_input); log2tablesize = atoi(++argv); if (log2tablesize < 1){ printf("ERROR: Log2 tablesize is %d; must be >= 1\n",log2tablesize); exit(EXIT_FAILURE); } update_ratio = atoi(++argv); / test whether update ratio is positive / if (update_ratio <1) { printf("ERROR: Invalid update ratio: %d, must be positive\n", update_ratio); exit(EXIT_FAILURE); } nstarts = atoi(++argv); /* if whether vector length is positive / if (nstarts <1) { printf("ERROR: Invalid vector length: %d, must be positive\n", nstarts); exit(EXIT_FAILURE); } / do some additional divisibility tests / if (nstarts%nthread_input) { printf("ERROR: vector length %d must be divisible by # threads %d\n", nstarts, nthread_input); exit(EXIT_FAILURE); } if (update_ratio%nstarts) { printf("ERROR: update ratio %d must be divisible by vector length %d\n", update_ratio, nstarts); exit(EXIT_FAILURE); } / compute table size carefully to make sure it can be represented / tablesize = 1; for (i=0; i<log2tablesize; i++) { oldsize = tablesize; tablesize <<=1; if (tablesize/2 != oldsize) { printf("Requested table size too large; reduce log2 tablesize = %d\n", log2tablesize); exit(EXIT_FAILURE); } } / even though the table size can be represented, computing the space required for the table may lead to overflow / tablespace = (size_t) tablesizesizeof(u64Int); if ((tablespace/sizeof(u64Int)) != tablesize \|\| tablespace <=0) { printf("Cannot represent space for table on this system; "); printf("reduce log2 tablesize\n"); exit(EXIT_FAILURE); } #if VERBOSE Hist = (u64Int ) prk_malloc(tablespace); HistHist = (unsigned int ) prk_malloc(tablespace); if (!Hist \|\| ! HistHist) { printf("ERROR: Could not allocate space for histograms\n"); exit(EXIT_FAILURE); } #endif /* compute number of updates carefully to make sure it can be represented / nupdate = update_ratio tablesize; if (nupdate/tablesize != update_ratio) { printf("Requested number of updates too large; "); printf("reduce log2 tablesize or update ratio\n"); exit(EXIT_FAILURE); } Table = (u64Int ) prk_malloc(tablespace); if (!Table) { printf("ERROR: Could not allocate space of "FSTR64U" bytes for table\n", (u64Int) tablespace); exit(EXIT_FAILURE); } error = 0; #pragma omp parallel private(i, j, ran, round, index, my_ID) reduction(+:error) { int my_starts; my_ID = omp_get_thread_num(); #pragma omp master { nthread = omp_get_num_threads(); if (nthread != nthread_input) { num_error = 1; printf("ERROR: number of requested threads %d does not equal ", nthread_input); printf("number of spawned threads %d\n", nthread); } else { printf("Number of threads = "FSTR64U"\n", (u64Int) nthread_input); printf("Table size (shared) = "FSTR64U"\n", tablesize); printf("Update ratio = "FSTR64U"\n", (u64Int) update_ratio); printf("Number of updates = "FSTR64U"\n", nupdate); printf("Vector length = "FSTR64U"\n", (u64Int) nstarts); printf("Percent errors allowed = "FSTR64U"\n", (u64Int) ERRORPERCENT); #if RESTRICT_KEYWORD printf("No aliasing = on\n"); #else printf("No aliasing = off\n"); #endif #if defined(ATOMIC) && !defined(CHUNKED) printf("Shared table, atomic updates\n"); #elif defined(CHUNKED) printf("Shared, chunked table\n"); #else printf("Shared table, non-atomic updates\n"); #endif } } bail_out(num_error); #if CHUNKED / compute upper and lower table bounds for this thread / u64Int low = my_ID (tablesize/nthread); u64Int up = (my_ID+1)(tablesize/nthread); my_starts = nstarts; #else my_starts = nstarts/nthread; #endif ran = (u64Int ) prk_malloc(my_startssizeof(u64Int)); if (!ran) { printf("ERROR: Thread %d Could not allocate %d bytes for random numbers\n", my_ID, my_starts(int)sizeof(u64Int)); num_error = 1; } bail_out(num_error); /* initialize the table / #pragma omp for for(i=0;i<tablesize;i++) Table[i] = (u64Int) i; #pragma omp barrier #pragma omp master { random_time = wtime(); } / ran is privatized. Must make sure for non-chunked version that we pick the right section of the originally shared ran array / #if CHUNKED int offset = 0; #else int offset = my_IDmy_starts; #endif /* do two identical rounds of Random Access to make sure we recover the initial condition / for (round=0; round <2; round++) { for (j=0; j<my_starts; j++) { ran[j] = PRK_starts(SEQSEED+(nupdate/nstarts)(j+offset)); } for (j=0; j<my_starts; j++) { /* because we do two rounds, we divide nupdates in two / for (i=0; i<nupdate/(nstarts2); i++) { ran[j] = (ran[j] << 1) ^ ((s64Int)ran[j] < 0? POLY: 0); index = ran[j] & (tablesize-1); #if defined(ATOMIC) #pragma omp atomic #elif defined(CHUNKED) if (index >= low && index < up) { #endif Table[index] ^= ran[j]; #if VERBOSE #pragma omp atomic Hist[index] += 1; #endif #if CHUNKED } #endif } } } #pragma omp master { random_time = wtime() - random_time; } } /* end of OpenMP parallel region / / verification test / for(i=0;i<tablesize;i++) { if(Table[i] != (u64Int) i) { #if VERBOSE printf("Error Table["FSTR64U"]="FSTR64U"\n",i,Table[i]); #endif error++; } } if ((error && (ERRORPERCENT==0)) \|\| ((double)error/(double)tablesize > ((double) ERRORPERCENT)0.01)) { printf("ERROR: number of incorrect table elements = "FSTR64U"\n", error); exit(EXIT_FAILURE); } else { printf("Solution validates, number of errors: %ld\n",(long) error); printf("Rate (GUPs/s): %lf, time (s) = %lf\n", 1.e-9nupdate/random_time,random_time); } #if VERBOSE for(i=0;i<tablesize;i++) HistHist[Hist[i]]+=1; for(i=0;i<=tablesize;i++) if (HistHist[i] != 0) printf("HistHist[%4.1d]=%9.1d\n",(int)i,HistHist[i]); #endif exit(EXIT_SUCCESS); } / Utility routine to start random number generator at nth step / u64Int PRK_starts(s64Int n) { int i, j; u64Int m2[64]; u64Int temp, ran; while (n < 0) n += PERIOD; while (n > PERIOD) n -= PERIOD; if (n == 0) return 0x1; temp = 0x1; for (i=0; i<64; i++) { m2[i] = temp; temp = (temp << 1) ^ ((s64Int) temp < 0 ? POLY : 0); temp = (temp << 1) ^ ((s64Int) temp < 0 ? POLY : 0); } for (i=62; i>=0; i--) if ((n >> i) & 1) break; ran = 0x2; while (i > 0) { temp = 0; for (j=0; j<64; j++) if ((unsigned int)((ran >> j) & 1)) temp ^= m2[j]; ran = temp; i -= 1; if ((n >> i) & 1) ran = (ran << 1) ^ ((s64Int) ran < 0 ? POLY : 0); } return ran; } #if UNUSED / utility routine that tests whether an integer is a power of two */ int poweroftwo(int n) { int log2n = 0; while ((1<<log2n)<n) log2n++; if (1<<log2n != n) return (-1); else return (log2n); } #endif
NETLMv2_fmt_plug.c	/* * NETLMv2_fmt.c -- LMv2 Challenge/Response * * Written by JoMo-Kun <jmk at foofus.net> in 2008 * and placed in the public domain. * * Performance fixes, OMP and utf-8 support by magnum 2010-2011 * * This algorithm is designed for performing brute-force cracking of the LMv2 * challenge/response sets exchanged during network-based authentication * attempts [1]. The captured challenge/response set from these attempts * should be stored using the following format: * * USERNAME::DOMAIN:SERVER CHALLENGE:LMv2 RESPONSE:CLIENT CHALLENGE * * For example: * Administrator::WORKGROUP:1122334455667788:6759A5A7EFB25452911DE7DE8296A0D8:F503236B200A5B3A * * It should be noted that a LMv2 authentication response is not same as a LM * password hash, which can be extracted using tools such as FgDump [2]. In * fact, a NTLM hash and not a LM hash is used within the LMv2 algorithm. LMv2 * challenge/response authentication typically takes place when the GPO * "Network Security: LAN Manager authentication level" is configured to a setting * that enforces the use of NTLMv2, such as "Send NTLMv2 response only\refuse * LM & NTLM." * * LMv2 responses can be gathered via normal network capture or via tools which * perform layer 2 attacks, such as Ettercap [3] and Cain [4]. The responses can * also be harvested using a modified Samba service [5] in conjunction with * some trickery to convince the user to connect to it. I leave what that * trickery may actually be as an exercise for the reader (HINT: Karma, NMB * broadcasts, IE, Outlook, social engineering, ...). * * [1] http://davenport.sourceforge.net/ntlm.html#theLmv2Response * [2] http://www.foofus.net/~fizzgig/fgdump/ * [3] http://ettercap.sourceforge.net/ * [4] http://www.oxid.it/cain.html * [5] http://www.foofus.net/jmk/smbchallenge.html * / #if FMT_EXTERNS_H extern struct fmt_main fmt_NETLMv2; #elif FMT_REGISTERS_H john_register_one(&fmt_NETLMv2); #else #include <string.h> #ifdef _OPENMP #include <omp.h> #endif #include "arch.h" #include "misc.h" #include "common.h" #include "formats.h" #include "options.h" #include "unicode.h" #include "stdint.h" #include "md5.h" #include "hmacmd5.h" #include "byteorder.h" #include "memdbg.h" #ifndef uchar #define uchar unsigned char #endif #define FORMAT_LABEL "netlmv2" #define FORMAT_NAME "LMv2 C/R" #define ALGORITHM_NAME "MD4 HMAC-MD5 32/" ARCH_BITS_STR #define BENCHMARK_COMMENT "" #define BENCHMARK_LENGTH 0 #define PLAINTEXT_LENGTH 125 / lmcons.h - PWLEN (256) ? 127 ? / #define USERNAME_LENGTH 60 / lmcons.h - UNLEN (256) / LM20_UNLEN (20) / #define DOMAIN_LENGTH 45 / lmcons.h - CNLEN / DNLEN / #define BINARY_SIZE 16 #define BINARY_ALIGN 4 #define CHALLENGE_LENGTH 32 #define SALT_SIZE 16 + 1 + 2 (USERNAME_LENGTH + DOMAIN_LENGTH) + 1 #define SALT_ALIGN 4 #define CIPHERTEXT_LENGTH 32 #define TOTAL_LENGTH 12 + USERNAME_LENGTH + DOMAIN_LENGTH + CHALLENGE_LENGTH + CIPHERTEXT_LENGTH // these may be altered in init() if running OMP #define MIN_KEYS_PER_CRYPT 1 #define MAX_KEYS_PER_CRYPT 1 #ifndef OMP_SCALE #define OMP_SCALE 1536 #endif static struct fmt_tests tests[] = { {"", "1337adminPASS", {"FOODOM\\Administrator", "", "", "1122334455667788", "6F64C5C1E35F68DD80388C0F00F34406", "F0F3FF27037AA69F"} }, {"$NETLMv2$ADMINISTRATORFOODOM$1122334455667788$6F64C5C1E35F68DD80388C0F00F34406$F0F3FF27037AA69F", "1337adminPASS"}, {"$NETLMv2$USER1$1122334455667788$B1D163EA5881504F3963DC50FCDC26C1$EB4D9E8138149E20", "foobar"}, // repeat in exactly the same format that is used in john.pot (lower case hex) {"$NETLMv2$USER1$1122334455667788$b1d163ea5881504f3963dc50fcdc26c1$eb4d9e8138149e20", "foobar"}, {"$NETLMv2$ATEST$1122334455667788$83B59F1536D3321DBF1FAEC14ADB1675$A1E7281FE8C10E53", "SomeFancyP4$$w0rdHere"}, {"", "1337adminPASS", {"administrator", "", "FOODOM", "1122334455667788", "6F64C5C1E35F68DD80388C0F00F34406", "F0F3FF27037AA69F"} }, {"", "foobar", {"user1", "", "", "1122334455667788", "B1D163EA5881504F3963DC50FCDC26C1", "EB4D9E8138149E20"} }, {"", "SomeFancyP4$$w0rdHere", {"aTest", "", "", "1122334455667788", "83B59F1536D3321DBF1FAEC14ADB1675", "A1E7281FE8C10E53"} }, {NULL} }; static uchar (saved_plain)[PLAINTEXT_LENGTH + 1]; static int (saved_len); static uchar (output)[BINARY_SIZE]; static HMACMD5Context (saved_ctx); static int keys_prepared; static unsigned char challenge; static void init(struct fmt_main self) { #ifdef _OPENMP int omp_t = omp_get_max_threads(); self->params.min_keys_per_crypt = omp_t; omp_t = OMP_SCALE; self->params.max_keys_per_crypt = omp_t; #endif saved_plain = mem_calloc(self->params.max_keys_per_crypt, sizeof(saved_plain)); saved_len = mem_calloc(self->params.max_keys_per_crypt, sizeof(saved_len)); output = mem_calloc(self->params.max_keys_per_crypt, sizeof(output)); saved_ctx = mem_calloc(self->params.max_keys_per_crypt, sizeof(saved_ctx)); } static void done(void) { MEM_FREE(saved_ctx); MEM_FREE(output); MEM_FREE(saved_len); MEM_FREE(saved_plain); } static int valid(char ciphertext, struct fmt_main self) { char pos, pos2; if (ciphertext == NULL) return 0; else if (strncmp(ciphertext, "$NETLMv2$", 9)!=0) return 0; pos = &ciphertext[9]; / Validate Username and Domain Length / for (pos2 = pos; pos2 != '$'; pos2++) if ((unsigned char)pos2 < 0x20) return 0; if ( !(pos2 && (pos2 - pos <= USERNAME_LENGTH + DOMAIN_LENGTH)) ) return 0; /* Validate Server Challenge Length / pos2++; pos = pos2; for (; pos2 != '$'; pos2++) if (atoi16[ARCH_INDEX(pos2)] == 0x7F) return 0; if ( !(pos2 && (pos2 - pos == CHALLENGE_LENGTH / 2)) ) return 0; /* Validate LMv2 Response Length / pos2++; pos = pos2; for (; pos2 != '$'; pos2++) if (atoi16[ARCH_INDEX(pos2)] == 0x7F) return 0; if ( !(pos2 && (pos2 - pos == CIPHERTEXT_LENGTH)) ) return 0; /* Validate Client Challenge Length / pos2++; pos = pos2; for (; atoi16[ARCH_INDEX(pos2)] != 0x7F; pos2++); if (pos2 - pos != CHALLENGE_LENGTH / 2) return 0; if (pos2[0] != '\0') return 0; return 1; } static char prepare(char split_fields[10], struct fmt_main self) { char srv_challenge = split_fields[3]; char nethashv2 = split_fields[4]; char cli_challenge = split_fields[5]; char login = split_fields[0]; char uid = split_fields[2]; char identity = NULL, tmp; if (!strncmp(split_fields[1], "$NETLMv2$", 9)) return split_fields[1]; if (!split_fields[0]\|\|!split_fields[2]\|\|!split_fields[3]\|\|!split_fields[4]\|\|!split_fields[5]) return split_fields[1]; /* DOMAIN\USER: -or- USER::DOMAIN: / if ((tmp = strstr(login, "\\")) != NULL) { identity = (char ) mem_alloc(strlen(login)2 + 1); strcpy(identity, tmp + 1); / Upper-Case Username - Not Domain / enc_strupper(identity); strncat(identity, login, tmp - login); } else { identity = (char ) mem_alloc(strlen(login)2 + strlen(uid) + 1); strcpy(identity, login); enc_strupper(identity); strcat(identity, uid); } tmp = (char ) mem_alloc(9 + strlen(identity) + 1 + strlen(srv_challenge) + 1 + strlen(nethashv2) + 1 + strlen(cli_challenge) + 1); sprintf(tmp, "$NETLMv2$%s$%s$%s$%s", identity, srv_challenge, nethashv2, cli_challenge); MEM_FREE(identity); if (valid(tmp, self)) { char cp = str_alloc_copy(tmp); MEM_FREE(tmp); return cp; } MEM_FREE(tmp); return split_fields[1]; } static char split(char ciphertext, int index, struct fmt_main self) { static char out[TOTAL_LENGTH + 1]; char pos = NULL; int identity_length = 0; / Calculate identity length / for (pos = ciphertext + 9; pos != '$'; pos++); identity_length = pos - (ciphertext + 9); memset(out, 0, TOTAL_LENGTH + 1); memcpy(out, ciphertext, strlen(ciphertext)); strlwr(&out[10 + identity_length]); /* Exclude: $NETLMv2$USERDOMAIN$ / return out; } static void get_binary(char ciphertext) { static uchar binary; char pos = NULL; int i, identity_length; if (!binary) binary = mem_alloc_tiny(BINARY_SIZE, MEM_ALIGN_WORD); for (pos = ciphertext + 9; pos != '$'; pos++); identity_length = pos - (ciphertext + 9); ciphertext += 9 + identity_length + 1 + CHALLENGE_LENGTH / 2 + 1; for (i=0; i<BINARY_SIZE; i++) { binary[i] = (atoi16[ARCH_INDEX(ciphertext[i2])])<<4; binary[i] \|= (atoi16[ARCH_INDEX(ciphertext[i2+1])]); } return binary; } /* Calculate the LMv2 response for the given challenge, using the specified authentication identity (username and domain), password and client nonce. / static int crypt_all(int pcount, struct db_salt salt) { const int count = pcount; int i = 0; #ifdef _OPENMP #pragma omp parallel for for(i = 0; i < count; i++) #endif { unsigned char ntlm_v2_hash[16]; HMACMD5Context ctx; // can't be moved above the OMP pragma if (!keys_prepared) { int len; unsigned char ntlm[16]; /* Generate 16-byte NTLM hash / len = E_md4hash(saved_plain[i], saved_len[i], ntlm); // We do key setup of the next HMAC_MD5 here (once per salt) hmac_md5_init_K16(ntlm, &saved_ctx[i]); if (len <= 0) saved_plain[i][-len] = 0; // match truncation } / HMAC-MD5(Username + Domain, NTLM Hash) / memcpy(&ctx, &saved_ctx[i], sizeof(ctx)); hmac_md5_update(&challenge[17], (int)challenge[16], &ctx); hmac_md5_final(ntlm_v2_hash, &ctx); / Generate 16-byte non-client nonce portion of LMv2 Response / / HMAC-MD5(Challenge + Nonce, NTLMv2 Hash) + Nonce / hmac_md5(ntlm_v2_hash, challenge, 16, (unsigned char)output[i]); } keys_prepared = 1; return count; } static int cmp_all(void binary, int count) { int index; for(index=0; index<count; index++) if (!memcmp(output[index], binary, BINARY_SIZE)) return 1; return 0; } static int cmp_one(void binary, int index) { return !memcmp(output[index], binary, BINARY_SIZE); } static int cmp_exact(char source, int index) { return !memcmp(output[index], get_binary(source), BINARY_SIZE); } / We're essentially using three salts, but we're going to pack it into a single blob for now. \|Client Challenge (8 Bytes)\|Server Challenge (8 Bytes)\|Unicode(Username (<=20).Domain (<=15)) / static void get_salt(char ciphertext) { static unsigned char binary_salt; unsigned char identity[USERNAME_LENGTH + DOMAIN_LENGTH + 1]; UTF16 identity_ucs2[USERNAME_LENGTH + DOMAIN_LENGTH + 1]; int i, identity_length; int identity_ucs2_length; char pos = NULL; if (!binary_salt) binary_salt = mem_alloc_tiny(SALT_SIZE, MEM_ALIGN_WORD); memset(binary_salt, 0, SALT_SIZE); / Calculate identity length / for (pos = ciphertext + 9; pos != '$'; pos++); identity_length = pos - (ciphertext + 9); /* Convert identity (username + domain) string to NT unicode / strnzcpy((char )identity, ciphertext + 9, sizeof(identity)); identity_ucs2_length = enc_to_utf16((UTF16 )identity_ucs2, USERNAME_LENGTH + DOMAIN_LENGTH, (UTF8 )identity, identity_length) * sizeof(int16_t); if (identity_ucs2_length < 0) // Truncated at Unicode conversion. identity_ucs2_length = strlen16((UTF16 )identity_ucs2) sizeof(int16_t); binary_salt[16] = (unsigned char)identity_ucs2_length; memcpy(&binary_salt[17], (char )identity_ucs2, identity_ucs2_length); / Set server challenge / ciphertext += 10 + identity_length; for (i = 0; i < 8; i++) binary_salt[i] = (atoi16[ARCH_INDEX(ciphertext[i2])] << 4) + atoi16[ARCH_INDEX(ciphertext[i2+1])]; / Set client challenge / ciphertext += 2 + CHALLENGE_LENGTH / 2 + CIPHERTEXT_LENGTH; for (i = 0; i < 8; ++i) binary_salt[i + 8] = (atoi16[ARCH_INDEX(ciphertext[i2])] << 4) + atoi16[ARCH_INDEX(ciphertext[i2+1])]; / Return a concatenation of the server and client challenges and the identity value / return (void)binary_salt; } static void set_salt(void salt) { challenge = salt; } static void set_key(char key, int index) { saved_len[index] = strlen(key); memcpy((char )saved_plain[index], key, saved_len[index] + 1); keys_prepared = 0; } static char get_key(int index) { return (char )saved_plain[index]; } static int salt_hash(void salt) { // Hash the client challenge (in case server salt was spoofed) return ((ARCH_WORD_32 )salt+8) & (SALT_HASH_SIZE - 1); } static int get_hash_0(int index) { return (ARCH_WORD_32 )output[index] & PH_MASK_0; } static int get_hash_1(int index) { return (ARCH_WORD_32 )output[index] & PH_MASK_1; } static int get_hash_2(int index) { return (ARCH_WORD_32 )output[index] & PH_MASK_2; } static int get_hash_3(int index) { return (ARCH_WORD_32 )output[index] & PH_MASK_3; } static int get_hash_4(int index) { return (ARCH_WORD_32 )output[index] & PH_MASK_4; } static int get_hash_5(int index) { return (ARCH_WORD_32 )output[index] & PH_MASK_5; } static int get_hash_6(int index) { return (ARCH_WORD_32 )output[index] & PH_MASK_6; } struct fmt_main fmt_NETLMv2 = { { FORMAT_LABEL, FORMAT_NAME, ALGORITHM_NAME, BENCHMARK_COMMENT, BENCHMARK_LENGTH, 0, PLAINTEXT_LENGTH, BINARY_SIZE, BINARY_ALIGN, SALT_SIZE, SALT_ALIGN, MIN_KEYS_PER_CRYPT, MAX_KEYS_PER_CRYPT, FMT_CASE \| FMT_8_BIT \| FMT_SPLIT_UNIFIES_CASE \| FMT_OMP \| FMT_UNICODE \| FMT_UTF8, { NULL }, tests }, { init, done, fmt_default_reset, prepare, valid, split, get_binary, get_salt, { NULL }, fmt_default_source, { fmt_default_binary_hash_0, fmt_default_binary_hash_1, fmt_default_binary_hash_2, fmt_default_binary_hash_3, fmt_default_binary_hash_4, fmt_default_binary_hash_5, fmt_default_binary_hash_6 }, salt_hash, NULL, set_salt, set_key, get_key, fmt_default_clear_keys, crypt_all, { get_hash_0, get_hash_1, get_hash_2, get_hash_3, get_hash_4, get_hash_5, get_hash_6 }, cmp_all, cmp_one, cmp_exact } }; #endif /* plugin stanza */
rawMD5flat_fmt_plug.c	/* * Raw-MD5 "flat intrinsics" experimental format * * This software is Copyright (c) 2011-2015 magnum, * and it is hereby released to the general public under the following terms: * Redistribution and use in source and binary forms, with or without * modification, are permitted. * / #include "arch.h" #if USE_EXPERIMENTAL #if FMT_EXTERNS_H extern struct fmt_main fmt_rawMD5f; #elif FMT_REGISTERS_H john_register_one(&fmt_rawMD5f); #else #include <string.h> #include "md5.h" #include "common.h" #include "formats.h" #if !FAST_FORMATS_OMP #undef _OPENMP #endif #ifdef _OPENMP #ifdef SIMD_COEF_32 #ifndef OMP_SCALE #define OMP_SCALE 1024 #endif #else #ifndef OMP_SCALE #define OMP_SCALE 2048 #endif #endif #include <omp.h> #endif #include "simd-intrinsics.h" #include "memdbg.h" #ifdef SIMD_COEF_32 #define NBKEYS (SIMD_COEF_32 SIMD_PARA_MD5) #define PLAINTEXT_LENGTH 55 #define MIN_KEYS_PER_CRYPT NBKEYS #define MAX_KEYS_PER_CRYPT NBKEYS #else #define PLAINTEXT_LENGTH 125 #define MIN_KEYS_PER_CRYPT 1 #define MAX_KEYS_PER_CRYPT 1 #endif #define FORMAT_LABEL "Raw-MD5-flat" #define FORMAT_NAME "" #define ALGORITHM_NAME "MD5 " MD5_ALGORITHM_NAME " (experimental)" #define BENCHMARK_COMMENT "" #define BENCHMARK_LENGTH -1 #define CIPHERTEXT_LENGTH 32 #define DIGEST_SIZE 16 #define BINARY_SIZE 16 // source() #define BINARY_ALIGN 4 #define SALT_SIZE 0 #define SALT_ALIGN 1 #define FORMAT_TAG "$dynamic_0$" #define TAG_LENGTH (sizeof(FORMAT_TAG) - 1) static struct fmt_tests tests[] = { {"5a105e8b9d40e1329780d62ea2265d8a", "test1"}, {FORMAT_TAG "5a105e8b9d40e1329780d62ea2265d8a", "test1"}, {"098f6bcd4621d373cade4e832627b4f6", "test"}, {FORMAT_TAG "378e2c4a07968da2eca692320136433d", "thatsworking"}, {FORMAT_TAG "8ad8757baa8564dc136c1e07507f4a98", "test3"}, {"d41d8cd98f00b204e9800998ecf8427e", ""}, #ifdef DEBUG #if PLAINTEXT_LENGTH >= 55 {FORMAT_TAG "c9ccf168914a1bcfc3229f1948e67da0","1234567890123456789012345678901234567890123456789012345"}, #if PLAINTEXT_LENGTH >= 80 {FORMAT_TAG "57edf4a22be3c955ac49da2e2107b67a","12345678901234567890123456789012345678901234567890123456789012345678901234567890"}, #endif // 80 #endif // 55 #endif // DEBUG {NULL} }; #ifdef SIMD_COEF_32 static ARCH_WORD_32 (crypt_key)[DIGEST_SIZE/4NBKEYS]; static ARCH_WORD_32 (saved_key)[64/4]; static int sz; #else static char (saved_key)[PLAINTEXT_LENGTH + 1]; static ARCH_WORD_32 (crypt_key)[DIGEST_SIZE/4]; #endif static void init(struct fmt_main self) { #ifdef _OPENMP int omp_t = omp_get_max_threads(); self->params.min_keys_per_crypt = omp_t; omp_t = OMP_SCALE; self->params.max_keys_per_crypt = omp_t; #endif sz = self->params.max_keys_per_crypt 64; #ifndef SIMD_COEF_32 saved_key = mem_calloc(self->params.max_keys_per_crypt, sizeof(saved_key)); crypt_key = mem_calloc(self->params.max_keys_per_crypt, sizeof(crypt_key)); #else saved_key = mem_calloc_align(self->params.max_keys_per_crypt, sizeof(saved_key), MEM_ALIGN_SIMD); crypt_key = mem_calloc_align(self->params.max_keys_per_crypt/NBKEYS, sizeof(crypt_key), MEM_ALIGN_SIMD); #endif } static void done(void) { MEM_FREE(crypt_key); MEM_FREE(saved_key); } static int valid(char ciphertext, struct fmt_main self) { char p, q; p = ciphertext; if (!strncmp(p, FORMAT_TAG, TAG_LENGTH)) p += TAG_LENGTH; q = p; while (atoi16[ARCH_INDEX(q)] != 0x7F) { if (q >= 'A' && q <= 'F') / support lowercase only / return 0; q++; } return !q && q - p == CIPHERTEXT_LENGTH; } static char split(char ciphertext, int index, struct fmt_main self) { static char out[TAG_LENGTH + CIPHERTEXT_LENGTH + 1]; if (!strncmp(ciphertext, FORMAT_TAG, TAG_LENGTH)) return ciphertext; memcpy(out, FORMAT_TAG, TAG_LENGTH); memcpy(out + TAG_LENGTH, ciphertext, CIPHERTEXT_LENGTH + 1); return out; } static void get_binary(char ciphertext) { static unsigned char out; char p; int i; if (!out) out = mem_alloc_tiny(DIGEST_SIZE, MEM_ALIGN_WORD); p = ciphertext + TAG_LENGTH; for (i = 0; i < DIGEST_SIZE; i++) { out[i] = (atoi16[ARCH_INDEX(p)] << 4) \| atoi16[ARCH_INDEX(p[1])]; p += 2; } return out; } #ifdef SIMD_COEF_32 #define HASH_OFFSET (index&(SIMD_COEF_32-1))+(((unsigned int)index%NBKEYS)/SIMD_COEF_32)SIMD_COEF_324 static int get_hash_0(int index) { return crypt_key[index/NBKEYS][HASH_OFFSET] & PH_MASK_0; } static int get_hash_1(int index) { return crypt_key[index/NBKEYS][HASH_OFFSET] & PH_MASK_1; } static int get_hash_2(int index) { return crypt_key[index/NBKEYS][HASH_OFFSET] & PH_MASK_2; } static int get_hash_3(int index) { return crypt_key[index/NBKEYS][HASH_OFFSET] & PH_MASK_3; } static int get_hash_4(int index) { return crypt_key[index/NBKEYS][HASH_OFFSET] & PH_MASK_4; } static int get_hash_5(int index) { return crypt_key[index/NBKEYS][HASH_OFFSET] & PH_MASK_5; } static int get_hash_6(int index) { return crypt_key[index/NBKEYS][HASH_OFFSET] & PH_MASK_6; } #else static int get_hash_0(int index) { return crypt_key[index][0] & PH_MASK_0; } static int get_hash_1(int index) { return crypt_key[index][0] & PH_MASK_1; } static int get_hash_2(int index) { return crypt_key[index][0] & PH_MASK_2; } static int get_hash_3(int index) { return crypt_key[index][0] & PH_MASK_3; } static int get_hash_4(int index) { return crypt_key[index][0] & PH_MASK_4; } static int get_hash_5(int index) { return crypt_key[index][0] & PH_MASK_5; } static int get_hash_6(int index) { return crypt_key[index][0] & PH_MASK_6; } #endif static void set_key(char key, int index) { #ifdef SIMD_COEF_32 int len = strlen(key); strncpy((char)saved_key[index], key, sizeof(saved_key[0])); ((unsigned char)saved_key[index])[len] = 0x80; saved_key[index][14] = len << 3; #else strcpy(saved_key[index], key); #endif } static char get_key(int index) { #ifdef SIMD_COEF_32 int len = saved_key[index][14] >> 3; ((char)saved_key[index])[len] = 0; #endif return (char)saved_key[index]; } static int crypt_all(int pcount, struct db_salt salt) { const int count = pcount; int index = 0; #ifdef _OPENMP #ifdef SIMD_COEF_32 const int inc = SIMD_COEF_32; #else const int inc = 1; #endif const int loops = (count + MAX_KEYS_PER_CRYPT - 1) / MAX_KEYS_PER_CRYPT; #pragma omp parallel for for (index = 0; index < loops; index += inc) #endif { #if SIMD_COEF_32 SIMDmd5body(saved_key[index], crypt_key[index/NBKEYS], NULL, SSEi_FLAT_IN); #else MD5_CTX ctx; MD5_Init(&ctx); MD5_Update(&ctx, saved_key[index], strlen(saved_key[index])); MD5_Final((unsigned char )crypt_key[index], &ctx); #endif } return count; } static int cmp_all(void binary, int count) { int index; for (index = 0; index < count; index++) #ifdef SIMD_COEF_32 if (((ARCH_WORD_32 ) binary)[0] == ((ARCH_WORD_32)crypt_key)[(index&(SIMD_COEF_32-1)) + (unsigned int)index/SIMD_COEF_324SIMD_COEF_32]) #else if ( ((ARCH_WORD_32)binary)[0] == crypt_key[index][0] ) #endif return 1; return 0; } static int cmp_one(void binary, int index) { #ifdef SIMD_COEF_32 int i; for (i = 0; i < BINARY_SIZE/sizeof(ARCH_WORD_32); i++) if (((ARCH_WORD_32 ) binary)[i] != ((ARCH_WORD_32)crypt_key)[(index&(SIMD_COEF_32-1)) + (unsigned int)index/SIMD_COEF_324SIMD_COEF_32+iSIMD_COEF_32]) return 0; return 1; #else return !memcmp(binary, crypt_key[index], BINARY_SIZE); #endif } static int cmp_exact(char source, int index) { return 1; } static char source(char source, void binary) { static char Buf[CIPHERTEXT_LENGTH + TAG_LENGTH + 1]; unsigned char cpi; char cpo; int i; strcpy(Buf, FORMAT_TAG); cpo = &Buf[TAG_LENGTH]; cpi = (unsigned char)(binary); for (i = 0; i < BINARY_SIZE; ++i) { cpo++ = itoa16[(cpi)>>4]; cpo++ = itoa16[cpi&0xF]; ++cpi; } cpo = 0; return Buf; } struct fmt_main fmt_rawMD5f = { { FORMAT_LABEL, FORMAT_NAME, ALGORITHM_NAME, BENCHMARK_COMMENT, BENCHMARK_LENGTH, 0, PLAINTEXT_LENGTH, BINARY_SIZE, BINARY_ALIGN, SALT_SIZE, SALT_ALIGN, MIN_KEYS_PER_CRYPT, MAX_KEYS_PER_CRYPT, #ifdef _OPENMP FMT_OMP \| FMT_OMP_BAD \| #endif FMT_CASE \| FMT_8_BIT, { NULL }, tests }, { init, done, fmt_default_reset, fmt_default_prepare, valid, split, get_binary, fmt_default_salt, { NULL }, source, { fmt_default_binary_hash_0, fmt_default_binary_hash_1, fmt_default_binary_hash_2, fmt_default_binary_hash_3, fmt_default_binary_hash_4, fmt_default_binary_hash_5, fmt_default_binary_hash_6 }, fmt_default_salt_hash, NULL, fmt_default_set_salt, set_key, get_key, fmt_default_clear_keys, crypt_all, { get_hash_0, get_hash_1, get_hash_2, get_hash_3, get_hash_4, get_hash_5, get_hash_6 }, cmp_all, cmp_one, cmp_exact } }; #endif /* plugin stanza / #endif / USE_EXPERIMENTAL */
mero-ummap-bandwidth-mpi.c	//mpicc ioc-ummap-bandwidth-mpi.c -I$HOME/test-rdma/usr2/include -lioc-client -lummap-io -L$HOME/test-rdma/usr2/lib -Wl,-rpath,$HOME/test-rdma/usr2/lib -o ioc-ummap-bandwidth-mpi #include <stdlib.h> #include <stdio.h> #include <string.h> #include <stdbool.h> #include <ioc-client.h> #include <time.h> #include <mpi.h> #include <ummap/ummap.h> #include <omp.h> const size_t total_size = 1UL1024UL1024UL1024UL; const size_t ref_repeat = 10; static inline double timespec_diff(struct timespec a, struct timespec b) { struct timespec result; result.tv_sec = a->tv_sec - b->tv_sec; result.tv_nsec = a->tv_nsec - b->tv_nsec; if (result.tv_nsec < 0) { --result.tv_sec; result.tv_nsec += 1000000000L; } return (double)result.tv_sec + (double)result.tv_nsec / (double)1e9; } void make_ummap_read(ioc_client_t client, char * buffer0, size_t size, size_t seg_size, size_t repeat) { //get MPI rank int rank; MPI_Comm_rank(MPI_COMM_WORLD, &rank); size_t threads = omp_get_max_threads(); //calc base size_t base = rank * size; //ummap //ummap_driver_t * driver = ummap_driver_create_ioc(client, 10, 20, rank == 0); ummap_driver_t * driver = ummap_driver_create_uri("clovis://10:20"); ummap_policy_t * policy = ummap_policy_create_fifo(2 * threads * seg_size, true); int flags = 0; if (seg_size <= 131072) flags \|= UMMAP_THREAD_UNSAFE; char * buffer = ummap(NULL, size, seg_size, base, PROT_READ\|PROT_WRITE, flags, driver, policy, NULL); //access size_t r; size_t offset; size_t sum = 0; for (r = 0 ; r < repeat ; r++) { #pragma omp parallel for for (offset = 0 ; offset < size ; offset +=seg_size) sum+=buffer[offset]; } //unmap umunmap(buffer, false); } void make_ummap_write(ioc_client_t * client, char * buffer0, size_t size, size_t seg_size, size_t repeat) { //get MPI rank int rank; MPI_Comm_rank(MPI_COMM_WORLD, &rank); size_t threads = omp_get_max_threads(); //calc base size_t base = rank * size; //ummap //ummap_driver_t * driver = ummap_driver_create_ioc(client, 10, 20, rank == 0); ummap_driver_t * driver = ummap_driver_create_uri("clovis://10:20"); ummap_policy_t * policy = ummap_policy_create_fifo(2 * threads * seg_size, true); int flags = 0; if (seg_size <= 131072) flags \|= UMMAP_THREAD_UNSAFE; char * buffer = ummap(NULL, size, seg_size, base, PROT_READ\|PROT_WRITE, UMMAP_NO_FIRST_READ\|flags, driver, policy, NULL); //access size_t r; size_t offset; for (r = 0 ; r < repeat ; r++) { ummap_skip_first_read(buffer); #pragma omp parallel for for (offset = 0 ; offset < size ; offset += seg_size) buffer[offset]++; } //unmap umunmap(buffer, false); } void make_write(ioc_client_t * client, char * buffer, size_t size, size_t seg_size, size_t repeat) { //get MPI rank int rank; MPI_Comm_rank(MPI_COMM_WORLD, &rank); //do size_t r; size_t offset; size_t base = rank * size; for (r = 0 ; r < repeat ; r++) for (offset = 0 ; offset < size ; offset += seg_size) ioc_client_obj_write(client, 10, 20, buffer, seg_size, base + offset); } void make_read(ioc_client_t * client, char * buffer, size_t size, size_t seg_size, size_t repeat) { //get MPI rank int rank; MPI_Comm_rank(MPI_COMM_WORLD, &rank); //do size_t r; size_t offset; size_t base = rank * size; for (r = 0 ; r < repeat ; r++) for (offset = 0 ; offset < size ; offset += seg_size) ioc_client_obj_read(client, 10, 20, buffer, seg_size, base + offset); } double calc_bandwidth(ioc_client_t * client, char * buffer, size_t size, size_t seg_size, size_t repeat, void(op)(ioc_client_t client, char * buffer, size_t size, size_t seg_size, size_t repeat)) { //wait all MPI_Barrier(MPI_COMM_WORLD); //start struct timespec start, stop; clock_gettime(CLOCK_MONOTONIC, &start); //call to all op(client, buffer, size, seg_size, repeat); //wait all MPI_Barrier(MPI_COMM_WORLD); //stop clock_gettime(CLOCK_MONOTONIC, &stop); //compute time double t = timespec_diff(&stop, &start); //calc bandwidth double bw = (double)repeat * (double)total_size / 1024.0 / 1024.0 / 1024.0 / t; //ok return return bw; } int main(int argc, char ** argv) { //check args if (argc < 2) { fprintf(stderr, "%s {ioc_server_ip}\n", argv[0]); return EXIT_FAILURE; } //init MPI MPI_Init(&argc, &argv); //init ummapio ummap_init(); //get MPI infos int rank; int world; MPI_Comm_rank(MPI_COMM_WORLD, &rank); MPI_Comm_size(MPI_COMM_WORLD, &world); ummap_config_clovis_init_options("mero_ressource_file.rc", rank); //connect to server //ioc_client_t * client = ioc_client_init(argv[1], "8556"); ioc_client_t * client = NULL; //cal size size_t size = total_size / world; //allocate buffer char * buffer = malloc(size); memset(buffer, 0, size); //to ensure object is created, make a first round trip //calc_bandwidth(client, buffer, size, 810241024, ref_repeat, make_read); //calc_bandwidth(client, buffer, size, 810241024, ref_repeat, make_write); calc_bandwidth(client, buffer, size, 810241024, ref_repeat, make_ummap_read); calc_bandwidth(client, buffer, size, 810241024, ref_repeat, make_ummap_write); //header if (rank == 0) { printf("#total_size=%f GB\n", (double)total_size/1024.0/1024.0/1024.0); printf("#world_size=%d\n", world); printf("#seg_size (bytes) read (GB/s) twrite(GB/s)\n"); } //loop on all size size_t seg_size = 8 * 1024 * 1024; for ( ; seg_size >= 4096 ; seg_size /= 2) { //calc repeat size_t repeat = ref_repeat; //if (seg_size > 2561024) // repeat = 2; //measure read //double read_bw = calc_bandwidth(client, buffer, size, seg_size, repeat, make_read); //double write_bw = calc_bandwidth(client, buffer, size, seg_size, repeat, make_write); double read_bw = calc_bandwidth(client, buffer, size, seg_size, repeat, make_ummap_read); double write_bw = calc_bandwidth(client, buffer, size, seg_size, repeat, make_ummap_write); //print if (rank == 0) printf("%zu %f %f\n", seg_size, read_bw, write_bw); } //close connection //ioc_client_fini(client); //fini ummap ummap_finalize(); //fin i mpi MPI_Finalize(); //ok return EXIT_SUCCESS; }
ComputeNonbondedBase2.h	/ * Copyright (c) 1995, 1996, 1997, 1998, 1999, 2000 by * The Board of Trustees of the University of Illinois. * All rights reserved. */ EXCLUDED( FAST( foo bar ) ) EXCLUDED( MODIFIED( foo bar ) ) EXCLUDED( NORMAL( foo bar ) ) NORMAL( MODIFIED( foo bar ) ) ALCHPAIR( NOT_ALCHPAIR( foo bar ) ) ALCHPAIR( // get alchemical nonbonded scaling parameters (once per pairlist) myLambda = ALCH1(lambdaUp) ALCH2(lambdaDown) ALCH3(lambdaUp) ALCH4(lambdaDown); FEP(myLambda2 = ALCH1(lambda2Up) ALCH2(lambda2Down) ALCH3(lambda2Up) ALCH4(lambda2Down);) myElecLambda = ALCH1(elecLambdaUp) ALCH2(elecLambdaDown) ALCH3(elecLambdaUp) ALCH4(elecLambdaDown); FEP(myElecLambda2 = ALCH1(elecLambda2Up) ALCH2(elecLambda2Down) ALCH3(elecLambda2Up) ALCH4(elecLambda2Down);) myVdwLambda = ALCH1(vdwLambdaUp) ALCH2(vdwLambdaDown) ALCH3(vdwLambdaUp) ALCH4(vdwLambdaDown); FEP(myVdwLambda2 = ALCH1(vdwLambda2Up) ALCH2(vdwLambda2Down) ALCH3(vdwLambda2Up) ALCH4(vdwLambda2Down);) ALCH1(myRepLambda = repLambdaUp) ALCH2(myRepLambda = repLambdaDown); FEP(ALCH1(myRepLambda2 = repLambda2Up) ALCH2(myRepLambda2 = repLambda2Down);) ALCH1(myVdwShift = vdwShiftUp) ALCH2(myVdwShift = vdwShiftDown); FEP(ALCH1(myVdwShift2 = vdwShift2Up) ALCH2(myVdwShift2 = vdwShift2Down);) ) #ifdef A2_QPX #if ( SHORT(1+) 0 ) NORMAL(kq_iv = vec_splats(kq_i); ) MODIFIED(kq_iv = vec_splats((1.0-modf_mod) kq_i); ) #endif #if ( FULL( 1+ ) 0 ) EXCLUDED( SHORT( full_cnst = (vector4double)(6., 4., 2., 1.); ) NOSHORT( full_cnst = (vector4double)(1., 1., 1., 1.); ) ) MODIFIED( SHORT( full_cnst = (vector4double)(6., 4., 2., 1.); full_cnst = vec_mul (full_cnst, vec_splats(modf_mod)); ) NOSHORT( full_cnst = vec_splats(modf_mod); ) ) #endif #endif #ifdef ARCH_POWERPC __alignx(64, table_four); __alignx(32, p_1); #pragma unroll(1) #pragma ibm independent_loop #endif #ifndef ARCH_POWERPC #pragma ivdep #endif #if ( FULL( EXCLUDED( SHORT( 1+ ) ) ) 0 ) // avoid bug in Intel 15.0 compiler #pragma novector #else #ifdef PRAGMA_SIMD #ifndef TABENERGYFLAG #ifndef GOFORCES #pragma omp simd SHORT(FAST(reduction(+:f_i_x,f_i_y,f_i_z)) ENERGY(FAST(reduction(+:vdwEnergy) SHORT(reduction(+:electEnergy))))) \ FULL(reduction(+:fullf_i_x,fullf_i_y,fullf_i_z) ENERGY(reduction(+:fullElectEnergy))) #endif #endif #pragma loop_count avg=100 #else // PRAGMA_SIMD #pragma loop_count avg=4 #endif // PRAGMA_SIMD #endif for (k=0; k<npairi; ++k) { TABENERGY( const int numtypes = simParams->tableNumTypes; const float table_spacing = simParams->tableSpacing; const int npertype = (int) (namdnearbyint(simParams->tableMaxDist / simParams->tableSpacing) + 1); ) int table_i = (r2iilist[2k] >> 14) + r2_delta_expc; // table_i >= 0 const int j = pairlisti[k]; //register const CompAtom p_j = p_1 + j; #define p_j (p_1+j) #ifdef A2_QPX register double p_j_d = (double ) p_j; #endif // const CompAtomExt pExt_j = pExt_1 + j; BigReal diffa = r2list[k] - r2_table[table_i]; //const BigReal const table_four_i = table_four + 16table_i; #define table_four_i (table_four + 16table_i) #if ( FAST( 1 + ) TABENERGY( 1 + ) 0 ) // FAST or TABENERGY //const LJTable::TableEntry * lj_pars = // lj_row + 2 * p_j->vdwType MODIFIED(+ 1); const int lj_index = 2 * p_j->vdwType MODIFIED(+ 1); #define lj_pars (lj_row+lj_index) #ifdef A2_QPX double lj_pars_d = (double ) lj_pars; #endif #endif TABENERGY( register const int tabtype = -1 - ( lj_pars->A < 0 ? lj_pars->A : 0 ); ) #if ( SHORT( FAST( 1+ ) ) 0 ) //Force f_j = f_1 + j; #define f_j (f_1+j) #endif #if ( FULL( 1+ ) 0 ) //Force fullf_j = fullf_1 + j; #define fullf_j (fullf_1+j) #endif //Power PC aliasing and alignment constraints #ifdef ARCH_POWERPC #if ( FULL( 1+ ) 0 ) #pragma disjoint (table_four, fullf_1) #pragma disjoint (p_1, fullf_1) #ifdef A2_QPX #pragma disjoint (p_j_d, fullf_1) #endif #pragma disjoint (r2_table, fullf_1) #pragma disjoint (r2list, fullf_1) #if ( SHORT( FAST( 1+ ) ) 0 ) #pragma disjoint (f_1 , fullf_1) #pragma disjoint (fullf_1, f_1) #endif //Short + fast #endif //Full #if ( SHORT( FAST( 1+ ) ) 0 ) #pragma disjoint (table_four, f_1) #pragma disjoint (p_1, f_1) #pragma disjoint (r2_table, f_1) #pragma disjoint (r2list, f_1) #pragma disjoint (lj_row, f_1) #ifdef A2_QPX #pragma disjoint (p_j_d, f_1) #endif #endif //Short + Fast __alignx(64, table_four_i); FAST ( __alignx(32, lj_pars); ) __alignx(32, p_j); #endif //ARCH_POWERPC /* BigReal modf = 0.0; int atom2 = p_j->id; register char excl_flag = ( (atom2 >= excl_min && atom2 <= excl_max) ? excl_flags[atom2-excl_min] : 0 ); if ( excl_flag ) { ++exclChecksum; } SELF( if ( j < j_hgroup ) { excl_flag = EXCHCK_FULL; } ) if ( excl_flag ) { if ( excl_flag == EXCHCK_FULL ) { lj_pars = lj_null_pars; modf = 1.0; } else { ++lj_pars; modf = modf_mod; } } / BigReal kqq = kq_i p_j->charge; #ifdef A2_QPX float * cg = (float )&p_j->charge; #if ( FULL( 1+ ) 0 ) #pragma disjoint (cg, fullf_1) #endif //Full #if ( SHORT( FAST( 1+ ) ) 0 ) #pragma disjoint (cg, f_1) #endif //Short + fast #endif LES( BigReal lambda_pair = lambda_table_i[p_j->partition]; ) #ifndef A2_QPX register const BigReal p_ij_x = p_i_x - p_j->position.x; register const BigReal p_ij_y = p_i_y - p_j->position.y; register const BigReal p_ij_z = p_i_z - p_j->position.z; #else vector4double charge_v = vec_lds(0, cg); vector4double kqqv = vec_mul(kq_iv, charge_v ); vector4double p_ij_v = vec_sub(p_i_v, vec_ld (0, p_j_d)); #define p_ij_x vec_extract(p_i_v, 0) #define p_ij_y vec_extract(p_i_v, 1) #define p_ij_z vec_extract(p_i_v, 2) #endif #if ( FAST(1+) 0 ) const BigReal A = scaling lj_pars->A; const BigReal B = scaling * lj_pars->B; #ifndef A2_QPX BigReal vdw_d = A * table_four_i[0] - B * table_four_i[4]; BigReal vdw_c = A * table_four_i[1] - B * table_four_i[5]; BigReal vdw_b = A * table_four_i[2] - B * table_four_i[6]; BigReal vdw_a = A * table_four_i[3] - B * table_four_i[7]; #else const vector4double Av = vec_mul(scalingv, vec_lds(0, lj_pars_d)); const vector4double Bv = vec_mul(scalingv, vec_lds(8, lj_pars_d)); vector4double vdw_v = vec_msub( Av, vec_ld(0, (BigReal)table_four_i), vec_mul(Bv, vec_ld(4sizeof(BigReal), (BigReal)table_four_i)) ); #define vdw_d vec_extract(vdw_v, 0) #define vdw_c vec_extract(vdw_v, 1) #define vdw_b vec_extract(vdw_v, 2) #define vdw_a vec_extract(vdw_v, 3) #endif ALCHPAIR ( // Alchemical free energy calculation // Pairlist 1 and 2 are for softcore atoms, while 3 and 4 are single topology atoms. // Pairlists are separated so that lambda-coupled pairs are handled // independently from normal nonbonded (inside ALCHPAIR macro). // The separation-shifted van der Waals potential and a shifted // electrostatics potential for decoupling are calculated explicitly. // Would be faster with lookup tables but because only a small minority // of nonbonded pairs are lambda-coupled the impact is minimal. // Explicit calculation also makes things easier to modify. // These are now inline functions (in ComputeNonbondedFep.C) to // tidy the code const BigReal r2 = r2list[k] - r2_delta; // These are now inline functions (in ComputeNonbondedFep.C) to // tidy the code FEP( ALCH1 ( // Don't merge/recombine the ALCH 1, 2, 3 ,4. Their functions might be modified for future algorithm changes. fep_vdw_forceandenergies(A, B, r2, myVdwShift, myVdwShift2, switchdist2, cutoff2, switchfactor, vdwForceSwitching, myVdwLambda, myVdwLambda2, alchWCAOn, myRepLambda, myRepLambda2, &alch_vdw_energy, &alch_vdw_force, &alch_vdw_energy_2);) ALCH2 ( fep_vdw_forceandenergies(A, B, r2, myVdwShift, myVdwShift2, switchdist2, cutoff2, switchfactor, vdwForceSwitching, myVdwLambda, myVdwLambda2, alchWCAOn, myRepLambda, myRepLambda2, &alch_vdw_energy, &alch_vdw_force, &alch_vdw_energy_2);) ALCH3 ( // In single topology region ALCH3 & 4, all atoms are paired so softcore potential is unnecessary. ENERGY(alch_vdw_energy = -myVdwLambda (( ( diffa * vdw_d * (1/6.)+ vdw_c * (1/4.)) * diffa + vdw_b (1/2.)) diffa + vdw_a);) alch_vdw_energy_2 = -myVdwLambda2 * (( ( diffa * vdw_d * (1/6.)+ vdw_c * (1/4.)) * diffa + vdw_b (1/2.)) diffa + vdw_a); alch_vdw_force = myVdwLambda * ((diffa * vdw_d + vdw_c) * diffa + vdw_b);) ALCH4 ( ENERGY(alch_vdw_energy = -myVdwLambda * (( ( diffa * vdw_d * (1/6.)+ vdw_c * (1/4.)) * diffa + vdw_b (1/2.)) diffa + vdw_a);) alch_vdw_energy_2 = -myVdwLambda2 * (( ( diffa * vdw_d * (1/6.)+ vdw_c * (1/4.)) * diffa + vdw_b (1/2.)) diffa + vdw_a); alch_vdw_force = myVdwLambda * ((diffa * vdw_d + vdw_c) * diffa + vdw_b);) ) TI(ti_vdw_force_energy_dUdl(A, B, r2, myVdwShift, switchdist2, cutoff2, switchfactor, vdwForceSwitching, myVdwLambda, alchVdwShiftCoeff, alchWCAOn, myRepLambda, &alch_vdw_energy, &alch_vdw_force, &alch_vdw_dUdl);) ) //NOT_ALCHPAIR( //TABENERGY( #if (NOT_ALCHPAIR(1+) 0) #if (TABENERGY(1+) 0) if (tabtype >= 0) { register BigReal r1; r1 = sqrt(p_ij_xp_ij_x + p_ij_yp_ij_y + p_ij_zp_ij_z); //CkPrintf("%i %i %f %f %i\n", npertype, tabtype, r1, table_spacing, (int) (namdnearbyint(r1 / table_spacing))); register int eneraddress; eneraddress = 2 ((npertype * tabtype) + ((int) namdnearbyint(r1 / table_spacing))); //CkPrintf("Using distance bin %i for distance %f\n", eneraddress, r1); #ifndef A2_QPX vdw_d = 0.; vdw_c = 0.; vdw_b = table_ener[eneraddress + 1] / r1; vdw_a = (-1/2.) * diffa * vdw_b; #else vec_insert(0., vdw_v, 0); vec_insert(0., vdw_v, 1); vec_insert(table_ener[eneraddress + 1] / r1, vdw_v, 2); vec_insert((-1/2.) * diffa * vdw_b, vdw_v, 3); #endif ENERGY( register BigReal vdw_val = table_ener[eneraddress]; //CkPrintf("Found vdw energy of %f\n", vdw_val); vdwEnergy += LAM(lambda_pair ) vdw_val; FEP( vdwEnergy_s += d_lambda_pair vdw_val; ) ) } else { //) #endif ENERGY( register BigReal vdw_val = ( ( diffa * vdw_d * (1/6.)+ vdw_c * (1/4.)) * diffa + vdw_b (1/2.)) diffa + vdw_a; vdwEnergy -= LAM(lambda_pair ) vdw_val; FEP(vdwEnergy_s -= vdw_val;) ) //TABENERGY( } ) / endif (tabtype >= 0) / #if (TABENERGY (1+) 0) } #endif //) // NOT_ALCHPAIR #endif ALCHPAIR( ENERGY(vdwEnergy += alch_vdw_energy;) FEP(vdwEnergy_s += alch_vdw_energy_2;) TI(ALCH1(vdwEnergy_ti_1 += alch_vdw_dUdl;) ALCH2(vdwEnergy_ti_2 += alch_vdw_dUdl;)) ) // ALCHPAIR #endif // FAST #if ( FAST(1+) 0 ) INT( register BigReal vdw_dir; vdw_dir = ( diffa vdw_d + vdw_c ) * diffa + vdw_b; //BigReal force_r = LAM(lambda_pair ) vdw_dir; reduction[pairVDWForceIndex_X] += force_sign vdw_dir * p_ij_x; reduction[pairVDWForceIndex_Y] += force_sign * vdw_dir * p_ij_y; reduction[pairVDWForceIndex_Z] += force_sign * vdw_dir * p_ij_z; ) #if ( SHORT(1+) 0 ) // Short-range electrostatics #ifndef A2_QPX NORMAL( BigReal fast_d = kqq * table_four_i[8]; BigReal fast_c = kqq * table_four_i[9]; BigReal fast_b = kqq * table_four_i[10]; BigReal fast_a = kqq * table_four_i[11]; ) MODIFIED( BigReal modfckqq = (1.0-modf_mod) * kqq; BigReal fast_d = modfckqq * table_four_i[8]; BigReal fast_c = modfckqq * table_four_i[9]; BigReal fast_b = modfckqq * table_four_i[10]; BigReal fast_a = modfckqq * table_four_i[11]; ) #else vector4double fastv = vec_mul(kqqv, vec_ld(8 * sizeof(BigReal), (BigReal)table_four_i)); #define fast_d vec_extract(fastv, 0) #define fast_c vec_extract(fastv, 1) #define fast_b vec_extract(fastv, 2) #define fast_a vec_extract(fastv, 3) #endif { ENERGY( register BigReal fast_val = ( ( diffa fast_d * (1/6.)+ fast_c * (1/4.)) * diffa + fast_b (1/2.)) diffa + fast_a; NOT_ALCHPAIR ( electEnergy -= LAM(lambda_pair ) fast_val; FEP(electEnergy_s -= fast_val;) ) ) //ENERGY ALCHPAIR( ENERGY(electEnergy -= myElecLambda fast_val;) FEP(electEnergy_s -= myElecLambda2 * fast_val;) TI( NOENERGY(register BigReal fast_val = ( ( diffa * fast_d * (1/6.)+ fast_c * (1/4.)) * diffa + fast_b (1/2.)) diffa + fast_a;) ALCH1(electEnergy_ti_1 -= fast_val;) ALCH2(electEnergy_ti_2 -= fast_val;) ) ) INT( register BigReal fast_dir = ( diffa * fast_d + fast_c ) * diffa + fast_b; // force_r -= -1.0 * LAM(lambda_pair ) fast_dir; reduction[pairElectForceIndex_X] += force_sign fast_dir * p_ij_x; reduction[pairElectForceIndex_Y] += force_sign * fast_dir * p_ij_y; reduction[pairElectForceIndex_Z] += force_sign * fast_dir * p_ij_z; ) } /*** JE - Go **/ // Now Go energy should appear in VDW place -- put vdw_b back into place #if ( NORMAL (1+) 0) #if ( GO (1+) 0) // JLai #ifndef CODE_REDUNDANT #define CODE_REDUNDANT 0 #endif #if CODE_REDUNDANT if (ComputeNonbondedUtil::goGroPair) { // Explicit goGroPair calculation; only calculates goGroPair if goGroPair is turned on // // get_gro_force has an internal checklist that sees if atom_i and atom_j are // in the explicit pairlist. This is done because there is no guarantee that a // processor will have atom_i and atom_j so we cannot loop over the explict atom pairs. // We can only loop over all pairs. // // NOTE: It does not look like fast_b is not normalized by the r vector. // // JLai BigReal groLJe = 0.0; BigReal groGausse = 0.0; const CompAtomExt pExt_z = pExt_1 + j; BigReal groForce = mol->get_gro_force2(p_ij_x, p_ij_y, p_ij_z,pExt_i.id,pExt_z->id,&groLJe,&groGausse); NAMD_die("Failsafe. This line should never be reached\n"); #ifndef A2_QPX fast_b += groForce; #else vec_insert(fast_b + groForce, fastv, 2); #endif ENERGY( NOT_ALCHPAIR ( // JLai groLJEnergy += groLJe; groGaussEnergy += groGausse; ) ) //ENERGY } #endif BigReal goNative = 0; BigReal goNonnative = 0; BigReal goForce = 0; register const CompAtomExt pExt_j = pExt_1 + j; if (ComputeNonbondedUtil::goMethod == 2) { goForce = mol->get_go_force2(p_ij_x, p_ij_y, p_ij_z, pExt_i.id, pExt_j->id,&goNative,&goNonnative); } else { // Ported by JLai -- JE - added ( const BigReal r2go = square(p_ij_x, p_ij_y, p_ij_z); const BigReal rgo = sqrt(r2go); if (ComputeNonbondedUtil::goMethod == 1) { goForce = mol->get_go_force(rgo, pExt_i.id, pExt_j->id, &goNative, &goNonnative); } else if (ComputeNonbondedUtil::goMethod == 3) { goForce = mol->get_go_force_new(rgo, pExt_i.id, pExt_j->id, &goNative, &goNonnative); } else { NAMD_die("I SHOULDN'T BE HERE. DYING MELODRAMATICALLY.\n"); } } #ifndef A2_QPX fast_b += goForce; #else vec_insert(fast_b + goForce, fastv, 2); #endif { ENERGY( NOT_ALCHPAIR ( // JLai goEnergyNative += goNative; goEnergyNonnative += goNonnative; ) ) //ENERGY INT( reduction[pairVDWForceIndex_X] += force_sign goForce * p_ij_x; reduction[pairVDWForceIndex_Y] += force_sign * goForce * p_ij_y; reduction[pairVDWForceIndex_Z] += force_sign * goForce * p_ij_z; ) } // End of INT //DebugM(3,"rgo:" << rgo << ", pExt_i.id:" << pExt_i.id << ", pExt_j->id:" << pExt_j->id << \ // ", goForce:" << goForce << ", fast_b:" << fast_b << std::endl); #endif // ) // End of GO macro /*** JE - End Go **/ // End of port JL #endif //) // End of Normal MACRO // Combined short-range electrostatics and VdW force: #if ( NOT_ALCHPAIR(1+) 0) #ifndef A2_QPX fast_d += vdw_d; fast_c += vdw_c; fast_b += vdw_b; fast_a += vdw_a; // not used! #else fastv = vec_add(fastv, vdw_v); #endif #endif register BigReal fast_dir = (diffa fast_d + fast_c) * diffa + fast_b; BigReal force_r = LAM(lambda_pair ) fast_dir; ALCHPAIR( force_r = myElecLambda; force_r += alch_vdw_force; // special ALCH forces already multiplied by relevant lambda ) #ifndef NAMD_CUDA #ifndef A2_QPX register BigReal tmp_x = force_r * p_ij_x; f_i_x += tmp_x; f_j->x -= tmp_x; register BigReal tmp_y = force_r * p_ij_y; f_i_y += tmp_y; f_j->y -= tmp_y; register BigReal tmp_z = force_r * p_ij_z; f_i_z += tmp_z; f_j->z -= tmp_z; #else vector4double force_rv = vec_splats (force_r); vector4double tmp_v = vec_mul(force_rv, p_ij_v); f_i_v = vec_add(f_i_v, tmp_v); #define tmp_x vec_extract(tmp_v, 0) #define tmp_y vec_extract(tmp_v, 1) #define tmp_z vec_extract(tmp_v, 2) f_j->x -= tmp_x; f_j->y -= tmp_y; f_j->z -= tmp_z; #endif PPROF( const BigReal p_j_z = p_j->position.z; int n2 = (int)floor((p_j_z-pressureProfileMin)invThickness); pp_clamp(n2, pressureProfileSlabs); int p_j_partition = p_j->partition; pp_reduction(pressureProfileSlabs, n1, n2, p_i_partition, p_j_partition, pressureProfileAtomTypes, tmp_xp_ij_x, tmp_y * p_ij_y, tmp_zp_ij_z, pressureProfileReduction); ) #endif #endif // SHORT #endif // FAST #if ( FULL (EXCLUDED( SHORT ( 1+ ) ) ) 0 ) //const BigReal const slow_i = slow_table + 4table_i; #define slow_i (slow_table + 4table_i) #ifdef ARCH_POWERPC //Alignment and aliasing constraints __alignx (32, slow_table); #if ( SHORT( FAST( 1+ ) ) 0 ) #pragma disjoint (slow_table, f_1) #endif #pragma disjoint (slow_table, fullf_1) #endif //ARCH_POWERPC #endif //FULL #if ( FULL (MODIFIED( SHORT ( 1+ ) ) ) 0 ) //const BigReal* const slow_i = slow_table + 4table_i; #define slow_i (slow_table + 4table_i) #ifdef ARCH_POWERPC //Alignment and aliasing constraints __alignx (32, slow_table); #if ( SHORT( FAST( 1+ ) ) 0 ) #pragma disjoint (slow_table, f_1) #endif #pragma disjoint (slow_table, fullf_1) #endif //ARCH_POWERPC #endif //FULL #if ( FULL( 1+ ) 0 ) #ifndef A2_QPX BigReal slow_d = table_four_i[8 SHORT(+ 4)]; BigReal slow_c = table_four_i[9 SHORT(+ 4)]; BigReal slow_b = table_four_i[10 SHORT(+ 4)]; BigReal slow_a = table_four_i[11 SHORT(+ 4)]; EXCLUDED( SHORT( slow_a += slow_i[3]; slow_b += 2.slow_i[2]; slow_c += 4.slow_i[1]; slow_d += 6.slow_i[0]; ) NOSHORT( slow_d -= table_four_i[12]; slow_c -= table_four_i[13]; slow_b -= table_four_i[14]; slow_a -= table_four_i[15]; ) ) MODIFIED( SHORT( slow_a += modf_mod slow_i[3]; slow_b += 2.modf_mod slow_i[2]; slow_c += 4.modf_mod slow_i[1]; slow_d += 6.modf_mod slow_i[0]; ) NOSHORT( slow_d -= modf_mod * table_four_i[12]; slow_c -= modf_mod * table_four_i[13]; slow_b -= modf_mod * table_four_i[14]; slow_a -= modf_mod * table_four_i[15]; ) ) slow_d = kqq; slow_c = kqq; slow_b = kqq; slow_a = kqq; #else vector4double slow_v = vec_ld((8 SHORT(+ 4)) * sizeof(BigReal), (BigReal)table_four_i); EXCLUDED( SHORT( slow_v = vec_madd(full_cnst, vec_ld(0, (BigReal)slow_i), slow_v); ) NOSHORT( slow_v = vec_sub(slow_v, vec_ld(12sizeof(BigReal), (BigReal)table_four_i)); ) ); MODIFIED( SHORT( slow_v = vec_madd(full_cnst, vec_ld(0, (BigReal)slow_i), slow_v); ) NOSHORT( slow_v = vec_nmsub(full_cnst, vec_ld(12sizeof(BigReal), (BigReal)table_four_i), slow_v); ) ); slow_v = vec_mul (slow_v, vec_splats(kqq)); #define slow_d vec_extract(slow_v, 0) #define slow_c vec_extract(slow_v, 1) #define slow_b vec_extract(slow_v, 2) #define slow_a vec_extract(slow_v, 3) #endif ENERGY( register BigReal slow_val = ( ( diffa slow_d (1/6.)+ slow_c (1/4.)) * diffa + slow_b (1/2.)) diffa + slow_a; NOT_ALCHPAIR ( fullElectEnergy -= LAM(lambda_pair ) slow_val; FEP(fullElectEnergy_s -= slow_val;) ) ) // ENERGY ALCHPAIR( ENERGY(fullElectEnergy -= myElecLambda slow_val;) FEP(fullElectEnergy_s -= myElecLambda2 * slow_val;) TI( NOENERGY(register BigReal slow_val = ( ( diffa * slow_d (1/6.)+ slow_c (1/4.)) * diffa + slow_b (1/2.)) diffa + slow_a;) ALCH1(fullElectEnergy_ti_1 -= slow_val;) ALCH2(fullElectEnergy_ti_2 -= slow_val;) ) ) INT( { register BigReal slow_dir = ( diffa * slow_d + slow_c ) * diffa + slow_b; reduction[pairElectForceIndex_X] += force_sign * slow_dir * p_ij_x; reduction[pairElectForceIndex_Y] += force_sign * slow_dir * p_ij_y; reduction[pairElectForceIndex_Z] += force_sign * slow_dir * p_ij_z; } ) #if (NOT_ALCHPAIR (1+) 0) #if (FAST(1+) 0) #if (NOSHORT(1+) 0) #ifndef A2_QPX slow_d += vdw_d; slow_c += vdw_c; slow_b += vdw_b; slow_a += vdw_a; // unused! #else slow_v = vec_add (slow_v, vdw_v); #endif #endif #endif #endif register BigReal slow_dir = (diffa * slow_d + slow_c) * diffa + slow_b; BigReal fullforce_r = slow_dir LAM(* lambda_pair); ALCHPAIR ( fullforce_r = myElecLambda; FAST( NOSHORT( fullforce_r += alch_vdw_force; )) ) #ifndef NAMD_CUDA { #ifndef A2_QPX register BigReal ftmp_x = fullforce_r p_ij_x; fullf_i_x += ftmp_x; fullf_j->x -= ftmp_x; register BigReal ftmp_y = fullforce_r * p_ij_y; fullf_i_y += ftmp_y; fullf_j->y -= ftmp_y; register BigReal ftmp_z = fullforce_r * p_ij_z; fullf_i_z += ftmp_z; fullf_j->z -= ftmp_z; #else vector4double fforce_rv = vec_splats (fullforce_r); vector4double ftmp_v = vec_mul(fforce_rv, p_ij_v); fullf_i_v = vec_add(fullf_i_v, ftmp_v); #define ftmp_x vec_extract(ftmp_v, 0) #define ftmp_y vec_extract(ftmp_v, 1) #define ftmp_z vec_extract(ftmp_v, 2) fullf_j->x -= ftmp_x; fullf_j->y -= ftmp_y; fullf_j->z -= ftmp_z; #endif PPROF( const BigReal p_j_z = p_j->position.z; int n2 = (int)floor((p_j_z-pressureProfileMin)invThickness); pp_clamp(n2, pressureProfileSlabs); int p_j_partition = p_j->partition; pp_reduction(pressureProfileSlabs, n1, n2, p_i_partition, p_j_partition, pressureProfileAtomTypes, ftmp_xp_ij_x, ftmp_y * p_ij_y, ftmp_z*p_ij_z, pressureProfileReduction); ) } #endif #endif //FULL } // for pairlist #undef p_j #undef lj_pars #undef table_four_i #undef slow_i #undef f_j #undef fullf_j
GambitReader.h	/** * @file * This file is part of PUMGen * * For conditions of distribution and use, please see the copyright * notice in the file 'COPYING' at the root directory of this package * and the copyright notice at https://github.com/SeisSol/PUMGen * * @copyright 2017 Technical University of Munich * @author Sebastian Rettenberger <sebastian.rettenberger@tum.de> / #ifndef GAMBIT_READER_H #define GAMBIT_READER_H #include <fstream> #include <limits> #include <sstream> #include <vector> #include <map> #include "utils/stringutils.h" #include "utils/logger.h" #include "MeshReader.h" namespace puml { /* * Describes the group of an element / struct ElementGroup { /* The element / unsigned int element; /* The group for this element / int group; }; /* * Describes a boundary face / struct GambitBoundaryFace { /* The element the face belongs to / unsigned int element; /* The face of the element / unsigned int face; /* The type of the boundary / int type; }; class GambitReader : public MeshReader { private: struct ElementSection : FileSection { /* Start of vertices in an element / size_t vertexStart; /* Size per vertex id / size_t vertexSize; }; struct GroupSection : FileSection { /* Size per element id / size_t elementSize; /* Group number / int group; }; struct BoundarySection : FileSection { /* Type of the boundary / int type; /* Size per element id (only fixed line length) / size_t elementSize; /* Size per element type (only fixed line length) / size_t elementTypeSize; /* Size per face id (only fixed line length) / size_t faceSize; /* Is line length variable? / bool variableLineLength; }; // Section descriptions FileSection m_vertices; ElementSection m_elements; std::vector<GroupSection> m_groups; std::vector<BoundarySection> m_boundaries; std::map<int, int> id_map; //matches element-id in .neu file to local id, Key = id in .neu file, Value = local id public: void open(const char meshFile) { MeshReader::open(meshFile); std::string line; // Read header information getline(m_mesh, line); // First line contains version // we ignore this line for know line.clear(); getline(m_mesh, line); utils::StringUtils::trim(line); if (line != GAMBIT_FILE_ID) logError() << "Not a Gambit mesh file:" << meshFile; std::string name; getline(m_mesh, name); // Internal name getline(m_mesh, line); // Skip line: // PROGRAM: Gambit VERSION: x.y.z getline(m_mesh, line); // Date getline(m_mesh, line); // Skip problem size names unsigned int nGroups, nBoundaries, dimensions; m_mesh >> m_vertices.nLines; m_mesh >> m_elements.nLines; m_mesh >> nGroups; m_mesh >> nBoundaries; m_mesh >> dimensions; getline(m_mesh, line); // Skip rest of the line if (dimensions != 3) logError() << "Gambit file does not contain a 3 dimensional mesh"; getline(m_mesh, line); utils::StringUtils::trim(line); if (line != ENDSECTION) logError() << "Invalid Gambit format: End of header expected, found" << line; // Find seek positions // Vertices getline(m_mesh, line); if (line.find(NODAL_COORDINATES) == std::string::npos) logError() << "Invalid Gambit format: Coordinates expected, found" << line; m_vertices.seekPosition = m_mesh.tellg(); getline(m_mesh, line); m_vertices.lineSize = line.length() + 1; m_mesh.seekg(m_vertices.seekPosition + m_vertices.nLines * m_vertices.lineSize); getline(m_mesh, line); utils::StringUtils::rtrim(line); // remove \r if (line != ENDSECTION) logError() << "Invalid Gambit format: End of coordinates expected, found" << line; // Elements getline(m_mesh, line); if (line.find(ELEMENT_CELLS) == std::string::npos) logError() << "Invalid Gambit format: Elements expected, found" << line; m_elements.seekPosition = m_mesh.tellg(); getline(m_mesh, line); m_elements.lineSize = line.length() + 1; m_mesh.seekg(m_elements.seekPosition + m_elements.nLines * m_elements.lineSize); std::istringstream ss(line); int tmp; ss >> tmp; // Element id ss >> tmp; ss >> tmp; ss.seekg(1, std::stringstream::cur); // White space m_elements.vertexStart = ss.tellg(); // TODO works only for tetrahedrals utils::StringUtils::rtrim(line); if ((line.length() - m_elements.vertexStart) % 4 != 0) logError() << "Invalid Gambit format: Mesh does not seem to contain tetrahedrals"; m_elements.vertexSize = (line.length() - m_elements.vertexStart) / 4; getline(m_mesh, line); utils::StringUtils::rtrim(line); // remove \r if (line != ENDSECTION) logError() << "Invalid Gambit format: End of elements expected, found" << line; // Groups m_groups.resize(nGroups); for (unsigned int i = 0; i < nGroups; i++) { getline(m_mesh, line); if (line.find(ELEMENT_GROUP) == std::string::npos) logError() << "Invalid Gambit format: Group expected, found" << line; getline(m_mesh, line); // Group size and material std::string y; std::istringstream ss(line); ss >> y; ss >> m_groups[i].group; ss >> y; ss >> m_groups[i].nLines; // This is not the actual number of lines // Because Gambit stores more than one element // per line. getline(m_mesh, line); getline(m_mesh, line); m_groups[i].seekPosition = m_mesh.tellg(); getline(m_mesh, line); m_groups[i].lineSize = line.size() + 1; utils::StringUtils::rtrim(line); if (line.length() % ELEMENTS_PER_LINE_GROUP != 0) logError() << "Invalid Gambit format: Mesh does not contain" << ELEMENTS_PER_LINE_GROUP << "in one group line"; m_groups[i].elementSize = line.length() / ELEMENTS_PER_LINE_GROUP; m_mesh.seekg(m_groups[i].seekPosition + (m_groups[i].nLines / ELEMENTS_PER_LINE_GROUP) * m_groups[i].lineSize); if (m_groups[i].nLines % ELEMENTS_PER_LINE_GROUP != 0) // Last line m_mesh.seekg(m_groups[i].lineSize - (ELEMENTS_PER_LINE_GROUP - m_groups[i].nLines % ELEMENTS_PER_LINE_GROUP) * m_groups[i].elementSize, std::ifstream::cur); getline(m_mesh, line); utils::StringUtils::rtrim(line); // remove \r if (line != ENDSECTION) logError() << "Invalid Gambit format: End of group expected, found" << line; } // Boundaries m_boundaries.resize(nBoundaries); for (unsigned int i = 0; i < nBoundaries; i++) { getline(m_mesh, line); if (line.find(BOUNDARY_CONDITIONS) == std::string::npos) logError() << "Invalid Gambit format: Boundaries expected, found" << line; m_boundaries[i].variableLineLength = false; getline(m_mesh, line); m_boundaries[i].seekPosition = m_mesh.tellg(); // Boundary type and size int x; std::istringstream ss(line); ss >> m_boundaries[i].type; m_boundaries[i].type %= 100; // Fix boundary type TODO not sure where this should be placed ss >> x; ss >> m_boundaries[i].nLines; // Try boundary with fixed line length getline(m_mesh, line); m_boundaries[i].lineSize = line.size() + 1; // Get element size std::istringstream ssE(line); unsigned int element, type, face; ssE >> element; m_boundaries[i].elementSize = ssE.tellg(); ssE >> type; m_boundaries[i].elementTypeSize = static_cast<size_t>(ssE.tellg()) - m_boundaries[i].elementSize; ssE >> face; if (ssE.tellg() == -1) m_boundaries[i].faceSize = line.length() - m_boundaries[i].elementSize - m_boundaries[i].elementTypeSize; else m_boundaries[i].faceSize = static_cast<size_t>(ssE.tellg()) - m_boundaries[i].elementSize - m_boundaries[i].elementTypeSize; m_mesh.seekg(m_boundaries[i].seekPosition + m_boundaries[i].nLines * m_boundaries[i].lineSize); getline(m_mesh, line); utils::StringUtils::rtrim(line); // remove \r if (line != ENDSECTION) { logWarning() << "Gambit format does not seem to have a fixed boundary line length. Trying with variable line length"; m_boundaries[i].variableLineLength = true; m_boundaries[i].lineSize = 0; // Variable line size m_boundaries[i].elementSize = 0; m_mesh.clear(); // The fixed boundary try may seek beyond the end of the file m_mesh.seekg(m_boundaries[i].seekPosition); for (size_t j = 0; j < m_boundaries[i].nLines; j++) m_mesh.ignore(std::numeric_limits<std::streamsize>::max(), '\n'); getline(m_mesh, line); utils::StringUtils::rtrim(line); // remove \r if (line != ENDSECTION) logError() << "Invalid Gambit format: End of boundaries expected, found" << line; } } } unsigned int nVertices() const { return m_vertices.nLines; } unsigned int nElements() const { return m_elements.nLines; } unsigned int nBoundaries() const { unsigned int count = 0; for (std::vector<BoundarySection>::const_iterator i = m_boundaries.begin(); i != m_boundaries.end(); i++) { count += i->nLines; } return count; } /** * @copydoc MeshReader::readVertices(unsigned int, unsigned int, double) * @todo Only 3 dimensional meshes are supported / void readVertices(unsigned int start, unsigned int count, double vertices) { m_mesh.clear(); m_mesh.seekg(m_vertices.seekPosition + start * m_vertices.lineSize + m_vertices.lineSize - 3COORDINATE_SIZE - 1); char buf = new char[3COORDINATE_SIZE]; for (unsigned int i = 0; i < count; i++) { m_mesh.read(buf, 3COORDINATE_SIZE); for (int j = 0; j < 3; j++) { std::istringstream ss(std::string(&buf[jCOORDINATE_SIZE], COORDINATE_SIZE)); ss >> vertices[i 3 + j]; } m_mesh.seekg(m_vertices.lineSize - 3COORDINATE_SIZE, std::fstream::cur); } delete [] buf; } /* * @copydoc MeshReader::readElements(unsigned int, unsigned int, int) * @todo Only tetrahedral meshes are supported * @todo Support for varying coordinate/vertexid fields / void readElements(unsigned int start, unsigned int count, int elements) { int value = 0; m_mesh.clear(); m_mesh.seekg(m_elements.seekPosition + start * m_elements.lineSize); //char* buf = new char[4m_elements.vertexSize]; std::string line; for (unsigned int i = 0; i < count; i++) { getline(m_mesh, line); std::istringstream mesh_String(line); int key; //local id mesh_String >> key; int six; //a value that appears in every file but is not used again mesh_String >> six; int four; //a value that appears in every file but is not used again mesh_String >> four; id_map.insert(std::pair<int, int>(key, value)); //inserts an element, using his original id as key and his local id as value value++; //incremented, so the next id is different and again unique for (int j = 0; j < 4; j++) { mesh_String >> elements[i 4 + j]; elements[i * 4 + j]--; mesh_String.seekg(1, std::stringstream::cur); // White space } } } /** * Reads group number for elements from start to start+count * * @param groups Buffer for storing the group numbers. The caller is responsible * for allocating the buffer. / void readGroups(unsigned int start, unsigned int count, ElementGroup groups) { m_mesh.clear(); // Get the group, were we should start reading std::vector<GroupSection>::const_iterator section; for (section = m_groups.begin(); section != m_groups.end() && section->nLines < start; section++) start -= section->nLines; m_mesh.seekg(section->seekPosition + (start / ELEMENTS_PER_LINE_GROUP) * section->lineSize + (start % ELEMENTS_PER_LINE_GROUP) * section->elementSize); char* buf = new char[section->elementSize]; for (unsigned int i = 0; i < count; i++) { m_mesh.read(buf, section->elementSize); std::istringstream ss(std::string(buf, section->elementSize)); ss >> groups[i].element;//read element id from file int key = groups[i].element; //save parsed id to key groups[i].element = id_map[key]; //lookup local id by using the parsed id as key groups[i].group = section->group; start++; // May need to jump from one section to the next if (start >= section->nLines) { start = 0; section++; m_mesh.seekg(section->seekPosition); } else if (start % ELEMENTS_PER_LINE_GROUP == 0) // Skip newline char at end of line m_mesh.seekg(section->lineSize - section->elementSize * ELEMENTS_PER_LINE_GROUP, std::fstream::cur); } delete [] buf; } /** * Reads all groups numbers. * In contrast to readGroups(unsigned int, unsigned int, ElementGroup) it returns the group numbers sorted according to the elements. / void readGroups(int groups) { logInfo() << "Reading group information"; ElementGroup* map = new ElementGroup[nElements()]; readGroups(0, nElements(), map); #ifdef _OPENMP #pragma omp parallel for schedule(static) #endif for (unsigned int i = 0; i < nElements(); i++) groups[map[i].element] = map[i].group; delete [] map; } /** * Reads boundaries from start to start+count from the file and stores them in * <code>boundaries</code>. * * @param elements Buffer to store boundaries. Each boundary consists of the element, the * face and the boundary type. / void readBoundaries(unsigned int start, unsigned int count, GambitBoundaryFace boundaries) { m_mesh.clear(); // Get the boundary, were we should start reading std::vector<BoundarySection>::const_iterator section; for (section = m_boundaries.begin(); section != m_boundaries.end() && section->nLines < start; section++) start -= section->nLines; char* buf; if (section->variableLineLength) { m_mesh.seekg(section->seekPosition); for (size_t i = 0; i < start; i++) m_mesh.ignore(std::numeric_limits<std::streamsize>::max(), '\n'); buf = 0L; } else { m_mesh.seekg(section->seekPosition + start * section->lineSize); buf = new char[section->elementSize + section->elementTypeSize + section->faceSize]; } for (unsigned int i = 0; i < count; i++) { if (start >= section->nLines) { // Are we starting a new section in this iteration? start = 0; section++; m_mesh.seekg(section->seekPosition); delete [] buf; if (section->variableLineLength) buf = 0L; else buf = new char[section->elementSize + section->elementTypeSize + section->faceSize]; } if (section->variableLineLength) { unsigned int elementType; // Ignored m_mesh >> boundaries[i].element; m_mesh >> elementType; m_mesh >> boundaries[i].face; } else { m_mesh.read(buf, section->elementSize + section->elementTypeSize + section->faceSize); std::istringstream ssE(std::string(buf, section->elementSize)); ssE >> boundaries[i].element; std::istringstream ssF(std::string(&buf[section->elementSize + section->elementTypeSize], section->faceSize)); ssF >> boundaries[i].face; // Seek to next position m_mesh.seekg(section->lineSize - (section->elementSize + section->elementTypeSize + section->faceSize), std::fstream::cur); } int key = boundaries[i].element; //save parsed element id to key boundaries[i].element = id_map[key]; //lookup local id by using parsed element id boundaries[i].face--; boundaries[i].type = section->type; start++; // Line in the current section } delete [] buf; } /** * Reads all boundaries. * * @param Boundary condition for all faces. The caller is responsible * for allocation the memory (<code>nElements()4</code>). Only the faces for which boundary conditions are available are modified. * * @todo Only tetrahedral meshes are supported / void readBoundaries(int boundaries) { logInfo() << "Reading boundary conditions"; unsigned int nBnds = nBoundaries(); GambitBoundaryFace* faces = new GambitBoundaryFace[nBoundaries()]; readBoundaries(0, nBnds, faces); for (unsigned int i = 0; i < nBnds; i++) boundaries[faces[i].element4 + faces[i].face] = faces[i].type; delete [] faces; } private: /* Number of character required to store a coordinate / static const size_t COORDINATE_SIZE = 20ul; /* Number of elements stored in one group line / static const size_t ELEMENTS_PER_LINE_GROUP = 10ul; static const char GAMBIT_FILE_ID; static const char* ENDSECTION; static const char* NODAL_COORDINATES; static const char* ELEMENT_CELLS; static const char* ELEMENT_GROUP; static const char* BOUNDARY_CONDITIONS; }; } #endif // GAMBIT_READER_H
matrix.c	/* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % M M AAA TTTTT RRRR IIIII X X % % MM MM A A T R R I X X % % M M M AAAAA T RRRR I X % % M M A A T R R I X X % % M M A A T R R IIIII X X % % % % % % MagickCore Matrix Methods % % % % Software Design % % Cristy % % August 2007 % % % % % % Copyright 1999-2017 ImageMagick Studio LLC, a non-profit organization % % dedicated to making software imaging solutions freely available. % % % % You may not use this file except in compliance with the License. You may % % obtain a copy of the License at % % % % https://www.imagemagick.org/script/license.php % % % % Unless required by applicable law or agreed to in writing, software % % distributed under the License is distributed on an "AS IS" BASIS, % % WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. % % See the License for the specific language governing permissions and % % limitations under the License. % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % / / Include declarations. / #include "MagickCore/studio.h" #include "MagickCore/blob.h" #include "MagickCore/blob-private.h" #include "MagickCore/cache.h" #include "MagickCore/exception.h" #include "MagickCore/exception-private.h" #include "MagickCore/image-private.h" #include "MagickCore/matrix.h" #include "MagickCore/matrix-private.h" #include "MagickCore/memory_.h" #include "MagickCore/pixel-accessor.h" #include "MagickCore/pixel-private.h" #include "MagickCore/resource_.h" #include "MagickCore/semaphore.h" #include "MagickCore/thread-private.h" #include "MagickCore/utility.h" / Typedef declaration. / struct _MatrixInfo { CacheType type; size_t columns, rows, stride; MagickSizeType length; MagickBooleanType mapped, synchronize; char path[MagickPathExtent]; int file; void elements; SemaphoreInfo semaphore; size_t signature; }; / %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % A c q u i r e M a t r i x I n f o % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % AcquireMatrixInfo() allocates the ImageInfo structure. % % The format of the AcquireMatrixInfo method is: % % MatrixInfo AcquireMatrixInfo(const size_t columns,const size_t rows, % const size_t stride,ExceptionInfo exception) % % A description of each parameter follows: % % o columns: the matrix columns. % % o rows: the matrix rows. % % o stride: the matrix stride. % % o exception: return any errors or warnings in this structure. % / #if defined(SIGBUS) static void MatrixSignalHandler(int status) { ThrowFatalException(CacheFatalError,"UnableToExtendMatrixCache"); } #endif static inline MagickOffsetType WriteMatrixElements( const MatrixInfo magick_restrict matrix_info,const MagickOffsetType offset, const MagickSizeType length,const unsigned char magick_restrict buffer) { register MagickOffsetType i; ssize_t count; #if !defined(MAGICKCORE_HAVE_PWRITE) LockSemaphoreInfo(matrix_info->semaphore); if (lseek(matrix_info->file,offset,SEEK_SET) < 0) { UnlockSemaphoreInfo(matrix_info->semaphore); return((MagickOffsetType) -1); } #endif count=0; for (i=0; i < (MagickOffsetType) length; i+=count) { #if !defined(MAGICKCORE_HAVE_PWRITE) count=write(matrix_info->file,buffer+i,(size_t) MagickMin(length-i, (MagickSizeType) SSIZE_MAX)); #else count=pwrite(matrix_info->file,buffer+i,(size_t) MagickMin(length-i, (MagickSizeType) SSIZE_MAX),(off_t) (offset+i)); #endif if (count <= 0) { count=0; if (errno != EINTR) break; } } #if !defined(MAGICKCORE_HAVE_PWRITE) UnlockSemaphoreInfo(matrix_info->semaphore); #endif return(i); } static MagickBooleanType SetMatrixExtent( MatrixInfo magick_restrict matrix_info,MagickSizeType length) { MagickOffsetType count, extent, offset; if (length != (MagickSizeType) ((MagickOffsetType) length)) return(MagickFalse); offset=(MagickOffsetType) lseek(matrix_info->file,0,SEEK_END); if (offset < 0) return(MagickFalse); if ((MagickSizeType) offset >= length) return(MagickTrue); extent=(MagickOffsetType) length-1; count=WriteMatrixElements(matrix_info,extent,1,(const unsigned char ) ""); #if defined(MAGICKCORE_HAVE_POSIX_FALLOCATE) if (matrix_info->synchronize != MagickFalse) (void) posix_fallocate(matrix_info->file,offset+1,extent-offset); #endif #if defined(SIGBUS) (void) signal(SIGBUS,MatrixSignalHandler); #endif return(count != (MagickOffsetType) 1 ? MagickFalse : MagickTrue); } MagickExport MatrixInfo AcquireMatrixInfo(const size_t columns, const size_t rows,const size_t stride,ExceptionInfo exception) { char synchronize; MagickBooleanType status; MatrixInfo matrix_info; matrix_info=(MatrixInfo ) AcquireMagickMemory(sizeof(matrix_info)); if (matrix_info == (MatrixInfo ) NULL) return((MatrixInfo ) NULL); (void) ResetMagickMemory(matrix_info,0,sizeof(matrix_info)); matrix_info->signature=MagickCoreSignature; matrix_info->columns=columns; matrix_info->rows=rows; matrix_info->stride=stride; matrix_info->semaphore=AcquireSemaphoreInfo(); synchronize=GetEnvironmentValue("MAGICK_SYNCHRONIZE"); if (synchronize != (const char ) NULL) { matrix_info->synchronize=IsStringTrue(synchronize); synchronize=DestroyString(synchronize); } matrix_info->length=(MagickSizeType) columnsrowsstride; if (matrix_info->columns != (size_t) (matrix_info->length/rows/stride)) { (void) ThrowMagickException(exception,GetMagickModule(),CacheError, "CacheResourcesExhausted","`%s'","matrix cache"); return(DestroyMatrixInfo(matrix_info)); } matrix_info->type=MemoryCache; status=AcquireMagickResource(AreaResource,matrix_info->length); if ((status != MagickFalse) && (matrix_info->length == (MagickSizeType) ((size_t) matrix_info->length))) { status=AcquireMagickResource(MemoryResource,matrix_info->length); if (status != MagickFalse) { matrix_info->mapped=MagickFalse; matrix_info->elements=AcquireMagickMemory((size_t) matrix_info->length); if (matrix_info->elements == NULL) { matrix_info->mapped=MagickTrue; matrix_info->elements=MapBlob(-1,IOMode,0,(size_t) matrix_info->length); } if (matrix_info->elements == (unsigned short ) NULL) RelinquishMagickResource(MemoryResource,matrix_info->length); } } matrix_info->file=(-1); if (matrix_info->elements == (unsigned short ) NULL) { status=AcquireMagickResource(DiskResource,matrix_info->length); if (status == MagickFalse) { (void) ThrowMagickException(exception,GetMagickModule(),CacheError, "CacheResourcesExhausted","`%s'","matrix cache"); return(DestroyMatrixInfo(matrix_info)); } matrix_info->type=DiskCache; matrix_info->file=AcquireUniqueFileResource(matrix_info->path); if (matrix_info->file == -1) return(DestroyMatrixInfo(matrix_info)); status=AcquireMagickResource(MapResource,matrix_info->length); if (status != MagickFalse) { status=SetMatrixExtent(matrix_info,matrix_info->length); if (status != MagickFalse) matrix_info->elements=(void ) MapBlob(matrix_info->file,IOMode,0, (size_t) matrix_info->length); if (matrix_info->elements != NULL) matrix_info->type=MapCache; else RelinquishMagickResource(MapResource,matrix_info->length); } } return(matrix_info); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % A c q u i r e M a g i c k M a t r i x % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % AcquireMagickMatrix() allocates and returns a matrix in the form of an % array of pointers to an array of doubles, with all values pre-set to zero. % % This used to generate the two dimensional matrix, and vectors required % for the GaussJordanElimination() method below, solving some system of % simultanious equations. % % The format of the AcquireMagickMatrix method is: % % double *AcquireMagickMatrix(const size_t number_rows, % const size_t size) % % A description of each parameter follows: % % o number_rows: the number pointers for the array of pointers % (first dimension). % % o size: the size of the array of doubles each pointer points to % (second dimension). % / MagickExport double AcquireMagickMatrix(const size_t number_rows, const size_t size) { double matrix; register ssize_t i, j; matrix=(double *) AcquireQuantumMemory(number_rows,sizeof(matrix)); if (matrix == (double ) NULL) return((double ) NULL); for (i=0; i < (ssize_t) number_rows; i++) { matrix[i]=(double ) AcquireQuantumMemory(size,sizeof(matrix[i])); if (matrix[i] == (double ) NULL) { for (j=0; j < i; j++) matrix[j]=(double ) RelinquishMagickMemory(matrix[j]); matrix=(double ) RelinquishMagickMemory(matrix); return((double ) NULL); } for (j=0; j < (ssize_t) size; j++) matrix[i][j]=0.0; } return(matrix); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % D e s t r o y M a t r i x I n f o % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % DestroyMatrixInfo() dereferences a matrix, deallocating memory associated % with the matrix. % % The format of the DestroyImage method is: % % MatrixInfo DestroyMatrixInfo(MatrixInfo matrix_info) % % A description of each parameter follows: % % o matrix_info: the matrix. % / MagickExport MatrixInfo DestroyMatrixInfo(MatrixInfo matrix_info) { assert(matrix_info != (MatrixInfo ) NULL); assert(matrix_info->signature == MagickCoreSignature); LockSemaphoreInfo(matrix_info->semaphore); switch (matrix_info->type) { case MemoryCache: { if (matrix_info->mapped == MagickFalse) matrix_info->elements=RelinquishMagickMemory(matrix_info->elements); else { (void) UnmapBlob(matrix_info->elements,(size_t) matrix_info->length); matrix_info->elements=(unsigned short ) NULL; } RelinquishMagickResource(MemoryResource,matrix_info->length); break; } case MapCache: { (void) UnmapBlob(matrix_info->elements,(size_t) matrix_info->length); matrix_info->elements=NULL; RelinquishMagickResource(MapResource,matrix_info->length); } case DiskCache: { if (matrix_info->file != -1) (void) close(matrix_info->file); (void) RelinquishUniqueFileResource(matrix_info->path); RelinquishMagickResource(DiskResource,matrix_info->length); break; } default: break; } UnlockSemaphoreInfo(matrix_info->semaphore); RelinquishSemaphoreInfo(&matrix_info->semaphore); return((MatrixInfo ) RelinquishMagickMemory(matrix_info)); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % + G a u s s J o r d a n E l i m i n a t i o n % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % GaussJordanElimination() returns a matrix in reduced row echelon form, % while simultaneously reducing and thus solving the augumented results % matrix. % % See also http://en.wikipedia.org/wiki/Gauss-Jordan_elimination % % The format of the GaussJordanElimination method is: % % MagickBooleanType GaussJordanElimination(double matrix, % double vectors,const size_t rank,const size_t number_vectors) % % A description of each parameter follows: % % o matrix: the matrix to be reduced, as an 'array of row pointers'. % % o vectors: the additional matrix argumenting the matrix for row reduction. % Producing an 'array of column vectors'. % % o rank: The size of the matrix (both rows and columns). % Also represents the number terms that need to be solved. % % o number_vectors: Number of vectors columns, argumenting the above matrix. % Usally 1, but can be more for more complex equation solving. % % Note that the 'matrix' is given as a 'array of row pointers' of rank size. % That is values can be assigned as matrix[row][column] where 'row' is % typically the equation, and 'column' is the term of the equation. % That is the matrix is in the form of a 'row first array'. % % However 'vectors' is a 'array of column pointers' which can have any number % of columns, with each column array the same 'rank' size as 'matrix'. % % This allows for simpler handling of the results, especially is only one % column 'vector' is all that is required to produce the desired solution. % % For example, the 'vectors' can consist of a pointer to a simple array of % doubles. when only one set of simultanious equations is to be solved from % the given set of coefficient weighted terms. % % double *matrix = AcquireMagickMatrix(8UL,8UL); % double coefficents[8]; % ... % GaussJordanElimination(matrix, &coefficents, 8UL, 1UL); % % However by specifing more 'columns' (as an 'array of vector columns', % you can use this function to solve a set of 'separable' equations. % % For example a distortion function where u = U(x,y) v = V(x,y) % And the functions U() and V() have separate coefficents, but are being % generated from a common x,y->u,v data set. % % Another example is generation of a color gradient from a set of colors at % specific coordients, such as a list x,y -> r,g,b,a. % % You can also use the 'vectors' to generate an inverse of the given 'matrix' % though as a 'column first array' rather than a 'row first array'. For % details see http://en.wikipedia.org/wiki/Gauss-Jordan_elimination % / MagickPrivate MagickBooleanType GaussJordanElimination(double matrix, double vectors,const size_t rank,const size_t number_vectors) { #define GaussJordanSwap(x,y) \ { \ if ((x) != (y)) \ { \ (x)+=(y); \ (y)=(x)-(y); \ (x)=(x)-(y); \ } \ } double max, scale; register ssize_t i, j, k; ssize_t column, columns, pivots, row, rows; columns=(ssize_t ) AcquireQuantumMemory(rank,sizeof(columns)); rows=(ssize_t ) AcquireQuantumMemory(rank,sizeof(rows)); pivots=(ssize_t ) AcquireQuantumMemory(rank,sizeof(pivots)); if ((rows == (ssize_t ) NULL) \|\| (columns == (ssize_t ) NULL) \|\| (pivots == (ssize_t ) NULL)) { if (pivots != (ssize_t ) NULL) pivots=(ssize_t ) RelinquishMagickMemory(pivots); if (columns != (ssize_t ) NULL) columns=(ssize_t ) RelinquishMagickMemory(columns); if (rows != (ssize_t ) NULL) rows=(ssize_t ) RelinquishMagickMemory(rows); return(MagickFalse); } (void) ResetMagickMemory(columns,0,ranksizeof(columns)); (void) ResetMagickMemory(rows,0,ranksizeof(rows)); (void) ResetMagickMemory(pivots,0,ranksizeof(pivots)); column=0; row=0; for (i=0; i < (ssize_t) rank; i++) { max=0.0; for (j=0; j < (ssize_t) rank; j++) if (pivots[j] != 1) { for (k=0; k < (ssize_t) rank; k++) if (pivots[k] != 0) { if (pivots[k] > 1) return(MagickFalse); } else if (fabs(matrix[j][k]) >= max) { max=fabs(matrix[j][k]); row=j; column=k; } } pivots[column]++; if (row != column) { for (k=0; k < (ssize_t) rank; k++) GaussJordanSwap(matrix[row][k],matrix[column][k]); for (k=0; k < (ssize_t) number_vectors; k++) GaussJordanSwap(vectors[k][row],vectors[k][column]); } rows[i]=row; columns[i]=column; if (matrix[column][column] == 0.0) return(MagickFalse); /* sigularity / scale=PerceptibleReciprocal(matrix[column][column]); matrix[column][column]=1.0; for (j=0; j < (ssize_t) rank; j++) matrix[column][j]=scale; for (j=0; j < (ssize_t) number_vectors; j++) vectors[j][column]=scale; for (j=0; j < (ssize_t) rank; j++) if (j != column) { scale=matrix[j][column]; matrix[j][column]=0.0; for (k=0; k < (ssize_t) rank; k++) matrix[j][k]-=scalematrix[column][k]; for (k=0; k < (ssize_t) number_vectors; k++) vectors[k][j]-=scalevectors[k][column]; } } for (j=(ssize_t) rank-1; j >= 0; j--) if (columns[j] != rows[j]) for (i=0; i < (ssize_t) rank; i++) GaussJordanSwap(matrix[i][rows[j]],matrix[i][columns[j]]); pivots=(ssize_t ) RelinquishMagickMemory(pivots); rows=(ssize_t ) RelinquishMagickMemory(rows); columns=(ssize_t ) RelinquishMagickMemory(columns); return(MagickTrue); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % G e t M a t r i x C o l u m n s % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % GetMatrixColumns() returns the number of columns in the matrix. % % The format of the GetMatrixColumns method is: % % size_t GetMatrixColumns(const MatrixInfo matrix_info) % % A description of each parameter follows: % % o matrix_info: the matrix. % / MagickExport size_t GetMatrixColumns(const MatrixInfo matrix_info) { assert(matrix_info != (MatrixInfo ) NULL); assert(matrix_info->signature == MagickCoreSignature); return(matrix_info->columns); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % G e t M a t r i x E l e m e n t % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % GetMatrixElement() returns the specifed element in the matrix. % % The format of the GetMatrixElement method is: % % MagickBooleanType GetMatrixElement(const MatrixInfo matrix_info, % const ssize_t x,const ssize_t y,void value) % % A description of each parameter follows: % % o matrix_info: the matrix columns. % % o x: the matrix x-offset. % % o y: the matrix y-offset. % % o value: return the matrix element in this buffer. % / static inline ssize_t EdgeX(const ssize_t x,const size_t columns) { if (x < 0L) return(0L); if (x >= (ssize_t) columns) return((ssize_t) (columns-1)); return(x); } static inline ssize_t EdgeY(const ssize_t y,const size_t rows) { if (y < 0L) return(0L); if (y >= (ssize_t) rows) return((ssize_t) (rows-1)); return(y); } static inline MagickOffsetType ReadMatrixElements( const MatrixInfo magick_restrict matrix_info,const MagickOffsetType offset, const MagickSizeType length,unsigned char magick_restrict buffer) { register MagickOffsetType i; ssize_t count; #if !defined(MAGICKCORE_HAVE_PREAD) LockSemaphoreInfo(matrix_info->semaphore); if (lseek(matrix_info->file,offset,SEEK_SET) < 0) { UnlockSemaphoreInfo(matrix_info->semaphore); return((MagickOffsetType) -1); } #endif count=0; for (i=0; i < (MagickOffsetType) length; i+=count) { #if !defined(MAGICKCORE_HAVE_PREAD) count=read(matrix_info->file,buffer+i,(size_t) MagickMin(length-i, (MagickSizeType) SSIZE_MAX)); #else count=pread(matrix_info->file,buffer+i,(size_t) MagickMin(length-i, (MagickSizeType) SSIZE_MAX),(off_t) (offset+i)); #endif if (count <= 0) { count=0; if (errno != EINTR) break; } } #if !defined(MAGICKCORE_HAVE_PREAD) UnlockSemaphoreInfo(matrix_info->semaphore); #endif return(i); } MagickExport MagickBooleanType GetMatrixElement(const MatrixInfo matrix_info, const ssize_t x,const ssize_t y,void value) { MagickOffsetType count, i; assert(matrix_info != (const MatrixInfo ) NULL); assert(matrix_info->signature == MagickCoreSignature); i=(MagickOffsetType) EdgeY(y,matrix_info->rows)matrix_info->columns+ EdgeX(x,matrix_info->columns); if (matrix_info->type != DiskCache) { (void) memcpy(value,(unsigned char ) matrix_info->elements+i* matrix_info->stride,matrix_info->stride); return(MagickTrue); } count=ReadMatrixElements(matrix_info,imatrix_info->stride, matrix_info->stride,(unsigned char ) value); if (count != (MagickOffsetType) matrix_info->stride) return(MagickFalse); return(MagickTrue); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % G e t M a t r i x R o w s % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % GetMatrixRows() returns the number of rows in the matrix. % % The format of the GetMatrixRows method is: % % size_t GetMatrixRows(const MatrixInfo matrix_info) % % A description of each parameter follows: % % o matrix_info: the matrix. % / MagickExport size_t GetMatrixRows(const MatrixInfo matrix_info) { assert(matrix_info != (const MatrixInfo ) NULL); assert(matrix_info->signature == MagickCoreSignature); return(matrix_info->rows); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % + L e a s t S q u a r e s A d d T e r m s % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % LeastSquaresAddTerms() adds one set of terms and associate results to the % given matrix and vectors for solving using least-squares function fitting. % % The format of the AcquireMagickMatrix method is: % % void LeastSquaresAddTerms(double matrix,double vectors, % const double terms,const double results,const size_t rank, % const size_t number_vectors); % % A description of each parameter follows: % % o matrix: the square matrix to add given terms/results to. % % o vectors: the result vectors to add terms/results to. % % o terms: the pre-calculated terms (without the unknown coefficent % weights) that forms the equation being added. % % o results: the result(s) that should be generated from the given terms % weighted by the yet-to-be-solved coefficents. % % o rank: the rank or size of the dimensions of the square matrix. % Also the length of vectors, and number of terms being added. % % o number_vectors: Number of result vectors, and number or results being % added. Also represents the number of separable systems of equations % that is being solved. % % Example of use... % % 2 dimensional Affine Equations (which are separable) % c0x + c2y + c41 => u % c1x + c3y + c51 => v % % double matrix = AcquireMagickMatrix(3UL,3UL); % double vectors = AcquireMagickMatrix(2UL,3UL); % double terms[3], results[2]; % ... % for each given x,y -> u,v % terms[0] = x; % terms[1] = y; % terms[2] = 1; % results[0] = u; % results[1] = v; % LeastSquaresAddTerms(matrix,vectors,terms,results,3UL,2UL); % ... % if ( GaussJordanElimination(matrix,vectors,3UL,2UL) ) { % c0 = vectors[0][0]; % c2 = vectors[0][1]; % c4 = vectors[0][2]; % c1 = vectors[1][0]; % c3 = vectors[1][1]; % c5 = vectors[1][2]; % } % else % printf("Matrix unsolvable\n); % RelinquishMagickMatrix(matrix,3UL); % RelinquishMagickMatrix(vectors,2UL); % / MagickPrivate void LeastSquaresAddTerms(double matrix,double vectors, const double terms,const double results,const size_t rank, const size_t number_vectors) { register ssize_t i, j; for (j=0; j < (ssize_t) rank; j++) { for (i=0; i < (ssize_t) rank; i++) matrix[i][j]+=terms[i]terms[j]; for (i=0; i < (ssize_t) number_vectors; i++) vectors[i][j]+=results[i]terms[j]; } } / %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % M a t r i x T o I m a g e % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % MatrixToImage() returns a matrix as an image. The matrix elements must be % of type double otherwise nonsense is returned. % % The format of the MatrixToImage method is: % % Image MatrixToImage(const MatrixInfo matrix_info, % ExceptionInfo exception) % % A description of each parameter follows: % % o matrix_info: the matrix. % % o exception: return any errors or warnings in this structure. % / MagickExport Image MatrixToImage(const MatrixInfo matrix_info, ExceptionInfo exception) { CacheView image_view; double max_value, min_value, scale_factor, value; Image image; MagickBooleanType status; ssize_t y; assert(matrix_info != (const MatrixInfo ) NULL); assert(matrix_info->signature == MagickCoreSignature); assert(exception != (ExceptionInfo ) NULL); assert(exception->signature == MagickCoreSignature); if (matrix_info->stride < sizeof(double)) return((Image ) NULL); /* Determine range of matrix. / (void) GetMatrixElement(matrix_info,0,0,&value); min_value=value; max_value=value; for (y=0; y < (ssize_t) matrix_info->rows; y++) { register ssize_t x; for (x=0; x < (ssize_t) matrix_info->columns; x++) { if (GetMatrixElement(matrix_info,x,y,&value) == MagickFalse) continue; if (value < min_value) min_value=value; else if (value > max_value) max_value=value; } } if ((min_value == 0.0) && (max_value == 0.0)) scale_factor=0; else if (min_value == max_value) { scale_factor=(double) QuantumRange/min_value; min_value=0; } else scale_factor=(double) QuantumRange/(max_value-min_value); / Convert matrix to image. / image=AcquireImage((ImageInfo ) NULL,exception); image->columns=matrix_info->columns; image->rows=matrix_info->rows; image->colorspace=GRAYColorspace; status=MagickTrue; image_view=AcquireAuthenticCacheView(image,exception); #if defined(MAGICKCORE_OPENMP_SUPPORT) #pragma omp parallel for schedule(static,4) shared(status) \ magick_number_threads(image,image,image->rows,1) #endif for (y=0; y < (ssize_t) image->rows; y++) { double value; register Quantum q; register ssize_t x; if (status == MagickFalse) continue; q=QueueCacheViewAuthenticPixels(image_view,0,y,image->columns,1,exception); if (q == (Quantum ) NULL) { status=MagickFalse; continue; } for (x=0; x < (ssize_t) image->columns; x++) { if (GetMatrixElement(matrix_info,x,y,&value) == MagickFalse) continue; value=scale_factor(value-min_value); q=ClampToQuantum(value); q+=GetPixelChannels(image); } if (SyncCacheViewAuthenticPixels(image_view,exception) == MagickFalse) status=MagickFalse; } image_view=DestroyCacheView(image_view); if (status == MagickFalse) image=DestroyImage(image); return(image); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % N u l l M a t r i x % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % NullMatrix() sets all elements of the matrix to zero. % % The format of the ResetMagickMemory method is: % % MagickBooleanType NullMatrix(MatrixInfo matrix_info) % % A description of each parameter follows: % % o matrix_info: the matrix. % / MagickExport MagickBooleanType NullMatrix(MatrixInfo matrix_info) { register ssize_t x; ssize_t count, y; unsigned char value; assert(matrix_info != (const MatrixInfo ) NULL); assert(matrix_info->signature == MagickCoreSignature); if (matrix_info->type != DiskCache) { (void) ResetMagickMemory(matrix_info->elements,0,(size_t) matrix_info->length); return(MagickTrue); } value=0; (void) lseek(matrix_info->file,0,SEEK_SET); for (y=0; y < (ssize_t) matrix_info->rows; y++) { for (x=0; x < (ssize_t) matrix_info->length; x++) { count=write(matrix_info->file,&value,sizeof(value)); if (count != (ssize_t) sizeof(value)) break; } if (x < (ssize_t) matrix_info->length) break; } return(y < (ssize_t) matrix_info->rows ? MagickFalse : MagickTrue); } / %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % R e l i n q u i s h M a g i c k M a t r i x % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % RelinquishMagickMatrix() frees the previously acquired matrix (array of % pointers to arrays of doubles). % % The format of the RelinquishMagickMatrix method is: % % double RelinquishMagickMatrix(double matrix, % const size_t number_rows) % % A description of each parameter follows: % % o matrix: the matrix to relinquish % % o number_rows: the first dimension of the acquired matrix (number of % pointers) % / MagickExport double RelinquishMagickMatrix(double matrix, const size_t number_rows) { register ssize_t i; if (matrix == (double ) NULL ) return(matrix); for (i=0; i < (ssize_t) number_rows; i++) matrix[i]=(double ) RelinquishMagickMemory(matrix[i]); matrix=(double *) RelinquishMagickMemory(matrix); return(matrix); } / %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % S e t M a t r i x E l e m e n t % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % SetMatrixElement() sets the specifed element in the matrix. % % The format of the SetMatrixElement method is: % % MagickBooleanType SetMatrixElement(const MatrixInfo matrix_info, % const ssize_t x,const ssize_t y,void value) % % A description of each parameter follows: % % o matrix_info: the matrix columns. % % o x: the matrix x-offset. % % o y: the matrix y-offset. % % o value: set the matrix element to this value. % / MagickExport MagickBooleanType SetMatrixElement(const MatrixInfo matrix_info, const ssize_t x,const ssize_t y,const void value) { MagickOffsetType count, i; assert(matrix_info != (const MatrixInfo ) NULL); assert(matrix_info->signature == MagickCoreSignature); i=(MagickOffsetType) ymatrix_info->columns+x; if ((i < 0) \|\| ((MagickSizeType) (imatrix_info->stride) >= matrix_info->length)) return(MagickFalse); if (matrix_info->type != DiskCache) { (void) memcpy((unsigned char ) matrix_info->elements+i matrix_info->stride,value,matrix_info->stride); return(MagickTrue); } count=WriteMatrixElements(matrix_info,imatrix_info->stride, matrix_info->stride,(unsigned char ) value); if (count != (MagickOffsetType) matrix_info->stride) return(MagickFalse); return(MagickTrue); }
3mm.c	/** * 3mm.c: This file was adapted from PolyBench/GPU 1.0 test suite * to run on GPU with OpenMP 4.0 pragmas and OpenCL driver. * * http://www.cse.ohio-state.edu/~pouchet/software/polybench/GPU * * Contacts: Marcio M Pereira <mpereira@ic.unicamp.br> * Rafael Cardoso F Sousa <rafael.cardoso@students.ic.unicamp.br> * Luís Felipe Mattos <ra107822@students.ic.unicamp.br> / #include <assert.h> #include <math.h> #include <stdio.h> #include <stdlib.h> #include <sys/time.h> #include <unistd.h> #ifdef _OPENMP #include <omp.h> #endif #include "BenchmarksUtil.h" // define the error threshold for the results "not matching" #define PERCENT_DIFF_ERROR_THRESHOLD 0.05 / Problem size. / #ifdef RUN_TEST #define SIZE 1100 #elif RUN_BENCHMARK #define SIZE 9600 #else #define SIZE 1000 #endif #define NI SIZE #define NJ SIZE #define NK SIZE #define NL SIZE #define NM SIZE / Can switch DATA_TYPE between float and double / typedef float DATA_TYPE; void init_array(DATA_TYPE A, DATA_TYPE B, DATA_TYPE C, DATA_TYPE D) { int i, j; for (i = 0; i < NI; i++) { for (j = 0; j < NK; j++) { A[i NK + j] = ((DATA_TYPE)i * j) / NI; } } for (i = 0; i < NK; i++) { for (j = 0; j < NJ; j++) { B[i * NJ + j] = ((DATA_TYPE)i * (j + 1)) / NJ; } } for (i = 0; i < NJ; i++) { for (j = 0; j < NM; j++) { C[i * NM + j] = ((DATA_TYPE)i * (j + 3)) / NL; } } for (i = 0; i < NM; i++) { for (j = 0; j < NL; j++) { D[i * NL + j] = ((DATA_TYPE)i * (j + 2)) / NK; } } } int compareResults(DATA_TYPE G, DATA_TYPE G_outputFromGpu) { int i, j, fail; fail = 0; for (i = 0; i < NI; i++) { for (j = 0; j < NL; j++) { if (percentDiff(G[i * NL + j], G_outputFromGpu[i * NL + j]) > PERCENT_DIFF_ERROR_THRESHOLD) { fail++; } } } // print results printf("Non-Matching CPU-GPU Outputs Beyond Error Threshold of %4.2f " "Percent: %d\n", PERCENT_DIFF_ERROR_THRESHOLD, fail); return fail; } void mm3_cpu(DATA_TYPE A, DATA_TYPE B, DATA_TYPE C, DATA_TYPE D, DATA_TYPE E, DATA_TYPE F, DATA_TYPE G) { int i, j, k; / E := AB / for (i = 0; i < NI; i++) { for (j = 0; j < NJ; j++) { E[i * NJ + j] = 0; for (k = 0; k < NK; ++k) { E[i * NJ + j] += A[i * NK + k] * B[k * NJ + j]; } } } /* F := CD / for (i = 0; i < NJ; i++) { for (j = 0; j < NL; j++) { F[i * NL + j] = 0; for (k = 0; k < NM; ++k) { F[i * NL + j] += C[i * NM + k] * D[k * NL + j]; } } } /* G := EF / for (i = 0; i < NI; i++) { for (j = 0; j < NL; j++) { G[i * NL + j] = 0; for (k = 0; k < NJ; ++k) { G[i * NL + j] += E[i * NJ + k] * F[k * NL + j]; } } } } void mm3_OMP(DATA_TYPE A, DATA_TYPE B, DATA_TYPE C, DATA_TYPE D, DATA_TYPE E, DATA_TYPE F, DATA_TYPE G) { / E := AB / #pragma omp target teams map(to : A[ : NI NK], B[ : NK NJ], C[ : NJ NM], D[ : NM NL]) map(from : E[ : NI NJ], F[ : NJ NL], G[ : NI NL]) device(DEVICE_ID) thread_limit(128) { #pragma omp distribute parallel for collapse(2) for (int i = 0; i < NI; i++) { for (int j = 0; j < NJ; j++) { E[i NJ + j] = 0; for (int k = 0; k < NK; ++k) { E[i * NJ + j] += A[i * NK + k] * B[k * NJ + j]; } } } /* F := CD / #pragma omp distribute parallel for collapse(2) for (int i = 0; i < NJ; i++) { for (int j = 0; j < NL; j++) { F[i * NL + j] = 0; for (int k = 0; k < NM; ++k) { F[i * NL + j] += C[i * NM + k] * D[k * NL + j]; } } } /* G := EF / #pragma omp distribute parallel for collapse(2) for (int i = 0; i < NI; i++) { for (int j = 0; j < NL; j++) { G[i * NL + j] = 0; for (int k = 0; k < NJ; ++k) { G[i * NL + j] += E[i * NJ + k] * F[k * NL + j]; } } } } } int main(int argc, char *argv) { double t_start, t_end; int fail = 0; DATA_TYPE A; DATA_TYPE B; DATA_TYPE C; DATA_TYPE D; DATA_TYPE E; DATA_TYPE F; DATA_TYPE G; DATA_TYPE E_outputFromGpu; DATA_TYPE F_outputFromGpu; DATA_TYPE G_outputFromGpu; A = (DATA_TYPE )malloc(NI * NK * sizeof(DATA_TYPE)); B = (DATA_TYPE )malloc(NK NJ * sizeof(DATA_TYPE)); C = (DATA_TYPE )malloc(NJ NM * sizeof(DATA_TYPE)); D = (DATA_TYPE )malloc(NM NL * sizeof(DATA_TYPE)); E = (DATA_TYPE )malloc(NI NJ * sizeof(DATA_TYPE)); F = (DATA_TYPE )malloc(NJ NL * sizeof(DATA_TYPE)); G = (DATA_TYPE )malloc(NI NL * sizeof(DATA_TYPE)); E_outputFromGpu = (DATA_TYPE )calloc(NI NJ, sizeof(DATA_TYPE)); F_outputFromGpu = (DATA_TYPE )calloc(NJ NL, sizeof(DATA_TYPE)); G_outputFromGpu = (DATA_TYPE )calloc(NI NL, sizeof(DATA_TYPE)); fprintf( stdout, "<< Linear Algebra: 3 Matrix Multiplications (E=A.B; F=C.D; G=E.F) >>\n"); init_array(A, B, C, D); t_start = rtclock(); mm3_OMP(A, B, C, D, E_outputFromGpu, F_outputFromGpu, G_outputFromGpu); t_end = rtclock(); fprintf(stdout, "GPU Runtime: %0.6lfs\n", t_end - t_start); #ifdef RUN_TEST t_start = rtclock(); mm3_cpu(A, B, C, D, E, F, G); t_end = rtclock(); fprintf(stdout, "CPU Runtime: %0.6lfs\n", t_end - t_start); fail = compareResults(G, G_outputFromGpu); #endif free(A); free(B); free(C); free(D); free(E); free(F); free(G); free(G_outputFromGpu); return fail; }
GB_binop__isle_uint32.c	//------------------------------------------------------------------------------ // GB_binop: hard-coded functions for each built-in binary operator //------------------------------------------------------------------------------ // SuiteSparse:GraphBLAS, Timothy A. Davis, (c) 2017-2021, All Rights Reserved. // SPDX-License-Identifier: Apache-2.0 //------------------------------------------------------------------------------ // If this file is in the Generated2/ folder, do not edit it // (it is auto-generated from Generator/). #include "GB.h" #ifndef GBCOMPACT #include "GB_emult.h" #include "GB_control.h" #include "GB_ek_slice.h" #include "GB_dense.h" #include "GB_atomics.h" #include "GB_bitmap_assign_methods.h" #include "GB_binop__include.h" // C=binop(A,B) is defined by the following types and operators: // A+B function (eWiseAdd): GB (_AaddB__isle_uint32) // A.B function (eWiseMult): GB (_AemultB_08__isle_uint32) // A.B function (eWiseMult): GB (_AemultB_02__isle_uint32) // A.B function (eWiseMult): GB (_AemultB_04__isle_uint32) // A.B function (eWiseMult): GB (_AemultB_bitmap__isle_uint32) // AD function (colscale): GB (_AxD__isle_uint32) // DA function (rowscale): GB (_DxB__isle_uint32) // C+=B function (dense accum): GB (_Cdense_accumB__isle_uint32) // C+=b function (dense accum): GB (_Cdense_accumb__isle_uint32) // C+=A+B function (dense ewise3): GB ((none)) // C=A+B function (dense ewise3): GB (_Cdense_ewise3_noaccum__isle_uint32) // C=scalar+B GB (_bind1st__isle_uint32) // C=scalar+B' GB (_bind1st_tran__isle_uint32) // C=A+scalar GB (_bind2nd__isle_uint32) // C=A'+scalar GB (_bind2nd_tran__isle_uint32) // C type: uint32_t // A type: uint32_t // A pattern? 0 // B type: uint32_t // B pattern? 0 // BinaryOp: cij = (aij <= bij) #define GB_ATYPE \ uint32_t #define GB_BTYPE \ uint32_t #define GB_CTYPE \ uint32_t // true if the types of A and B are identical #define GB_ATYPE_IS_BTYPE \ 1 // true if the types of C and A are identical #define GB_CTYPE_IS_ATYPE \ 1 // true if the types of C and B are identical #define GB_CTYPE_IS_BTYPE \ 1 // aij = Ax [pA] #define GB_GETA(aij,Ax,pA,A_iso) \ uint32_t aij = GBX (Ax, pA, A_iso) // true if values of A are not used #define GB_A_IS_PATTERN \ 0 \ // bij = Bx [pB] #define GB_GETB(bij,Bx,pB,B_iso) \ uint32_t bij = GBX (Bx, pB, B_iso) // true if values of B are not used #define GB_B_IS_PATTERN \ 0 \ // declare scalar of the same type as C #define GB_CTYPE_SCALAR(t) \ uint32_t t // cij = Ax [pA] #define GB_COPY_A_TO_C(cij,Ax,pA,A_iso) \ cij = GBX (Ax, pA, A_iso) // cij = Bx [pB] #define GB_COPY_B_TO_C(cij,Bx,pB,B_iso) \ cij = GBX (Bx, pB, B_iso) #define GB_CX(p) Cx [p] // binary operator #define GB_BINOP(z,x,y,i,j) \ z = (x <= y) ; // true if the binop must be flipped #define GB_BINOP_FLIP \ 0 // op is second #define GB_OP_IS_SECOND \ 0 // do the numerical phases of GB_add and GB_emult #define GB_PHASE_2_OF_2 // hard-coded loops can be vectorized #define GB_PRAGMA_SIMD_VECTORIZE GB_PRAGMA_SIMD // disable this operator and use the generic case if these conditions hold #define GB_DISABLE \ (GxB_NO_ISLE \|\| GxB_NO_UINT32 \|\| GxB_NO_ISLE_UINT32) //------------------------------------------------------------------------------ // C += A+B, all 3 matrices dense //------------------------------------------------------------------------------ #if 0 // The op must be MIN, MAX, PLUS, MINUS, RMINUS, TIMES, DIV, or RDIV. void GB ((none)) ( GrB_Matrix C, const GrB_Matrix A, const GrB_Matrix B, const int nthreads ) { #include "GB_dense_ewise3_accum_template.c" } #endif //------------------------------------------------------------------------------ // C = A+B, all 3 matrices dense //------------------------------------------------------------------------------ void GB (_Cdense_ewise3_noaccum__isle_uint32) ( GrB_Matrix C, const GrB_Matrix A, const GrB_Matrix B, const int nthreads ) { #include "GB_dense_ewise3_noaccum_template.c" } //------------------------------------------------------------------------------ // C += B, accumulate a sparse matrix into a dense matrix //------------------------------------------------------------------------------ GrB_Info GB (_Cdense_accumB__isle_uint32) ( GrB_Matrix C, const GrB_Matrix B, const int64_t B_ek_slicing, const int B_ntasks, const int B_nthreads ) { #if GB_DISABLE return (GrB_NO_VALUE) ; #else { #include "GB_dense_subassign_23_template.c" } return (GrB_SUCCESS) ; #endif } //------------------------------------------------------------------------------ // C += b, accumulate a scalar into a dense matrix //------------------------------------------------------------------------------ GrB_Info GB (_Cdense_accumb__isle_uint32) ( GrB_Matrix C, const GB_void p_bwork, const int nthreads ) { #if GB_DISABLE return (GrB_NO_VALUE) ; #else { // get the scalar b for C += b, of type uint32_t uint32_t bwork = (((uint32_t ) p_bwork)) ; #include "GB_dense_subassign_22_template.c" return (GrB_SUCCESS) ; } return (GrB_SUCCESS) ; #endif } //------------------------------------------------------------------------------ // C = AD, column scale with diagonal D matrix //------------------------------------------------------------------------------ GrB_Info GB (_AxD__isle_uint32) ( GrB_Matrix C, const GrB_Matrix A, const GrB_Matrix D, const int64_t A_ek_slicing, const int A_ntasks, const int A_nthreads ) { #if GB_DISABLE return (GrB_NO_VALUE) ; #else uint32_t restrict Cx = (uint32_t ) C->x ; #include "GB_AxB_colscale_template.c" return (GrB_SUCCESS) ; #endif } //------------------------------------------------------------------------------ // C = DB, row scale with diagonal D matrix //------------------------------------------------------------------------------ GrB_Info GB (_DxB__isle_uint32) ( GrB_Matrix C, const GrB_Matrix D, const GrB_Matrix B, int nthreads ) { #if GB_DISABLE return (GrB_NO_VALUE) ; #else uint32_t restrict Cx = (uint32_t ) C->x ; #include "GB_AxB_rowscale_template.c" return (GrB_SUCCESS) ; #endif } //------------------------------------------------------------------------------ // eWiseAdd: C=A+B, C<M>=A+B, C<!M>=A+B //------------------------------------------------------------------------------ GrB_Info GB (_AaddB__isle_uint32) ( GrB_Matrix C, const int C_sparsity, const GrB_Matrix M, const bool Mask_struct, const bool Mask_comp, const GrB_Matrix A, const GrB_Matrix B, const bool is_eWiseUnion, const GB_void alpha_scalar_in, const GB_void beta_scalar_in, const bool Ch_is_Mh, const int64_t restrict C_to_M, const int64_t restrict C_to_A, const int64_t restrict C_to_B, const GB_task_struct restrict TaskList, const int C_ntasks, const int C_nthreads, GB_Context Context ) { #if GB_DISABLE return (GrB_NO_VALUE) ; #else GB_WERK_DECLARE (M_ek_slicing, int64_t) ; GB_WERK_DECLARE (A_ek_slicing, int64_t) ; GB_WERK_DECLARE (B_ek_slicing, int64_t) ; uint32_t alpha_scalar ; uint32_t beta_scalar ; if (is_eWiseUnion) { alpha_scalar = (((uint32_t ) alpha_scalar_in)) ; beta_scalar = (((uint32_t ) beta_scalar_in )) ; } #include "GB_add_template.c" GB_FREE_WORKSPACE ; return (GrB_SUCCESS) ; #endif } //------------------------------------------------------------------------------ // eWiseMult: C=A.B, C<M>=A.B, or C<M!>=A.B where C is sparse/hyper //------------------------------------------------------------------------------ GrB_Info GB (_AemultB_08__isle_uint32) ( GrB_Matrix C, const int C_sparsity, const int ewise_method, const GrB_Matrix M, const bool Mask_struct, const bool Mask_comp, const GrB_Matrix A, const GrB_Matrix B, const int64_t restrict C_to_M, const int64_t restrict C_to_A, const int64_t restrict C_to_B, const GB_task_struct restrict TaskList, const int C_ntasks, const int C_nthreads, GB_Context Context ) { #if GB_DISABLE return (GrB_NO_VALUE) ; #else #include "GB_emult_08_meta.c" return (GrB_SUCCESS) ; #endif } //------------------------------------------------------------------------------ // eWiseMult: C<#> = A.B when A is sparse/hyper and B is bitmap/full //------------------------------------------------------------------------------ GrB_Info GB (_AemultB_02__isle_uint32) ( GrB_Matrix C, const GrB_Matrix M, const bool Mask_struct, const bool Mask_comp, const GrB_Matrix A, const GrB_Matrix B, const bool flipxy, const int64_t restrict Cp_kfirst, const int64_t A_ek_slicing, const int A_ntasks, const int A_nthreads ) { #if GB_DISABLE return (GrB_NO_VALUE) ; #else #if GB_BINOP_FLIP // The operator is not commutative, and does not have a flipped // variant. For example z=atan2(y,x). if (flipxy) { // use fmult(y,x) #undef GB_FLIPPED #define GB_FLIPPED 1 #include "GB_emult_02_template.c" } else { // use fmult(x,y) #undef GB_FLIPPED #define GB_FLIPPED 0 #include "GB_emult_02_template.c" } #else // No need to handle the flip: the operator is either commutative, or // has been handled by changing z=div(y,x) to z=rdiv(x,y) for example. #undef GB_FLIPPED #define GB_FLIPPED 0 #include "GB_emult_02_template.c" #endif return (GrB_SUCCESS) ; #endif } //------------------------------------------------------------------------------ // eWiseMult: C<M> = A.B, M sparse/hyper, A and B bitmap/full //------------------------------------------------------------------------------ GrB_Info GB (_AemultB_04__isle_uint32) ( GrB_Matrix C, const GrB_Matrix M, const bool Mask_struct, const GrB_Matrix A, const GrB_Matrix B, const int64_t restrict Cp_kfirst, const int64_t M_ek_slicing, const int M_ntasks, const int M_nthreads ) { #if GB_DISABLE return (GrB_NO_VALUE) ; #else #include "GB_emult_04_template.c" return (GrB_SUCCESS) ; #endif } //------------------------------------------------------------------------------ // eWiseMult: C=A.B, C<M>=A.B, C<!M>=A.B where C is bitmap //------------------------------------------------------------------------------ GrB_Info GB (_AemultB_bitmap__isle_uint32) ( GrB_Matrix C, const int ewise_method, const GrB_Matrix M, const bool Mask_struct, const bool Mask_comp, const GrB_Matrix A, const GrB_Matrix B, const int64_t M_ek_slicing, const int M_ntasks, const int M_nthreads, const int C_nthreads, GB_Context Context ) { #if GB_DISABLE return (GrB_NO_VALUE) ; #else #include "GB_bitmap_emult_template.c" return (GrB_SUCCESS) ; #endif } //------------------------------------------------------------------------------ // Cx = op (x,Bx): apply a binary operator to a matrix with scalar bind1st //------------------------------------------------------------------------------ GrB_Info GB (_bind1st__isle_uint32) ( GB_void Cx_output, // Cx and Bx may be aliased const GB_void x_input, const GB_void Bx_input, const int8_t restrict Bb, int64_t bnz, int nthreads ) { #if GB_DISABLE return (GrB_NO_VALUE) ; #else uint32_t Cx = (uint32_t ) Cx_output ; uint32_t x = (((uint32_t ) x_input)) ; uint32_t Bx = (uint32_t ) Bx_input ; int64_t p ; #pragma omp parallel for num_threads(nthreads) schedule(static) for (p = 0 ; p < bnz ; p++) { if (!GBB (Bb, p)) continue ; uint32_t bij = GBX (Bx, p, false) ; Cx [p] = (x <= bij) ; } return (GrB_SUCCESS) ; #endif } //------------------------------------------------------------------------------ // Cx = op (Ax,y): apply a binary operator to a matrix with scalar bind2nd //------------------------------------------------------------------------------ GrB_Info GB (_bind2nd__isle_uint32) ( GB_void Cx_output, // Cx and Ax may be aliased const GB_void Ax_input, const GB_void y_input, const int8_t restrict Ab, int64_t anz, int nthreads ) { #if GB_DISABLE return (GrB_NO_VALUE) ; #else int64_t p ; uint32_t Cx = (uint32_t ) Cx_output ; uint32_t Ax = (uint32_t ) Ax_input ; uint32_t y = (((uint32_t ) y_input)) ; #pragma omp parallel for num_threads(nthreads) schedule(static) for (p = 0 ; p < anz ; p++) { if (!GBB (Ab, p)) continue ; uint32_t aij = GBX (Ax, p, false) ; Cx [p] = (aij <= y) ; } return (GrB_SUCCESS) ; #endif } //------------------------------------------------------------------------------ // C = op (x, A'): transpose and apply a binary operator //------------------------------------------------------------------------------ // cij = op (x, aij), no typecasting (in spite of the macro name) #undef GB_CAST_OP #define GB_CAST_OP(pC,pA) \ { \ uint32_t aij = GBX (Ax, pA, false) ; \ Cx [pC] = (x <= aij) ; \ } GrB_Info GB (_bind1st_tran__isle_uint32) ( GrB_Matrix C, const GB_void x_input, const GrB_Matrix A, int64_t restrict Workspaces, const int64_t restrict A_slice, int nworkspaces, int nthreads ) { // GB_unop_transpose.c uses GB_ATYPE, but A is // the 2nd input to binary operator z=f(x,y). #undef GB_ATYPE #define GB_ATYPE \ uint32_t #if GB_DISABLE return (GrB_NO_VALUE) ; #else uint32_t x = (((const uint32_t ) x_input)) ; #include "GB_unop_transpose.c" return (GrB_SUCCESS) ; #endif #undef GB_ATYPE #define GB_ATYPE \ uint32_t } //------------------------------------------------------------------------------ // C = op (A', y): transpose and apply a binary operator //------------------------------------------------------------------------------ // cij = op (aij, y), no typecasting (in spite of the macro name) #undef GB_CAST_OP #define GB_CAST_OP(pC,pA) \ { \ uint32_t aij = GBX (Ax, pA, false) ; \ Cx [pC] = (aij <= y) ; \ } GrB_Info GB (_bind2nd_tran__isle_uint32) ( GrB_Matrix C, const GrB_Matrix A, const GB_void y_input, int64_t restrict Workspaces, const int64_t restrict A_slice, int nworkspaces, int nthreads ) { #if GB_DISABLE return (GrB_NO_VALUE) ; #else uint32_t y = (((const uint32_t *) y_input)) ; #include "GB_unop_transpose.c" return (GrB_SUCCESS) ; #endif } #endif
sgeswp.c	/** * * @file * * PLASMA is a software package provided by: * University of Tennessee, US, * University of Manchester, UK. * * @generated from /home/luszczek/workspace/plasma/bitbucket/plasma/compute/zgeswp.c, normal z -> s, Fri Sep 28 17:38:05 2018 * / #include "plasma.h" #include "plasma_async.h" #include "plasma_context.h" #include "plasma_descriptor.h" #include "plasma_internal.h" #include "plasma_tuning.h" #include "plasma_types.h" /***************************************************************************/ int plasma_sgeswp(plasma_enum_t colrow, int m, int n, float pA, int lda, int ipiv, int incx) { // Get PLASMA context. plasma_context_t plasma = plasma_context_self(); if (plasma == NULL) { plasma_error("PLASMA not initialized"); return PlasmaErrorNotInitialized; } // Check input arguments. if ((colrow != PlasmaColumnwise) && (colrow != PlasmaRowwise)) { plasma_error("illegal value of colrow"); return -1; } if (m < 0) { plasma_error("illegal value of m"); return -2; } if (n < 0) { plasma_error("illegal value of n"); return -3; } if (lda < imax(1, m)) { plasma_error("illegal value of lda"); return -5; } // quick return if (imin(n, m) == 0) return PlasmaSuccess; // Tune parameters. if (plasma->tuning) plasma_tune_geswp(plasma, PlasmaRealFloat, m, n); // Set tiling parameters. int nb = plasma->nb; // Create tile matrices. plasma_desc_t A; int retval; retval = plasma_desc_general_create(PlasmaRealFloat, nb, nb, m, n, 0, 0, m, n, &A); if (retval != PlasmaSuccess) { plasma_error("plasma_general_desc_create() failed"); return retval; } // Initialize sequence. plasma_sequence_t sequence; retval = plasma_sequence_init(&sequence); // Initialize request. plasma_request_t request; retval = plasma_request_init(&request); // asynchronous block #pragma omp parallel #pragma omp master { // Translate to tile layout. plasma_omp_sge2desc(pA, lda, A, &sequence, &request); // Call tile async function. plasma_omp_sgeswp(colrow, A, ipiv, incx, &sequence, &request); // Translate back to LAPACK layout. plasma_omp_sdesc2ge(A, pA, lda, &sequence, &request); } // implicit synchronization // Free matrices in tile layout. plasma_desc_destroy(&A); // Return status. int status = sequence.status; return status; } /*****************************************************************************/ void plasma_omp_sgeswp(plasma_enum_t colrow, plasma_desc_t A, int ipiv, int incx, plasma_sequence_t sequence, plasma_request_t request) { // Get PLASMA context. plasma_context_t *plasma = plasma_context_self(); if (plasma == NULL) { plasma_error("PLASMA not initialized"); plasma_request_fail(sequence, request, PlasmaErrorIllegalValue); return; } // Check input arguments. if ((colrow != PlasmaColumnwise) && (colrow != PlasmaRowwise)) { plasma_error("illegal value of colrow"); plasma_request_fail(sequence, request, PlasmaErrorIllegalValue); return; } if (plasma_desc_check(A) != PlasmaSuccess) { plasma_error("invalid A"); plasma_request_fail(sequence, request, PlasmaErrorIllegalValue); return; } if (sequence == NULL) { plasma_error("NULL sequence"); plasma_request_fail(sequence, request, PlasmaErrorIllegalValue); return; } if (request == NULL) { plasma_error("NULL request"); plasma_request_fail(sequence, request, PlasmaErrorIllegalValue); return; } // quick return if (imin(A.m, A.n) == 0) return; // Call the parallel function. plasma_psgeswp(colrow, A, ipiv, incx, sequence, request); }
lloyds_par16.c	#include <stdio.h> #include <stdlib.h> #include <math.h> #include <time.h> #include <stdbool.h> #include <omp.h> #include "csvparser.h" void vector_init(double a, int length) { for (int i = 0; i < length; i++) { a[i] = 0; } } void vector_copy(double dst, double src, int length) { for (int i = 0; i < length; i++) { dst[i] = src[i]; } } void vector_add(double dst, double a, double b, int length) { for (int i = 0; i < length; i++) { dst[i] = a[i] + b[i]; } } void vector_elementwise_avg(double dst, double a, int denominator, int length) { for (int i = 0; i < length; i++) { dst[i] = a[i] / denominator; } } // Program should take K, a data set (.csv), a delimiter, // a binary flag data_contains_header, and a binary flag to drop labels int main(int argc, char argv[]){ // Seed for consistent cluster center selection // In a working implementation, seeding would be variable (e.g. time(NULL)) srand(111); CsvParser reader; CsvRow row; int i,j; if(argc < 6){ printf("Incorrect number of args. Should be 5, received %d\n", argc - 1); exit(1); } int K = atoi(argv[1]); char data_fp = argv[2]; char delimiter = argv[3]; int has_header_row = atoi(argv[4]); int drop_labels = atoi(argv[5]); // Take in data set reader = CsvParser_new(data_fp, delimiter, has_header_row); // Get number of columns row = CsvParser_getRow(reader); int num_cols = CsvParser_getNumFields(row); CsvParser_destroy_row(row); if (drop_labels){ num_cols--; } // Get number of rows like lazy people int num_rows = 1; while ((row = CsvParser_getRow(reader))){ num_rows++; CsvParser_destroy_row(row); } // Torch the CsvParser and start again so we can read data in. CsvParser_destroy(reader); reader = CsvParser_new(data_fp, delimiter, has_header_row); double data_matrix = malloc(num_rows sizeof(double )); for (int i = 0; i < num_rows; i++) { data_matrix[i] = malloc(num_cols sizeof(double)); } int row_index = 0; while ((row = CsvParser_getRow(reader))){ const char *row_fields = CsvParser_getFields(row); for (int col_index = 0; col_index < num_cols; col_index++) { data_matrix[row_index][col_index] = atof(row_fields[col_index]); } CsvParser_destroy_row(row); row_index++; } CsvParser_destroy(reader); // Initialize some cluster centers from random rows in our data // Given the fact that we will usually have way more rows than centers, we can // probably just roll a number and reroll if we already rolled it. Collisions // should be relatively infrequent bool collided; double centers[K][num_cols]; if (argc == 7) { int center_indices[3] = {12, 67, 106}; for (i = 0; i < K; i ++) { vector_copy(centers[i], data_matrix[center_indices[i]], num_cols); } } else { for (i = 0; i < K; i++) { int center_indices[K]; collided = true; while (collided) { center_indices[i] = rand() % num_rows; collided = false; for (j = 0; j < i; j++) { if (center_indices[j] == center_indices[i]) { collided = true; break; } } vector_copy(centers[i], data_matrix[center_indices[i]], num_cols); } } } printf("Initial cluster centers:\n"); for (int i = 0; i < K; i++) { for (int j = 0; j < num_cols; j++) { printf("%f ", centers[i][j]); } printf("\n"); } printf("\n"); int num_iterations = 0; int clusterings = calloc(num_rows, sizeof(int)); bool changes; double tstart = omp_get_wtime(); while (1) { // Assign points to cluster centers changes = false; omp_set_num_threads(16); int center, observation, new_center, col; double idx_diff, current_diff, best_diff; #pragma omp parallel for \ private(center, observation, idx_diff, current_diff, best_diff, new_center, col) \ shared(num_rows, K, data_matrix, centers) for (observation = 0; observation < num_rows; observation++) { best_diff = INFINITY; for (center = 0; center < K; center++) { current_diff = 0; for (col = 0; col < num_cols; col++) { idx_diff = data_matrix[observation][col] - centers[center][col]; current_diff += idx_diff * idx_diff; } if (current_diff < best_diff) { best_diff = current_diff; new_center = center; } } if (clusterings[observation] != new_center) { // NOTE: There is an acceptable data race on changes. Threads only ever // set it to true; lost updates are inconsequential. No need to slow // things down for safety. changes = true; clusterings[observation] = new_center; } } // If we didn't change any cluster assignments, we're at convergence if (!changes) { break; } num_iterations++; // Find cluster means and reassign centers int cluster_index, element, elements_in_cluster; double cluster_means[num_cols]; #pragma omp parallel for \ private(cluster_index, element, elements_in_cluster, cluster_means) \ shared(num_rows, clusterings, data_matrix, K) for (cluster_index = 0; cluster_index < K; cluster_index++) { elements_in_cluster = 0; vector_init(cluster_means, num_cols); // Aggregate in-cluster values we can use to take the clusterings mean for (element = 0; element < num_rows; element++) { if (clusterings[element] == cluster_index) { vector_add(cluster_means, cluster_means, data_matrix[element], num_cols); elements_in_cluster++; } } // Finish calculating cluster mean, and overwrite centers with the new value vector_elementwise_avg(cluster_means, cluster_means, elements_in_cluster, num_cols); vector_copy(centers[cluster_index], cluster_means, num_cols); } } double tend = omp_get_wtime(); printf("\nFinal cluster centers:\n"); for (int i = 0; i < K; i++) { for (int j = 0; j < num_cols; j++) { printf("%f ", centers[i][j]); } printf("\n"); } printf("\nNum iterations: %d\n", num_iterations); printf("Time taken for %d clusters: %f seconds\n", K, tend - tstart); for (int i = 0; i < num_rows; i++) { free(data_matrix[i]); } free(data_matrix); free(clusterings); exit(0); }
ChMatrix.h	// ============================================================================= // PROJECT CHRONO - http://projectchrono.org // // Copyright (c) 2014 projectchrono.org // All rights reserved. // // Use of this source code is governed by a BSD-style license that can be found // in the LICENSE file at the top level of the distribution and at // http://projectchrono.org/license-chrono.txt. // // ============================================================================= // Authors: Alessandro Tasora, Radu Serban // ============================================================================= #ifndef CHMATRIX_H #define CHMATRIX_H #include <immintrin.h> #include "chrono/core/ChCoordsys.h" #include "chrono/core/ChException.h" #include "chrono/ChConfig.h" #include "chrono/serialization/ChArchive.h" #include "chrono/serialization/ChArchiveAsciiDump.h" namespace chrono { // // FAST MACROS TO SPEEDUP CODE // #define Set33Element(a, b, val) SetElementN(((a * 3) + (b)), val) #define Get33Element(a, b) GetElementN((a * 3) + (b)) #define Set34Element(a, b, val) SetElementN(((a * 4) + (b)), val) #define Get34Element(a, b) GetElementN((a * 4) + (b)) #define Set34Row(ma, a, val0, val1, val2, val3) \ ma.SetElementN((a * 4), val0); \ ma.SetElementN((a * 4) + 1, val1); \ ma.SetElementN((a * 4) + 2, val2); \ ma.SetElementN((a * 4) + 3, val3); #define Set44Element(a, b, val) SetElementN(((a * 4) + (b)), val) #define Get44Element(a, b) GetElementN((a * 4) + (b)) // forward declaration template <class Real = double> class ChMatrixDynamic; /// /// ChMatrix: /// /// A base class for matrix objects (tables of NxM numbers). /// To access elements, the indexes start from zero, and /// you must indicate first row, then column, that is: m(2,4) /// means the element at 3rd row, 5th column. /// This is an abstract class, so you cannot instantiate /// objects from it: you must rather create matrices using the /// specialized child classes like ChMatrixDynamic, ChMatrixNM, /// ChMatrix33 and so on; all of them have this same base class. /// Warning: for optimization reasons, not all functions will /// check about boundaries of element indexes and matrix sizes (in /// some cases, if sizes are wrong, debug asserts are used). /// /// Further info at the @ref mathematical_objects manual page. template <class Real = double> class ChMatrix { protected: // // DATA // int rows; int columns; Real* address; public: // // CONSTRUCTORS (none - abstract class that must be implemented with child classes) // virtual ~ChMatrix() {} // // OPERATORS OVERLOADING // /// Parenthesis () operator, to access a single element of the matrix, by /// supplying the row and the column (indexes start from 0). /// For example: m(3,5) gets the element at the 4th row, 6th column. /// Value is returned by reference, so it can be modified, like in m(1,2)=10. Real& operator()(const int row, const int col) { assert(row >= 0 && col >= 0 && row < rows && col < columns); return ((address + col + (row columns))); } const Real& operator()(const int row, const int col) const { assert(row >= 0 && col >= 0 && row < rows && col < columns); return ((address + col + (row columns))); } /// Parenthesis () operator, to access a single element of the matrix, by /// supplying the ordinal of the element (indexes start from 0). /// For example: m(3) gets the 4th element, counting row by row. /// Mostly useful if the matrix is Nx1 sized (i.e. a N-element vector). /// Value is returned by reference, so it can be modified, like in m(1,2)=10. Real& operator()(const int el) { assert(el >= 0 && el < rows * columns); return ((address + el)); } const Real& operator()(const int el) const { assert(el >= 0 && el < rows columns); return ((address + el)); } /// The [] operator returns the address of the n-th row. This is mostly /// for compatibility with old matrix programming styles (2d array-like) /// where to access an element at row i, column j, one can write mymatrix[i][j]. Real operator[](const int row) { assert(row >= 0 && row < rows); return ((address + (row * columns))); } const Real* operator[](const int row) const { assert(row >= 0 && row < rows); return ((address + (row * columns))); } /// Multiplies this matrix by a factor, in place ChMatrix<Real>& operator=(const Real factor) { MatrScale(factor); return this; } /// Increments this matrix by another matrix, in place template <class RealB> ChMatrix<Real>& operator+=(const ChMatrix<RealB>& matbis) { MatrInc(matbis); return this; } /// Decrements this matrix by another matrix, in place template <class RealB> ChMatrix<Real>& operator-=(const ChMatrix<RealB>& matbis) { MatrDec(matbis); return this; } /// Matrices are equal? bool operator==(const ChMatrix<Real>& other) { return Equals(other); } /// Matrices are not equal? bool operator!=(const ChMatrix<Real>& other) { return !Equals(other); } /// Assignment operator ChMatrix<Real>& operator=(const ChMatrix<Real>& matbis) { if (&matbis != this) CopyFromMatrix(matbis); return this; } template <class RealB> ChMatrix<Real>& operator=(const ChMatrix<RealB>& matbis) { CopyFromMatrix(matbis); return this; } // // FUNCTIONS // /// Sets the element at row,col position. Indexes start with zero. void SetElement(int row, int col, Real elem) { assert(row >= 0 && col >= 0 && row < rows && col < columns); // boundary checks (address + col + (row columns)) = elem; } /// Gets the element at row,col position. Indexes start with zero. /// The return value is a copy of original value. Use Element() instead if you /// want to access directly by reference the original element. Real GetElement(int row, int col) { assert(row >= 0 && col >= 0 && row < rows && col < columns); // boundary checks return ((address + col + (row columns))); } Real GetElement(int row, int col) const { assert(row >= 0 && col >= 0 && row < rows && col < columns); // boundary checks return ((address + col + (row columns))); } /// Sets the Nth element, counting row after row. void SetElementN(int index, Real elem) { assert(index >= 0 && index < (rows * columns)); // boundary checks (address + index) = elem; } /// Gets the Nth element, counting row after row. Real GetElementN(int index) { assert(index >= 0 && index < (rows columns)); return ((address + index)); } const Real GetElementN(int index) const { assert(index >= 0 && index < (rows columns)); return ((address + index)); } /// Access a single element of the matrix, by /// supplying the row and the column (indexes start from 0). /// Value is returned by reference, so it can be modified, like in m.Element(1,2)=10. Real& Element(int row, int col) { assert(row >= 0 && col >= 0 && row < rows && col < columns); return ((address + col + (row * columns))); } const Real& Element(int row, int col) const { assert(row >= 0 && col >= 0 && row < rows && col < columns); return ((address + col + (row columns))); } /// Access a single element of the matrix, the Nth element, counting row after row. /// Value is returned by reference, so it can be modified, like in m.Element(5)=10. Real& ElementN(int index) { assert(index >= 0 && index < (rows * columns)); return ((address + index)); } const Real& ElementN(int index) const { assert(index >= 0 && index < (rows columns)); return ((address + index)); } /// Access directly the "Real address" buffer. Warning! this is a low level /// function, it should be used in rare cases, if really needed! Real* GetAddress() { return address; } const Real* GetAddress() const { return address; } /// Gets the number of rows int GetRows() const { return rows; } /// Gets the number of columns int GetColumns() const { return columns; } /// Reallocate memory for a new size. VIRTUAL! Must be implemented by child classes! virtual void Resize(int nrows, int ncols) {} /// Swaps the columns a and b void SwapColumns(int a, int b) { Real temp; for (int i = 0; i < rows; i++) { temp = GetElement(i, a); SetElement(i, a, GetElement(i, b)); SetElement(i, b, temp); } } /// Swap the rows a and b void SwapRows(int a, int b) { Real temp; for (int i = 0; i < columns; i++) { temp = GetElement(a, i); SetElement(a, i, GetElement(b, i)); SetElement(b, i, temp); } } /// Fill the diagonal elements, given a sample. /// Note that the matrix must already be square (no check for /// rectangular matrices!), and the extra-diagonal elements are /// not modified -this function does not set them to 0- void FillDiag(Real sample) { for (int i = 0; i < rows; ++i) SetElement(i, i, sample); } /// Fill the matrix with the same value in all elements void FillElem(Real sample) { for (int i = 0; i < rows * columns; ++i) SetElementN(i, sample); } /// Fill the matrix with random float numbers, falling within the /// "max"/"min" range. void FillRandom(Real max, Real min) { for (int i = 0; i < rows * columns; ++i) SetElementN(i, min + (Real)ChRandom() * (max - min)); } /// Resets the matrix to zero (warning: simply sets memory to 0 bytes!) void Reset() { // SetZero(rowscolumns); //memset(address, 0, sizeof(Real) rows * columns); for (int i = 0; i < rows * columns; ++i) this->address[i] = 0; } /// Reset to zeroes and (if needed) changes the size to have row and col void Reset(int nrows, int ncols) { Resize(nrows, ncols); // SetZero(rowscolumns); //memset(address, 0, sizeof(Real) rows * columns); for (int i = 0; i < rows * columns; ++i) this->address[i] = 0; } /// Reset to identity matrix (ones on diagonal, zero elsewhere) void SetIdentity() { Reset(); FillDiag(1.0); } /// Copy a matrix "matra" into this matrix. Note that /// the destination matrix will be resized if necessary. template <class RealB> void CopyFromMatrix(const ChMatrix<RealB>& matra) { Resize(matra.GetRows(), matra.GetColumns()); // ElementsCopy(address, matra.GetAddress(), rowscolumns); // memcpy (address, matra.address, (sizeof(Real) rows * columns)); for (int i = 0; i < rows * columns; ++i) address[i] = (Real)matra.GetAddress()[i]; } /// Copy the transpose of matrix "matra" into this matrix. Note that /// the destination matrix will be resized if necessary. template <class RealB> void CopyFromMatrixT(const ChMatrix<RealB>& matra) { Resize(matra.GetColumns(), matra.GetRows()); for (int i = 0; i < matra.GetRows(); ++i) for (int j = 0; j < matra.GetColumns(); ++j) SetElement(j, i, (Real)matra.Element(i, j)); } /// Copy the transposed upper triangular part of "matra" in the lower triangular /// part of this matrix. (matra must be square) /// Note that the destination matrix will be resized if necessary. template <class RealB> // _______ // void CopyTUpMatrix(const ChMatrix<RealB>& matra) // \ \| \|\ // { // \ A'\| ---> \| \ // Resize(matra.GetRows(), matra.GetColumns()); // \ \| \|this\ // for (int i = 0; i < matra.GetRows(); i++) { // \\| \|______\ // for (int j = 0; j < matra.GetRows(); j++) SetElement(j, i, (Real)matra.GetElement(i, j)); } } /// Copy the transposed lower triangulat part of "matra" in the upper triangular /// part of this matrix. (matra must be square) /// Note that the destination matrix will be resized if necessary. template <class RealB> // _______ // void CopyTLwMatrix(const ChMatrix<RealB>& matra) // \|\ \ \| // { // \| \ ---> \this\| // Resize(matra.GetRows(), matra.GetColumns()); // \|A' \ \ \| // for (int i = 0; i < matra.GetRows(); i++) { // \|______\ \\| // for (int j = 0; j < matra.GetRows(); j++) SetElement(i, j, (Real)matra.GetElement(j, i)); } } // // STREAMING // /// Method to allow serialization of transient data in archives. virtual void ArchiveOUT(ChArchiveOut& marchive) { // suggested: use versioning marchive.VersionWrite(1); // stream out all member data marchive << make_ChNameValue("rows", rows); marchive << make_ChNameValue("columns", columns); // custom output of matrix data as array if (ChArchiveAsciiDump* mascii = dynamic_cast<ChArchiveAsciiDump>(&marchive)) { // CUSTOM row x col 'intuitive' table-like log when using ChArchiveAsciiDump: for (int i = 0; i < rows; i++) { mascii->indent(); for (int j = 0; j < columns; j++) { mascii->GetStream()->operator<<(Element(i, j)); mascii->GetStream()->operator<<(", "); } mascii->GetStream()->operator<<("\n"); } } else { // NORMAL array-based serialization: int tot_elements = GetRows() GetColumns(); marchive.out_array_pre("data", tot_elements, typeid(Real).name()); for (int i = 0; i < tot_elements; i++) { marchive << CHNVP(ElementN(i), ""); marchive.out_array_between(tot_elements, typeid(Real).name()); } marchive.out_array_end(tot_elements, typeid(Real).name()); } } /// Method to allow de serialization of transient data from archives. virtual void ArchiveIN(ChArchiveIn& marchive) { // suggested: use versioning int version = marchive.VersionRead(); // stream in all member data int m_row, m_col; marchive >> make_ChNameValue("rows", m_row); marchive >> make_ChNameValue("columns", m_col); Reset(m_row, m_col); // custom input of matrix data as array size_t tot_elements = GetRows() * GetColumns(); marchive.in_array_pre("data", tot_elements); for (int i = 0; i < tot_elements; i++) { marchive >> CHNVP(ElementN(i)); marchive.in_array_between("data"); } marchive.in_array_end("data"); } /// Method to allow serializing transient data into in ascii /// as a readable item, for example "chrono::GetLog() << myobject;" /// *OBSOLETE* void StreamOUT(ChStreamOutAscii& mstream) { mstream << "\n" << "Matrix " << GetRows() << " rows, " << GetColumns() << " columns." << "\n"; for (int i = 0; i < ChMin(GetRows(), 8); i++) { for (int j = 0; j < ChMin(GetColumns(), 8); j++) mstream << GetElement(i, j) << " "; if (GetColumns() > 8) mstream << "..."; mstream << "\n"; } if (GetRows() > 8) mstream << "... \n\n"; } /// Method to allow serializing transient data into an ascii stream (ex. a file) /// as a Matlab .dat file (all numbers in a row, separated by space, then CR) void StreamOUTdenseMatlabFormat(ChStreamOutAscii& mstream) { for (int ii = 0; ii < this->GetRows(); ii++) { for (int jj = 0; jj < this->GetColumns(); jj++) { mstream << this->GetElement(ii, jj); if (jj < (this->GetColumns() - 1)) mstream << " "; } mstream << "\n"; } } // // MATH MEMBER FUNCTIONS. // For speed reasons, sometimes size checking of operands is left to the user! // /// Changes the sign of all the elements of this matrix, in place. void MatrNeg() { for (int nel = 0; nel < rows * columns; ++nel) ElementN(nel) = -ElementN(nel); } /// Sum two matrices, and stores the result in "this" matrix: [this]=[A]+[B]. template <class RealB, class RealC> void MatrAdd(const ChMatrix<RealB>& matra, const ChMatrix<RealC>& matrb) { assert(matra.GetColumns() == matrb.GetColumns() && matra.rows == matrb.GetRows()); assert(this->columns == matrb.GetColumns() && this->rows == matrb.GetRows()); for (int nel = 0; nel < rows * columns; ++nel) ElementN(nel) = (Real)(matra.ElementN(nel) + matrb.ElementN(nel)); } /// Subtract two matrices, and stores the result in "this" matrix: [this]=[A]-[B]. template <class RealB, class RealC> void MatrSub(const ChMatrix<RealB>& matra, const ChMatrix<RealC>& matrb) { assert(matra.GetColumns() == matrb.GetColumns() && matra.rows == matrb.GetRows()); assert(this->columns == matrb.GetColumns() && this->rows == matrb.GetRows()); for (int nel = 0; nel < rows * columns; ++nel) ElementN(nel) = (Real)(matra.ElementN(nel) - matrb.ElementN(nel)); } /// Increments this matrix with another matrix A, as: [this]+=[A] template <class RealB> void MatrInc(const ChMatrix<RealB>& matra) { assert(matra.GetColumns() == columns && matra.GetRows() == rows); for (int nel = 0; nel < rows * columns; ++nel) ElementN(nel) += (Real)matra.ElementN(nel); } /// Decrements this matrix with another matrix A, as: [this]-=[A] template <class RealB> void MatrDec(const ChMatrix<RealB>& matra) { assert(matra.GetColumns() == columns && matra.GetRows() == rows); for (int nel = 0; nel < rows * columns; ++nel) ElementN(nel) -= (Real)matra.ElementN(nel); } /// Scales a matrix, multiplying all elements by a constant value: [this]=f void MatrScale(Real factor) { for (int nel = 0; nel < rows columns; ++nel) ElementN(nel) = factor; } /// Scales a matrix, multiplying all element by all oter elements of /// matra (it is not the classical matrix multiplication!) template <class RealB> void MatrScale(const ChMatrix<RealB>& matra) { assert(matra.GetColumns() == columns && matra.GetRows() == rows); for (int nel = 0; nel < rows columns; ++nel) ElementN(nel) = (Real)matra.ElementN(nel); } /// Scales a matrix, dividing all elements by a constant value: [this]/=f void MatrDivScale(Real factor) { for (int nel = 0; nel < rows columns; ++nel) ElementN(nel) /= factor; } /// Scales a matrix, dividing all element by all oter elements of /// matra (it is not the classical matrix multiplication!) template <class RealB> void MatrDivScale(const ChMatrix<RealB>& matra) { assert(matra.GetColumns() == columns && matra.GetRows() == rows); for (int nel = 0; nel < rows * columns; ++nel) ElementN(nel) /= (Real)matra.ElementN(nel); } /// Multiplies two matrices, and stores the result in "this" matrix: [this]=[A][B]. template <class RealB, class RealC> void MatrMultiply(const ChMatrix<RealB>& matra, const ChMatrix<RealC>& matrb) { assert(matra.GetColumns() == matrb.GetRows()); assert(this->rows == matra.GetRows()); assert(this->columns == matrb.GetColumns()); int col, row, colres; Real sum; for (colres = 0; colres < matrb.GetColumns(); ++colres) { for (row = 0; row < matra.GetRows(); ++row) { sum = 0; for (col = 0; col < matra.GetColumns(); ++col) sum += (Real)(matra.Element(row, col) matrb.Element(col, colres)); SetElement(row, colres, sum); } } } #ifdef CHRONO_HAS_AVX /// Multiplies two matrices, and stores the result in "this" matrix: [this]=[A][B]. /// AVX implementation: The speed up is marginal if size of the matrices are small, e.g. 33 /// Generally, as the matra.GetColumns() increases the method performs better void MatrMultiplyAVX(const ChMatrix<double>& matra, const ChMatrix<double>& matrb) { assert(matra.GetColumns() == matrb.GetRows()); assert(this->rows == matra.GetRows()); assert(this->columns == matrb.GetColumns()); int A_Nrow = matra.GetRows(); int B_Nrow = matrb.GetRows(); int A_NCol = matra.GetColumns(); int B_NCol = matrb.GetColumns(); const double* A_add = matra.GetAddress(); const double* B_add = matrb.GetAddress(); double* this_Add = this->GetAddress(); for (int rowA = 0; rowA < A_Nrow; rowA++) { for (int colB = 0; colB < B_NCol; colB += 4) { __m256d sum = _mm256_setzero_pd(); for (int elem = 0; elem < A_NCol; elem++) { __m256d ymmA = _mm256_broadcast_sd(A_add + A_NCol * rowA + elem); __m256d ymmB = _mm256_loadu_pd(B_add + elem * B_NCol + colB); __m256d prod = _mm256_mul_pd(ymmA, ymmB); sum = _mm256_add_pd(sum, prod); } _mm256_storeu_pd(this_Add + rowA * B_NCol + colB, sum); } } } /// Multiplies two matrices (the second is considered transposed): [this]=[A][B]' /// Note: This method is faster than MatrMultiplyT if matra.GetColumns()%4=0 && matra.GetColumns()>8 /// It is still fast if matra.GetColumns() is large enough even if matra.GetColumns()%4!=0 void MatrMultiplyTAVX(const ChMatrix<double>& matra, const ChMatrix<double>& matrb) { assert(matra.GetColumns() == matrb.GetColumns()); assert(this->GetRows() == matra.GetRows()); assert(this->GetColumns() == matrb.GetRows()); int A_Nrow = matra.GetRows(); int B_Nrow = matrb.GetRows(); int A_NCol = matra.GetColumns(); int B_NCol = matrb.GetColumns(); const double A_add = matra.GetAddress(); const double* B_add = matrb.GetAddress(); bool NeedsPadding = (B_NCol % 4 != 0); int CorrectFAT = ((B_NCol >> 2) << 2); for (int rowA = 0; rowA < A_Nrow; rowA++) { for (int rowB = 0; rowB < B_Nrow; rowB++) { int colB; double temp_sum = 0.0; __m256d sum = _mm256_setzero_pd(); for (colB = 0; colB < CorrectFAT; colB += 4) { __m256d ymmA = _mm256_loadu_pd(A_add + rowA * A_NCol + colB); __m256d ymmB = _mm256_loadu_pd(B_add + rowB * B_NCol + colB); __m256d prod = _mm256_mul_pd(ymmA, ymmB); sum = _mm256_add_pd(sum, prod); } sum = _mm256_hadd_pd(sum, sum); temp_sum = ((double)&sum)[0] + ((double)&sum)[2]; if (NeedsPadding) for (colB = CorrectFAT; colB < B_NCol; colB++) { temp_sum += (matra.Element(rowA, colB) * matrb.Element(rowB, colB)); } SetElement(rowA, rowB, temp_sum); } } } #endif /// Multiplies two matrices (the second is considered transposed): [this]=[A][B]' /// Faster than doing B.MatrTranspose(); result.MatrMultiply(A,B); /// Note: no check on mistaken size of this! template <class RealB, class RealC> void MatrMultiplyT(const ChMatrix<RealB>& matra, const ChMatrix<RealC>& matrb) { assert(matra.GetColumns() == matrb.GetColumns()); assert(this->rows == matra.GetRows()); assert(this->columns == matrb.GetRows()); int col, row, colres; Real sum; for (colres = 0; colres < matrb.GetRows(); ++colres) { for (row = 0; row < matra.GetRows(); ++row) { sum = 0; for (col = 0; col < matra.GetColumns(); ++col) sum += (Real)(matra.Element(row, col) matrb.Element(colres, col)); SetElement(row, colres, sum); } } } /// Multiplies two matrices (the first is considered transposed): [this]=[A]'[B] /// Faster than doing A.MatrTranspose(); result.MatrMultiply(A,B); template <class RealB, class RealC> void MatrTMultiply(const ChMatrix<RealB>& matra, const ChMatrix<RealC>& matrb) { assert(matra.GetRows() == matrb.GetRows()); assert(this->rows == matra.GetColumns()); assert(this->columns == matrb.GetColumns()); int col, row, colres; Real sum; for (colres = 0; colres < matrb.GetColumns(); ++colres) { for (row = 0; row < matra.GetColumns(); ++row) { sum = 0; for (col = 0; col < (matra.GetRows()); ++col) sum += (Real)(matra.Element(col, row) matrb.Element(col, colres)); SetElement(row, colres, sum); } } } /// Computes dot product between two column-matrices (vectors) with /// same size. Returns a scalar value. template <class RealB, class RealC> static Real MatrDot(const ChMatrix<RealB>& ma, const ChMatrix<RealC>& mb) { assert(ma.GetColumns() == mb.GetColumns() && ma.GetRows() == mb.GetRows()); Real tot = 0; for (int i = 0; i < ma.GetRows(); ++i) tot += (Real)(ma.ElementN(i) * mb.ElementN(i)); return tot; } /// Transpose this matrix in place void MatrTranspose() { if (columns == rows) // Square transp.is optimized { for (int row = 0; row < rows; ++row) for (int col = row; col < columns; ++col) if (row != col) { Real temp = Element(row, col); Element(row, col) = Element(col, row); Element(col, row) = temp; } int tmpr = rows; rows = columns; columns = tmpr; } else // Naive implementation for rectangular case. Not in-place. Slower. { ChMatrixDynamic<Real> matrcopy(this); int tmpr = rows; rows = columns; columns = tmpr; // dont' realloc buffer, anyway for (int row = 0; row < rows; ++row) for (int col = 0; col < columns; ++col) Element(row, col) = matrcopy.Element(col, row); } } /// Returns the determinant of the matrix. /// Note! This method must be used only with max 4x4 matrices, /// otherwise it throws an exception. Real Det() { assert(this->GetRows() == this->GetColumns()); assert(this->GetRows() <= 4); if (this->GetRows() != this->GetColumns()) throw("Cannot compute matrix determinant because rectangular matrix"); if (this->GetRows() > 4) throw("Cannot compute matrix determinant because matr. larger than 3x3"); Real det = 0; switch (this->GetRows()) { case 1: det = (this)(0, 0); break; case 2: det = (this)(0, 0) (this)(1, 1) - (this)(0, 1) * (this)(1, 0); break; case 3: det = (this)(0, 0) * (this)(1, 1) (this)(2, 2) + (this)(0, 1) * (this)(1, 2) (this)(2, 0) + (this)(0, 2) * (this)(1, 0) (this)(2, 1) - (this)(2, 0) * (this)(1, 1) (this)(0, 2) - (this)(2, 1) * (this)(1, 2) (this)(0, 0) - (this)(2, 2) * (this)(1, 0) (this)(0, 1); break; case 4: det = (this)(0, 0) * (this)(1, 1) (this)(2, 2) (this)(3, 3) + (this)(0, 0) * (this)(1, 2) (this)(2, 3) (this)(3, 1) + (this)(0, 0) * (this)(1, 3) (this)(2, 1) (this)(3, 2) + (this)(0, 1) * (this)(1, 0) (this)(2, 3) (this)(3, 2) + (this)(0, 1) * (this)(1, 2) (this)(2, 0) (this)(3, 3) + (this)(0, 1) * (this)(1, 3) (this)(2, 2) (this)(3, 0) + (this)(0, 2) * (this)(1, 0) (this)(2, 1) (this)(3, 3) + (this)(0, 2) * (this)(1, 1) (this)(2, 3) (this)(3, 0) + (this)(0, 2) * (this)(1, 3) (this)(2, 0) (this)(3, 1) + (this)(0, 3) * (this)(1, 0) (this)(2, 2) (this)(3, 1) + (this)(0, 3) * (this)(1, 1) (this)(2, 0) (this)(3, 2) + (this)(0, 3) * (this)(1, 2) (this)(2, 1) (this)(3, 0) - (this)(0, 0) * (this)(1, 1) (this)(2, 3) (this)(3, 2) - (this)(0, 0) * (this)(1, 2) (this)(2, 1) (this)(3, 3) - (this)(0, 0) * (this)(1, 3) (this)(2, 2) (this)(3, 1) - (this)(0, 1) * (this)(1, 0) (this)(2, 2) (this)(3, 3) - (this)(0, 1) * (this)(1, 2) (this)(2, 3) (this)(3, 0) - (this)(0, 1) * (this)(1, 3) (this)(2, 0) (this)(3, 2) - (this)(0, 2) * (this)(1, 0) (this)(2, 3) (this)(3, 1) - (this)(0, 2) * (this)(1, 1) (this)(2, 0) (this)(3, 3) - (this)(0, 2) * (this)(1, 3) (this)(2, 1) (this)(3, 0) - (this)(0, 3) * (this)(1, 0) (this)(2, 1) (this)(3, 2) - (this)(0, 3) * (this)(1, 1) (this)(2, 2) (this)(3, 0) - (this)(0, 3) * (this)(1, 2) (this)(2, 0) (this)(3, 1); break; } return det; } /// Returns the inverse of the matrix. /// Note! This method must be used only with max 4x4 matrices, /// otherwise it throws an exception. void MatrInverse() { assert(this->GetRows() == this->GetColumns()); assert(this->GetRows() <= 4); assert(this->Det() != 0); if (this->GetRows() != this->GetColumns()) throw("Cannot compute matrix inverse because rectangular matrix"); if (this->GetRows() > 4) throw("Cannot compute matrix inverse because matr. larger than 4x4"); if (this->Det() == 0) throw("Cannot compute matrix inverse because singular matrix"); switch (this->GetRows()) { case 1: (this)(0, 0) = (1 / (this)(0, 0)); break; case 2: { ChMatrixDynamic<Real> inv(2, 2); inv(0, 0) = (this)(1, 1); inv(0, 1) = -(this)(0, 1); inv(1, 1) = (this)(0, 0); inv(1, 0) = -(this)(1, 0); inv.MatrDivScale(this->Det()); this->CopyFromMatrix(inv); break; } case 3: { ChMatrixDynamic<Real> inv(3, 3); inv(0, 0) = (this)(1, 1) * (this)(2, 2) - (this)(1, 2) * (this)(2, 1); inv(0, 1) = (this)(2, 1) * (this)(0, 2) - (this)(0, 1) * (this)(2, 2); inv(0, 2) = (this)(0, 1) * (this)(1, 2) - (this)(0, 2) * (this)(1, 1); inv(1, 0) = (this)(1, 2) * (this)(2, 0) - (this)(1, 0) * (this)(2, 2); inv(1, 1) = (this)(2, 2) * (this)(0, 0) - (this)(2, 0) * (this)(0, 2); inv(1, 2) = (this)(0, 2) * (this)(1, 0) - (this)(1, 2) * (this)(0, 0); inv(2, 0) = (this)(1, 0) * (this)(2, 1) - (this)(1, 1) * (this)(2, 0); inv(2, 1) = (this)(0, 1) * (this)(2, 0) - (this)(0, 0) * (this)(2, 1); inv(2, 2) = (this)(0, 0) * (this)(1, 1) - (this)(0, 1) * (this)(1, 0); inv.MatrDivScale(this->Det()); this->CopyFromMatrix(inv); break; } case 4: { ChMatrixDynamic<Real> inv(4, 4); inv.SetElement( 0, 0, (this)(1, 2) * (this)(2, 3) (this)(3, 1) - (this)(1, 3) * (this)(2, 2) (this)(3, 1) + (this)(1, 3) * (this)(2, 1) (this)(3, 2) - (this)(1, 1) * (this)(2, 3) (this)(3, 2) - (this)(1, 2) * (this)(2, 1) (this)(3, 3) + (this)(1, 1) * (this)(2, 2) (this)(3, 3)); inv.SetElement( 0, 1, (this)(0, 3) * (this)(2, 2) (this)(3, 1) - (this)(0, 2) * (this)(2, 3) (this)(3, 1) - (this)(0, 3) * (this)(2, 1) (this)(3, 2) + (this)(0, 1) * (this)(2, 3) (this)(3, 2) + (this)(0, 2) * (this)(2, 1) (this)(3, 3) - (this)(0, 1) * (this)(2, 2) (this)(3, 3)); inv.SetElement( 0, 2, (this)(0, 2) * (this)(1, 3) (this)(3, 1) - (this)(0, 3) * (this)(1, 2) (this)(3, 1) + (this)(0, 3) * (this)(1, 1) (this)(3, 2) - (this)(0, 1) * (this)(1, 3) (this)(3, 2) - (this)(0, 2) * (this)(1, 1) (this)(3, 3) + (this)(0, 1) * (this)(1, 2) (this)(3, 3)); inv.SetElement( 0, 3, (this)(0, 3) * (this)(1, 2) (this)(2, 1) - (this)(0, 2) * (this)(1, 3) (this)(2, 1) - (this)(0, 3) * (this)(1, 1) (this)(2, 2) + (this)(0, 1) * (this)(1, 3) (this)(2, 2) + (this)(0, 2) * (this)(1, 1) (this)(2, 3) - (this)(0, 1) * (this)(1, 2) (this)(2, 3)); inv.SetElement( 1, 0, (this)(1, 3) * (this)(2, 2) (this)(3, 0) - (this)(1, 2) * (this)(2, 3) (this)(3, 0) - (this)(1, 3) * (this)(2, 0) (this)(3, 2) + (this)(1, 0) * (this)(2, 3) (this)(3, 2) + (this)(1, 2) * (this)(2, 0) (this)(3, 3) - (this)(1, 0) * (this)(2, 2) (this)(3, 3)); inv.SetElement( 1, 1, (this)(0, 2) * (this)(2, 3) (this)(3, 0) - (this)(0, 3) * (this)(2, 2) (this)(3, 0) + (this)(0, 3) * (this)(2, 0) (this)(3, 2) - (this)(0, 0) * (this)(2, 3) (this)(3, 2) - (this)(0, 2) * (this)(2, 0) (this)(3, 3) + (this)(0, 0) * (this)(2, 2) (this)(3, 3)); inv.SetElement( 1, 2, (this)(0, 3) * (this)(1, 2) (this)(3, 0) - (this)(0, 2) * (this)(1, 3) (this)(3, 0) - (this)(0, 3) * (this)(1, 0) (this)(3, 2) + (this)(0, 0) * (this)(1, 3) (this)(3, 2) + (this)(0, 2) * (this)(1, 0) (this)(3, 3) - (this)(0, 0) * (this)(1, 2) (this)(3, 3)); inv.SetElement( 1, 3, (this)(0, 2) * (this)(1, 3) (this)(2, 0) - (this)(0, 3) * (this)(1, 2) (this)(2, 0) + (this)(0, 3) * (this)(1, 0) (this)(2, 2) - (this)(0, 0) * (this)(1, 3) (this)(2, 2) - (this)(0, 2) * (this)(1, 0) (this)(2, 3) + (this)(0, 0) * (this)(1, 2) (this)(2, 3)); inv.SetElement( 2, 0, (this)(1, 1) * (this)(2, 3) (this)(3, 0) - (this)(1, 3) * (this)(2, 1) (this)(3, 0) + (this)(1, 3) * (this)(2, 0) (this)(3, 1) - (this)(1, 0) * (this)(2, 3) (this)(3, 1) - (this)(1, 1) * (this)(2, 0) (this)(3, 3) + (this)(1, 0) * (this)(2, 1) (this)(3, 3)); inv.SetElement( 2, 1, (this)(0, 3) * (this)(2, 1) (this)(3, 0) - (this)(0, 1) * (this)(2, 3) (this)(3, 0) - (this)(0, 3) * (this)(2, 0) (this)(3, 1) + (this)(0, 0) * (this)(2, 3) (this)(3, 1) + (this)(0, 1) * (this)(2, 0) (this)(3, 3) - (this)(0, 0) * (this)(2, 1) (this)(3, 3)); inv.SetElement( 2, 2, (this)(0, 1) * (this)(1, 3) (this)(3, 0) - (this)(0, 3) * (this)(1, 1) (this)(3, 0) + (this)(0, 3) * (this)(1, 0) (this)(3, 1) - (this)(0, 0) * (this)(1, 3) (this)(3, 1) - (this)(0, 1) * (this)(1, 0) (this)(3, 3) + (this)(0, 0) * (this)(1, 1) (this)(3, 3)); inv.SetElement( 2, 3, (this)(0, 3) * (this)(1, 1) (this)(2, 0) - (this)(0, 1) * (this)(1, 3) (this)(2, 0) - (this)(0, 3) * (this)(1, 0) (this)(2, 1) + (this)(0, 0) * (this)(1, 3) (this)(2, 1) + (this)(0, 1) * (this)(1, 0) (this)(2, 3) - (this)(0, 0) * (this)(1, 1) (this)(2, 3)); inv.SetElement( 3, 0, (this)(1, 2) * (this)(2, 1) (this)(3, 0) - (this)(1, 1) * (this)(2, 2) (this)(3, 0) - (this)(1, 2) * (this)(2, 0) (this)(3, 1) + (this)(1, 0) * (this)(2, 2) (this)(3, 1) + (this)(1, 1) * (this)(2, 0) (this)(3, 2) - (this)(1, 0) * (this)(2, 1) (this)(3, 2)); inv.SetElement( 3, 1, (this)(0, 1) * (this)(2, 2) (this)(3, 0) - (this)(0, 2) * (this)(2, 1) (this)(3, 0) + (this)(0, 2) * (this)(2, 0) (this)(3, 1) - (this)(0, 0) * (this)(2, 2) (this)(3, 1) - (this)(0, 1) * (this)(2, 0) (this)(3, 2) + (this)(0, 0) * (this)(2, 1) (this)(3, 2)); inv.SetElement( 3, 2, (this)(0, 2) * (this)(1, 1) (this)(3, 0) - (this)(0, 1) * (this)(1, 2) (this)(3, 0) - (this)(0, 2) * (this)(1, 0) (this)(3, 1) + (this)(0, 0) * (this)(1, 2) (this)(3, 1) + (this)(0, 1) * (this)(1, 0) (this)(3, 2) - (this)(0, 0) * (this)(1, 1) (this)(3, 2)); inv.SetElement( 3, 3, (this)(0, 1) * (this)(1, 2) (this)(2, 0) - (this)(0, 2) * (this)(1, 1) (this)(2, 0) + (this)(0, 2) * (this)(1, 0) (this)(2, 1) - (this)(0, 0) * (this)(1, 2) (this)(2, 1) - (this)(0, 1) * (this)(1, 0) (this)(2, 2) + (this)(0, 0) * (this)(1, 1) (this)(2, 2)); inv.MatrDivScale(this->Det()); this->CopyFromMatrix(inv); break; } } } /// Returns true if vector is identical to other matrix bool Equals(const ChMatrix<Real>& other) { return Equals(other, 0.0); } /// Returns true if vector equals another vector, within a tolerance 'tol' bool Equals(const ChMatrix<Real>& other, Real tol) { if ((other.GetColumns() != this->columns) \|\| (other.GetRows() != this->rows)) return false; for (int nel = 0; nel < rows columns; ++nel) if (fabs(ElementN(nel) - other.ElementN(nel)) > tol) return false; return true; } /// Multiplies this 3x4 matrix by a quaternion, as v=[G]q /// The matrix must be 3x4. /// \return The result of the multiplication, i.e. a vector. template <class RealB> ChVector<Real> Matr34_x_Quat(const ChQuaternion<RealB>& qua) { assert((rows == 3) && (columns == 4)); return ChVector<Real>(Get34Element(0, 0) (Real)qua.e0() + Get34Element(0, 1) * (Real)qua.e1() + Get34Element(0, 2) * (Real)qua.e2() + Get34Element(0, 3) * (Real)qua.e3(), Get34Element(1, 0) * (Real)qua.e0() + Get34Element(1, 1) * (Real)qua.e1() + Get34Element(1, 2) * (Real)qua.e2() + Get34Element(1, 3) * (Real)qua.e3(), Get34Element(2, 0) * (Real)qua.e0() + Get34Element(2, 1) * (Real)qua.e1() + Get34Element(2, 2) * (Real)qua.e2() + Get34Element(2, 3) * (Real)qua.e3()); } /// Multiplies this 3x4 matrix (transposed) by a vector, as q=[G]'v /// The matrix must be 3x4. /// \return The result of the multiplication, i.e. a quaternion. template <class RealB> ChQuaternion<Real> Matr34T_x_Vect(const ChVector<RealB>& va) { assert((rows == 3) && (columns == 4)); return ChQuaternion<Real>( Get34Element(0, 0) (Real)va.x() + Get34Element(1, 0) * (Real)va.y() + Get34Element(2, 0) * (Real)va.z(), Get34Element(0, 1) * (Real)va.x() + Get34Element(1, 1) * (Real)va.y() + Get34Element(2, 1) * (Real)va.z(), Get34Element(0, 2) * (Real)va.x() + Get34Element(1, 2) * (Real)va.y() + Get34Element(2, 2) * (Real)va.z(), Get34Element(0, 3) * (Real)va.x() + Get34Element(1, 3) * (Real)va.y() + Get34Element(2, 3) * (Real)va.z()); } /// Multiplies this 4x4 matrix (transposed) by a quaternion, /// The matrix must be 4x4. /// \return The result of the multiplication, i.e. a quaternion. template <class RealB> ChQuaternion<Real> Matr44_x_Quat(const ChQuaternion<RealB>& qua) { assert((rows == 4) && (columns == 4)); return ChQuaternion<Real>(Get44Element(0, 0) * (Real)qua.e0() + Get44Element(0, 1) * (Real)qua.e1() + Get44Element(0, 2) * (Real)qua.e2() + Get44Element(0, 3) * (Real)qua.e3(), Get44Element(1, 0) * (Real)qua.e0() + Get44Element(1, 1) * (Real)qua.e1() + Get44Element(1, 2) * (Real)qua.e2() + Get44Element(1, 3) * (Real)qua.e3(), Get44Element(2, 0) * (Real)qua.e0() + Get44Element(2, 1) * (Real)qua.e1() + Get44Element(2, 2) * (Real)qua.e2() + Get44Element(2, 3) * (Real)qua.e3(), Get44Element(3, 0) * (Real)qua.e0() + Get44Element(3, 1) * (Real)qua.e1() + Get44Element(3, 2) * (Real)qua.e2() + Get44Element(3, 3) * (Real)qua.e3()); } /// Transposes only the lower-right 3x3 submatrix of a hemisymmetric 4x4 matrix, /// used when the 4x4 matrix is a "star" matrix [q] coming from a quaternion q: /// the non commutative quat. product is: /// q1 x q2 = [q1]q2 = [q2st]q1 /// where [q2st] is the "semi-transpose of [q2]. void MatrXq_SemiTranspose() { SetElement(1, 2, -GetElement(1, 2)); SetElement(1, 3, -GetElement(1, 3)); SetElement(2, 1, -GetElement(2, 1)); SetElement(2, 3, -GetElement(2, 3)); SetElement(3, 1, -GetElement(3, 1)); SetElement(3, 2, -GetElement(3, 2)); } /// Change the sign of the 2nd, 3rd and 4th columns of a 4x4 matrix, /// The product between a quaternion q1 and the conjugate of q2 (q2'), is: /// q1 x q2' = [q1]q2' = [q1sn]q2 /// where [q1sn] is the semi-negation of the 4x4 matrix [q1]. void MatrXq_SemiNeg() { for (int i = 0; i < rows; ++i) for (int j = 1; j < columns; ++j) SetElement(i, j, -GetElement(i, j)); } /// Gets the norm infinite of the matrix, i.e. the max. /// of its elements in absolute value. Real NormInf() { Real norm = 0; for (int nel = 0; nel < rows * columns; ++nel) if ((fabs(ElementN(nel))) > norm) norm = fabs(ElementN(nel)); return norm; } /// Gets the norm two of the matrix, i.e. the square root /// of the sum of the elements squared. Real NormTwo() { Real norm = 0; for (int nel = 0; nel < rows * columns; ++nel) norm += ElementN(nel) * ElementN(nel); return (sqrt(norm)); } /// Finds max value among the values of the matrix Real Max() { Real mmax = GetElement(0, 0); for (int nel = 0; nel < rows * columns; ++nel) if (ElementN(nel) > mmax) mmax = ElementN(nel); return mmax; } /// Finds min value among the values of the matrix Real Min() { Real mmin = GetElement(0, 0); for (int nel = 0; nel < rows * columns; ++nel) if (ElementN(nel) < mmin) mmin = ElementN(nel); return mmin; } /// Linear interpolation of two matrices. Parameter mx must be 0...1. /// [this] =(1-x)[A]+ (x)[B] Matrices must have the same size!! void LinInterpolate(const ChMatrix<Real>& matra, const ChMatrix<Real>& matrb, Real mx) { assert(matra.columns == matrb.columns && matra.rows == matrb.rows); for (int nel = 0; nel < rows * columns; nel++) ElementN(nel) = matra.ElementN(nel) * (1 - mx) + matrb.ElementN(nel) * (mx); } /// Fills a matrix or a vector with a bilinear interpolation, /// from corner values (as a u-v patch). void RowColInterp(Real vmin, Real vmax, Real umin, Real umax) { for (int iu = 0; iu < GetColumns(); iu++) for (int iv = 0; iv < GetRows(); iv++) { if (GetRows() > 1) Element(iv, iu) = vmin + (vmax - vmin) * ((Real)iv / ((Real)(GetRows() - 1))); if (GetColumns() > 1) Element(iv, iu) += umin + (umax - umin) * ((Real)iu / ((Real)(GetColumns() - 1))); } } // // BOOKKEEPING // /// Paste a matrix "matra" into "this", inserting at location insrow-inscol. /// Normal copy for insrow=inscol=0 template <class RealB> void PasteMatrix(const ChMatrix<RealB>& matra, int insrow, int inscol) { for (int i = 0; i < matra.GetRows(); ++i) for (int j = 0; j < matra.GetColumns(); ++j) Element(i + insrow, j + inscol) = (Real)matra.Element(i, j); } /// Paste a matrix "matra" into "this", inserting at location insrow-inscol /// and performing a sum with the preexisting values. template <class RealB> void PasteSumMatrix(const ChMatrix<RealB>& matra, int insrow, int inscol) { for (int i = 0; i < matra.GetRows(); ++i) for (int j = 0; j < matra.GetColumns(); ++j) Element(i + insrow, j + inscol) += (Real)matra.Element(i, j); } /// Paste a matrix "matra", transposed, into "this", inserting at location insrow-inscol. /// Normal copy for insrow=inscol=0 template <class RealB> void PasteTranspMatrix(const ChMatrix<RealB>& matra, int insrow, int inscol) { for (int i = 0; i < matra.GetRows(); ++i) for (int j = 0; j < matra.GetColumns(); ++j) Element(j + insrow, i + inscol) = (Real)matra.Element(i, j); } /// Paste a matrix "matra", transposed, into "this", inserting at location insrow-inscol /// and performing a sum with the preexisting values. template <class RealB> void PasteSumTranspMatrix(const ChMatrix<RealB>& matra, int insrow, int inscol) { for (int i = 0; i < matra.GetRows(); ++i) for (int j = 0; j < matra.GetColumns(); ++j) Element(j + insrow, i + inscol) += (Real)matra.Element(i, j); } /// Paste a clipped portion of the matrix "matra" into "this", /// inserting the clip (of size nrows, ncolumns) at the location insrow-inscol. template <class RealB> void PasteClippedMatrix(const ChMatrix<RealB>& matra, int cliprow, int clipcol, int nrows, int ncolumns, int insrow, int inscol) { for (int i = 0; i < nrows; ++i) for (int j = 0; j < ncolumns; ++j) Element(i + insrow, j + inscol) = (Real)matra.Element(i + cliprow, j + clipcol); } /// Paste a clipped portion of the matrix "matra" into "this", where "this" /// is a vector (of ChMatrix type), /// inserting the clip (of size nrows, ncolumns) at the location insindex. template <class RealB> void PasteClippedMatrixToVector(const ChMatrix<RealB>& matra, int cliprow, int clipcol, int nrows, int ncolumns, int insindex) { for (int i = 0; i < nrows; ++i) for (int j = 0; j < ncolumns; ++j) ElementN(insindex + i * ncolumns + j) = (Real)matra.Element(cliprow + i, clipcol + j); } /// Paste a clipped portion of a vector into "this", where "this" /// is a matrix (of ChMatrix type), /// inserting the clip (of size nrows, ncolumns) at the location insindex. template <class RealB> void PasteClippedVectorToMatrix(const ChMatrix<RealB>& matra, int cliprow, int clipcol, int nrows, int ncolumns, int insindex) { for (int i = 0; i < nrows; ++i) for (int j = 0; j < ncolumns; ++j) Element(i + cliprow, j + clipcol) = (Real)matra.ElementN(insindex + i * ncolumns + j); } /// Paste a clipped portion of the matrix "matra" into "this", performing a sum with preexisting values, /// inserting the clip (of size nrows, ncolumns) at the location insrow-inscol. template <class RealB> void PasteSumClippedMatrix(const ChMatrix<RealB>& matra, int cliprow, int clipcol, int nrows, int ncolumns, int insrow, int inscol) { for (int i = 0; i < nrows; ++i) for (int j = 0; j < ncolumns; ++j) #pragma omp atomic Element(i + insrow, j + inscol) += (Real)matra.Element(i + cliprow, j + clipcol); } /// Paste a vector "va" into the matrix. template <class RealB> void PasteVector(const ChVector<RealB>& va, int insrow, int inscol) { SetElement(insrow + 0, inscol, (Real)va.x()); SetElement(insrow + 1, inscol, (Real)va.y()); SetElement(insrow + 2, inscol, (Real)va.z()); } /// Paste a vector "va" into the matrix, summing it with preexisting values. template <class RealB> void PasteSumVector(const ChVector<RealB>& va, int insrow, int inscol) { Element(insrow + 0, inscol) += (Real)va.x(); Element(insrow + 1, inscol) += (Real)va.y(); Element(insrow + 2, inscol) += (Real)va.z(); } /// Paste a vector "va" into the matrix, subtracting it from preexisting values. template <class RealB> void PasteSubVector(const ChVector<RealB>& va, int insrow, int inscol) { Element(insrow + 0, inscol) -= (Real)va.x(); Element(insrow + 1, inscol) -= (Real)va.y(); Element(insrow + 2, inscol) -= (Real)va.z(); } /// Paste a quaternion into the matrix. template <class RealB> void PasteQuaternion(const ChQuaternion<RealB>& qa, int insrow, int inscol) { SetElement(insrow + 0, inscol, (Real)qa.e0()); SetElement(insrow + 1, inscol, (Real)qa.e1()); SetElement(insrow + 2, inscol, (Real)qa.e2()); SetElement(insrow + 3, inscol, (Real)qa.e3()); } /// Paste a quaternion into the matrix, summing it with preexisting values. template <class RealB> void PasteSumQuaternion(const ChQuaternion<RealB>& qa, int insrow, int inscol) { Element(insrow + 0, inscol) += (Real)qa.e0(); Element(insrow + 1, inscol) += (Real)qa.e1(); Element(insrow + 2, inscol) += (Real)qa.e2(); Element(insrow + 3, inscol) += (Real)qa.e3(); } /// Paste a coordsys into the matrix. template <class RealB> void PasteCoordsys(const ChCoordsys<RealB>& cs, int insrow, int inscol) { PasteVector(cs.pos, insrow, inscol); PasteQuaternion(cs.rot, insrow + 3, inscol); } /// Returns the vector clipped from insrow, inscol. ChVector<Real> ClipVector(int insrow, int inscol) const { return ChVector<Real>(Element(insrow, inscol), Element(insrow + 1, inscol), Element(insrow + 2, inscol)); } /// Returns the quaternion clipped from insrow, inscol. ChQuaternion<Real> ClipQuaternion(int insrow, int inscol) const { return ChQuaternion<Real>(Element(insrow, inscol), Element(insrow + 1, inscol), Element(insrow + 2, inscol), Element(insrow + 3, inscol)); } /// Returns the coordsys clipped from insrow, inscol. ChCoordsys<Real> ClipCoordsys(int insrow, int inscol) const { return ChCoordsys<Real>(ClipVector(insrow, inscol), ClipQuaternion(insrow + 3, inscol)); } // // MULTIBODY SPECIFIC MATH FUCTION // /// Fills a 4x4 matrix as the "star" matrix, representing quaternion cross product. /// That is, given two quaternions a and b, aXb= [Astar]*b template <class RealB> void Set_Xq_matrix(const ChQuaternion<RealB>& q) { Set44Element(0, 0, (Real)q.e0()); Set44Element(0, 1, -(Real)q.e1()); Set44Element(0, 2, -(Real)q.e2()); Set44Element(0, 3, -(Real)q.e3()); Set44Element(1, 0, (Real)q.e1()); Set44Element(1, 1, (Real)q.e0()); Set44Element(1, 2, -(Real)q.e3()); Set44Element(1, 3, (Real)q.e2()); Set44Element(2, 0, (Real)q.e2()); Set44Element(2, 1, (Real)q.e3()); Set44Element(2, 2, (Real)q.e0()); Set44Element(2, 3, -(Real)q.e1()); Set44Element(3, 0, (Real)q.e3()); Set44Element(3, 1, -(Real)q.e2()); Set44Element(3, 2, (Real)q.e1()); Set44Element(3, 3, (Real)q.e0()); } }; } // end namespace chrono #endif
par_csr_matop_device.c	/****************************************************************************** * Copyright 1998-2019 Lawrence Livermore National Security, LLC and other * HYPRE Project Developers. See the top-level COPYRIGHT file for details. * * SPDX-License-Identifier: (Apache-2.0 OR MIT) *****************************************************************************/ #include "_hypre_utilities.h" #include "hypre_hopscotch_hash.h" #include "_hypre_parcsr_mv.h" #include "_hypre_lapack.h" #include "_hypre_blas.h" #include "_hypre_utilities.hpp" #if defined(HYPRE_USING_CUDA) HYPRE_Int hypre_ParcsrGetExternalRowsDeviceInit( hypre_ParCSRMatrix A, HYPRE_Int indices_len, HYPRE_Int indices, hypre_ParCSRCommPkg comm_pkg, HYPRE_Int want_data, void *request_ptr) { HYPRE_Int i, j; HYPRE_Int num_sends, num_rows_send, num_nnz_send, num_recvs, num_rows_recv, num_nnz_recv; HYPRE_Int d_send_i, send_i, d_send_map, d_recv_i, recv_i; HYPRE_BigInt d_send_j, d_recv_j; HYPRE_Int send_jstarts, recv_jstarts; HYPRE_Complex d_send_a = NULL, d_recv_a = NULL; hypre_ParCSRCommPkg comm_pkg_j; hypre_ParCSRCommHandle comm_handle, comm_handle_j, comm_handle_a; /* HYPRE_Int global_num_rows = hypre_ParCSRMatrixGlobalNumRows(A); / / diag part of A / hypre_CSRMatrix A_diag = hypre_ParCSRMatrixDiag(A); HYPRE_Complex A_diag_a = hypre_CSRMatrixData(A_diag); HYPRE_Int A_diag_i = hypre_CSRMatrixI(A_diag); HYPRE_Int A_diag_j = hypre_CSRMatrixJ(A_diag); / HYPRE_Int local_num_rows = hypre_CSRMatrixNumRows(A_diag); / / off-diag part of A / hypre_CSRMatrix A_offd = hypre_ParCSRMatrixOffd(A); HYPRE_Complex A_offd_a = hypre_CSRMatrixData(A_offd); HYPRE_Int A_offd_i = hypre_CSRMatrixI(A_offd); HYPRE_Int A_offd_j = hypre_CSRMatrixJ(A_offd); / HYPRE_Int row_starts = hypre_ParCSRMatrixRowStarts(A); / /* HYPRE_Int first_row = hypre_ParCSRMatrixFirstRowIndex(A); / HYPRE_Int first_col = hypre_ParCSRMatrixFirstColDiag(A); HYPRE_BigInt col_map_offd_A = hypre_ParCSRMatrixColMapOffd(A); HYPRE_Int num_cols_A_offd = hypre_CSRMatrixNumCols(A_offd); HYPRE_BigInt d_col_map_offd_A = hypre_ParCSRMatrixDeviceColMapOffd(A); MPI_Comm comm = hypre_ParCSRMatrixComm(A); HYPRE_Int num_procs; HYPRE_Int my_id; void vrequest; hypre_CSRMatrix A_ext; hypre_MPI_Comm_size(comm, &num_procs); hypre_MPI_Comm_rank(comm, &my_id); /* number of sends (#procs) / num_sends = hypre_ParCSRCommPkgNumSends(comm_pkg); / number of rows to send / num_rows_send = hypre_ParCSRCommPkgSendMapStart(comm_pkg, num_sends); / number of recvs (#procs) / num_recvs = hypre_ParCSRCommPkgNumRecvs(comm_pkg); / number of rows to recv / num_rows_recv = hypre_ParCSRCommPkgRecvVecStart(comm_pkg, num_recvs); / must be true if indices contains proper offd indices / hypre_assert(indices_len == num_rows_recv); / send_i/recv_i: * the arrays to send and recv: we first send and recv the row lengths / d_send_i = hypre_TAlloc(HYPRE_Int, num_rows_send + 1, HYPRE_MEMORY_DEVICE); d_send_map = hypre_TAlloc(HYPRE_Int, num_rows_send, HYPRE_MEMORY_DEVICE); send_i = hypre_TAlloc(HYPRE_Int, num_rows_send, HYPRE_MEMORY_HOST); recv_i = hypre_TAlloc(HYPRE_Int, num_rows_recv + 1, HYPRE_MEMORY_HOST); d_recv_i = hypre_TAlloc(HYPRE_Int, num_rows_recv + 1, HYPRE_MEMORY_DEVICE); / fill the send array with row lengths / hypre_TMemcpy(d_send_map, hypre_ParCSRCommPkgSendMapElmts(comm_pkg), HYPRE_Int, num_rows_send, HYPRE_MEMORY_DEVICE, HYPRE_MEMORY_HOST); hypre_Memset(d_send_i, 0, sizeof(HYPRE_Int), HYPRE_MEMORY_DEVICE); hypreDevice_GetRowNnz(num_rows_send, d_send_map, A_diag_i, A_offd_i, d_send_i+1); / send array send_i out: deviceTohost first and MPI (async) * note the shift in recv_i by one / hypre_TMemcpy(send_i, d_send_i+1, HYPRE_Int, num_rows_send, HYPRE_MEMORY_HOST, HYPRE_MEMORY_DEVICE); comm_handle = hypre_ParCSRCommHandleCreate(11, comm_pkg, send_i, recv_i+1); hypreDevice_IntegerInclusiveScan(num_rows_send + 1, d_send_i); / total number of nnz to send / hypre_TMemcpy(&num_nnz_send, d_send_i+num_rows_send, HYPRE_Int, 1, HYPRE_MEMORY_HOST, HYPRE_MEMORY_DEVICE); / prepare data to send out. overlap with the above commmunication / d_send_j = hypre_TAlloc(HYPRE_BigInt, num_nnz_send, HYPRE_MEMORY_DEVICE); if (want_data) { d_send_a = hypre_TAlloc(HYPRE_Complex, num_nnz_send, HYPRE_MEMORY_DEVICE); } if (d_col_map_offd_A == NULL) { d_col_map_offd_A = hypre_TAlloc(HYPRE_BigInt, num_cols_A_offd, HYPRE_MEMORY_DEVICE); hypre_TMemcpy(d_col_map_offd_A, col_map_offd_A, HYPRE_BigInt, num_cols_A_offd, HYPRE_MEMORY_DEVICE, HYPRE_MEMORY_HOST); hypre_ParCSRMatrixDeviceColMapOffd(A) = d_col_map_offd_A; } / job == 2, d_send_i is input that contains row ptrs (length num_rows_send) / hypreDevice_CopyParCSRRows(num_rows_send, d_send_map, 2, num_procs > 1, first_col, d_col_map_offd_A, A_diag_i, A_diag_j, A_diag_a, A_offd_i, A_offd_j, A_offd_a, d_send_i, d_send_j, d_send_a); / pointers to each proc in send_j / send_jstarts = hypre_TAlloc(HYPRE_Int, num_sends + 1, HYPRE_MEMORY_HOST); send_jstarts[0] = 0; for (i = 1; i <= num_sends; i++) { send_jstarts[i] = send_jstarts[i-1]; for ( j = hypre_ParCSRCommPkgSendMapStart(comm_pkg, i-1); j < hypre_ParCSRCommPkgSendMapStart(comm_pkg, i); j++ ) { send_jstarts[i] += send_i[j]; } } hypre_assert(send_jstarts[num_sends] == num_nnz_send); / finish the above communication: send_i/recv_i / hypre_ParCSRCommHandleDestroy(comm_handle); / adjust recv_i to ptrs / recv_i[0] = 0; for (i = 1; i <= num_rows_recv; i++) { recv_i[i] += recv_i[i-1]; } num_nnz_recv = recv_i[num_rows_recv]; / allocate device memory for j and a / d_recv_j = hypre_TAlloc(HYPRE_BigInt, num_nnz_recv, HYPRE_MEMORY_DEVICE); if (want_data) { d_recv_a = hypre_TAlloc(HYPRE_Complex, num_nnz_recv, HYPRE_MEMORY_DEVICE); } recv_jstarts = hypre_TAlloc(HYPRE_Int, num_recvs + 1, HYPRE_MEMORY_HOST); recv_jstarts[0] = 0; for (i = 1; i <= num_recvs; i++) { j = hypre_ParCSRCommPkgRecvVecStart(comm_pkg, i); recv_jstarts[i] = recv_i[j]; } / ready to send and recv: create a communication package for data / comm_pkg_j = hypre_CTAlloc(hypre_ParCSRCommPkg, 1, HYPRE_MEMORY_HOST); hypre_ParCSRCommPkgComm (comm_pkg_j) = comm; hypre_ParCSRCommPkgNumSends (comm_pkg_j) = num_sends; hypre_ParCSRCommPkgSendProcs (comm_pkg_j) = hypre_ParCSRCommPkgSendProcs(comm_pkg); hypre_ParCSRCommPkgSendMapStarts(comm_pkg_j) = send_jstarts; hypre_ParCSRCommPkgNumRecvs (comm_pkg_j) = num_recvs; hypre_ParCSRCommPkgRecvProcs (comm_pkg_j) = hypre_ParCSRCommPkgRecvProcs(comm_pkg); hypre_ParCSRCommPkgRecvVecStarts(comm_pkg_j) = recv_jstarts; / init communication / / ja / comm_handle_j = hypre_ParCSRCommHandleCreate_v2(21, comm_pkg_j, HYPRE_MEMORY_DEVICE, d_send_j, HYPRE_MEMORY_DEVICE, d_recv_j); if (want_data) { / a / comm_handle_a = hypre_ParCSRCommHandleCreate_v2(1, comm_pkg_j, HYPRE_MEMORY_DEVICE, d_send_a, HYPRE_MEMORY_DEVICE, d_recv_a); } else { comm_handle_a = NULL; } hypre_TMemcpy(d_recv_i, recv_i, HYPRE_Int, num_rows_recv+1, HYPRE_MEMORY_DEVICE, HYPRE_MEMORY_HOST); / create A_ext: on device / A_ext = hypre_CSRMatrixCreate(num_rows_recv, hypre_ParCSRMatrixGlobalNumCols(A), num_nnz_recv); hypre_CSRMatrixI (A_ext) = d_recv_i; hypre_CSRMatrixBigJ(A_ext) = d_recv_j; hypre_CSRMatrixData(A_ext) = d_recv_a; hypre_CSRMatrixMemoryLocation(A_ext) = HYPRE_MEMORY_DEVICE; / output / vrequest = hypre_TAlloc(void , 3, HYPRE_MEMORY_HOST); vrequest[0] = (void ) comm_handle_j; vrequest[1] = (void ) comm_handle_a; vrequest[2] = (void ) A_ext; request_ptr = (void ) vrequest; / free / hypre_TFree(send_i, HYPRE_MEMORY_HOST); hypre_TFree(recv_i, HYPRE_MEMORY_HOST); hypre_TFree(d_send_i, HYPRE_MEMORY_DEVICE); hypre_TFree(d_send_map, HYPRE_MEMORY_DEVICE); hypre_TFree(hypre_ParCSRCommPkgSendMapStarts(comm_pkg_j), HYPRE_MEMORY_HOST); hypre_TFree(hypre_ParCSRCommPkgRecvVecStarts(comm_pkg_j), HYPRE_MEMORY_HOST); hypre_TFree(comm_pkg_j, HYPRE_MEMORY_HOST); return hypre_error_flag; } hypre_CSRMatrix hypre_ParcsrGetExternalRowsDeviceWait(void vrequest) { void request = (void ) vrequest; hypre_ParCSRCommHandle comm_handle_j = (hypre_ParCSRCommHandle ) request[0]; hypre_ParCSRCommHandle comm_handle_a = (hypre_ParCSRCommHandle ) request[1]; hypre_CSRMatrix A_ext = (hypre_CSRMatrix ) request[2]; HYPRE_BigInt send_j = comm_handle_j ? (HYPRE_BigInt ) hypre_ParCSRCommHandleSendData(comm_handle_j) : NULL; HYPRE_Complex send_a = comm_handle_a ? (HYPRE_Complex ) hypre_ParCSRCommHandleSendData(comm_handle_a) : NULL; hypre_ParCSRCommHandleDestroy(comm_handle_j); hypre_ParCSRCommHandleDestroy(comm_handle_a); hypre_TFree(send_j, HYPRE_MEMORY_DEVICE); hypre_TFree(send_a, HYPRE_MEMORY_DEVICE); hypre_TFree(request, HYPRE_MEMORY_HOST); return A_ext; } hypre_CSRMatrix hypre_MergeDiagAndOffdDevice(hypre_ParCSRMatrix A) { MPI_Comm comm = hypre_ParCSRMatrixComm(A); hypre_CSRMatrix A_diag = hypre_ParCSRMatrixDiag(A); HYPRE_Complex A_diag_a = hypre_CSRMatrixData(A_diag); HYPRE_Int A_diag_i = hypre_CSRMatrixI(A_diag); HYPRE_Int A_diag_j = hypre_CSRMatrixJ(A_diag); hypre_CSRMatrix A_offd = hypre_ParCSRMatrixOffd(A); HYPRE_Complex A_offd_a = hypre_CSRMatrixData(A_offd); HYPRE_Int A_offd_i = hypre_CSRMatrixI(A_offd); HYPRE_Int A_offd_j = hypre_CSRMatrixJ(A_offd); HYPRE_Int local_num_rows = hypre_CSRMatrixNumRows(A_diag); HYPRE_BigInt glbal_num_cols = hypre_ParCSRMatrixGlobalNumCols(A); HYPRE_BigInt first_col = hypre_ParCSRMatrixFirstColDiag(A); HYPRE_Int num_cols_A_offd = hypre_CSRMatrixNumCols(A_offd); HYPRE_BigInt col_map_offd_A = hypre_ParCSRMatrixColMapOffd(A); HYPRE_BigInt d_col_map_offd_A = hypre_ParCSRMatrixDeviceColMapOffd(A); hypre_CSRMatrix B; HYPRE_Int B_nrows = local_num_rows; HYPRE_BigInt B_ncols = glbal_num_cols; HYPRE_Int B_i = hypre_TAlloc(HYPRE_Int, B_nrows + 1, HYPRE_MEMORY_DEVICE); HYPRE_BigInt B_j; HYPRE_Complex B_a; HYPRE_Int B_nnz; HYPRE_Int num_procs; hypre_MPI_Comm_size(comm, &num_procs); hypre_Memset(B_i, 0, sizeof(HYPRE_Int), HYPRE_MEMORY_DEVICE); hypreDevice_GetRowNnz(B_nrows, NULL, A_diag_i, A_offd_i, B_i+1); hypreDevice_IntegerInclusiveScan(B_nrows+1, B_i); / total number of nnz / hypre_TMemcpy(&B_nnz, B_i+B_nrows, HYPRE_Int, 1, HYPRE_MEMORY_HOST, HYPRE_MEMORY_DEVICE); B_j = hypre_TAlloc(HYPRE_BigInt, B_nnz, HYPRE_MEMORY_DEVICE); B_a = hypre_TAlloc(HYPRE_Complex, B_nnz, HYPRE_MEMORY_DEVICE); if (d_col_map_offd_A == NULL) { d_col_map_offd_A = hypre_TAlloc(HYPRE_BigInt, num_cols_A_offd, HYPRE_MEMORY_DEVICE); hypre_TMemcpy(d_col_map_offd_A, col_map_offd_A, HYPRE_BigInt, num_cols_A_offd, HYPRE_MEMORY_DEVICE, HYPRE_MEMORY_HOST); hypre_ParCSRMatrixDeviceColMapOffd(A) = d_col_map_offd_A; } hypreDevice_CopyParCSRRows(B_nrows, NULL, 2, num_procs > 1, first_col, d_col_map_offd_A, A_diag_i, A_diag_j, A_diag_a, A_offd_i, A_offd_j, A_offd_a, B_i, B_j, B_a); / output / B = hypre_CSRMatrixCreate(B_nrows, B_ncols, B_nnz); hypre_CSRMatrixI (B) = B_i; hypre_CSRMatrixBigJ(B) = B_j; hypre_CSRMatrixData(B) = B_a; hypre_CSRMatrixMemoryLocation(B) = HYPRE_MEMORY_DEVICE; hypre_SyncCudaComputeStream(hypre_handle()); return B; } HYPRE_Int hypre_ExchangeExternalRowsDeviceInit( hypre_CSRMatrix B_ext, hypre_ParCSRCommPkg comm_pkg_A, void request_ptr) { MPI_Comm comm = hypre_ParCSRCommPkgComm(comm_pkg_A); HYPRE_Int num_recvs = hypre_ParCSRCommPkgNumRecvs(comm_pkg_A); HYPRE_Int recv_procs = hypre_ParCSRCommPkgRecvProcs(comm_pkg_A); HYPRE_Int recv_vec_starts = hypre_ParCSRCommPkgRecvVecStarts(comm_pkg_A); HYPRE_Int num_sends = hypre_ParCSRCommPkgNumSends(comm_pkg_A); HYPRE_Int send_procs = hypre_ParCSRCommPkgSendProcs(comm_pkg_A); HYPRE_Int send_map_starts = hypre_ParCSRCommPkgSendMapStarts(comm_pkg_A); HYPRE_Int num_elmts_send = send_map_starts[num_sends]; HYPRE_Int num_elmts_recv = recv_vec_starts[num_recvs]; HYPRE_Int B_ext_i_d = hypre_CSRMatrixI(B_ext); HYPRE_BigInt B_ext_j_d = hypre_CSRMatrixBigJ(B_ext); HYPRE_Complex B_ext_a_d = hypre_CSRMatrixData(B_ext); HYPRE_Int B_ext_ncols = hypre_CSRMatrixNumCols(B_ext); HYPRE_Int B_ext_nrows = hypre_CSRMatrixNumRows(B_ext); HYPRE_Int B_ext_nnz = hypre_CSRMatrixNumNonzeros(B_ext); HYPRE_Int B_ext_rownnz_d = hypre_TAlloc(HYPRE_Int, B_ext_nrows + 1, HYPRE_MEMORY_DEVICE); HYPRE_Int B_ext_rownnz_h = hypre_TAlloc(HYPRE_Int, B_ext_nrows, HYPRE_MEMORY_HOST); HYPRE_Int B_ext_i_h = hypre_TAlloc(HYPRE_Int, B_ext_nrows + 1, HYPRE_MEMORY_HOST); hypre_assert(num_elmts_recv == B_ext_nrows); / output matrix / hypre_CSRMatrix B_int_d; HYPRE_Int B_int_nrows = num_elmts_send; HYPRE_Int B_int_ncols = B_ext_ncols; HYPRE_Int B_int_i_h = hypre_TAlloc(HYPRE_Int, B_int_nrows + 1, HYPRE_MEMORY_HOST); HYPRE_Int B_int_i_d = hypre_TAlloc(HYPRE_Int, B_int_nrows + 1, HYPRE_MEMORY_DEVICE); HYPRE_BigInt B_int_j_d = NULL; HYPRE_Complex B_int_a_d = NULL; HYPRE_Int B_int_nnz; hypre_ParCSRCommHandle comm_handle, comm_handle_j, comm_handle_a; hypre_ParCSRCommPkg comm_pkg_j; HYPRE_Int jdata_recv_vec_starts; HYPRE_Int jdata_send_map_starts; HYPRE_Int i; HYPRE_Int num_procs, my_id; void *vrequest; hypre_MPI_Comm_size(comm, &num_procs); hypre_MPI_Comm_rank(comm, &my_id); jdata_send_map_starts = hypre_TAlloc(HYPRE_Int, num_sends+1, HYPRE_MEMORY_HOST); /-------------------------------------------------------------------------- * B_ext_rownnz contains the number of elements of row j * (to be determined through send_map_elmnts on the receiving end) --------------------------------------------------------------------------/ HYPRE_THRUST_CALL(adjacent_difference, B_ext_i_d, B_ext_i_d + B_ext_nrows + 1, B_ext_rownnz_d); hypre_TMemcpy(B_ext_rownnz_h, B_ext_rownnz_d + 1, HYPRE_Int, B_ext_nrows, HYPRE_MEMORY_HOST, HYPRE_MEMORY_DEVICE); /-------------------------------------------------------------------------- initialize communication: send/recv the row nnz * (note the use of comm_pkg_A, mode 12, as in transpose matvec --------------------------------------------------------------------------/ comm_handle = hypre_ParCSRCommHandleCreate(12, comm_pkg_A, B_ext_rownnz_h, B_int_i_h + 1); jdata_recv_vec_starts = hypre_TAlloc(HYPRE_Int, num_recvs + 1, HYPRE_MEMORY_HOST); jdata_recv_vec_starts[0] = 0; B_ext_i_h[0] = 0; hypre_TMemcpy(B_ext_i_h + 1, B_ext_rownnz_h, HYPRE_Int, B_ext_nrows, HYPRE_MEMORY_HOST, HYPRE_MEMORY_HOST); for (i = 1; i <= B_ext_nrows; i++) { B_ext_i_h[i] += B_ext_i_h[i-1]; } hypre_assert(B_ext_i_h[B_ext_nrows] == B_ext_nnz); for (i = 1; i <= num_recvs; i++) { jdata_recv_vec_starts[i] = B_ext_i_h[recv_vec_starts[i]]; } comm_pkg_j = hypre_CTAlloc(hypre_ParCSRCommPkg, 1, HYPRE_MEMORY_HOST); hypre_ParCSRCommPkgComm(comm_pkg_j) = comm; hypre_ParCSRCommPkgNumSends(comm_pkg_j) = num_recvs; hypre_ParCSRCommPkgNumRecvs(comm_pkg_j) = num_sends; hypre_ParCSRCommPkgSendProcs(comm_pkg_j) = recv_procs; hypre_ParCSRCommPkgRecvProcs(comm_pkg_j) = send_procs; hypre_ParCSRCommHandleDestroy(comm_handle); /-------------------------------------------------------------------------- compute B_int: row nnz to row ptrs --------------------------------------------------------------------------/ B_int_i_h[0] = 0; for (i = 1; i <= B_int_nrows; i++) { B_int_i_h[i] += B_int_i_h[i-1]; } B_int_nnz = B_int_i_h[B_int_nrows]; B_int_j_d = hypre_TAlloc(HYPRE_BigInt, B_int_nnz, HYPRE_MEMORY_DEVICE); B_int_a_d = hypre_TAlloc(HYPRE_Complex, B_int_nnz, HYPRE_MEMORY_DEVICE); for (i = 0; i <= num_sends; i++) { jdata_send_map_starts[i] = B_int_i_h[send_map_starts[i]]; } /* note the order of send/recv is reversed / hypre_ParCSRCommPkgRecvVecStarts(comm_pkg_j) = jdata_send_map_starts; hypre_ParCSRCommPkgSendMapStarts(comm_pkg_j) = jdata_recv_vec_starts; / send/recv CSR rows / comm_handle_a = hypre_ParCSRCommHandleCreate_v2( 1, comm_pkg_j, HYPRE_MEMORY_DEVICE, B_ext_a_d, HYPRE_MEMORY_DEVICE, B_int_a_d ); comm_handle_j = hypre_ParCSRCommHandleCreate_v2(21, comm_pkg_j, HYPRE_MEMORY_DEVICE, B_ext_j_d, HYPRE_MEMORY_DEVICE, B_int_j_d ); hypre_TMemcpy(B_int_i_d, B_int_i_h, HYPRE_Int, B_int_nrows+1, HYPRE_MEMORY_DEVICE, HYPRE_MEMORY_HOST); / create CSR: on device / B_int_d = hypre_CSRMatrixCreate(B_int_nrows, B_int_ncols, B_int_nnz); hypre_CSRMatrixI(B_int_d) = B_int_i_d; hypre_CSRMatrixBigJ(B_int_d) = B_int_j_d; hypre_CSRMatrixData(B_int_d) = B_int_a_d; hypre_CSRMatrixMemoryLocation(B_int_d) = HYPRE_MEMORY_DEVICE; / output / vrequest = hypre_TAlloc(void , 3, HYPRE_MEMORY_HOST); vrequest[0] = (void ) comm_handle_j; vrequest[1] = (void ) comm_handle_a; vrequest[2] = (void ) B_int_d; request_ptr = (void ) vrequest; / free / hypre_TFree(B_ext_rownnz_d, HYPRE_MEMORY_DEVICE); hypre_TFree(B_ext_rownnz_h, HYPRE_MEMORY_HOST); hypre_TFree(B_ext_i_h, HYPRE_MEMORY_HOST); hypre_TFree(hypre_ParCSRCommPkgSendMapStarts(comm_pkg_j), HYPRE_MEMORY_HOST); hypre_TFree(hypre_ParCSRCommPkgRecvVecStarts(comm_pkg_j), HYPRE_MEMORY_HOST); hypre_TFree(comm_pkg_j, HYPRE_MEMORY_HOST); return hypre_error_flag; } hypre_CSRMatrix hypre_ExchangeExternalRowsDeviceWait(void vrequest) { void request = (void ) vrequest; hypre_ParCSRCommHandle comm_handle_j = (hypre_ParCSRCommHandle ) request[0]; hypre_ParCSRCommHandle comm_handle_a = (hypre_ParCSRCommHandle ) request[1]; hypre_CSRMatrix B_int_d = (hypre_CSRMatrix ) request[2]; / communication done / hypre_ParCSRCommHandleDestroy(comm_handle_j); hypre_ParCSRCommHandleDestroy(comm_handle_a); hypre_TFree(request, HYPRE_MEMORY_HOST); return B_int_d; } / - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - / / - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - / / - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - / HYPRE_Int hypre_ParCSRMatrixExtractBExtDeviceInit( hypre_ParCSRMatrix B, hypre_ParCSRMatrix A, HYPRE_Int want_data, void request_ptr) { hypre_assert( hypre_CSRMatrixMemoryLocation(hypre_ParCSRMatrixDiag(B)) == hypre_CSRMatrixMemoryLocation(hypre_ParCSRMatrixOffd(B)) ); / hypre_assert( hypre_GetActualMemLocation( hypre_CSRMatrixMemoryLocation(hypre_ParCSRMatrixDiag(B))) == HYPRE_MEMORY_DEVICE ); / hypre_ParcsrGetExternalRowsDeviceInit(B, hypre_CSRMatrixNumCols(hypre_ParCSRMatrixOffd(A)), hypre_ParCSRMatrixColMapOffd(A), hypre_ParCSRMatrixCommPkg(A), want_data, request_ptr); return hypre_error_flag; } hypre_CSRMatrix hypre_ParCSRMatrixExtractBExtDeviceWait(void request) { return hypre_ParcsrGetExternalRowsDeviceWait(request); } hypre_CSRMatrix hypre_ParCSRMatrixExtractBExtDevice( hypre_ParCSRMatrix B, hypre_ParCSRMatrix A, HYPRE_Int want_data ) { void request; hypre_ParCSRMatrixExtractBExtDeviceInit(B, A, want_data, &request); return hypre_ParCSRMatrixExtractBExtDeviceWait(request); } /--------------------------- ---------------------------/ typedef thrust::tuple<HYPRE_Int, HYPRE_Int> Tuple; //typedef thrust::tuple<HYPRE_Int, HYPRE_Int, HYPRe_Int> Tuple3; struct FFFC_functor : public thrust::unary_function<Tuple, HYPRE_BigInt> { HYPRE_BigInt CF_first[2]; FFFC_functor(HYPRE_BigInt F_first_, HYPRE_BigInt C_first_) { CF_first[1] = F_first_; CF_first[0] = C_first_; } __host__ __device__ HYPRE_BigInt operator()(const Tuple& t) const { const HYPRE_Int local_idx = thrust::get<0>(t); const HYPRE_Int cf_marker = thrust::get<1>(t); const HYPRE_Int s = cf_marker < 0; const HYPRE_Int m = 1 - 2s; return m(local_idx + CF_first[s] + s); } }; template<bool FCOL, typename T> struct FFFC_pred : public thrust::unary_function<Tuple, bool> { HYPRE_Int row_CF_marker; T col_CF_marker; FFFC_pred(HYPRE_Int row_CF_marker_, T col_CF_marker_) { row_CF_marker = row_CF_marker_; col_CF_marker = col_CF_marker_; } __host__ __device__ bool operator()(const Tuple& t) const { const HYPRE_Int i = thrust::get<0>(t); const HYPRE_Int j = thrust::get<1>(t); if (FCOL) { /* AFF / return row_CF_marker[i] < 0 && (j == -2 \|\| j >= 0 && col_CF_marker[j] < 0); } else { / AFC / return row_CF_marker[i] < 0 && (j >= 0 && col_CF_marker[j] >= 0); } } }; HYPRE_Int hypre_ParCSRMatrixGenerateFFFCDevice( hypre_ParCSRMatrix A, HYPRE_Int CF_marker_host, HYPRE_BigInt cpts_starts, hypre_ParCSRMatrix S, hypre_ParCSRMatrix AFC_ptr, hypre_ParCSRMatrix AFF_ptr ) { MPI_Comm comm = hypre_ParCSRMatrixComm(A); hypre_ParCSRCommPkg comm_pkg = hypre_ParCSRMatrixCommPkg(A); hypre_ParCSRCommHandle comm_handle; HYPRE_Int num_sends = hypre_ParCSRCommPkgNumSends(comm_pkg); HYPRE_Int num_elem_send = hypre_ParCSRCommPkgSendMapStart(comm_pkg, num_sends); //HYPRE_MemoryLocation memory_location = hypre_ParCSRMatrixMemoryLocation(A); / diag part of A / hypre_CSRMatrix A_diag = hypre_ParCSRMatrixDiag(A); HYPRE_Complex A_diag_a = hypre_CSRMatrixData(A_diag); HYPRE_Int A_diag_i = hypre_CSRMatrixI(A_diag); HYPRE_Int A_diag_j = hypre_CSRMatrixJ(A_diag); HYPRE_Int A_diag_nnz = hypre_CSRMatrixNumNonzeros(A_diag); / offd part of A / hypre_CSRMatrix A_offd = hypre_ParCSRMatrixOffd(A); HYPRE_Complex A_offd_a = hypre_CSRMatrixData(A_offd); HYPRE_Int A_offd_i = hypre_CSRMatrixI(A_offd); //HYPRE_Int A_offd_j = hypre_CSRMatrixJ(A_offd); HYPRE_Int A_offd_nnz = hypre_CSRMatrixNumNonzeros(A_offd); HYPRE_Int num_cols_A_offd = hypre_CSRMatrixNumCols(A_offd); / SoC / HYPRE_Int Soc_diag_j = hypre_ParCSRMatrixSocDiagJ(S); HYPRE_Int Soc_offd_j = hypre_ParCSRMatrixSocOffdJ(S); / MPI size and rank/ HYPRE_Int my_id, num_procs; / nF and nC / HYPRE_Int n_local, nF_local, nC_local; HYPRE_BigInt fpts_starts, row_starts; HYPRE_BigInt n_global, nF_global, nC_global; HYPRE_BigInt F_first, C_first; HYPRE_Int CF_marker; /* AFF / HYPRE_Int AFF_diag_nnz, AFF_offd_nnz; HYPRE_Int AFF_diag_ii, AFF_diag_i, AFF_diag_j; HYPRE_Complex AFF_diag_a; HYPRE_Int AFF_offd_ii, AFF_offd_i, AFF_offd_j; HYPRE_Complex AFF_offd_a; hypre_ParCSRMatrix AFF; hypre_CSRMatrix AFF_diag, AFF_offd; HYPRE_BigInt col_map_offd_AFF; HYPRE_Int num_cols_AFF_offd; / AFC / HYPRE_Int AFC_diag_nnz, AFC_offd_nnz; HYPRE_Int AFC_diag_ii, AFC_diag_i, AFC_diag_j; HYPRE_Complex AFC_diag_a; HYPRE_Int AFC_offd_ii, AFC_offd_i, AFC_offd_j; HYPRE_Complex AFC_offd_a; hypre_ParCSRMatrix AFC; hypre_CSRMatrix AFC_diag, AFC_offd; HYPRE_BigInt col_map_offd_AFC; HYPRE_Int num_cols_AFC_offd; / work arrays / HYPRE_Int map2FC, itmp, A_diag_ii, A_offd_ii, tmp_j, offd_mark; HYPRE_BigInt send_buf, recv_buf; hypre_MPI_Comm_size(comm, &num_procs); hypre_MPI_Comm_rank(comm, &my_id); n_global = hypre_ParCSRMatrixGlobalNumRows(A); n_local = hypre_ParCSRMatrixNumRows(A); row_starts = hypre_ParCSRMatrixRowStarts(A); map2FC = hypre_TAlloc(HYPRE_Int, n_local, HYPRE_MEMORY_DEVICE); itmp = hypre_TAlloc(HYPRE_Int, n_local, HYPRE_MEMORY_DEVICE);; recv_buf = hypre_TAlloc(HYPRE_BigInt, num_cols_A_offd, HYPRE_MEMORY_DEVICE); #ifdef HYPRE_NO_GLOBAL_PARTITION if (my_id == (num_procs -1)) { nC_global = cpts_starts[1]; } hypre_MPI_Bcast(&nC_global, 1, HYPRE_MPI_BIG_INT, num_procs-1, comm); nC_local = (HYPRE_Int) (cpts_starts[1] - cpts_starts[0]); fpts_starts = hypre_TAlloc(HYPRE_BigInt, 2, HYPRE_MEMORY_HOST); fpts_starts[0] = row_starts[0] - cpts_starts[0]; fpts_starts[1] = row_starts[1] - cpts_starts[1]; F_first = fpts_starts[0]; C_first = cpts_starts[0]; #else nC_global = cpts_starts[num_procs]; nC_local = (HYPRE_Int)(cpts_starts[my_id+1] - cpts_starts[my_id]); fpts_starts = hypre_TAlloc(HYPRE_BigInt, num_procs+1, HYPRE_MEMORY_HOST); for (i = 0; i <= num_procs; i++) { fpts_starts[i] = row_starts[i] - cpts_starts[i]; } F_first = fpts_starts[myid]; C_first = cpts_starts[myid]; #endif nF_local = n_local - nC_local; nF_global = n_global - nC_global; CF_marker = hypre_TAlloc(HYPRE_Int, n_local, HYPRE_MEMORY_DEVICE); hypre_TMemcpy( CF_marker, CF_marker_host, HYPRE_Int, n_local, HYPRE_MEMORY_DEVICE, HYPRE_MEMORY_HOST ); / map from F+C to F/C indices / HYPRE_THRUST_CALL( exclusive_scan, thrust::make_transform_iterator(CF_marker, is_negative<HYPRE_Int>()), thrust::make_transform_iterator(CF_marker + n_local, is_negative<HYPRE_Int>()), map2FC ); / F / HYPRE_THRUST_CALL( exclusive_scan, thrust::make_transform_iterator(CF_marker, is_nonnegative<HYPRE_Int>()), thrust::make_transform_iterator(CF_marker + n_local, is_nonnegative<HYPRE_Int>()), itmp ); / C / HYPRE_THRUST_CALL( scatter_if, itmp, itmp + n_local, thrust::counting_iterator<HYPRE_Int>(0), thrust::make_transform_iterator(CF_marker, is_nonnegative<HYPRE_Int>()), map2FC ); / FC combined / hypre_TFree(itmp, HYPRE_MEMORY_DEVICE); / send_buf: global F/C indices. Note F-pts are saved as "-x-1" / send_buf = hypre_TAlloc(HYPRE_BigInt, num_elem_send, HYPRE_MEMORY_DEVICE); hypre_ParCSRCommPkgCopySendMapElmtsToDevice(comm_pkg); FFFC_functor functor(F_first, C_first); HYPRE_THRUST_CALL( gather, hypre_ParCSRCommPkgDeviceSendMapElmts(comm_pkg), hypre_ParCSRCommPkgDeviceSendMapElmts(comm_pkg) + num_elem_send, thrust::make_transform_iterator(thrust::make_zip_iterator(thrust::make_tuple(map2FC, CF_marker)), functor), send_buf ); comm_handle = hypre_ParCSRCommHandleCreate_v2(21, comm_pkg, HYPRE_MEMORY_DEVICE, send_buf, HYPRE_MEMORY_DEVICE, recv_buf); hypre_ParCSRCommHandleDestroy(comm_handle); hypre_TFree(send_buf, HYPRE_MEMORY_DEVICE); / Diag / thrust::zip_iterator< thrust::tuple<HYPRE_Int, HYPRE_Int, HYPRE_Complex> > new_end; A_diag_ii = hypre_TAlloc(HYPRE_Int, A_diag_nnz, HYPRE_MEMORY_DEVICE); hypreDevice_CsrRowPtrsToIndices_v2(n_local, A_diag_nnz, A_diag_i, A_diag_ii); /* AFF Diag / FFFC_pred<true, HYPRE_Int> AFF_pred_diag(CF_marker, CF_marker); AFF_diag_nnz = HYPRE_THRUST_CALL( count_if, thrust::make_zip_iterator(thrust::make_tuple(A_diag_ii, Soc_diag_j)), thrust::make_zip_iterator(thrust::make_tuple(A_diag_ii, Soc_diag_j)) + A_diag_nnz, AFF_pred_diag ); AFF_diag_ii = hypre_TAlloc(HYPRE_Int, AFF_diag_nnz, HYPRE_MEMORY_DEVICE); AFF_diag_j = hypre_TAlloc(HYPRE_Int, AFF_diag_nnz, HYPRE_MEMORY_DEVICE); AFF_diag_a = hypre_TAlloc(HYPRE_Complex, AFF_diag_nnz, HYPRE_MEMORY_DEVICE); new_end = HYPRE_THRUST_CALL( copy_if, thrust::make_zip_iterator(thrust::make_tuple(A_diag_ii, A_diag_j, A_diag_a)), thrust::make_zip_iterator(thrust::make_tuple(A_diag_ii, A_diag_j, A_diag_a)) + A_diag_nnz, thrust::make_zip_iterator(thrust::make_tuple(A_diag_ii, Soc_diag_j)), thrust::make_zip_iterator(thrust::make_tuple(AFF_diag_ii, AFF_diag_j, AFF_diag_a)), AFF_pred_diag ); hypre_assert( thrust::get<0>(new_end.get_iterator_tuple()) == AFF_diag_ii + AFF_diag_nnz ); HYPRE_THRUST_CALL ( gather, AFF_diag_j, AFF_diag_j + AFF_diag_nnz, map2FC, AFF_diag_j ); HYPRE_THRUST_CALL ( gather, AFF_diag_ii, AFF_diag_ii + AFF_diag_nnz, map2FC, AFF_diag_ii ); AFF_diag_i = hypreDevice_CsrRowIndicesToPtrs(nF_local, AFF_diag_nnz, AFF_diag_ii); hypre_TFree(AFF_diag_ii, HYPRE_MEMORY_DEVICE); / AFC Diag / FFFC_pred<false, HYPRE_Int> AFC_pred_diag(CF_marker, CF_marker); AFC_diag_nnz = HYPRE_THRUST_CALL( count_if, thrust::make_zip_iterator(thrust::make_tuple(A_diag_ii, Soc_diag_j)), thrust::make_zip_iterator(thrust::make_tuple(A_diag_ii, Soc_diag_j)) + A_diag_nnz, AFC_pred_diag ); AFC_diag_ii = hypre_TAlloc(HYPRE_Int, AFC_diag_nnz, HYPRE_MEMORY_DEVICE); AFC_diag_j = hypre_TAlloc(HYPRE_Int, AFC_diag_nnz, HYPRE_MEMORY_DEVICE); AFC_diag_a = hypre_TAlloc(HYPRE_Complex, AFC_diag_nnz, HYPRE_MEMORY_DEVICE); new_end = HYPRE_THRUST_CALL( copy_if, thrust::make_zip_iterator(thrust::make_tuple(A_diag_ii, Soc_diag_j, A_diag_a)), thrust::make_zip_iterator(thrust::make_tuple(A_diag_ii, Soc_diag_j, A_diag_a)) + A_diag_nnz, thrust::make_zip_iterator(thrust::make_tuple(A_diag_ii, Soc_diag_j)), thrust::make_zip_iterator(thrust::make_tuple(AFC_diag_ii, AFC_diag_j, AFC_diag_a)), AFC_pred_diag ); hypre_TFree(A_diag_ii, HYPRE_MEMORY_DEVICE); hypre_assert( thrust::get<0>(new_end.get_iterator_tuple()) == AFC_diag_ii + AFC_diag_nnz ); HYPRE_THRUST_CALL ( gather, AFC_diag_j, AFC_diag_j + AFC_diag_nnz, map2FC, AFC_diag_j ); HYPRE_THRUST_CALL ( gather, AFC_diag_ii, AFC_diag_ii + AFC_diag_nnz, map2FC, AFC_diag_ii ); AFC_diag_i = hypreDevice_CsrRowIndicesToPtrs(nF_local, AFC_diag_nnz, AFC_diag_ii); hypre_TFree(AFC_diag_ii, HYPRE_MEMORY_DEVICE); / Offd / A_offd_ii = hypre_TAlloc(HYPRE_Int, A_offd_nnz, HYPRE_MEMORY_DEVICE); hypreDevice_CsrRowPtrsToIndices_v2(n_local, A_offd_nnz, A_offd_i, A_offd_ii); / AFF Offd / FFFC_pred<true, HYPRE_BigInt> AFF_pred_offd(CF_marker, recv_buf); AFF_offd_nnz = HYPRE_THRUST_CALL( count_if, thrust::make_zip_iterator(thrust::make_tuple(A_offd_ii, Soc_offd_j)), thrust::make_zip_iterator(thrust::make_tuple(A_offd_ii, Soc_offd_j)) + A_offd_nnz, AFF_pred_offd ); AFF_offd_ii = hypre_TAlloc(HYPRE_Int, AFF_offd_nnz, HYPRE_MEMORY_DEVICE); AFF_offd_j = hypre_TAlloc(HYPRE_Int, AFF_offd_nnz, HYPRE_MEMORY_DEVICE); AFF_offd_a = hypre_TAlloc(HYPRE_Complex, AFF_offd_nnz, HYPRE_MEMORY_DEVICE); new_end = HYPRE_THRUST_CALL( copy_if, thrust::make_zip_iterator(thrust::make_tuple(A_offd_ii, Soc_offd_j, A_offd_a)), thrust::make_zip_iterator(thrust::make_tuple(A_offd_ii, Soc_offd_j, A_offd_a)) + A_offd_nnz, thrust::make_zip_iterator(thrust::make_tuple(A_offd_ii, Soc_offd_j)), thrust::make_zip_iterator(thrust::make_tuple(AFF_offd_ii, AFF_offd_j, AFF_offd_a)), AFF_pred_offd ); hypre_assert( thrust::get<0>(new_end.get_iterator_tuple()) == AFF_offd_ii + AFF_offd_nnz ); HYPRE_THRUST_CALL ( gather, AFF_offd_ii, AFF_offd_ii + AFF_offd_nnz, map2FC, AFF_offd_ii ); AFF_offd_i = hypreDevice_CsrRowIndicesToPtrs(nF_local, AFF_offd_nnz, AFF_offd_ii); hypre_TFree(AFF_offd_ii, HYPRE_MEMORY_DEVICE); / AFC Offd / FFFC_pred<false, HYPRE_BigInt> AFC_pred_offd(CF_marker, recv_buf); AFC_offd_nnz = HYPRE_THRUST_CALL( count_if, thrust::make_zip_iterator(thrust::make_tuple(A_offd_ii, Soc_offd_j)), thrust::make_zip_iterator(thrust::make_tuple(A_offd_ii, Soc_offd_j)) + A_offd_nnz, AFC_pred_offd ); AFC_offd_ii = hypre_TAlloc(HYPRE_Int, AFC_offd_nnz, HYPRE_MEMORY_DEVICE); AFC_offd_j = hypre_TAlloc(HYPRE_Int, AFC_offd_nnz, HYPRE_MEMORY_DEVICE); AFC_offd_a = hypre_TAlloc(HYPRE_Complex, AFC_offd_nnz, HYPRE_MEMORY_DEVICE); new_end = HYPRE_THRUST_CALL( copy_if, thrust::make_zip_iterator(thrust::make_tuple(A_offd_ii, Soc_offd_j, A_offd_a)), thrust::make_zip_iterator(thrust::make_tuple(A_offd_ii, Soc_offd_j, A_offd_a)) + A_offd_nnz, thrust::make_zip_iterator(thrust::make_tuple(A_offd_ii, Soc_offd_j)), thrust::make_zip_iterator(thrust::make_tuple(AFC_offd_ii, AFC_offd_j, AFC_offd_a)), AFC_pred_offd ); hypre_TFree(A_offd_ii, HYPRE_MEMORY_DEVICE); hypre_assert( thrust::get<0>(new_end.get_iterator_tuple()) == AFC_offd_ii + AFC_offd_nnz ); HYPRE_THRUST_CALL ( gather, AFC_offd_ii, AFC_offd_ii + AFC_offd_nnz, map2FC, AFC_offd_ii ); AFC_offd_i = hypreDevice_CsrRowIndicesToPtrs(nF_local, AFC_offd_nnz, AFC_offd_ii); hypre_TFree(AFC_offd_ii, HYPRE_MEMORY_DEVICE); hypre_TFree(CF_marker, HYPRE_MEMORY_DEVICE); hypre_TFree(map2FC, HYPRE_MEMORY_DEVICE); / col_map_offd_AFF / HYPRE_Int tmp_j_size = hypre_max(hypre_max(AFF_offd_nnz, AFC_offd_nnz), num_cols_A_offd); tmp_j = hypre_TAlloc(HYPRE_Int, tmp_j_size, HYPRE_MEMORY_DEVICE); offd_mark = hypre_TAlloc(HYPRE_Int, num_cols_A_offd, HYPRE_MEMORY_DEVICE); HYPRE_Int tmp_end; hypre_TMemcpy(tmp_j, AFF_offd_j, HYPRE_Int, AFF_offd_nnz, HYPRE_MEMORY_DEVICE, HYPRE_MEMORY_DEVICE); HYPRE_THRUST_CALL(sort, tmp_j, tmp_j + AFF_offd_nnz); tmp_end = HYPRE_THRUST_CALL(unique, tmp_j, tmp_j + AFF_offd_nnz); num_cols_AFF_offd = tmp_end - tmp_j; HYPRE_THRUST_CALL(fill_n, offd_mark, num_cols_A_offd, 0); hypreDevice_ScatterConstant(offd_mark, num_cols_AFF_offd, tmp_j, 1); HYPRE_THRUST_CALL(exclusive_scan, offd_mark, offd_mark + num_cols_A_offd, tmp_j); HYPRE_THRUST_CALL(gather, AFF_offd_j, AFF_offd_j + AFF_offd_nnz, tmp_j, AFF_offd_j); col_map_offd_AFF = hypre_TAlloc(HYPRE_Int, num_cols_AFF_offd, HYPRE_MEMORY_DEVICE); tmp_end = HYPRE_THRUST_CALL( copy_if, thrust::make_transform_iterator(recv_buf, -_1-1), thrust::make_transform_iterator(recv_buf, -_1-1) + num_cols_A_offd, offd_mark, col_map_offd_AFF, thrust::identity<HYPRE_Int>() ); hypre_assert(tmp_end - col_map_offd_AFF == num_cols_AFF_offd); /* col_map_offd_AFC / hypre_TMemcpy(tmp_j, AFC_offd_j, HYPRE_Int, AFC_offd_nnz, HYPRE_MEMORY_DEVICE, HYPRE_MEMORY_DEVICE); HYPRE_THRUST_CALL(sort, tmp_j, tmp_j + AFC_offd_nnz); tmp_end = HYPRE_THRUST_CALL(unique, tmp_j, tmp_j + AFC_offd_nnz); num_cols_AFC_offd = tmp_end - tmp_j; HYPRE_THRUST_CALL(fill_n, offd_mark, num_cols_A_offd, 0); hypreDevice_ScatterConstant(offd_mark, num_cols_AFC_offd, tmp_j, 1); HYPRE_THRUST_CALL(exclusive_scan, offd_mark, offd_mark + num_cols_A_offd, tmp_j); HYPRE_THRUST_CALL(gather, AFC_offd_j, AFC_offd_j + AFC_offd_nnz, tmp_j, AFC_offd_j); col_map_offd_AFC = hypre_TAlloc(HYPRE_Int, num_cols_AFC_offd, HYPRE_MEMORY_DEVICE); tmp_end = HYPRE_THRUST_CALL( copy_if, recv_buf, recv_buf + num_cols_A_offd, offd_mark, col_map_offd_AFC, thrust::identity<HYPRE_Int>()); hypre_assert(tmp_end - col_map_offd_AFC == num_cols_AFC_offd); hypre_TFree(tmp_j, HYPRE_MEMORY_DEVICE); hypre_TFree(offd_mark, HYPRE_MEMORY_DEVICE); hypre_TFree(recv_buf, HYPRE_MEMORY_DEVICE); //printf("AFF_diag_nnz %d, AFF_offd_nnz %d, AFC_diag_nnz %d, AFC_offd_nnz %d\n", AFF_diag_nnz, AFF_offd_nnz, AFC_diag_nnz, AFC_offd_nnz); / AFF / AFF = hypre_ParCSRMatrixCreate(comm, nF_global, nF_global, fpts_starts, fpts_starts, num_cols_AFF_offd, AFF_diag_nnz, AFF_offd_nnz); hypre_ParCSRMatrixOwnsRowStarts(AFF) = 1; hypre_ParCSRMatrixOwnsColStarts(AFF) = 0; AFF_diag = hypre_ParCSRMatrixDiag(AFF); hypre_CSRMatrixData(AFF_diag) = AFF_diag_a; hypre_CSRMatrixI(AFF_diag) = AFF_diag_i; hypre_CSRMatrixJ(AFF_diag) = AFF_diag_j; AFF_offd = hypre_ParCSRMatrixOffd(AFF); hypre_CSRMatrixData(AFF_offd) = AFF_offd_a; hypre_CSRMatrixI(AFF_offd) = AFF_offd_i; hypre_CSRMatrixJ(AFF_offd) = AFF_offd_j; hypre_CSRMatrixMemoryLocation(AFF_diag) = HYPRE_MEMORY_DEVICE; hypre_CSRMatrixMemoryLocation(AFF_offd) = HYPRE_MEMORY_DEVICE; hypre_ParCSRMatrixDeviceColMapOffd(AFF) = col_map_offd_AFF; hypre_ParCSRMatrixColMapOffd(AFF) = hypre_TAlloc(HYPRE_BigInt, num_cols_AFF_offd, HYPRE_MEMORY_HOST); hypre_TMemcpy(hypre_ParCSRMatrixColMapOffd(AFF), col_map_offd_AFF, HYPRE_BigInt, num_cols_AFF_offd, HYPRE_MEMORY_HOST, HYPRE_MEMORY_DEVICE); hypre_ParCSRMatrixSetNumNonzeros(AFF); hypre_ParCSRMatrixDNumNonzeros(AFF) = (HYPRE_Real) hypre_ParCSRMatrixNumNonzeros(AFF); hypre_MatvecCommPkgCreate(AFF); / AFC / AFC = hypre_ParCSRMatrixCreate(comm, nF_global, nC_global, fpts_starts, cpts_starts, num_cols_AFC_offd, AFC_diag_nnz, AFC_offd_nnz); hypre_ParCSRMatrixOwnsRowStarts(AFC) = 0; hypre_ParCSRMatrixOwnsColStarts(AFC) = 0; AFC_diag = hypre_ParCSRMatrixDiag(AFC); hypre_CSRMatrixData(AFC_diag) = AFC_diag_a; hypre_CSRMatrixI(AFC_diag) = AFC_diag_i; hypre_CSRMatrixJ(AFC_diag) = AFC_diag_j; AFC_offd = hypre_ParCSRMatrixOffd(AFC); hypre_CSRMatrixData(AFC_offd) = AFC_offd_a; hypre_CSRMatrixI(AFC_offd) = AFC_offd_i; hypre_CSRMatrixJ(AFC_offd) = AFC_offd_j; hypre_CSRMatrixMemoryLocation(AFC_diag) = HYPRE_MEMORY_DEVICE; hypre_CSRMatrixMemoryLocation(AFC_offd) = HYPRE_MEMORY_DEVICE; hypre_ParCSRMatrixDeviceColMapOffd(AFC) = col_map_offd_AFC; hypre_ParCSRMatrixColMapOffd(AFC) = hypre_TAlloc(HYPRE_BigInt, num_cols_AFC_offd, HYPRE_MEMORY_HOST); hypre_TMemcpy(hypre_ParCSRMatrixColMapOffd(AFC), col_map_offd_AFC, HYPRE_BigInt, num_cols_AFC_offd, HYPRE_MEMORY_HOST, HYPRE_MEMORY_DEVICE); hypre_ParCSRMatrixSetNumNonzeros(AFC); hypre_ParCSRMatrixDNumNonzeros(AFC) = (HYPRE_Real) hypre_ParCSRMatrixNumNonzeros(AFC); hypre_MatvecCommPkgCreate(AFC); AFC_ptr = AFC; AFF_ptr = AFF; return hypre_error_flag; } / return B = [Adiag, Aoffd] / #if 1 __global__ void hypreCUDAKernel_ConcatDiagAndOffd(HYPRE_Int nrows, HYPRE_Int diag_ncol, HYPRE_Int d_diag_i, HYPRE_Int d_diag_j, HYPRE_Complex d_diag_a, HYPRE_Int d_offd_i, HYPRE_Int d_offd_j, HYPRE_Complex d_offd_a, HYPRE_Int cols_offd_map, HYPRE_Int d_ib, HYPRE_Int d_jb, HYPRE_Complex d_ab) { const HYPRE_Int row = hypre_cuda_get_grid_warp_id<1,1>(); if (row >= nrows) { return; } / lane id inside the warp / const HYPRE_Int lane_id = hypre_cuda_get_lane_id<1>(); HYPRE_Int i, j, k, p, istart, iend, bstart; / diag part / if (lane_id < 2) { j = read_only_load(d_diag_i + row + lane_id); } if (lane_id == 0) { k = read_only_load(d_ib + row); } istart = __shfl_sync(HYPRE_WARP_FULL_MASK, j, 0); iend = __shfl_sync(HYPRE_WARP_FULL_MASK, j, 1); bstart = __shfl_sync(HYPRE_WARP_FULL_MASK, k, 0); p = bstart - istart; for (i = istart + lane_id; i < iend; i += HYPRE_WARP_SIZE) { d_jb[p+i] = read_only_load(d_diag_j + i); d_ab[p+i] = read_only_load(d_diag_a + i); } / offd part / if (lane_id < 2) { j = read_only_load(d_offd_i + row + lane_id); } bstart += iend - istart; istart = __shfl_sync(HYPRE_WARP_FULL_MASK, j, 0); iend = __shfl_sync(HYPRE_WARP_FULL_MASK, j, 1); p = bstart - istart; for (i = istart + lane_id; i < iend; i += HYPRE_WARP_SIZE) { const HYPRE_Int t = read_only_load(d_offd_j + i); d_jb[p+i] = (cols_offd_map ? read_only_load(&cols_offd_map[t]) : t) + diag_ncol; d_ab[p+i] = read_only_load(d_offd_a + i); } } hypre_CSRMatrix hypre_ConcatDiagAndOffdDevice(hypre_ParCSRMatrix A) { hypre_CSRMatrix A_diag = hypre_ParCSRMatrixDiag(A); hypre_CSRMatrix A_offd = hypre_ParCSRMatrixOffd(A); hypre_CSRMatrix B = hypre_CSRMatrixCreate( hypre_CSRMatrixNumRows(A_diag), hypre_CSRMatrixNumCols(A_diag) + hypre_CSRMatrixNumCols(A_offd), hypre_CSRMatrixNumNonzeros(A_diag) + hypre_CSRMatrixNumNonzeros(A_offd) ); hypre_CSRMatrixInitialize_v2(B, 0, HYPRE_MEMORY_DEVICE); hypreDevice_GetRowNnz(hypre_CSRMatrixNumRows(B), NULL, hypre_CSRMatrixI(A_diag), hypre_CSRMatrixI(A_offd), hypre_CSRMatrixI(B)); HYPRE_THRUST_CALL( exclusive_scan, hypre_CSRMatrixI(B), hypre_CSRMatrixI(B) + hypre_CSRMatrixNumRows(B) + 1, hypre_CSRMatrixI(B) ); const dim3 bDim = hypre_GetDefaultCUDABlockDimension(); const dim3 gDim = hypre_GetDefaultCUDAGridDimension(hypre_CSRMatrixNumRows(A_diag), "warp", bDim); HYPRE_CUDA_LAUNCH( hypreCUDAKernel_ConcatDiagAndOffd, gDim, bDim, hypre_CSRMatrixNumRows(A_diag), hypre_CSRMatrixNumCols(A_diag), hypre_CSRMatrixI(A_diag), hypre_CSRMatrixJ(A_diag), hypre_CSRMatrixData(A_diag), hypre_CSRMatrixI(A_offd), hypre_CSRMatrixJ(A_offd), hypre_CSRMatrixData(A_offd), NULL, hypre_CSRMatrixI(B), hypre_CSRMatrixJ(B), hypre_CSRMatrixData(B) ); return B; } #else hypre_CSRMatrix* hypre_ConcatDiagAndOffdDevice(hypre_ParCSRMatrix A) { hypre_CSRMatrix A_diag = hypre_ParCSRMatrixDiag(A); HYPRE_Int A_diag_i = hypre_CSRMatrixI(A_diag); HYPRE_Int A_diag_j = hypre_CSRMatrixJ(A_diag); HYPRE_Complex A_diag_a = hypre_CSRMatrixData(A_diag); HYPRE_Int A_diag_nnz = hypre_CSRMatrixNumNonzeros(A_diag); hypre_CSRMatrix A_offd = hypre_ParCSRMatrixOffd(A); HYPRE_Int A_offd_i = hypre_CSRMatrixI(A_offd); HYPRE_Int A_offd_j = hypre_CSRMatrixJ(A_offd); HYPRE_Complex A_offd_a = hypre_CSRMatrixData(A_offd); HYPRE_Int A_offd_nnz = hypre_CSRMatrixNumNonzeros(A_offd); hypre_CSRMatrix B; HYPRE_Int B_nrows = hypre_CSRMatrixNumRows(A_diag); HYPRE_Int B_ncols = hypre_CSRMatrixNumCols(A_diag) + hypre_CSRMatrixNumCols(A_offd); HYPRE_Int B_nnz = A_diag_nnz + A_offd_nnz; HYPRE_Int B_ii = hypre_TAlloc(HYPRE_Int, B_nnz, HYPRE_MEMORY_DEVICE); HYPRE_Int B_j = hypre_TAlloc(HYPRE_Int, B_nnz, HYPRE_MEMORY_DEVICE); HYPRE_Complex B_a = hypre_TAlloc(HYPRE_Complex, B_nnz, HYPRE_MEMORY_DEVICE); // Adiag HYPRE_Int A_diag_ii = hypreDevice_CsrRowPtrsToIndices(B_nrows, A_diag_nnz, A_diag_i); HYPRE_THRUST_CALL( copy_n, thrust::make_zip_iterator(thrust::make_tuple(A_diag_ii, A_diag_j, A_diag_a)), A_diag_nnz, thrust::make_zip_iterator(thrust::make_tuple(B_ii, B_j, B_a)) ); hypre_TFree(A_diag_ii, HYPRE_MEMORY_DEVICE); // Aoffd HYPRE_Int A_offd_ii = hypreDevice_CsrRowPtrsToIndices(B_nrows, A_offd_nnz, A_offd_i); HYPRE_THRUST_CALL( copy_n, thrust::make_zip_iterator(thrust::make_tuple(A_offd_ii, A_offd_a)), A_offd_nnz, thrust::make_zip_iterator(thrust::make_tuple(B_ii, B_a)) + A_diag_nnz ); hypre_TFree(A_offd_ii, HYPRE_MEMORY_DEVICE); HYPRE_THRUST_CALL( transform, A_offd_j, A_offd_j + A_offd_nnz, thrust::make_constant_iterator(hypre_CSRMatrixNumCols(A_diag)), B_j + A_diag_nnz, thrust::plus<HYPRE_Int>() ); // B HYPRE_THRUST_CALL( stable_sort_by_key, B_ii, B_ii + B_nnz, thrust::make_zip_iterator(thrust::make_tuple(B_j, B_a)) ); HYPRE_Int B_i = hypreDevice_CsrRowIndicesToPtrs(B_nrows, B_nnz, B_ii); hypre_TFree(B_ii, HYPRE_MEMORY_DEVICE); B = hypre_CSRMatrixCreate(B_nrows, B_ncols, B_nnz); hypre_CSRMatrixI(B) = B_i; hypre_CSRMatrixJ(B) = B_j; hypre_CSRMatrixData(B) = B_a; hypre_CSRMatrixMemoryLocation(B) = HYPRE_MEMORY_DEVICE; return B; } #endif /* return B = [Adiag, Aoffd; E] / #if 1 HYPRE_Int hypre_ConcatDiagOffdAndExtDevice(hypre_ParCSRMatrix A, hypre_CSRMatrix E, hypre_CSRMatrix B_ptr, HYPRE_Int num_cols_offd_ptr, HYPRE_BigInt *cols_map_offd_ptr) { hypre_CSRMatrix A_diag = hypre_ParCSRMatrixDiag(A); hypre_CSRMatrix A_offd = hypre_ParCSRMatrixOffd(A); hypre_CSRMatrix E_diag, E_offd, B; HYPRE_Int cols_offd_map, num_cols_offd; HYPRE_BigInt cols_map_offd; hypre_CSRMatrixSplitDevice(E, hypre_ParCSRMatrixFirstColDiag(A), hypre_ParCSRMatrixLastColDiag(A), hypre_CSRMatrixNumCols(A_offd), hypre_ParCSRMatrixDeviceColMapOffd(A), &cols_offd_map, &num_cols_offd, &cols_map_offd, &E_diag, &E_offd); B = hypre_CSRMatrixCreate(hypre_ParCSRMatrixNumRows(A) + hypre_CSRMatrixNumRows(E), hypre_ParCSRMatrixNumCols(A) + num_cols_offd, hypre_CSRMatrixNumNonzeros(A_diag) + hypre_CSRMatrixNumNonzeros(A_offd) + hypre_CSRMatrixNumNonzeros(E)); hypre_CSRMatrixInitialize_v2(B, 0, HYPRE_MEMORY_DEVICE); hypreDevice_GetRowNnz(hypre_ParCSRMatrixNumRows(A), NULL, hypre_CSRMatrixI(A_diag), hypre_CSRMatrixI(A_offd), hypre_CSRMatrixI(B)); HYPRE_THRUST_CALL( exclusive_scan, hypre_CSRMatrixI(B), hypre_CSRMatrixI(B) + hypre_ParCSRMatrixNumRows(A) + 1, hypre_CSRMatrixI(B) ); dim3 bDim = hypre_GetDefaultCUDABlockDimension(); dim3 gDim = hypre_GetDefaultCUDAGridDimension(hypre_ParCSRMatrixNumRows(A), "warp", bDim); HYPRE_CUDA_LAUNCH( hypreCUDAKernel_ConcatDiagAndOffd, gDim, bDim, hypre_CSRMatrixNumRows(A_diag), hypre_CSRMatrixNumCols(A_diag), hypre_CSRMatrixI(A_diag), hypre_CSRMatrixJ(A_diag), hypre_CSRMatrixData(A_diag), hypre_CSRMatrixI(A_offd), hypre_CSRMatrixJ(A_offd), hypre_CSRMatrixData(A_offd), cols_offd_map, hypre_CSRMatrixI(B), hypre_CSRMatrixJ(B), hypre_CSRMatrixData(B) ); hypre_TFree(cols_offd_map, HYPRE_MEMORY_DEVICE); hypre_TMemcpy(hypre_CSRMatrixI(B) + hypre_ParCSRMatrixNumRows(A) + 1, hypre_CSRMatrixI(E) + 1, HYPRE_Int, hypre_CSRMatrixNumRows(E), HYPRE_MEMORY_DEVICE, HYPRE_MEMORY_DEVICE); HYPRE_THRUST_CALL( transform, hypre_CSRMatrixI(B) + hypre_ParCSRMatrixNumRows(A) + 1, hypre_CSRMatrixI(B) + hypre_ParCSRMatrixNumRows(A) + hypre_CSRMatrixNumRows(E) + 1, thrust::make_constant_iterator(hypre_CSRMatrixNumNonzeros(A_diag) + hypre_CSRMatrixNumNonzeros(A_offd)), hypre_CSRMatrixI(B) + hypre_ParCSRMatrixNumRows(A) + 1, thrust::plus<HYPRE_Int>() ); gDim = hypre_GetDefaultCUDAGridDimension(hypre_CSRMatrixNumRows(E), "warp", bDim); hypre_assert(hypre_CSRMatrixNumCols(E_diag) == hypre_CSRMatrixNumCols(A_diag)); HYPRE_CUDA_LAUNCH( hypreCUDAKernel_ConcatDiagAndOffd, gDim, bDim, hypre_CSRMatrixNumRows(E_diag), hypre_CSRMatrixNumCols(E_diag), hypre_CSRMatrixI(E_diag), hypre_CSRMatrixJ(E_diag), hypre_CSRMatrixData(E_diag), hypre_CSRMatrixI(E_offd), hypre_CSRMatrixJ(E_offd), hypre_CSRMatrixData(E_offd), NULL, hypre_CSRMatrixI(B) + hypre_ParCSRMatrixNumRows(A), hypre_CSRMatrixJ(B), hypre_CSRMatrixData(B) ); hypre_CSRMatrixDestroy(E_diag); hypre_CSRMatrixDestroy(E_offd); B_ptr = B; num_cols_offd_ptr = num_cols_offd; cols_map_offd_ptr = cols_map_offd; return hypre_error_flag; } #else HYPRE_Int hypre_ConcatDiagOffdAndExtDevice(hypre_ParCSRMatrix A, hypre_CSRMatrix E, hypre_CSRMatrix B_ptr, HYPRE_Int num_cols_offd_ptr, HYPRE_BigInt *cols_map_offd_ptr) { hypre_CSRMatrix A_diag = hypre_ParCSRMatrixDiag(A); HYPRE_Int A_nrows = hypre_CSRMatrixNumRows(A_diag); HYPRE_Int A_ncols = hypre_CSRMatrixNumCols(A_diag); HYPRE_Int A_diag_i = hypre_CSRMatrixI(A_diag); HYPRE_Int A_diag_j = hypre_CSRMatrixJ(A_diag); HYPRE_Complex A_diag_a = hypre_CSRMatrixData(A_diag); HYPRE_Int A_diag_nnz = hypre_CSRMatrixNumNonzeros(A_diag); hypre_CSRMatrix A_offd = hypre_ParCSRMatrixOffd(A); HYPRE_Int A_offd_i = hypre_CSRMatrixI(A_offd); HYPRE_Int A_offd_j = hypre_CSRMatrixJ(A_offd); HYPRE_Complex A_offd_a = hypre_CSRMatrixData(A_offd); HYPRE_Int A_offd_nnz = hypre_CSRMatrixNumNonzeros(A_offd); HYPRE_BigInt first_col_A = hypre_ParCSRMatrixFirstColDiag(A); HYPRE_BigInt last_col_A = hypre_ParCSRMatrixLastColDiag(A); HYPRE_Int num_cols_offd_A = hypre_CSRMatrixNumCols(A_offd); HYPRE_BigInt col_map_offd_A = hypre_ParCSRMatrixDeviceColMapOffd(A); HYPRE_Int E_i = hypre_CSRMatrixI(E); HYPRE_BigInt E_bigj = hypre_CSRMatrixBigJ(E); HYPRE_Complex E_a = hypre_CSRMatrixData(E); HYPRE_Int E_nrows = hypre_CSRMatrixNumRows(E); HYPRE_Int E_nnz = hypre_CSRMatrixNumNonzeros(E); HYPRE_Int E_diag_nnz, E_offd_nnz; hypre_CSRMatrix B; HYPRE_Int B_nnz = A_diag_nnz + A_offd_nnz + E_nnz; HYPRE_Int B_ii = hypre_TAlloc(HYPRE_Int, B_nnz, HYPRE_MEMORY_DEVICE); HYPRE_Int B_j = hypre_TAlloc(HYPRE_Int, B_nnz, HYPRE_MEMORY_DEVICE); HYPRE_Complex B_a = hypre_TAlloc(HYPRE_Complex, B_nnz, HYPRE_MEMORY_DEVICE); // E hypre_CSRMatrixSplitDevice_core(0, E_nrows, E_nnz, NULL, E_bigj, NULL, NULL, first_col_A, last_col_A, num_cols_offd_A, NULL, NULL, NULL, NULL, &E_diag_nnz, NULL, NULL, NULL, NULL, &E_offd_nnz, NULL, NULL, NULL, NULL); HYPRE_Int cols_offd_map, num_cols_offd; HYPRE_BigInt cols_map_offd; HYPRE_Int E_ii = hypreDevice_CsrRowPtrsToIndices(E_nrows, E_nnz, E_i); hypre_CSRMatrixSplitDevice_core(1, E_nrows, E_nnz, E_ii, E_bigj, E_a, NULL, first_col_A, last_col_A, num_cols_offd_A, col_map_offd_A, &cols_offd_map, &num_cols_offd, &cols_map_offd, &E_diag_nnz, B_ii + A_diag_nnz + A_offd_nnz, B_j + A_diag_nnz + A_offd_nnz, B_a + A_diag_nnz + A_offd_nnz, NULL, &E_offd_nnz, B_ii + A_diag_nnz + A_offd_nnz + E_diag_nnz, B_j + A_diag_nnz + A_offd_nnz + E_diag_nnz, B_a + A_diag_nnz + A_offd_nnz + E_diag_nnz, NULL); hypre_TFree(E_ii, HYPRE_MEMORY_DEVICE); HYPRE_THRUST_CALL( transform, B_ii + A_diag_nnz + A_offd_nnz, B_ii + B_nnz, thrust::make_constant_iterator(A_nrows), B_ii + A_diag_nnz + A_offd_nnz, thrust::plus<HYPRE_Int>() ); // Adiag HYPRE_Int A_diag_ii = hypreDevice_CsrRowPtrsToIndices(A_nrows, A_diag_nnz, A_diag_i); HYPRE_THRUST_CALL( copy_n, thrust::make_zip_iterator(thrust::make_tuple(A_diag_ii, A_diag_j, A_diag_a)), A_diag_nnz, thrust::make_zip_iterator(thrust::make_tuple(B_ii, B_j, B_a)) ); hypre_TFree(A_diag_ii, HYPRE_MEMORY_DEVICE); // Aoffd HYPRE_Int A_offd_ii = hypreDevice_CsrRowPtrsToIndices(A_nrows, A_offd_nnz, A_offd_i); HYPRE_THRUST_CALL( copy_n, thrust::make_zip_iterator(thrust::make_tuple(A_offd_ii, A_offd_a)), A_offd_nnz, thrust::make_zip_iterator(thrust::make_tuple(B_ii, B_a)) + A_diag_nnz ); hypre_TFree(A_offd_ii, HYPRE_MEMORY_DEVICE); HYPRE_THRUST_CALL( gather, A_offd_j, A_offd_j + A_offd_nnz, cols_offd_map, B_j + A_diag_nnz); hypre_TFree(cols_offd_map, HYPRE_MEMORY_DEVICE); HYPRE_THRUST_CALL( transform, B_j + A_diag_nnz, B_j + A_diag_nnz + A_offd_nnz, thrust::make_constant_iterator(A_ncols), B_j + A_diag_nnz, thrust::plus<HYPRE_Int>() ); HYPRE_THRUST_CALL( transform, B_j + A_diag_nnz + A_offd_nnz + E_diag_nnz, B_j + B_nnz, thrust::make_constant_iterator(A_ncols), B_j + A_diag_nnz + A_offd_nnz + E_diag_nnz, thrust::plus<HYPRE_Int>() ); // B HYPRE_THRUST_CALL( stable_sort_by_key, B_ii, B_ii + B_nnz, thrust::make_zip_iterator(thrust::make_tuple(B_j, B_a)) ); HYPRE_Int B_i = hypreDevice_CsrRowIndicesToPtrs(A_nrows + E_nrows, B_nnz, B_ii); hypre_TFree(B_ii, HYPRE_MEMORY_DEVICE); B = hypre_CSRMatrixCreate(A_nrows + E_nrows, A_ncols + num_cols_offd, B_nnz); hypre_CSRMatrixI(B) = B_i; hypre_CSRMatrixJ(B) = B_j; hypre_CSRMatrixData(B) = B_a; hypre_CSRMatrixMemoryLocation(B) = HYPRE_MEMORY_DEVICE; B_ptr = B; num_cols_offd_ptr = num_cols_offd; cols_map_offd_ptr = cols_map_offd; return hypre_error_flag; } #endif HYPRE_Int hypre_ParCSRMatrixGetRowDevice( hypre_ParCSRMatrix mat, HYPRE_BigInt row, HYPRE_Int size, HYPRE_BigInt col_ind, HYPRE_Complex values ) { HYPRE_Int nrows, local_row; HYPRE_BigInt row_start, row_end; hypre_CSRMatrix Aa; hypre_CSRMatrix Ba; if (!mat) { hypre_error_in_arg(1); return hypre_error_flag; } Aa = (hypre_CSRMatrix ) hypre_ParCSRMatrixDiag(mat); Ba = (hypre_CSRMatrix ) hypre_ParCSRMatrixOffd(mat); if (hypre_ParCSRMatrixGetrowactive(mat)) { return(-1); } hypre_ParCSRMatrixGetrowactive(mat) = 1; #ifdef HYPRE_NO_GLOBAL_PARTITION row_start = hypre_ParCSRMatrixFirstRowIndex(mat); row_end = hypre_ParCSRMatrixLastRowIndex(mat) + 1; #else HYPRE_Int my_id; hypre_MPI_Comm_rank(hypre_ParCSRMatrixComm(mat), &my_id); row_end = hypre_ParCSRMatrixRowStarts(mat)[ my_id + 1 ]; row_start = hypre_ParCSRMatrixRowStarts(mat)[ my_id ]; #endif nrows = row_end - row_start; if (row < row_start \|\| row >= row_end) { return(-1); } local_row = row - row_start; /* if buffer is not allocated and some information is requested, allocate buffer with the max row_nnz / if ( !hypre_ParCSRMatrixRowvalues(mat) && (col_ind \|\| values) ) { HYPRE_Int max_row_nnz; HYPRE_Int row_nnz = hypre_TAlloc(HYPRE_Int, nrows, HYPRE_MEMORY_DEVICE); hypreDevice_GetRowNnz(nrows, NULL, hypre_CSRMatrixI(Aa), hypre_CSRMatrixI(Ba), row_nnz); hypre_TMemcpy(size, row_nnz + local_row, HYPRE_Int, 1, HYPRE_MEMORY_HOST, HYPRE_MEMORY_DEVICE); max_row_nnz = HYPRE_THRUST_CALL(reduce, row_nnz, row_nnz + nrows, 0, thrust::maximum<HYPRE_Int>()); /* HYPRE_Int max_row_nnz_d = HYPRE_THRUST_CALL(max_element, row_nnz, row_nnz + nrows); hypre_TMemcpy( &max_row_nnz, max_row_nnz_d, HYPRE_Int, 1, HYPRE_MEMORY_HOST, HYPRE_MEMORY_DEVICE ); / hypre_TFree(row_nnz, HYPRE_MEMORY_DEVICE); hypre_ParCSRMatrixRowvalues(mat) = (HYPRE_Complex ) hypre_TAlloc(HYPRE_Complex, max_row_nnz, hypre_ParCSRMatrixMemoryLocation(mat)); hypre_ParCSRMatrixRowindices(mat) = (HYPRE_BigInt ) hypre_TAlloc(HYPRE_BigInt, max_row_nnz, hypre_ParCSRMatrixMemoryLocation(mat)); } else { HYPRE_Int size_d = hypre_TAlloc(HYPRE_Int, 1, HYPRE_MEMORY_DEVICE); hypreDevice_GetRowNnz(1, NULL, hypre_CSRMatrixI(Aa) + local_row, hypre_CSRMatrixI(Ba) + local_row, size_d); hypre_TMemcpy(size, size_d, HYPRE_Int, 1, HYPRE_MEMORY_HOST, HYPRE_MEMORY_DEVICE); hypre_TFree(size_d, HYPRE_MEMORY_DEVICE); } if (col_ind \|\| values) { if (hypre_ParCSRMatrixDeviceColMapOffd(mat) == NULL) { hypre_ParCSRMatrixDeviceColMapOffd(mat) = hypre_TAlloc(HYPRE_BigInt, hypre_CSRMatrixNumCols(Ba), HYPRE_MEMORY_DEVICE); hypre_TMemcpy( hypre_ParCSRMatrixDeviceColMapOffd(mat), hypre_ParCSRMatrixColMapOffd(mat), HYPRE_BigInt, hypre_CSRMatrixNumCols(Ba), HYPRE_MEMORY_DEVICE, HYPRE_MEMORY_HOST ); } hypreDevice_CopyParCSRRows( 1, NULL, -1, Ba != NULL, hypre_ParCSRMatrixFirstColDiag(mat), hypre_ParCSRMatrixDeviceColMapOffd(mat), hypre_CSRMatrixI(Aa) + local_row, hypre_CSRMatrixJ(Aa), hypre_CSRMatrixData(Aa), hypre_CSRMatrixI(Ba) + local_row, hypre_CSRMatrixJ(Ba), hypre_CSRMatrixData(Ba), NULL, hypre_ParCSRMatrixRowindices(mat), hypre_ParCSRMatrixRowvalues(mat) ); } if (col_ind) { col_ind = hypre_ParCSRMatrixRowindices(mat); } if (values) { values = hypre_ParCSRMatrixRowvalues(mat); } hypre_SyncCudaComputeStream(hypre_handle()); return hypre_error_flag; } #endif // #if defined(HYPRE_USING_CUDA) /-------------------------------------------------------------------------- * HYPRE_ParCSRDiagScale --------------------------------------------------------------------------/ HYPRE_Int hypre_ParCSRDiagScale( HYPRE_ParCSRMatrix HA, HYPRE_ParVector Hy, HYPRE_ParVector Hx ) { hypre_ParCSRMatrix A = (hypre_ParCSRMatrix ) HA; hypre_ParVector y = (hypre_ParVector ) Hy; hypre_ParVector x = (hypre_ParVector ) Hx; HYPRE_Real x_data = hypre_VectorData(hypre_ParVectorLocalVector(x)); HYPRE_Real y_data = hypre_VectorData(hypre_ParVectorLocalVector(y)); HYPRE_Real A_data = hypre_CSRMatrixData(hypre_ParCSRMatrixDiag(A)); HYPRE_Int A_i = hypre_CSRMatrixI(hypre_ParCSRMatrixDiag(A)); HYPRE_Int local_size = hypre_VectorSize(hypre_ParVectorLocalVector(x)); HYPRE_Int ierr = 0; #if defined(HYPRE_USING_CUDA) hypreDevice_DiagScaleVector(local_size, A_i, A_data, y_data, x_data); //hypre_SyncCudaComputeStream(hypre_handle()); #else /* #if defined(HYPRE_USING_CUDA) / HYPRE_Int i; #if defined(HYPRE_USING_DEVICE_OPENMP) #pragma omp target teams distribute parallel for private(i) is_device_ptr(x_data,y_data,A_data,A_i) #elif defined(HYPRE_USING_OPENMP) #pragma omp parallel for private(i) HYPRE_SMP_SCHEDULE #endif for (i = 0; i < local_size; i++) { x_data[i] = y_data[i]/A_data[A_i[i]]; } #endif / #if defined(HYPRE_USING_CUDA) */ return ierr; }
GB_binop__plus_fc32.c	//------------------------------------------------------------------------------ // GB_binop: hard-coded functions for each built-in binary operator //------------------------------------------------------------------------------ // SuiteSparse:GraphBLAS, Timothy A. Davis, (c) 2017-2021, All Rights Reserved. // SPDX-License-Identifier: Apache-2.0 //------------------------------------------------------------------------------ // If this file is in the Generated2/ folder, do not edit it // (it is auto-generated from Generator/). #include "GB.h" #ifndef GBCOMPACT #include "GB_emult.h" #include "GB_control.h" #include "GB_ek_slice.h" #include "GB_dense.h" #include "GB_atomics.h" #include "GB_bitmap_assign_methods.h" #include "GB_binop__include.h" // C=binop(A,B) is defined by the following types and operators: // A+B function (eWiseAdd): GB (_AaddB__plus_fc32) // A.B function (eWiseMult): GB (_AemultB_01__plus_fc32) // A.B function (eWiseMult): GB (_AemultB_02__plus_fc32) // A.B function (eWiseMult): GB (_AemultB_03__plus_fc32) // A.B function (eWiseMult): GB (_AemultB_bitmap__plus_fc32) // AD function (colscale): GB (_AxD__plus_fc32) // DA function (rowscale): GB (_DxB__plus_fc32) // C+=B function (dense accum): GB (_Cdense_accumB__plus_fc32) // C+=b function (dense accum): GB (_Cdense_accumb__plus_fc32) // C+=A+B function (dense ewise3): GB (_Cdense_ewise3_accum__plus_fc32) // C=A+B function (dense ewise3): GB (_Cdense_ewise3_noaccum__plus_fc32) // C=scalar+B GB (_bind1st__plus_fc32) // C=scalar+B' GB (_bind1st_tran__plus_fc32) // C=A+scalar GB (_bind2nd__plus_fc32) // C=A'+scalar GB (_bind2nd_tran__plus_fc32) // C type: GxB_FC32_t // A type: GxB_FC32_t // B,b type: GxB_FC32_t // BinaryOp: cij = GB_FC32_add (aij, bij) #define GB_ATYPE \ GxB_FC32_t #define GB_BTYPE \ GxB_FC32_t #define GB_CTYPE \ GxB_FC32_t // true if the types of A and B are identical #define GB_ATYPE_IS_BTYPE \ 1 // true if the types of C and A are identical #define GB_CTYPE_IS_ATYPE \ 1 // true if the types of C and B are identical #define GB_CTYPE_IS_BTYPE \ 1 // aij = Ax [pA] #define GB_GETA(aij,Ax,pA,A_iso) \ GxB_FC32_t aij = GBX (Ax, pA, A_iso) // bij = Bx [pB] #define GB_GETB(bij,Bx,pB,B_iso) \ GxB_FC32_t bij = GBX (Bx, pB, B_iso) // declare scalar of the same type as C #define GB_CTYPE_SCALAR(t) \ GxB_FC32_t t // cij = Ax [pA] #define GB_COPY_A_TO_C(cij,Ax,pA,A_iso) \ cij = GBX (Ax, pA, A_iso) // cij = Bx [pB] #define GB_COPY_B_TO_C(cij,Bx,pB,B_iso) \ cij = GBX (Bx, pB, B_iso) #define GB_CX(p) Cx [p] // binary operator #define GB_BINOP(z,x,y,i,j) \ z = GB_FC32_add (x, y) ; // true if the binop must be flipped #define GB_BINOP_FLIP \ 0 // op is second #define GB_OP_IS_SECOND \ 0 // do the numerical phases of GB_add and GB_emult #define GB_PHASE_2_OF_2 // hard-coded loops can be vectorized #define GB_PRAGMA_SIMD_VECTORIZE GB_PRAGMA_SIMD // disable this operator and use the generic case if these conditions hold #define GB_DISABLE \ (GxB_NO_PLUS \|\| GxB_NO_FC32 \|\| GxB_NO_PLUS_FC32) //------------------------------------------------------------------------------ // C += A+B, all 3 matrices dense //------------------------------------------------------------------------------ // The op must be MIN, MAX, PLUS, MINUS, RMINUS, TIMES, DIV, or RDIV. void GB (_Cdense_ewise3_accum__plus_fc32) ( GrB_Matrix C, const GrB_Matrix A, const GrB_Matrix B, const int nthreads ) { #include "GB_dense_ewise3_accum_template.c" } //------------------------------------------------------------------------------ // C = A+B, all 3 matrices dense //------------------------------------------------------------------------------ GrB_Info GB (_Cdense_ewise3_noaccum__plus_fc32) ( GrB_Matrix C, const GrB_Matrix A, const GrB_Matrix B, const int nthreads ) { #if GB_DISABLE return (GrB_NO_VALUE) ; #else #include "GB_dense_ewise3_noaccum_template.c" return (GrB_SUCCESS) ; #endif } //------------------------------------------------------------------------------ // C += B, accumulate a sparse matrix into a dense matrix //------------------------------------------------------------------------------ GrB_Info GB (_Cdense_accumB__plus_fc32) ( GrB_Matrix C, const GrB_Matrix B, const int64_t B_ek_slicing, const int B_ntasks, const int B_nthreads ) { #if GB_DISABLE return (GrB_NO_VALUE) ; #else { #include "GB_dense_subassign_23_template.c" } return (GrB_SUCCESS) ; #endif } //------------------------------------------------------------------------------ // C += b, accumulate a scalar into a dense matrix //------------------------------------------------------------------------------ GrB_Info GB (_Cdense_accumb__plus_fc32) ( GrB_Matrix C, const GB_void p_bwork, const int nthreads ) { #if GB_DISABLE return (GrB_NO_VALUE) ; #else { // get the scalar b for C += b, of type GxB_FC32_t GxB_FC32_t bwork = (((GxB_FC32_t ) p_bwork)) ; #include "GB_dense_subassign_22_template.c" return (GrB_SUCCESS) ; } return (GrB_SUCCESS) ; #endif } //------------------------------------------------------------------------------ // C = AD, column scale with diagonal D matrix //------------------------------------------------------------------------------ GrB_Info GB (_AxD__plus_fc32) ( GrB_Matrix C, const GrB_Matrix A, bool A_is_pattern, const GrB_Matrix D, bool D_is_pattern, const int64_t A_ek_slicing, const int A_ntasks, const int A_nthreads ) { #if GB_DISABLE return (GrB_NO_VALUE) ; #else GxB_FC32_t restrict Cx = (GxB_FC32_t ) C->x ; #include "GB_AxB_colscale_template.c" return (GrB_SUCCESS) ; #endif } //------------------------------------------------------------------------------ // C = DB, row scale with diagonal D matrix //------------------------------------------------------------------------------ GrB_Info GB (_DxB__plus_fc32) ( GrB_Matrix C, const GrB_Matrix D, bool D_is_pattern, const GrB_Matrix B, bool B_is_pattern, int nthreads ) { #if GB_DISABLE return (GrB_NO_VALUE) ; #else GxB_FC32_t restrict Cx = (GxB_FC32_t ) C->x ; #include "GB_AxB_rowscale_template.c" return (GrB_SUCCESS) ; #endif } //------------------------------------------------------------------------------ // eWiseAdd: C = A+B or C<M> = A+B //------------------------------------------------------------------------------ GrB_Info GB (_AaddB__plus_fc32) ( GrB_Matrix C, const int C_sparsity, const GrB_Matrix M, const bool Mask_struct, const bool Mask_comp, const GrB_Matrix A, const GrB_Matrix B, const bool Ch_is_Mh, const int64_t restrict C_to_M, const int64_t restrict C_to_A, const int64_t restrict C_to_B, const GB_task_struct restrict TaskList, const int C_ntasks, const int C_nthreads, GB_Context Context ) { #if GB_DISABLE return (GrB_NO_VALUE) ; #else GB_WERK_DECLARE (M_ek_slicing, int64_t) ; GB_WERK_DECLARE (A_ek_slicing, int64_t) ; GB_WERK_DECLARE (B_ek_slicing, int64_t) ; #include "GB_add_template.c" GB_FREE_WORK ; return (GrB_SUCCESS) ; #endif } //------------------------------------------------------------------------------ // eWiseMult: C = A.B or C<M> = A.B //------------------------------------------------------------------------------ GrB_Info GB (_AemultB_01__plus_fc32) ( GrB_Matrix C, const int C_sparsity, const int ewise_method, const GrB_Matrix M, const bool Mask_struct, const bool Mask_comp, const GrB_Matrix A, const GrB_Matrix B, const int64_t restrict C_to_M, const int64_t restrict C_to_A, const int64_t restrict C_to_B, const GB_task_struct restrict TaskList, const int C_ntasks, const int C_nthreads, GB_Context Context ) { #if GB_DISABLE return (GrB_NO_VALUE) ; #else #include "GB_emult_01_meta.c" return (GrB_SUCCESS) ; #endif } //------------------------------------------------------------------------------ // eWiseMult: C<#> = A.B when A is sparse/hyper and B is bitmap/full //------------------------------------------------------------------------------ GrB_Info GB (_AemultB_02__plus_fc32) ( GrB_Matrix C, const GrB_Matrix M, const bool Mask_struct, const bool Mask_comp, const GrB_Matrix A, const GrB_Matrix B, const bool flipxy, const int64_t restrict Cp_kfirst, const int64_t A_ek_slicing, const int A_ntasks, const int A_nthreads ) { #if GB_DISABLE return (GrB_NO_VALUE) ; #else #if GB_BINOP_FLIP // The operator is not commutative, and does not have a flipped // variant. For example z=atan2(y,x). if (flipxy) { // use fmult(y,x) #undef GB_FLIPPED #define GB_FLIPPED 1 #include "GB_emult_02_template.c" } else { // use fmult(x,y) #undef GB_FLIPPED #define GB_FLIPPED 0 #include "GB_emult_02_template.c" } #else // No need to handle the flip: the operator is either commutative, or // has been handled by changing z=div(y,x) to z=rdiv(x,y) for example. #undef GB_FLIPPED #define GB_FLIPPED 0 #include "GB_emult_02_template.c" #endif return (GrB_SUCCESS) ; #endif } //------------------------------------------------------------------------------ // eWiseMult: C<M> = A.B, M sparse/hyper, A and B bitmap/full //------------------------------------------------------------------------------ GrB_Info GB (_AemultB_03__plus_fc32) ( GrB_Matrix C, const GrB_Matrix M, const bool Mask_struct, const GrB_Matrix A, const GrB_Matrix B, const int64_t restrict Cp_kfirst, const int64_t M_ek_slicing, const int M_ntasks, const int M_nthreads ) { #if GB_DISABLE return (GrB_NO_VALUE) ; #else #include "GB_emult_03_template.c" return (GrB_SUCCESS) ; #endif } //------------------------------------------------------------------------------ // eWiseMult: C=A.B, C<M>=A.B, C<!M>=A.B where C is bitmap //------------------------------------------------------------------------------ GrB_Info GB (_AemultB_bitmap__plus_fc32) ( GrB_Matrix C, const int ewise_method, const GrB_Matrix M, const bool Mask_struct, const bool Mask_comp, const GrB_Matrix A, const GrB_Matrix B, const int64_t M_ek_slicing, const int M_ntasks, const int M_nthreads, const int C_nthreads, GB_Context Context ) { #if GB_DISABLE return (GrB_NO_VALUE) ; #else #include "GB_bitmap_emult_template.c" return (GrB_SUCCESS) ; #endif } //------------------------------------------------------------------------------ // Cx = op (x,Bx): apply a binary operator to a matrix with scalar bind1st //------------------------------------------------------------------------------ GrB_Info GB (_bind1st__plus_fc32) ( GB_void Cx_output, // Cx and Bx may be aliased const GB_void x_input, const GB_void Bx_input, const int8_t restrict Bb, int64_t bnz, int nthreads ) { #if GB_DISABLE return (GrB_NO_VALUE) ; #else GxB_FC32_t Cx = (GxB_FC32_t ) Cx_output ; GxB_FC32_t x = (((GxB_FC32_t ) x_input)) ; GxB_FC32_t Bx = (GxB_FC32_t ) Bx_input ; int64_t p ; #pragma omp parallel for num_threads(nthreads) schedule(static) for (p = 0 ; p < bnz ; p++) { if (!GBB (Bb, p)) continue ; GxB_FC32_t bij = GBX (Bx, p, false) ; Cx [p] = GB_FC32_add (x, bij) ; } return (GrB_SUCCESS) ; #endif } //------------------------------------------------------------------------------ // Cx = op (Ax,y): apply a binary operator to a matrix with scalar bind2nd //------------------------------------------------------------------------------ GrB_Info GB (_bind2nd__plus_fc32) ( GB_void Cx_output, // Cx and Ax may be aliased const GB_void Ax_input, const GB_void y_input, const int8_t restrict Ab, int64_t anz, int nthreads ) { #if GB_DISABLE return (GrB_NO_VALUE) ; #else int64_t p ; GxB_FC32_t Cx = (GxB_FC32_t ) Cx_output ; GxB_FC32_t Ax = (GxB_FC32_t ) Ax_input ; GxB_FC32_t y = (((GxB_FC32_t ) y_input)) ; #pragma omp parallel for num_threads(nthreads) schedule(static) for (p = 0 ; p < anz ; p++) { if (!GBB (Ab, p)) continue ; GxB_FC32_t aij = GBX (Ax, p, false) ; Cx [p] = GB_FC32_add (aij, y) ; } return (GrB_SUCCESS) ; #endif } //------------------------------------------------------------------------------ // C = op (x, A'): transpose and apply a binary operator //------------------------------------------------------------------------------ // cij = op (x, aij), no typecasting (in spite of the macro name) #undef GB_CAST_OP #define GB_CAST_OP(pC,pA) \ { \ GxB_FC32_t aij = GBX (Ax, pA, false) ; \ Cx [pC] = GB_FC32_add (x, aij) ; \ } GrB_Info GB (_bind1st_tran__plus_fc32) ( GrB_Matrix C, const GB_void x_input, const GrB_Matrix A, int64_t restrict Workspaces, const int64_t restrict A_slice, int nworkspaces, int nthreads ) { // GB_unop_transpose.c uses GB_ATYPE, but A is // the 2nd input to binary operator z=f(x,y). #undef GB_ATYPE #define GB_ATYPE \ GxB_FC32_t #if GB_DISABLE return (GrB_NO_VALUE) ; #else GxB_FC32_t x = (((const GxB_FC32_t ) x_input)) ; #include "GB_unop_transpose.c" return (GrB_SUCCESS) ; #endif #undef GB_ATYPE #define GB_ATYPE \ GxB_FC32_t } //------------------------------------------------------------------------------ // C = op (A', y): transpose and apply a binary operator //------------------------------------------------------------------------------ // cij = op (aij, y), no typecasting (in spite of the macro name) #undef GB_CAST_OP #define GB_CAST_OP(pC,pA) \ { \ GxB_FC32_t aij = GBX (Ax, pA, false) ; \ Cx [pC] = GB_FC32_add (aij, y) ; \ } GrB_Info GB (_bind2nd_tran__plus_fc32) ( GrB_Matrix C, const GrB_Matrix A, const GB_void y_input, int64_t restrict Workspaces, const int64_t restrict A_slice, int nworkspaces, int nthreads ) { #if GB_DISABLE return (GrB_NO_VALUE) ; #else GxB_FC32_t y = (((const GxB_FC32_t ) y_input)) ; #include "GB_unop_transpose.c" return (GrB_SUCCESS) ; #endif } #endif
ParallelHelper.h	/** * This file contains (modified) code from the Eigen library. * Eigen License: * * Copyright (C) 2008 Gael Guennebaud <gael.guennebaud@inria.fr> * Copyright (C) 2007-2011 Benoit Jacob <jacob.benoit.1@gmail.com> * * This Source Code Form is subject to the terms of the Mozilla * Public License v. 2.0. If a copy of the MPL was not distributed * with this file, You can obtain one at http://mozilla.org/MPL/2.0/. * * * ====================== * * The modifications are part of the Eigen Recursive Matrix Extension (ERME). * ERME License: * * Copyright (c) 2019 Darius Rückert * Licensed under the MIT License. / #pragma once #include "MatrixScalar.h" #include <numeric> namespace Eigen { namespace Recursive { template <typename T, typename T2> inline void squaredNorm_omp_local(const T& v, T2& result) { // using Scalar = typename BaseScalar<T>::type; result = 0; #pragma omp for for (int i = 0; i < v.rows(); ++i) { result += v(i).get().squaredNorm(); } } template <typename T, typename T2> inline void dot_omp_local(const T& a, const T& b, T2& result) { // using Scalar = typename BaseScalar<T>::type; result = 0; #pragma omp for for (int i = 0; i < a.rows(); ++i) { result += a(i).get().dot(b(i).get()); } } template <typename SparseLhsType, typename DenseRhsType, typename DenseResType> inline void sparse_mv_omp(const SparseLhsType& lhs, const DenseRhsType& rhs, DenseResType& res) { typedef typename internal::remove_all<SparseLhsType>::type Lhs; typedef Eigen::internal::evaluator<Lhs> LhsEval; typedef typename Eigen::internal::evaluator<Lhs>::InnerIterator LhsInnerIterator; //#pragma omp single { LhsEval lhsEval(lhs); Index n = lhs.outerSize(); // for (Index c = 0; c < rhs.cols(); ++c) { #pragma omp for for (Index i = 0; i < n; ++i) { res.coeffRef(i).get().setZero(); for (LhsInnerIterator it(lhs, i); it; ++it) { auto& vlhs = it.value().get(); auto& vrhs = rhs.coeff(it.index()).get(); res.coeffRef(i).get() += vlhs vrhs; } } } } } } // namespace Recursive } // namespace Eigen
single.c	#include <omp.h> #include <stdio.h> main() { int x; x = 0; #pragma omp parallel shared(x) { #pragma omp single { int id = omp_get_thread_num(); printf("I am thread #%d\n",id); x = x + 1; } } /* end of parallel section */ printf("out of the parallel region : X = %d\n",x); }
segment.c	/* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % SSSSS EEEEE GGGG M M EEEEE N N TTTTT % % SS E G MM MM E NN N T % % SSS EEE G GGG M M M EEE N N N T % % SS E G G M M E N NN T % % SSSSS EEEEE GGGG M M EEEEE N N T % % % % % % MagickCore Methods to Segment an Image with Thresholding Fuzzy c-Means % % % % Software Design % % Cristy % % April 1993 % % % % % % Copyright 1999-2020 ImageMagick Studio LLC, a non-profit organization % % dedicated to making software imaging solutions freely available. % % % % You may not use this file except in compliance with the License. You may % % obtain a copy of the License at % % % % https://imagemagick.org/script/license.php % % % % Unless required by applicable law or agreed to in writing, software % % distributed under the License is distributed on an "AS IS" BASIS, % % WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. % % See the License for the specific language governing permissions and % % limitations under the License. % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % Segment segments an image by analyzing the histograms of the color % components and identifying units that are homogeneous with the fuzzy % c-means technique. The scale-space filter analyzes the histograms of % the three color components of the image and identifies a set of % classes. The extents of each class is used to coarsely segment the % image with thresholding. The color associated with each class is % determined by the mean color of all pixels within the extents of a % particular class. Finally, any unclassified pixels are assigned to % the closest class with the fuzzy c-means technique. % % The fuzzy c-Means algorithm can be summarized as follows: % % o Build a histogram, one for each color component of the image. % % o For each histogram, successively apply the scale-space filter and % build an interval tree of zero crossings in the second derivative % at each scale. Analyze this scale-space ``fingerprint'' to % determine which peaks and valleys in the histogram are most % predominant. % % o The fingerprint defines intervals on the axis of the histogram. % Each interval contains either a minima or a maxima in the original % signal. If each color component lies within the maxima interval, % that pixel is considered ``classified'' and is assigned an unique % class number. % % o Any pixel that fails to be classified in the above thresholding % pass is classified using the fuzzy c-Means technique. It is % assigned to one of the classes discovered in the histogram analysis % phase. % % The fuzzy c-Means technique attempts to cluster a pixel by finding % the local minima of the generalized within group sum of squared error % objective function. A pixel is assigned to the closest class of % which the fuzzy membership has a maximum value. % % Segment is strongly based on software written by Andy Gallo, % University of Delaware. % % The following reference was used in creating this program: % % Young Won Lim, Sang Uk Lee, "On The Color Image Segmentation % Algorithm Based on the Thresholding and the Fuzzy c-Means % Techniques", Pattern Recognition, Volume 23, Number 9, pages % 935-952, 1990. % % / #include "magick/studio.h" #include "magick/cache.h" #include "magick/color.h" #include "magick/colormap.h" #include "magick/colorspace.h" #include "magick/colorspace-private.h" #include "magick/exception.h" #include "magick/exception-private.h" #include "magick/image.h" #include "magick/image-private.h" #include "magick/memory_.h" #include "magick/memory-private.h" #include "magick/monitor.h" #include "magick/monitor-private.h" #include "magick/quantize.h" #include "magick/quantum.h" #include "magick/quantum-private.h" #include "magick/resource_.h" #include "magick/segment.h" #include "magick/string_.h" #include "magick/thread-private.h" / Define declarations. / #define MaxDimension 3 #define DeltaTau 0.5f #if defined(FastClassify) #define WeightingExponent 2.0 #define SegmentPower(ratio) (ratio) #else #define WeightingExponent 2.5 #define SegmentPower(ratio) pow(ratio,(double) (1.0/(weighting_exponent-1.0))); #endif #define Tau 5.2f / Typedef declarations. / typedef struct _ExtentPacket { MagickRealType center; ssize_t index, left, right; } ExtentPacket; typedef struct _Cluster { struct _Cluster next; ExtentPacket red, green, blue; ssize_t count, id; } Cluster; typedef struct _IntervalTree { MagickRealType tau; ssize_t left, right; MagickRealType mean_stability, stability; struct _IntervalTree sibling, child; } IntervalTree; typedef struct _ZeroCrossing { MagickRealType tau, histogram[256]; short crossings[256]; } ZeroCrossing; /* Constant declarations. / static const int Blue = 2, Green = 1, Red = 0, SafeMargin = 3, TreeLength = 600; / Method prototypes. / static MagickRealType OptimalTau(const ssize_t ,const double,const double,const double, const double,short ); static ssize_t DefineRegion(const short ,ExtentPacket ); static void FreeNodes(IntervalTree ), InitializeHistogram(const Image ,ssize_t ,ExceptionInfo ), ScaleSpace(const ssize_t ,const MagickRealType,MagickRealType ), ZeroCrossHistogram(MagickRealType ,const MagickRealType,short ); /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % + C l a s s i f y % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % Classify() defines one or more classes. Each pixel is thresholded to % determine which class it belongs to. If the class is not identified it is % assigned to the closest class based on the fuzzy c-Means technique. % % The format of the Classify method is: % % MagickBooleanType Classify(Image image,short extrema, % const MagickRealType cluster_threshold, % const MagickRealType weighting_exponent, % const MagickBooleanType verbose) % % A description of each parameter follows. % % o image: the image. % % o extrema: Specifies a pointer to an array of integers. They % represent the peaks and valleys of the histogram for each color % component. % % o cluster_threshold: This MagickRealType represents the minimum number of % pixels contained in a hexahedra before it can be considered valid % (expressed as a percentage). % % o weighting_exponent: Specifies the membership weighting exponent. % % o verbose: A value greater than zero prints detailed information about % the identified classes. % / static MagickBooleanType Classify(Image image,short extrema, const MagickRealType cluster_threshold, const MagickRealType weighting_exponent,const MagickBooleanType verbose) { #define SegmentImageTag "Segment/Image" #define ThrowClassifyException(severity,tag,label) \ {\ for (cluster=head; cluster != (Cluster ) NULL; cluster=next_cluster) \ { \ next_cluster=cluster->next; \ cluster=(Cluster ) RelinquishMagickMemory(cluster); \ } \ if (squares != (double ) NULL) \ { \ squares-=255; \ free_squares=squares; \ free_squares=(double ) RelinquishMagickMemory(free_squares); \ } \ ThrowBinaryException(severity,tag,label); \ } CacheView image_view; Cluster cluster, head, last_cluster, next_cluster; ExceptionInfo exception; ExtentPacket blue, green, red; MagickOffsetType progress; MagickRealType free_squares; MagickStatusType status; register ssize_t i; register MagickRealType squares; size_t number_clusters; ssize_t count, y; / Form clusters. / cluster=(Cluster ) NULL; head=(Cluster ) NULL; squares=(double ) NULL; (void) memset(&red,0,sizeof(red)); (void) memset(&green,0,sizeof(green)); (void) memset(&blue,0,sizeof(blue)); exception=(&image->exception); while (DefineRegion(extrema[Red],&red) != 0) { green.index=0; while (DefineRegion(extrema[Green],&green) != 0) { blue.index=0; while (DefineRegion(extrema[Blue],&blue) != 0) { /* Allocate a new class. / if (head != (Cluster ) NULL) { cluster->next=(Cluster ) AcquireMagickMemory( sizeof(cluster->next)); cluster=cluster->next; } else { cluster=(Cluster ) AcquireMagickMemory(sizeof(cluster)); head=cluster; } if (cluster == (Cluster ) NULL) ThrowClassifyException(ResourceLimitError,"MemoryAllocationFailed", image->filename); / Initialize a new class. / cluster->count=0; cluster->red=red; cluster->green=green; cluster->blue=blue; cluster->next=(Cluster ) NULL; } } } if (head == (Cluster ) NULL) { / No classes were identified-- create one. / cluster=(Cluster ) AcquireMagickMemory(sizeof(cluster)); if (cluster == (Cluster ) NULL) ThrowClassifyException(ResourceLimitError,"MemoryAllocationFailed", image->filename); /* Initialize a new class. / cluster->count=0; cluster->red=red; cluster->green=green; cluster->blue=blue; cluster->next=(Cluster ) NULL; head=cluster; } /* Count the pixels for each cluster. / status=MagickTrue; count=0; progress=0; image_view=AcquireVirtualCacheView(image,exception); for (y=0; y < (ssize_t) image->rows; y++) { register const PixelPacket p; register ssize_t x; p=GetCacheViewVirtualPixels(image_view,0,y,image->columns,1,exception); if (p == (const PixelPacket ) NULL) break; for (x=0; x < (ssize_t) image->columns; x++) { for (cluster=head; cluster != (Cluster ) NULL; cluster=cluster->next) if (((ssize_t) ScaleQuantumToChar(GetPixelRed(p)) >= (cluster->red.left-SafeMargin)) && ((ssize_t) ScaleQuantumToChar(GetPixelRed(p)) <= (cluster->red.right+SafeMargin)) && ((ssize_t) ScaleQuantumToChar(GetPixelGreen(p)) >= (cluster->green.left-SafeMargin)) && ((ssize_t) ScaleQuantumToChar(GetPixelGreen(p)) <= (cluster->green.right+SafeMargin)) && ((ssize_t) ScaleQuantumToChar(GetPixelBlue(p)) >= (cluster->blue.left-SafeMargin)) && ((ssize_t) ScaleQuantumToChar(GetPixelBlue(p)) <= (cluster->blue.right+SafeMargin))) { /* Count this pixel. / count++; cluster->red.center+=(MagickRealType) ScaleQuantumToChar(GetPixelRed(p)); cluster->green.center+=(MagickRealType) ScaleQuantumToChar(GetPixelGreen(p)); cluster->blue.center+=(MagickRealType) ScaleQuantumToChar(GetPixelBlue(p)); cluster->count++; break; } p++; } if (image->progress_monitor != (MagickProgressMonitor) NULL) { MagickBooleanType proceed; #if defined(MAGICKCORE_OPENMP_SUPPORT) #pragma omp atomic #endif progress++; proceed=SetImageProgress(image,SegmentImageTag,progress,2image->rows); if (proceed == MagickFalse) status=MagickFalse; } } image_view=DestroyCacheView(image_view); /* Remove clusters that do not meet minimum cluster threshold. / count=0; last_cluster=head; next_cluster=head; for (cluster=head; cluster != (Cluster ) NULL; cluster=next_cluster) { next_cluster=cluster->next; if ((cluster->count > 0) && (cluster->count >= (countcluster_threshold/100.0))) { / Initialize cluster. / cluster->id=count; cluster->red.center/=cluster->count; cluster->green.center/=cluster->count; cluster->blue.center/=cluster->count; count++; last_cluster=cluster; continue; } / Delete cluster. / if (cluster == head) head=next_cluster; else last_cluster->next=next_cluster; cluster=(Cluster ) RelinquishMagickMemory(cluster); } number_clusters=(size_t) count; if (verbose != MagickFalse) { /* Print cluster statistics. / (void) FormatLocaleFile(stdout,"Fuzzy C-means Statistics\n"); (void) FormatLocaleFile(stdout,"===================\n\n"); (void) FormatLocaleFile(stdout,"\tCluster Threshold = %g\n",(double) cluster_threshold); (void) FormatLocaleFile(stdout,"\tWeighting Exponent = %g\n",(double) weighting_exponent); (void) FormatLocaleFile(stdout,"\tTotal Number of Clusters = %.20g\n\n", (double) number_clusters); / Print the total number of points per cluster. / (void) FormatLocaleFile(stdout,"\n\nNumber of Vectors Per Cluster\n"); (void) FormatLocaleFile(stdout,"=============================\n\n"); for (cluster=head; cluster != (Cluster ) NULL; cluster=cluster->next) (void) FormatLocaleFile(stdout,"Cluster #%.20g = %.20g\n",(double) cluster->id,(double) cluster->count); /* Print the cluster extents. / (void) FormatLocaleFile(stdout, "\n\n\nCluster Extents: (Vector Size: %d)\n",MaxDimension); (void) FormatLocaleFile(stdout,"================"); for (cluster=head; cluster != (Cluster ) NULL; cluster=cluster->next) { (void) FormatLocaleFile(stdout,"\n\nCluster #%.20g\n\n",(double) cluster->id); (void) FormatLocaleFile(stdout, "%.20g-%.20g %.20g-%.20g %.20g-%.20g\n",(double) cluster->red.left,(double) cluster->red.right,(double) cluster->green.left,(double) cluster->green.right,(double) cluster->blue.left,(double) cluster->blue.right); } /* Print the cluster center values. / (void) FormatLocaleFile(stdout, "\n\n\nCluster Center Values: (Vector Size: %d)\n",MaxDimension); (void) FormatLocaleFile(stdout,"====================="); for (cluster=head; cluster != (Cluster ) NULL; cluster=cluster->next) { (void) FormatLocaleFile(stdout,"\n\nCluster #%.20g\n\n",(double) cluster->id); (void) FormatLocaleFile(stdout,"%g %g %g\n",(double) cluster->red.center,(double) cluster->green.center,(double) cluster->blue.center); } (void) FormatLocaleFile(stdout,"\n"); } if (number_clusters > 256) ThrowClassifyException(ImageError,"TooManyClusters",image->filename); /* Speed up distance calculations. / squares=(MagickRealType ) AcquireQuantumMemory(513UL,sizeof(squares)); if (squares == (MagickRealType ) NULL) ThrowClassifyException(ResourceLimitError,"MemoryAllocationFailed", image->filename); squares+=255; for (i=(-255); i <= 255; i++) squares[i]=(MagickRealType) i(MagickRealType) i; / Allocate image colormap. / if (AcquireImageColormap(image,number_clusters) == MagickFalse) ThrowClassifyException(ResourceLimitError,"MemoryAllocationFailed", image->filename); i=0; for (cluster=head; cluster != (Cluster ) NULL; cluster=cluster->next) { image->colormap[i].red=ScaleCharToQuantum((unsigned char) (cluster->red.center+0.5)); image->colormap[i].green=ScaleCharToQuantum((unsigned char) (cluster->green.center+0.5)); image->colormap[i].blue=ScaleCharToQuantum((unsigned char) (cluster->blue.center+0.5)); i++; } /* Do course grain classes. / exception=(&image->exception); image_view=AcquireAuthenticCacheView(image,exception); #if defined(MAGICKCORE_OPENMP_SUPPORT) #pragma omp parallel for schedule(static) shared(progress,status) \ magick_number_threads(image,image,image->rows,1) #endif for (y=0; y < (ssize_t) image->rows; y++) { Cluster cluster; register const PixelPacket magick_restrict p; register IndexPacket magick_restrict indexes; register ssize_t x; register PixelPacket magick_restrict q; if (status == MagickFalse) continue; q=GetCacheViewAuthenticPixels(image_view,0,y,image->columns,1,exception); if (q == (PixelPacket ) NULL) { status=MagickFalse; continue; } indexes=GetCacheViewAuthenticIndexQueue(image_view); for (x=0; x < (ssize_t) image->columns; x++) { SetPixelIndex(indexes+x,0); for (cluster=head; cluster != (Cluster ) NULL; cluster=cluster->next) { if (((ssize_t) ScaleQuantumToChar(q->red) >= (cluster->red.left-SafeMargin)) && ((ssize_t) ScaleQuantumToChar(q->red) <= (cluster->red.right+SafeMargin)) && ((ssize_t) ScaleQuantumToChar(q->green) >= (cluster->green.left-SafeMargin)) && ((ssize_t) ScaleQuantumToChar(q->green) <= (cluster->green.right+SafeMargin)) && ((ssize_t) ScaleQuantumToChar(q->blue) >= (cluster->blue.left-SafeMargin)) && ((ssize_t) ScaleQuantumToChar(q->blue) <= (cluster->blue.right+SafeMargin))) { / Classify this pixel. / SetPixelIndex(indexes+x,cluster->id); break; } } if (cluster == (Cluster ) NULL) { MagickRealType distance_squared, local_minima, numerator, ratio, sum; register ssize_t j, k; /* Compute fuzzy membership. / local_minima=0.0; for (j=0; j < (ssize_t) image->colors; j++) { sum=0.0; p=image->colormap+j; distance_squared=squares[(ssize_t) ScaleQuantumToChar(q->red)- (ssize_t) ScaleQuantumToChar(GetPixelRed(p))]+ squares[(ssize_t) ScaleQuantumToChar(q->green)- (ssize_t) ScaleQuantumToChar(GetPixelGreen(p))]+ squares[(ssize_t) ScaleQuantumToChar(q->blue)- (ssize_t) ScaleQuantumToChar(GetPixelBlue(p))]; numerator=distance_squared; for (k=0; k < (ssize_t) image->colors; k++) { p=image->colormap+k; distance_squared=squares[(ssize_t) ScaleQuantumToChar(q->red)- (ssize_t) ScaleQuantumToChar(GetPixelRed(p))]+ squares[(ssize_t) ScaleQuantumToChar(q->green)- (ssize_t) ScaleQuantumToChar(GetPixelGreen(p))]+ squares[(ssize_t) ScaleQuantumToChar(q->blue)- (ssize_t) ScaleQuantumToChar(GetPixelBlue(p))]; ratio=numerator/distance_squared; sum+=SegmentPower(ratio); } if ((sum != 0.0) && ((1.0/sum) > local_minima)) { / Classify this pixel. / local_minima=1.0/sum; SetPixelIndex(indexes+x,j); } } } q++; } if (SyncCacheViewAuthenticPixels(image_view,exception) == MagickFalse) status=MagickFalse; if (image->progress_monitor != (MagickProgressMonitor) NULL) { MagickBooleanType proceed; #if defined(MAGICKCORE_OPENMP_SUPPORT) #pragma omp atomic #endif progress++; proceed=SetImageProgress(image,SegmentImageTag,progress,2image->rows); if (proceed == MagickFalse) status=MagickFalse; } } image_view=DestroyCacheView(image_view); status&=SyncImage(image); /* Relinquish resources. / for (cluster=head; cluster != (Cluster ) NULL; cluster=next_cluster) { next_cluster=cluster->next; cluster=(Cluster ) RelinquishMagickMemory(cluster); } squares-=255; free_squares=squares; free_squares=(MagickRealType ) RelinquishMagickMemory(free_squares); return(MagickTrue); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % + C o n s o l i d a t e C r o s s i n g s % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % ConsolidateCrossings() guarantees that an even number of zero crossings % always lie between two crossings. % % The format of the ConsolidateCrossings method is: % % ConsolidateCrossings(ZeroCrossing zero_crossing, % const size_t number_crossings) % % A description of each parameter follows. % % o zero_crossing: Specifies an array of structures of type ZeroCrossing. % % o number_crossings: This size_t specifies the number of elements % in the zero_crossing array. % / static void ConsolidateCrossings(ZeroCrossing zero_crossing, const size_t number_crossings) { register ssize_t i, j, k, l; ssize_t center, correct, count, left, right; / Consolidate zero crossings. / for (i=(ssize_t) number_crossings-1; i >= 0; i--) for (j=0; j <= 255; j++) { if (zero_crossing[i].crossings[j] == 0) continue; / Find the entry that is closest to j and still preserves the property that there are an even number of crossings between intervals. / for (k=j-1; k > 0; k--) if (zero_crossing[i+1].crossings[k] != 0) break; left=MagickMax(k,0); center=j; for (k=j+1; k < 255; k++) if (zero_crossing[i+1].crossings[k] != 0) break; right=MagickMin(k,255); / K is the zero crossing just left of j. / for (k=j-1; k > 0; k--) if (zero_crossing[i].crossings[k] != 0) break; if (k < 0) k=0; / Check center for an even number of crossings between k and j. / correct=(-1); if (zero_crossing[i+1].crossings[j] != 0) { count=0; for (l=k+1; l < center; l++) if (zero_crossing[i+1].crossings[l] != 0) count++; if (((count % 2) == 0) && (center != k)) correct=center; } / Check left for an even number of crossings between k and j. / if (correct == -1) { count=0; for (l=k+1; l < left; l++) if (zero_crossing[i+1].crossings[l] != 0) count++; if (((count % 2) == 0) && (left != k)) correct=left; } / Check right for an even number of crossings between k and j. / if (correct == -1) { count=0; for (l=k+1; l < right; l++) if (zero_crossing[i+1].crossings[l] != 0) count++; if (((count % 2) == 0) && (right != k)) correct=right; } l=(ssize_t) zero_crossing[i].crossings[j]; zero_crossing[i].crossings[j]=0; if (correct != -1) zero_crossing[i].crossings[correct]=(short) l; } } / %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % + D e f i n e R e g i o n % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % DefineRegion() defines the left and right boundaries of a peak region. % % The format of the DefineRegion method is: % % ssize_t DefineRegion(const short extrema,ExtentPacket extents) % % A description of each parameter follows. % % o extrema: Specifies a pointer to an array of integers. They % represent the peaks and valleys of the histogram for each color % component. % % o extents: This pointer to an ExtentPacket represent the extends % of a particular peak or valley of a color component. % / static ssize_t DefineRegion(const short extrema,ExtentPacket extents) { / Initialize to default values. / extents->left=0; extents->center=0.0; extents->right=255; / Find the left side (maxima). / for ( ; extents->index <= 255; extents->index++) if (extrema[extents->index] > 0) break; if (extents->index > 255) return(MagickFalse); / no left side - no region exists / extents->left=extents->index; / Find the right side (minima). / for ( ; extents->index <= 255; extents->index++) if (extrema[extents->index] < 0) break; extents->right=extents->index-1; return(MagickTrue); } / %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % + D e r i v a t i v e H i s t o g r a m % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % DerivativeHistogram() determines the derivative of the histogram using % central differencing. % % The format of the DerivativeHistogram method is: % % DerivativeHistogram(const MagickRealType histogram, % MagickRealType derivative) % % A description of each parameter follows. % % o histogram: Specifies an array of MagickRealTypes representing the number % of pixels for each intensity of a particular color component. % % o derivative: This array of MagickRealTypes is initialized by % DerivativeHistogram to the derivative of the histogram using central % differencing. % / static void DerivativeHistogram(const MagickRealType histogram, MagickRealType derivative) { register ssize_t i, n; / Compute endpoints using second order polynomial interpolation. / n=255; derivative[0]=(-1.5histogram[0]+2.0histogram[1]-0.5histogram[2]); derivative[n]=(0.5histogram[n-2]-2.0histogram[n-1]+1.5histogram[n]); / Compute derivative using central differencing. / for (i=1; i < n; i++) derivative[i]=(histogram[i+1]-histogram[i-1])/2.0; return; } / %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % + G e t I m a g e D y n a m i c T h r e s h o l d % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % GetImageDynamicThreshold() returns the dynamic threshold for an image. % % The format of the GetImageDynamicThreshold method is: % % MagickBooleanType GetImageDynamicThreshold(const Image image, % const double cluster_threshold,const double smooth_threshold, % MagickPixelPacket pixel,ExceptionInfo exception) % % A description of each parameter follows. % % o image: the image. % % o cluster_threshold: This MagickRealType represents the minimum number of % pixels contained in a hexahedra before it can be considered valid % (expressed as a percentage). % % o smooth_threshold: the smoothing threshold eliminates noise in the second % derivative of the histogram. As the value is increased, you can expect a % smoother second derivative. % % o pixel: return the dynamic threshold here. % % o exception: return any errors or warnings in this structure. % / MagickExport MagickBooleanType GetImageDynamicThreshold(const Image image, const double cluster_threshold,const double smooth_threshold, MagickPixelPacket pixel,ExceptionInfo exception) { Cluster background, cluster, object, head, last_cluster, next_cluster; ExtentPacket blue, green, red; MagickBooleanType proceed; MagickRealType threshold; register const PixelPacket p; register ssize_t i, x; short extrema[MaxDimension]; ssize_t count, histogram[MaxDimension], y; /* Allocate histogram and extrema. / assert(image != (Image ) NULL); assert(image->signature == MagickCoreSignature); if (image->debug != MagickFalse) (void) LogMagickEvent(TraceEvent,GetMagickModule(),"%s",image->filename); GetMagickPixelPacket(image,pixel); for (i=0; i < MaxDimension; i++) { histogram[i]=(ssize_t ) AcquireQuantumMemory(256UL,sizeof(histogram)); extrema[i]=(short ) AcquireQuantumMemory(256UL,sizeof(*histogram)); if ((histogram[i] == (ssize_t ) NULL) \|\| (extrema[i] == (short ) NULL)) { for (i-- ; i >= 0; i--) { extrema[i]=(short ) RelinquishMagickMemory(extrema[i]); histogram[i]=(ssize_t ) RelinquishMagickMemory(histogram[i]); } (void) ThrowMagickException(exception,GetMagickModule(), ResourceLimitError,"MemoryAllocationFailed","`%s'",image->filename); return(MagickFalse); } } / Initialize histogram. / InitializeHistogram(image,histogram,exception); (void) OptimalTau(histogram[Red],Tau,0.2f,DeltaTau, (smooth_threshold == 0.0f ? 1.0f : smooth_threshold),extrema[Red]); (void) OptimalTau(histogram[Green],Tau,0.2f,DeltaTau, (smooth_threshold == 0.0f ? 1.0f : smooth_threshold),extrema[Green]); (void) OptimalTau(histogram[Blue],Tau,0.2f,DeltaTau, (smooth_threshold == 0.0f ? 1.0f : smooth_threshold),extrema[Blue]); / Form clusters. / cluster=(Cluster ) NULL; head=(Cluster ) NULL; (void) memset(&red,0,sizeof(red)); (void) memset(&green,0,sizeof(green)); (void) memset(&blue,0,sizeof(blue)); while (DefineRegion(extrema[Red],&red) != 0) { green.index=0; while (DefineRegion(extrema[Green],&green) != 0) { blue.index=0; while (DefineRegion(extrema[Blue],&blue) != 0) { / Allocate a new class. / if (head != (Cluster ) NULL) { cluster->next=(Cluster ) AcquireMagickMemory( sizeof(cluster->next)); cluster=cluster->next; } else { cluster=(Cluster ) AcquireMagickMemory(sizeof(cluster)); head=cluster; } if (cluster == (Cluster ) NULL) { (void) ThrowMagickException(exception,GetMagickModule(), ResourceLimitError,"MemoryAllocationFailed","`%s'", image->filename); return(MagickFalse); } / Initialize a new class. / cluster->count=0; cluster->red=red; cluster->green=green; cluster->blue=blue; cluster->next=(Cluster ) NULL; } } } if (head == (Cluster ) NULL) { / No classes were identified-- create one. / cluster=(Cluster ) AcquireMagickMemory(sizeof(cluster)); if (cluster == (Cluster ) NULL) { (void) ThrowMagickException(exception,GetMagickModule(), ResourceLimitError,"MemoryAllocationFailed","`%s'",image->filename); return(MagickFalse); } /* Initialize a new class. / cluster->count=0; cluster->red=red; cluster->green=green; cluster->blue=blue; cluster->next=(Cluster ) NULL; head=cluster; } /* Count the pixels for each cluster. / count=0; for (y=0; y < (ssize_t) image->rows; y++) { p=GetVirtualPixels(image,0,y,image->columns,1,exception); if (p == (const PixelPacket ) NULL) break; for (x=0; x < (ssize_t) image->columns; x++) { for (cluster=head; cluster != (Cluster ) NULL; cluster=cluster->next) if (((ssize_t) ScaleQuantumToChar(GetPixelRed(p)) >= (cluster->red.left-SafeMargin)) && ((ssize_t) ScaleQuantumToChar(GetPixelRed(p)) <= (cluster->red.right+SafeMargin)) && ((ssize_t) ScaleQuantumToChar(GetPixelGreen(p)) >= (cluster->green.left-SafeMargin)) && ((ssize_t) ScaleQuantumToChar(GetPixelGreen(p)) <= (cluster->green.right+SafeMargin)) && ((ssize_t) ScaleQuantumToChar(GetPixelBlue(p)) >= (cluster->blue.left-SafeMargin)) && ((ssize_t) ScaleQuantumToChar(GetPixelBlue(p)) <= (cluster->blue.right+SafeMargin))) { / Count this pixel. / count++; cluster->red.center+=(MagickRealType) ScaleQuantumToChar(GetPixelRed(p)); cluster->green.center+=(MagickRealType) ScaleQuantumToChar(GetPixelGreen(p)); cluster->blue.center+=(MagickRealType) ScaleQuantumToChar(GetPixelBlue(p)); cluster->count++; break; } p++; } proceed=SetImageProgress(image,SegmentImageTag,(MagickOffsetType) y, 2image->rows); if (proceed == MagickFalse) break; } /* Remove clusters that do not meet minimum cluster threshold. / count=0; last_cluster=head; next_cluster=head; for (cluster=head; cluster != (Cluster ) NULL; cluster=next_cluster) { next_cluster=cluster->next; if ((cluster->count > 0) && (cluster->count >= (countcluster_threshold/100.0))) { / Initialize cluster. / cluster->id=count; cluster->red.center/=cluster->count; cluster->green.center/=cluster->count; cluster->blue.center/=cluster->count; count++; last_cluster=cluster; continue; } / Delete cluster. / if (cluster == head) head=next_cluster; else last_cluster->next=next_cluster; cluster=(Cluster ) RelinquishMagickMemory(cluster); } object=head; background=head; if (count > 1) { object=head->next; for (cluster=object; cluster->next != (Cluster ) NULL; ) { if (cluster->count < object->count) object=cluster; cluster=cluster->next; } background=head->next; for (cluster=background; cluster->next != (Cluster ) NULL; ) { if (cluster->count > background->count) background=cluster; cluster=cluster->next; } } if (background != (Cluster ) NULL) { threshold=(background->red.center+object->red.center)/2.0; pixel->red=(MagickRealType) ScaleCharToQuantum((unsigned char) (threshold+0.5)); threshold=(background->green.center+object->green.center)/2.0; pixel->green=(MagickRealType) ScaleCharToQuantum((unsigned char) (threshold+0.5)); threshold=(background->blue.center+object->blue.center)/2.0; pixel->blue=(MagickRealType) ScaleCharToQuantum((unsigned char) (threshold+0.5)); } / Relinquish resources. / for (cluster=head; cluster != (Cluster ) NULL; cluster=next_cluster) { next_cluster=cluster->next; cluster=(Cluster ) RelinquishMagickMemory(cluster); } for (i=0; i < MaxDimension; i++) { extrema[i]=(short ) RelinquishMagickMemory(extrema[i]); histogram[i]=(ssize_t ) RelinquishMagickMemory(histogram[i]); } return(MagickTrue); } / %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % + I n i t i a l i z e H i s t o g r a m % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % InitializeHistogram() computes the histogram for an image. % % The format of the InitializeHistogram method is: % % InitializeHistogram(const Image image,ssize_t histogram) % % A description of each parameter follows. % % o image: Specifies a pointer to an Image structure; returned from % ReadImage. % % o histogram: Specifies an array of integers representing the number % of pixels for each intensity of a particular color component. % / static void InitializeHistogram(const Image image,ssize_t histogram, ExceptionInfo exception) { register const PixelPacket p; register ssize_t i, x; ssize_t y; / Initialize histogram. / for (i=0; i <= 255; i++) { histogram[Red][i]=0; histogram[Green][i]=0; histogram[Blue][i]=0; } for (y=0; y < (ssize_t) image->rows; y++) { p=GetVirtualPixels(image,0,y,image->columns,1,exception); if (p == (const PixelPacket ) NULL) break; for (x=0; x < (ssize_t) image->columns; x++) { histogram[Red][(ssize_t) ScaleQuantumToChar(GetPixelRed(p))]++; histogram[Green][(ssize_t) ScaleQuantumToChar(GetPixelGreen(p))]++; histogram[Blue][(ssize_t) ScaleQuantumToChar(GetPixelBlue(p))]++; p++; } } } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % + I n i t i a l i z e I n t e r v a l T r e e % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % InitializeIntervalTree() initializes an interval tree from the lists of % zero crossings. % % The format of the InitializeIntervalTree method is: % % InitializeIntervalTree(IntervalTree *list,ssize_t number_nodes, % IntervalTree node) % % A description of each parameter follows. % % o zero_crossing: Specifies an array of structures of type ZeroCrossing. % % o number_crossings: This size_t specifies the number of elements % in the zero_crossing array. % / static void InitializeList(IntervalTree *list,ssize_t number_nodes, IntervalTree node) { if (node == (IntervalTree ) NULL) return; if (node->child == (IntervalTree ) NULL) list[(number_nodes)++]=node; InitializeList(list,number_nodes,node->sibling); InitializeList(list,number_nodes,node->child); } static void MeanStability(IntervalTree node) { register IntervalTree child; if (node == (IntervalTree ) NULL) return; node->mean_stability=0.0; child=node->child; if (child != (IntervalTree ) NULL) { register ssize_t count; register MagickRealType sum; sum=0.0; count=0; for ( ; child != (IntervalTree ) NULL; child=child->sibling) { sum+=child->stability; count++; } node->mean_stability=sum/(MagickRealType) count; } MeanStability(node->sibling); MeanStability(node->child); } static void Stability(IntervalTree node) { if (node == (IntervalTree ) NULL) return; if (node->child == (IntervalTree ) NULL) node->stability=0.0; else node->stability=node->tau-(node->child)->tau; Stability(node->sibling); Stability(node->child); } static IntervalTree InitializeIntervalTree(const ZeroCrossing zero_crossing, const size_t number_crossings) { IntervalTree head, list, node, root; register ssize_t i; ssize_t j, k, left, number_nodes; / Allocate interval tree. / list=(IntervalTree ) AcquireQuantumMemory((size_t) TreeLength, sizeof(list)); if (list == (IntervalTree *) NULL) return((IntervalTree ) NULL); /* The root is the entire histogram. / root=(IntervalTree ) AcquireCriticalMemory(sizeof(root)); root->child=(IntervalTree ) NULL; root->sibling=(IntervalTree ) NULL; root->tau=0.0; root->left=0; root->right=255; root->mean_stability=0.0; root->stability=0.0; (void) memset(list,0,TreeLengthsizeof(list)); for (i=(-1); i < (ssize_t) number_crossings; i++) { / Initialize list with all nodes with no children. / number_nodes=0; InitializeList(list,&number_nodes,root); / Split list. / for (j=0; j < number_nodes; j++) { head=list[j]; left=head->left; node=head; for (k=head->left+1; k < head->right; k++) { if (zero_crossing[i+1].crossings[k] != 0) { if (node == head) { node->child=(IntervalTree ) AcquireMagickMemory( sizeof(node->child)); node=node->child; } else { node->sibling=(IntervalTree ) AcquireMagickMemory( sizeof(node->sibling)); node=node->sibling; } if (node == (IntervalTree ) NULL) { list=(IntervalTree *) RelinquishMagickMemory(list); FreeNodes(root); return((IntervalTree ) NULL); } node->tau=zero_crossing[i+1].tau; node->child=(IntervalTree ) NULL; node->sibling=(IntervalTree ) NULL; node->left=left; node->right=k; left=k; } } if (left != head->left) { node->sibling=(IntervalTree ) AcquireMagickMemory( sizeof(node->sibling)); node=node->sibling; if (node == (IntervalTree ) NULL) { list=(IntervalTree ) RelinquishMagickMemory(list); FreeNodes(root); return((IntervalTree ) NULL); } node->tau=zero_crossing[i+1].tau; node->child=(IntervalTree ) NULL; node->sibling=(IntervalTree ) NULL; node->left=left; node->right=head->right; } } } /* Determine the stability: difference between a nodes tau and its child. / Stability(root->child); MeanStability(root->child); list=(IntervalTree ) RelinquishMagickMemory(list); return(root); } / %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % + O p t i m a l T a u % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % OptimalTau() finds the optimal tau for each band of the histogram. % % The format of the OptimalTau method is: % % MagickRealType OptimalTau(const ssize_t histogram,const double max_tau, % const double min_tau,const double delta_tau, % const double smooth_threshold,short extrema) % % A description of each parameter follows. % % o histogram: Specifies an array of integers representing the number % of pixels for each intensity of a particular color component. % % o extrema: Specifies a pointer to an array of integers. They % represent the peaks and valleys of the histogram for each color % component. % / static void ActiveNodes(IntervalTree list,ssize_t number_nodes, IntervalTree node) { if (node == (IntervalTree ) NULL) return; if (node->stability >= node->mean_stability) { list[(number_nodes)++]=node; ActiveNodes(list,number_nodes,node->sibling); } else { ActiveNodes(list,number_nodes,node->sibling); ActiveNodes(list,number_nodes,node->child); } } static void FreeNodes(IntervalTree node) { if (node == (IntervalTree ) NULL) return; FreeNodes(node->sibling); FreeNodes(node->child); node=(IntervalTree ) RelinquishMagickMemory(node); } static MagickRealType OptimalTau(const ssize_t histogram,const double max_tau, const double min_tau,const double delta_tau,const double smooth_threshold, short extrema) { IntervalTree *list, node, root; MagickBooleanType peak; MagickRealType average_tau, derivative, second_derivative, tau, value; register ssize_t i, x; size_t count, number_crossings; ssize_t index, j, k, number_nodes; ZeroCrossing zero_crossing; /* Allocate interval tree. / list=(IntervalTree ) AcquireQuantumMemory((size_t) TreeLength, sizeof(list)); if (list == (IntervalTree *) NULL) return(0.0); / Allocate zero crossing list. / count=(size_t) ((max_tau-min_tau)/delta_tau)+2; zero_crossing=(ZeroCrossing ) AcquireQuantumMemory((size_t) count, sizeof(zero_crossing)); if (zero_crossing == (ZeroCrossing ) NULL) { list=(IntervalTree *) RelinquishMagickMemory(list); return(0.0); } for (i=0; i < (ssize_t) count; i++) zero_crossing[i].tau=(-1.0); / Initialize zero crossing list. / derivative=(MagickRealType ) AcquireCriticalMemory(256sizeof(derivative)); second_derivative=(MagickRealType ) AcquireCriticalMemory(256 sizeof(second_derivative)); i=0; for (tau=max_tau; tau >= min_tau; tau-=delta_tau) { zero_crossing[i].tau=tau; ScaleSpace(histogram,tau,zero_crossing[i].histogram); DerivativeHistogram(zero_crossing[i].histogram,derivative); DerivativeHistogram(derivative,second_derivative); ZeroCrossHistogram(second_derivative,smooth_threshold, zero_crossing[i].crossings); i++; } / Add an entry for the original histogram. / zero_crossing[i].tau=0.0; for (j=0; j <= 255; j++) zero_crossing[i].histogram[j]=(MagickRealType) histogram[j]; DerivativeHistogram(zero_crossing[i].histogram,derivative); DerivativeHistogram(derivative,second_derivative); ZeroCrossHistogram(second_derivative,smooth_threshold, zero_crossing[i].crossings); number_crossings=(size_t) i; derivative=(MagickRealType ) RelinquishMagickMemory(derivative); second_derivative=(MagickRealType ) RelinquishMagickMemory(second_derivative); / Ensure the scale-space fingerprints form lines in scale-space, not loops. / ConsolidateCrossings(zero_crossing,number_crossings); / Force endpoints to be included in the interval. / for (i=0; i <= (ssize_t) number_crossings; i++) { for (j=0; j < 255; j++) if (zero_crossing[i].crossings[j] != 0) break; zero_crossing[i].crossings[0]=(-zero_crossing[i].crossings[j]); for (j=255; j > 0; j--) if (zero_crossing[i].crossings[j] != 0) break; zero_crossing[i].crossings[255]=(-zero_crossing[i].crossings[j]); } / Initialize interval tree. / root=InitializeIntervalTree(zero_crossing,number_crossings); if (root == (IntervalTree ) NULL) { zero_crossing=(ZeroCrossing ) RelinquishMagickMemory(zero_crossing); list=(IntervalTree ) RelinquishMagickMemory(list); return(0.0); } / Find active nodes: stability is greater (or equal) to the mean stability of its children. / number_nodes=0; ActiveNodes(list,&number_nodes,root->child); / Initialize extrema. / for (i=0; i <= 255; i++) extrema[i]=0; for (i=0; i < number_nodes; i++) { / Find this tau in zero crossings list. / k=0; node=list[i]; for (j=0; j <= (ssize_t) number_crossings; j++) if (zero_crossing[j].tau == node->tau) k=j; / Find the value of the peak. / peak=zero_crossing[k].crossings[node->right] == -1 ? MagickTrue : MagickFalse; index=node->left; value=zero_crossing[k].histogram[index]; for (x=node->left; x <= node->right; x++) { if (peak != MagickFalse) { if (zero_crossing[k].histogram[x] > value) { value=zero_crossing[k].histogram[x]; index=x; } } else if (zero_crossing[k].histogram[x] < value) { value=zero_crossing[k].histogram[x]; index=x; } } for (x=node->left; x <= node->right; x++) { if (index == 0) index=256; if (peak != MagickFalse) extrema[x]=(short) index; else extrema[x]=(short) (-index); } } / Determine the average tau. / average_tau=0.0; for (i=0; i < number_nodes; i++) average_tau+=list[i]->tau; average_tau=PerceptibleReciprocal((MagickRealType) number_nodes); /* Relinquish resources. / FreeNodes(root); zero_crossing=(ZeroCrossing ) RelinquishMagickMemory(zero_crossing); list=(IntervalTree *) RelinquishMagickMemory(list); return(average_tau); } / %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % + S c a l e S p a c e % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % ScaleSpace() performs a scale-space filter on the 1D histogram. % % The format of the ScaleSpace method is: % % ScaleSpace(const ssize_t histogram,const MagickRealType tau, % MagickRealType scale_histogram) % % A description of each parameter follows. % % o histogram: Specifies an array of MagickRealTypes representing the number % of pixels for each intensity of a particular color component. % / static void ScaleSpace(const ssize_t histogram,const MagickRealType tau, MagickRealType scale_histogram) { double alpha, beta, gamma, sum; register ssize_t u, x; gamma=(double ) AcquireQuantumMemory(256,sizeof(gamma)); if (gamma == (double ) NULL) ThrowFatalException(ResourceLimitFatalError,"UnableToAllocateGammaMap"); alpha=1.0/(tausqrt(2.0MagickPI)); beta=(-1.0/(2.0tautau)); for (x=0; x <= 255; x++) gamma[x]=0.0; for (x=0; x <= 255; x++) { gamma[x]=exp((double) betaxx); if (gamma[x] < MagickEpsilon) break; } for (x=0; x <= 255; x++) { sum=0.0; for (u=0; u <= 255; u++) sum+=(double) histogram[u]gamma[MagickAbsoluteValue(x-u)]; scale_histogram[x]=(MagickRealType) (alphasum); } gamma=(double ) RelinquishMagickMemory(gamma); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % S e g m e n t I m a g e % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % SegmentImage() segment an image by analyzing the histograms of the color % components and identifying units that are homogeneous with the fuzzy % C-means technique. % % The format of the SegmentImage method is: % % MagickBooleanType SegmentImage(Image image, % const ColorspaceType colorspace,const MagickBooleanType verbose, % const double cluster_threshold,const double smooth_threshold) % % A description of each parameter follows. % % o image: the image. % % o colorspace: Indicate the colorspace. % % o verbose: Set to MagickTrue to print detailed information about the % identified classes. % % o cluster_threshold: This represents the minimum number of pixels % contained in a hexahedra before it can be considered valid (expressed % as a percentage). % % o smooth_threshold: the smoothing threshold eliminates noise in the second % derivative of the histogram. As the value is increased, you can expect a % smoother second derivative. % / MagickExport MagickBooleanType SegmentImage(Image image, const ColorspaceType colorspace,const MagickBooleanType verbose, const double cluster_threshold,const double smooth_threshold) { ColorspaceType previous_colorspace; MagickBooleanType status; register ssize_t i; short extrema[MaxDimension]; ssize_t histogram[MaxDimension]; / Allocate histogram and extrema. / assert(image != (Image ) NULL); assert(image->signature == MagickCoreSignature); if (image->debug != MagickFalse) (void) LogMagickEvent(TraceEvent,GetMagickModule(),"%s",image->filename); for (i=0; i < MaxDimension; i++) { histogram[i]=(ssize_t ) AcquireQuantumMemory(256,sizeof(histogram)); extrema[i]=(short ) AcquireQuantumMemory(256,sizeof(*extrema)); if ((histogram[i] == (ssize_t ) NULL) \|\| (extrema[i] == (short ) NULL)) { for (i-- ; i >= 0; i--) { extrema[i]=(short ) RelinquishMagickMemory(extrema[i]); histogram[i]=(ssize_t ) RelinquishMagickMemory(histogram[i]); } ThrowBinaryImageException(ResourceLimitError,"MemoryAllocationFailed", image->filename) } } / Initialize histogram. / previous_colorspace=image->colorspace; (void) TransformImageColorspace(image,colorspace); InitializeHistogram(image,histogram,&image->exception); (void) OptimalTau(histogram[Red],Tau,0.2,DeltaTau, smooth_threshold == 0.0 ? 1.0 : smooth_threshold,extrema[Red]); (void) OptimalTau(histogram[Green],Tau,0.2,DeltaTau, smooth_threshold == 0.0 ? 1.0 : smooth_threshold,extrema[Green]); (void) OptimalTau(histogram[Blue],Tau,0.2,DeltaTau, smooth_threshold == 0.0 ? 1.0 : smooth_threshold,extrema[Blue]); / Classify using the fuzzy c-Means technique. / status=Classify(image,extrema,cluster_threshold,WeightingExponent,verbose); (void) TransformImageColorspace(image,previous_colorspace); / Relinquish resources. / for (i=0; i < MaxDimension; i++) { extrema[i]=(short ) RelinquishMagickMemory(extrema[i]); histogram[i]=(ssize_t ) RelinquishMagickMemory(histogram[i]); } return(status); } / %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % + Z e r o C r o s s H i s t o g r a m % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % ZeroCrossHistogram() find the zero crossings in a histogram and marks % directions as: 1 is negative to positive; 0 is zero crossing; and -1 % is positive to negative. % % The format of the ZeroCrossHistogram method is: % % ZeroCrossHistogram(MagickRealType second_derivative, % const MagickRealType smooth_threshold,short crossings) % % A description of each parameter follows. % % o second_derivative: Specifies an array of MagickRealTypes representing the % second derivative of the histogram of a particular color component. % % o crossings: This array of integers is initialized with % -1, 0, or 1 representing the slope of the first derivative of the % of a particular color component. % / static void ZeroCrossHistogram(MagickRealType second_derivative, const MagickRealType smooth_threshold,short crossings) { register ssize_t i; ssize_t parity; / Merge low numbers to zero to help prevent noise. / for (i=0; i <= 255; i++) if ((second_derivative[i] < smooth_threshold) && (second_derivative[i] >= -smooth_threshold)) second_derivative[i]=0.0; / Mark zero crossings. */ parity=0; for (i=0; i <= 255; i++) { crossings[i]=0; if (second_derivative[i] < 0.0) { if (parity > 0) crossings[i]=(-1); parity=1; } else if (second_derivative[i] > 0.0) { if (parity < 0) crossings[i]=1; parity=(-1); } } }
questao01.c	#include <stdio.h> #include <stdlib.h> #include "omp.h" int valida_primo(int numero); int main() { int num_inicio = 1, num_fim = 10; omp_set_num_threads(3); #pragma omp parallel { int thread_num = omp_get_thread_num(); int i; #pragma omp sections nowait { #pragma omp section { printf("\nthread: %d - ", thread_num); for(i=num_inicio - 1; i<=num_fim; i = i + 2) { printf("%d ", i); } } #pragma omp section { printf("\nthread: %d - ", thread_num); for(i=num_inicio; i<=num_fim; i = i + 2) { printf("%d ", i); } } #pragma omp section { printf("\nthread: %d - ", thread_num); for(i=num_inicio; i<=num_fim; i++) { if(valida_primo(i)) { printf("%d ", i); } } } } } return 0; } int valida_primo(int numero) { int i; for(i = 2; i < numero; i++) { if(numero % i == 0) { return 0; } } return 1; }
fourier.c	/* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % FFFFF OOO U U RRRR IIIII EEEEE RRRR % % F O O U U R R I E R R % % FFF O O U U RRRR I EEE RRRR % % F O O U U R R I E R R % % F OOO UUU R R IIIII EEEEE R R % % % % % % MagickCore Discrete Fourier Transform Methods % % % % Software Design % % Sean Burke % % Fred Weinhaus % % Cristy % % July 2009 % % % % % % Copyright @ 2009 ImageMagick Studio LLC, a non-profit organization % % dedicated to making software imaging solutions freely available. % % % % You may not use this file except in compliance with the License. You may % % obtain a copy of the License at % % % % https://imagemagick.org/script/license.php % % % % Unless required by applicable law or agreed to in writing, software % % distributed under the License is distributed on an "AS IS" BASIS, % % WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. % % See the License for the specific language governing permissions and % % limitations under the License. % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % / / Include declarations. / #include "MagickCore/studio.h" #include "MagickCore/artifact.h" #include "MagickCore/attribute.h" #include "MagickCore/blob.h" #include "MagickCore/cache.h" #include "MagickCore/image.h" #include "MagickCore/image-private.h" #include "MagickCore/list.h" #include "MagickCore/fourier.h" #include "MagickCore/log.h" #include "MagickCore/memory_.h" #include "MagickCore/monitor.h" #include "MagickCore/monitor-private.h" #include "MagickCore/pixel-accessor.h" #include "MagickCore/property.h" #include "MagickCore/quantum-private.h" #include "MagickCore/resource_.h" #include "MagickCore/string-private.h" #include "MagickCore/thread-private.h" #if defined(MAGICKCORE_FFTW_DELEGATE) #if defined(MAGICKCORE_HAVE_COMPLEX_H) #include <complex.h> #endif #include <fftw3.h> #if !defined(MAGICKCORE_HAVE_CABS) #define cabs(z) (sqrt(z[0]z[0]+z[1]z[1])) #endif #if !defined(MAGICKCORE_HAVE_CARG) #define carg(z) (atan2(cimag(z),creal(z))) #endif #if !defined(MAGICKCORE_HAVE_CIMAG) #define cimag(z) (z[1]) #endif #if !defined(MAGICKCORE_HAVE_CREAL) #define creal(z) (z[0]) #endif #endif / Typedef declarations. / typedef struct _FourierInfo { PixelChannel channel; MagickBooleanType modulus; size_t width, height; ssize_t center; } FourierInfo; / %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % C o m p l e x I m a g e s % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % ComplexImages() performs complex mathematics on an image sequence. % % The format of the ComplexImages method is: % % MagickBooleanType ComplexImages(Image images,const ComplexOperator op, % ExceptionInfo exception) % % A description of each parameter follows: % % o image: the image. % % o op: A complex operator. % % o exception: return any errors or warnings in this structure. % / MagickExport Image ComplexImages(const Image images,const ComplexOperator op, ExceptionInfo exception) { #define ComplexImageTag "Complex/Image" CacheView Ai_view, Ar_view, Bi_view, Br_view, Ci_view, Cr_view; const char artifact; const Image Ai_image, Ar_image, Bi_image, Br_image; double snr; Image Ci_image, complex_images, Cr_image, image; MagickBooleanType status; MagickOffsetType progress; size_t columns, number_channels, rows; ssize_t y; assert(images != (Image ) NULL); assert(images->signature == MagickCoreSignature); if (images->debug != MagickFalse) (void) LogMagickEvent(TraceEvent,GetMagickModule(),"%s",images->filename); assert(exception != (ExceptionInfo ) NULL); assert(exception->signature == MagickCoreSignature); if (images->next == (Image ) NULL) { (void) ThrowMagickException(exception,GetMagickModule(),ImageError, "ImageSequenceRequired","`%s'",images->filename); return((Image ) NULL); } image=CloneImage(images,0,0,MagickTrue,exception); if (image == (Image ) NULL) return((Image ) NULL); if (SetImageStorageClass(image,DirectClass,exception) == MagickFalse) { image=DestroyImageList(image); return(image); } image->depth=32UL; complex_images=NewImageList(); AppendImageToList(&complex_images,image); image=CloneImage(images->next,0,0,MagickTrue,exception); if (image == (Image ) NULL) { complex_images=DestroyImageList(complex_images); return(complex_images); } image->depth=32UL; AppendImageToList(&complex_images,image); if (SetImageStorageClass(image,DirectClass,exception) == MagickFalse) { complex_images=DestroyImageList(complex_images); return(complex_images); } /* Apply complex mathematics to image pixels. / artifact=GetImageArtifact(images,"complex:snr"); snr=0.0; if (artifact != (const char ) NULL) snr=StringToDouble(artifact,(char *) NULL); Ar_image=images; Ai_image=images->next; Br_image=images; Bi_image=images->next; if ((images->next->next != (Image ) NULL) && (images->next->next->next != (Image ) NULL)) { Br_image=images->next->next; Bi_image=images->next->next->next; } Cr_image=complex_images; Ci_image=complex_images->next; number_channels=MagickMin(MagickMin(MagickMin( Ar_image->number_channels,Ai_image->number_channels),MagickMin( Br_image->number_channels,Bi_image->number_channels)),MagickMin( Cr_image->number_channels,Ci_image->number_channels)); Ar_view=AcquireVirtualCacheView(Ar_image,exception); Ai_view=AcquireVirtualCacheView(Ai_image,exception); Br_view=AcquireVirtualCacheView(Br_image,exception); Bi_view=AcquireVirtualCacheView(Bi_image,exception); Cr_view=AcquireAuthenticCacheView(Cr_image,exception); Ci_view=AcquireAuthenticCacheView(Ci_image,exception); status=MagickTrue; progress=0; columns=MagickMin(Cr_image->columns,Ci_image->columns); rows=MagickMin(Cr_image->rows,Ci_image->rows); #if defined(MAGICKCORE_OPENMP_SUPPORT) #pragma omp parallel for schedule(static) shared(progress,status) \ magick_number_threads(Cr_image,complex_images,rows,1L) #endif for (y=0; y < (ssize_t) rows; y++) { const Quantum magick_restrict Ai, magick_restrict Ar, magick_restrict Bi, magick_restrict Br; Quantum magick_restrict Ci, magick_restrict Cr; ssize_t x; if (status == MagickFalse) continue; Ar=GetCacheViewVirtualPixels(Ar_view,0,y,columns,1,exception); Ai=GetCacheViewVirtualPixels(Ai_view,0,y,columns,1,exception); Br=GetCacheViewVirtualPixels(Br_view,0,y,columns,1,exception); Bi=GetCacheViewVirtualPixels(Bi_view,0,y,columns,1,exception); Cr=QueueCacheViewAuthenticPixels(Cr_view,0,y,columns,1,exception); Ci=QueueCacheViewAuthenticPixels(Ci_view,0,y,columns,1,exception); if ((Ar == (const Quantum ) NULL) \|\| (Ai == (const Quantum ) NULL) \|\| (Br == (const Quantum ) NULL) \|\| (Bi == (const Quantum ) NULL) \|\| (Cr == (Quantum ) NULL) \|\| (Ci == (Quantum ) NULL)) { status=MagickFalse; continue; } for (x=0; x < (ssize_t) columns; x++) { ssize_t i; for (i=0; i < (ssize_t) number_channels; i++) { switch (op) { case AddComplexOperator: { Cr[i]=Ar[i]+Br[i]; Ci[i]=Ai[i]+Bi[i]; break; } case ConjugateComplexOperator: default: { Cr[i]=Ar[i]; Ci[i]=(-Ai[i]); break; } case DivideComplexOperator: { double gamma; gamma=QuantumRangePerceptibleReciprocal(QuantumScaleBr[i]Br[i]+ QuantumScaleBi[i]Bi[i]+snr); Cr[i]=gamma(QuantumScaleAr[i]Br[i]+QuantumScaleAi[i]Bi[i]); Ci[i]=gamma(QuantumScaleAi[i]Br[i]-QuantumScaleAr[i]Bi[i]); break; } case MagnitudePhaseComplexOperator: { Cr[i]=sqrt(QuantumScaleAr[i]Ar[i]+QuantumScaleAi[i]Ai[i]); Ci[i]=atan2((double) Ai[i],(double) Ar[i])/(2.0MagickPI)+0.5; break; } case MultiplyComplexOperator: { Cr[i]=(QuantumScaleAr[i]Br[i]-QuantumScaleAi[i]Bi[i]); Ci[i]=(QuantumScaleAi[i]Br[i]+QuantumScaleAr[i]Bi[i]); break; } case RealImaginaryComplexOperator: { Cr[i]=Ar[i]cos(2.0MagickPI(Ai[i]-0.5)); Ci[i]=Ar[i]sin(2.0MagickPI(Ai[i]-0.5)); break; } case SubtractComplexOperator: { Cr[i]=Ar[i]-Br[i]; Ci[i]=Ai[i]-Bi[i]; break; } } } Ar+=GetPixelChannels(Ar_image); Ai+=GetPixelChannels(Ai_image); Br+=GetPixelChannels(Br_image); Bi+=GetPixelChannels(Bi_image); Cr+=GetPixelChannels(Cr_image); Ci+=GetPixelChannels(Ci_image); } if (SyncCacheViewAuthenticPixels(Ci_view,exception) == MagickFalse) status=MagickFalse; if (SyncCacheViewAuthenticPixels(Cr_view,exception) == MagickFalse) status=MagickFalse; if (images->progress_monitor != (MagickProgressMonitor) NULL) { MagickBooleanType proceed; #if defined(MAGICKCORE_OPENMP_SUPPORT) #pragma omp atomic #endif progress++; proceed=SetImageProgress(images,ComplexImageTag,progress,images->rows); if (proceed == MagickFalse) status=MagickFalse; } } Cr_view=DestroyCacheView(Cr_view); Ci_view=DestroyCacheView(Ci_view); Br_view=DestroyCacheView(Br_view); Bi_view=DestroyCacheView(Bi_view); Ar_view=DestroyCacheView(Ar_view); Ai_view=DestroyCacheView(Ai_view); if (status == MagickFalse) complex_images=DestroyImageList(complex_images); return(complex_images); } / %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % F o r w a r d F o u r i e r T r a n s f o r m I m a g e % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % ForwardFourierTransformImage() implements the discrete Fourier transform % (DFT) of the image either as a magnitude / phase or real / imaginary image % pair. % % The format of the ForwadFourierTransformImage method is: % % Image ForwardFourierTransformImage(const Image image, % const MagickBooleanType modulus,ExceptionInfo exception) % % A description of each parameter follows: % % o image: the image. % % o modulus: if true, return as transform as a magnitude / phase pair % otherwise a real / imaginary image pair. % % o exception: return any errors or warnings in this structure. % / #if defined(MAGICKCORE_FFTW_DELEGATE) static MagickBooleanType RollFourier(const size_t width,const size_t height, const ssize_t x_offset,const ssize_t y_offset,double roll_pixels) { double source_pixels; MemoryInfo source_info; ssize_t i, x; ssize_t u, v, y; / Move zero frequency (DC, average color) from (0,0) to (width/2,height/2). / source_info=AcquireVirtualMemory(width,heightsizeof(source_pixels)); if (source_info == (MemoryInfo ) NULL) return(MagickFalse); source_pixels=(double ) GetVirtualMemoryBlob(source_info); i=0L; for (y=0L; y < (ssize_t) height; y++) { if (y_offset < 0L) v=((y+y_offset) < 0L) ? y+y_offset+(ssize_t) height : y+y_offset; else v=((y+y_offset) > ((ssize_t) height-1L)) ? y+y_offset-(ssize_t) height : y+y_offset; for (x=0L; x < (ssize_t) width; x++) { if (x_offset < 0L) u=((x+x_offset) < 0L) ? x+x_offset+(ssize_t) width : x+x_offset; else u=((x+x_offset) > ((ssize_t) width-1L)) ? x+x_offset-(ssize_t) width : x+x_offset; source_pixels[vwidth+u]=roll_pixels[i++]; } } (void) memcpy(roll_pixels,source_pixels,heightwidthsizeof(source_pixels)); source_info=RelinquishVirtualMemory(source_info); return(MagickTrue); } static MagickBooleanType ForwardQuadrantSwap(const size_t width, const size_t height,double source_pixels,double forward_pixels) { MagickBooleanType status; ssize_t x; ssize_t center, y; / Swap quadrants. / center=(ssize_t) (width/2L)+1L; status=RollFourier((size_t) center,height,0L,(ssize_t) height/2L, source_pixels); if (status == MagickFalse) return(MagickFalse); for (y=0L; y < (ssize_t) height; y++) for (x=0L; x < (ssize_t) (width/2L); x++) forward_pixels[ywidth+x+width/2L]=source_pixels[ycenter+x]; for (y=1; y < (ssize_t) height; y++) for (x=0L; x < (ssize_t) (width/2L); x++) forward_pixels[(height-y)width+width/2L-x-1L]= source_pixels[ycenter+x+1L]; for (x=0L; x < (ssize_t) (width/2L); x++) forward_pixels[width/2L-x-1L]=source_pixels[x+1L]; return(MagickTrue); } static void CorrectPhaseLHS(const size_t width,const size_t height, double fourier_pixels) { ssize_t x; ssize_t y; for (y=0L; y < (ssize_t) height; y++) for (x=0L; x < (ssize_t) (width/2L); x++) fourier_pixels[ywidth+x]=(-1.0); } static MagickBooleanType ForwardFourier(const FourierInfo fourier_info, Image image,double magnitude,double phase,ExceptionInfo exception) { CacheView magnitude_view, phase_view; double magnitude_pixels, phase_pixels; Image magnitude_image, phase_image; MagickBooleanType status; MemoryInfo magnitude_info, phase_info; Quantum q; ssize_t x; ssize_t i, y; magnitude_image=GetFirstImageInList(image); phase_image=GetNextImageInList(image); if (phase_image == (Image ) NULL) { (void) ThrowMagickException(exception,GetMagickModule(),ImageError, "ImageSequenceRequired","`%s'",image->filename); return(MagickFalse); } / Create "Fourier Transform" image from constituent arrays. / magnitude_info=AcquireVirtualMemory((size_t) fourier_info->width, fourier_info->heightsizeof(magnitude_pixels)); phase_info=AcquireVirtualMemory((size_t) fourier_info->width, fourier_info->heightsizeof(phase_pixels)); if ((magnitude_info == (MemoryInfo ) NULL) \|\| (phase_info == (MemoryInfo ) NULL)) { if (phase_info != (MemoryInfo ) NULL) phase_info=RelinquishVirtualMemory(phase_info); if (magnitude_info != (MemoryInfo ) NULL) magnitude_info=RelinquishVirtualMemory(magnitude_info); (void) ThrowMagickException(exception,GetMagickModule(), ResourceLimitError,"MemoryAllocationFailed","`%s'",image->filename); return(MagickFalse); } magnitude_pixels=(double ) GetVirtualMemoryBlob(magnitude_info); (void) memset(magnitude_pixels,0,fourier_info->width* fourier_info->heightsizeof(magnitude_pixels)); phase_pixels=(double ) GetVirtualMemoryBlob(phase_info); (void) memset(phase_pixels,0,fourier_info->width fourier_info->heightsizeof(phase_pixels)); status=ForwardQuadrantSwap(fourier_info->width,fourier_info->height, magnitude,magnitude_pixels); if (status != MagickFalse) status=ForwardQuadrantSwap(fourier_info->width,fourier_info->height,phase, phase_pixels); CorrectPhaseLHS(fourier_info->width,fourier_info->height,phase_pixels); if (fourier_info->modulus != MagickFalse) { i=0L; for (y=0L; y < (ssize_t) fourier_info->height; y++) for (x=0L; x < (ssize_t) fourier_info->width; x++) { phase_pixels[i]/=(2.0MagickPI); phase_pixels[i]+=0.5; i++; } } magnitude_view=AcquireAuthenticCacheView(magnitude_image,exception); i=0L; for (y=0L; y < (ssize_t) fourier_info->height; y++) { q=GetCacheViewAuthenticPixels(magnitude_view,0L,y,fourier_info->width,1UL, exception); if (q == (Quantum ) NULL) break; for (x=0L; x < (ssize_t) fourier_info->width; x++) { switch (fourier_info->channel) { case RedPixelChannel: default: { SetPixelRed(magnitude_image,ClampToQuantum(QuantumRange* magnitude_pixels[i]),q); break; } case GreenPixelChannel: { SetPixelGreen(magnitude_image,ClampToQuantum(QuantumRange* magnitude_pixels[i]),q); break; } case BluePixelChannel: { SetPixelBlue(magnitude_image,ClampToQuantum(QuantumRange* magnitude_pixels[i]),q); break; } case BlackPixelChannel: { SetPixelBlack(magnitude_image,ClampToQuantum(QuantumRange* magnitude_pixels[i]),q); break; } case AlphaPixelChannel: { SetPixelAlpha(magnitude_image,ClampToQuantum(QuantumRange* magnitude_pixels[i]),q); break; } } i++; q+=GetPixelChannels(magnitude_image); } status=SyncCacheViewAuthenticPixels(magnitude_view,exception); if (status == MagickFalse) break; } magnitude_view=DestroyCacheView(magnitude_view); i=0L; phase_view=AcquireAuthenticCacheView(phase_image,exception); for (y=0L; y < (ssize_t) fourier_info->height; y++) { q=GetCacheViewAuthenticPixels(phase_view,0L,y,fourier_info->width,1UL, exception); if (q == (Quantum ) NULL) break; for (x=0L; x < (ssize_t) fourier_info->width; x++) { switch (fourier_info->channel) { case RedPixelChannel: default: { SetPixelRed(phase_image,ClampToQuantum(QuantumRange phase_pixels[i]),q); break; } case GreenPixelChannel: { SetPixelGreen(phase_image,ClampToQuantum(QuantumRange* phase_pixels[i]),q); break; } case BluePixelChannel: { SetPixelBlue(phase_image,ClampToQuantum(QuantumRange* phase_pixels[i]),q); break; } case BlackPixelChannel: { SetPixelBlack(phase_image,ClampToQuantum(QuantumRange* phase_pixels[i]),q); break; } case AlphaPixelChannel: { SetPixelAlpha(phase_image,ClampToQuantum(QuantumRange* phase_pixels[i]),q); break; } } i++; q+=GetPixelChannels(phase_image); } status=SyncCacheViewAuthenticPixels(phase_view,exception); if (status == MagickFalse) break; } phase_view=DestroyCacheView(phase_view); phase_info=RelinquishVirtualMemory(phase_info); magnitude_info=RelinquishVirtualMemory(magnitude_info); return(status); } static MagickBooleanType ForwardFourierTransform(FourierInfo fourier_info, const Image image,double magnitude_pixels,double phase_pixels, ExceptionInfo exception) { CacheView image_view; const char value; double source_pixels; fftw_complex forward_pixels; fftw_plan fftw_r2c_plan; MemoryInfo forward_info, source_info; const Quantum p; ssize_t i, x; ssize_t y; /* Generate the forward Fourier transform. / source_info=AcquireVirtualMemory((size_t) fourier_info->width, fourier_info->heightsizeof(source_pixels)); if (source_info == (MemoryInfo ) NULL) { (void) ThrowMagickException(exception,GetMagickModule(), ResourceLimitError,"MemoryAllocationFailed","`%s'",image->filename); return(MagickFalse); } source_pixels=(double ) GetVirtualMemoryBlob(source_info); memset(source_pixels,0,fourier_info->widthfourier_info->height* sizeof(source_pixels)); i=0L; image_view=AcquireVirtualCacheView(image,exception); for (y=0L; y < (ssize_t) fourier_info->height; y++) { p=GetCacheViewVirtualPixels(image_view,0L,y,fourier_info->width,1UL, exception); if (p == (const Quantum ) NULL) break; for (x=0L; x < (ssize_t) fourier_info->width; x++) { switch (fourier_info->channel) { case RedPixelChannel: default: { source_pixels[i]=QuantumScaleGetPixelRed(image,p); break; } case GreenPixelChannel: { source_pixels[i]=QuantumScaleGetPixelGreen(image,p); break; } case BluePixelChannel: { source_pixels[i]=QuantumScaleGetPixelBlue(image,p); break; } case BlackPixelChannel: { source_pixels[i]=QuantumScaleGetPixelBlack(image,p); break; } case AlphaPixelChannel: { source_pixels[i]=QuantumScaleGetPixelAlpha(image,p); break; } } i++; p+=GetPixelChannels(image); } } image_view=DestroyCacheView(image_view); forward_info=AcquireVirtualMemory((size_t) fourier_info->width, (fourier_info->height/2+1)sizeof(forward_pixels)); if (forward_info == (MemoryInfo ) NULL) { (void) ThrowMagickException(exception,GetMagickModule(), ResourceLimitError,"MemoryAllocationFailed","`%s'",image->filename); source_info=(MemoryInfo ) RelinquishVirtualMemory(source_info); return(MagickFalse); } forward_pixels=(fftw_complex ) GetVirtualMemoryBlob(forward_info); #if defined(MAGICKCORE_OPENMP_SUPPORT) #pragma omp critical (MagickCore_ForwardFourierTransform) #endif fftw_r2c_plan=fftw_plan_dft_r2c_2d(fourier_info->width,fourier_info->height, source_pixels,forward_pixels,FFTW_ESTIMATE); fftw_execute_dft_r2c(fftw_r2c_plan,source_pixels,forward_pixels); fftw_destroy_plan(fftw_r2c_plan); source_info=(MemoryInfo ) RelinquishVirtualMemory(source_info); value=GetImageArtifact(image,"fourier:normalize"); if ((value == (const char ) NULL) \|\| (LocaleCompare(value,"forward") == 0)) { double gamma; /* Normalize forward transform. / i=0L; gamma=PerceptibleReciprocal((double) fourier_info->width fourier_info->height); for (y=0L; y < (ssize_t) fourier_info->height; y++) for (x=0L; x < (ssize_t) fourier_info->center; x++) { #if defined(MAGICKCORE_HAVE_COMPLEX_H) forward_pixels[i]=gamma; #else forward_pixels[i][0]=gamma; forward_pixels[i][1]=gamma; #endif i++; } } / Generate magnitude and phase (or real and imaginary). / i=0L; if (fourier_info->modulus != MagickFalse) for (y=0L; y < (ssize_t) fourier_info->height; y++) for (x=0L; x < (ssize_t) fourier_info->center; x++) { magnitude_pixels[i]=cabs(forward_pixels[i]); phase_pixels[i]=carg(forward_pixels[i]); i++; } else for (y=0L; y < (ssize_t) fourier_info->height; y++) for (x=0L; x < (ssize_t) fourier_info->center; x++) { magnitude_pixels[i]=creal(forward_pixels[i]); phase_pixels[i]=cimag(forward_pixels[i]); i++; } forward_info=(MemoryInfo ) RelinquishVirtualMemory(forward_info); return(MagickTrue); } static MagickBooleanType ForwardFourierTransformChannel(const Image image, const PixelChannel channel,const MagickBooleanType modulus, Image fourier_image,ExceptionInfo exception) { double magnitude_pixels, phase_pixels; FourierInfo fourier_info; MagickBooleanType status; MemoryInfo magnitude_info, phase_info; fourier_info.width=image->columns; fourier_info.height=image->rows; if ((image->columns != image->rows) \|\| ((image->columns % 2) != 0) \|\| ((image->rows % 2) != 0)) { size_t extent=image->columns < image->rows ? image->rows : image->columns; fourier_info.width=(extent & 0x01) == 1 ? extent+1UL : extent; } fourier_info.height=fourier_info.width; fourier_info.center=(ssize_t) (fourier_info.width/2L)+1L; fourier_info.channel=channel; fourier_info.modulus=modulus; magnitude_info=AcquireVirtualMemory((size_t) fourier_info.width, (fourier_info.height/2+1)sizeof(magnitude_pixels)); phase_info=AcquireVirtualMemory((size_t) fourier_info.width, (fourier_info.height/2+1)sizeof(phase_pixels)); if ((magnitude_info == (MemoryInfo ) NULL) \|\| (phase_info == (MemoryInfo ) NULL)) { if (phase_info != (MemoryInfo ) NULL) phase_info=RelinquishVirtualMemory(phase_info); if (magnitude_info == (MemoryInfo ) NULL) magnitude_info=RelinquishVirtualMemory(magnitude_info); (void) ThrowMagickException(exception,GetMagickModule(), ResourceLimitError,"MemoryAllocationFailed","`%s'",image->filename); return(MagickFalse); } magnitude_pixels=(double ) GetVirtualMemoryBlob(magnitude_info); phase_pixels=(double ) GetVirtualMemoryBlob(phase_info); status=ForwardFourierTransform(&fourier_info,image,magnitude_pixels, phase_pixels,exception); if (status != MagickFalse) status=ForwardFourier(&fourier_info,fourier_image,magnitude_pixels, phase_pixels,exception); phase_info=RelinquishVirtualMemory(phase_info); magnitude_info=RelinquishVirtualMemory(magnitude_info); return(status); } #endif MagickExport Image ForwardFourierTransformImage(const Image image, const MagickBooleanType modulus,ExceptionInfo exception) { Image fourier_image; fourier_image=NewImageList(); #if !defined(MAGICKCORE_FFTW_DELEGATE) (void) modulus; (void) ThrowMagickException(exception,GetMagickModule(), MissingDelegateWarning,"DelegateLibrarySupportNotBuiltIn","`%s' (FFTW)", image->filename); #else { Image magnitude_image; size_t height, width; width=image->columns; height=image->rows; if ((image->columns != image->rows) \|\| ((image->columns % 2) != 0) \|\| ((image->rows % 2) != 0)) { size_t extent=image->columns < image->rows ? image->rows : image->columns; width=(extent & 0x01) == 1 ? extent+1UL : extent; } height=width; magnitude_image=CloneImage(image,width,height,MagickTrue,exception); if (magnitude_image != (Image ) NULL) { Image phase_image; magnitude_image->storage_class=DirectClass; magnitude_image->depth=32UL; phase_image=CloneImage(image,width,height,MagickTrue,exception); if (phase_image == (Image ) NULL) magnitude_image=DestroyImage(magnitude_image); else { MagickBooleanType is_gray, status; phase_image->storage_class=DirectClass; phase_image->depth=32UL; AppendImageToList(&fourier_image,magnitude_image); AppendImageToList(&fourier_image,phase_image); status=MagickTrue; is_gray=IsImageGray(image); #if defined(MAGICKCORE_OPENMP_SUPPORT) #pragma omp parallel sections #endif { #if defined(MAGICKCORE_OPENMP_SUPPORT) #pragma omp section #endif { MagickBooleanType thread_status; if (is_gray != MagickFalse) thread_status=ForwardFourierTransformChannel(image, GrayPixelChannel,modulus,fourier_image,exception); else thread_status=ForwardFourierTransformChannel(image, RedPixelChannel,modulus,fourier_image,exception); if (thread_status == MagickFalse) status=thread_status; } #if defined(MAGICKCORE_OPENMP_SUPPORT) #pragma omp section #endif { MagickBooleanType thread_status; thread_status=MagickTrue; if (is_gray == MagickFalse) thread_status=ForwardFourierTransformChannel(image, GreenPixelChannel,modulus,fourier_image,exception); if (thread_status == MagickFalse) status=thread_status; } #if defined(MAGICKCORE_OPENMP_SUPPORT) #pragma omp section #endif { MagickBooleanType thread_status; thread_status=MagickTrue; if (is_gray == MagickFalse) thread_status=ForwardFourierTransformChannel(image, BluePixelChannel,modulus,fourier_image,exception); if (thread_status == MagickFalse) status=thread_status; } #if defined(MAGICKCORE_OPENMP_SUPPORT) #pragma omp section #endif { MagickBooleanType thread_status; thread_status=MagickTrue; if (image->colorspace == CMYKColorspace) thread_status=ForwardFourierTransformChannel(image, BlackPixelChannel,modulus,fourier_image,exception); if (thread_status == MagickFalse) status=thread_status; } #if defined(MAGICKCORE_OPENMP_SUPPORT) #pragma omp section #endif { MagickBooleanType thread_status; thread_status=MagickTrue; if (image->alpha_trait != UndefinedPixelTrait) thread_status=ForwardFourierTransformChannel(image, AlphaPixelChannel,modulus,fourier_image,exception); if (thread_status == MagickFalse) status=thread_status; } } if (status == MagickFalse) fourier_image=DestroyImageList(fourier_image); fftw_cleanup(); } } } #endif return(fourier_image); } / %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % I n v e r s e F o u r i e r T r a n s f o r m I m a g e % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % InverseFourierTransformImage() implements the inverse discrete Fourier % transform (DFT) of the image either as a magnitude / phase or real / % imaginary image pair. % % The format of the InverseFourierTransformImage method is: % % Image InverseFourierTransformImage(const Image magnitude_image, % const Image phase_image,const MagickBooleanType modulus, % ExceptionInfo exception) % % A description of each parameter follows: % % o magnitude_image: the magnitude or real image. % % o phase_image: the phase or imaginary image. % % o modulus: if true, return transform as a magnitude / phase pair % otherwise a real / imaginary image pair. % % o exception: return any errors or warnings in this structure. % / #if defined(MAGICKCORE_FFTW_DELEGATE) static MagickBooleanType InverseQuadrantSwap(const size_t width, const size_t height,const double source,double destination) { ssize_t x; ssize_t center, y; / Swap quadrants. / center=(ssize_t) (width/2L)+1L; for (y=1L; y < (ssize_t) height; y++) for (x=0L; x < (ssize_t) (width/2L+1L); x++) destination[(height-y)center-x+width/2L]=source[ywidth+x]; for (y=0L; y < (ssize_t) height; y++) destination[ycenter]=source[ywidth+width/2L]; for (x=0L; x < center; x++) destination[x]=source[center-x-1L]; return(RollFourier(center,height,0L,(ssize_t) height/-2L,destination)); } static MagickBooleanType InverseFourier(FourierInfo fourier_info, const Image magnitude_image,const Image phase_image, fftw_complex fourier_pixels,ExceptionInfo exception) { CacheView magnitude_view, phase_view; double inverse_pixels, magnitude_pixels, phase_pixels; MagickBooleanType status; MemoryInfo inverse_info, magnitude_info, phase_info; const Quantum p; ssize_t i, x; ssize_t y; / Inverse fourier - read image and break down into a double array. / magnitude_info=AcquireVirtualMemory((size_t) fourier_info->width, fourier_info->heightsizeof(magnitude_pixels)); phase_info=AcquireVirtualMemory((size_t) fourier_info->width, fourier_info->heightsizeof(phase_pixels)); inverse_info=AcquireVirtualMemory((size_t) fourier_info->width, (fourier_info->height/2+1)sizeof(inverse_pixels)); if ((magnitude_info == (MemoryInfo ) NULL) \|\| (phase_info == (MemoryInfo ) NULL) \|\| (inverse_info == (MemoryInfo ) NULL)) { if (magnitude_info != (MemoryInfo ) NULL) magnitude_info=RelinquishVirtualMemory(magnitude_info); if (phase_info != (MemoryInfo ) NULL) phase_info=RelinquishVirtualMemory(phase_info); if (inverse_info != (MemoryInfo ) NULL) inverse_info=RelinquishVirtualMemory(inverse_info); (void) ThrowMagickException(exception,GetMagickModule(), ResourceLimitError,"MemoryAllocationFailed","`%s'", magnitude_image->filename); return(MagickFalse); } magnitude_pixels=(double ) GetVirtualMemoryBlob(magnitude_info); phase_pixels=(double ) GetVirtualMemoryBlob(phase_info); inverse_pixels=(double ) GetVirtualMemoryBlob(inverse_info); i=0L; magnitude_view=AcquireVirtualCacheView(magnitude_image,exception); for (y=0L; y < (ssize_t) fourier_info->height; y++) { p=GetCacheViewVirtualPixels(magnitude_view,0L,y,fourier_info->width,1UL, exception); if (p == (const Quantum ) NULL) break; for (x=0L; x < (ssize_t) fourier_info->width; x++) { switch (fourier_info->channel) { case RedPixelChannel: default: { magnitude_pixels[i]=QuantumScaleGetPixelRed(magnitude_image,p); break; } case GreenPixelChannel: { magnitude_pixels[i]=QuantumScaleGetPixelGreen(magnitude_image,p); break; } case BluePixelChannel: { magnitude_pixels[i]=QuantumScaleGetPixelBlue(magnitude_image,p); break; } case BlackPixelChannel: { magnitude_pixels[i]=QuantumScaleGetPixelBlack(magnitude_image,p); break; } case AlphaPixelChannel: { magnitude_pixels[i]=QuantumScaleGetPixelAlpha(magnitude_image,p); break; } } i++; p+=GetPixelChannels(magnitude_image); } } magnitude_view=DestroyCacheView(magnitude_view); status=InverseQuadrantSwap(fourier_info->width,fourier_info->height, magnitude_pixels,inverse_pixels); (void) memcpy(magnitude_pixels,inverse_pixels,fourier_info->height* fourier_info->centersizeof(magnitude_pixels)); i=0L; phase_view=AcquireVirtualCacheView(phase_image,exception); for (y=0L; y < (ssize_t) fourier_info->height; y++) { p=GetCacheViewVirtualPixels(phase_view,0,y,fourier_info->width,1, exception); if (p == (const Quantum ) NULL) break; for (x=0L; x < (ssize_t) fourier_info->width; x++) { switch (fourier_info->channel) { case RedPixelChannel: default: { phase_pixels[i]=QuantumScaleGetPixelRed(phase_image,p); break; } case GreenPixelChannel: { phase_pixels[i]=QuantumScaleGetPixelGreen(phase_image,p); break; } case BluePixelChannel: { phase_pixels[i]=QuantumScaleGetPixelBlue(phase_image,p); break; } case BlackPixelChannel: { phase_pixels[i]=QuantumScaleGetPixelBlack(phase_image,p); break; } case AlphaPixelChannel: { phase_pixels[i]=QuantumScaleGetPixelAlpha(phase_image,p); break; } } i++; p+=GetPixelChannels(phase_image); } } if (fourier_info->modulus != MagickFalse) { i=0L; for (y=0L; y < (ssize_t) fourier_info->height; y++) for (x=0L; x < (ssize_t) fourier_info->width; x++) { phase_pixels[i]-=0.5; phase_pixels[i]=(2.0MagickPI); i++; } } phase_view=DestroyCacheView(phase_view); CorrectPhaseLHS(fourier_info->width,fourier_info->height,phase_pixels); if (status != MagickFalse) status=InverseQuadrantSwap(fourier_info->width,fourier_info->height, phase_pixels,inverse_pixels); (void) memcpy(phase_pixels,inverse_pixels,fourier_info->height* fourier_info->centersizeof(phase_pixels)); inverse_info=RelinquishVirtualMemory(inverse_info); /* Merge two sets. / i=0L; if (fourier_info->modulus != MagickFalse) for (y=0L; y < (ssize_t) fourier_info->height; y++) for (x=0L; x < (ssize_t) fourier_info->center; x++) { #if defined(MAGICKCORE_HAVE_COMPLEX_H) fourier_pixels[i]=magnitude_pixels[i]cos(phase_pixels[i])+I* magnitude_pixels[i]sin(phase_pixels[i]); #else fourier_pixels[i][0]=magnitude_pixels[i]cos(phase_pixels[i]); fourier_pixels[i][1]=magnitude_pixels[i]sin(phase_pixels[i]); #endif i++; } else for (y=0L; y < (ssize_t) fourier_info->height; y++) for (x=0L; x < (ssize_t) fourier_info->center; x++) { #if defined(MAGICKCORE_HAVE_COMPLEX_H) fourier_pixels[i]=magnitude_pixels[i]+Iphase_pixels[i]; #else fourier_pixels[i][0]=magnitude_pixels[i]; fourier_pixels[i][1]=phase_pixels[i]; #endif i++; } magnitude_info=RelinquishVirtualMemory(magnitude_info); phase_info=RelinquishVirtualMemory(phase_info); return(status); } static MagickBooleanType InverseFourierTransform(FourierInfo fourier_info, fftw_complex fourier_pixels,Image image,ExceptionInfo exception) { CacheView image_view; const char value; double source_pixels; fftw_plan fftw_c2r_plan; MemoryInfo source_info; Quantum q; ssize_t i, x; ssize_t y; source_info=AcquireVirtualMemory((size_t) fourier_info->width, fourier_info->heightsizeof(source_pixels)); if (source_info == (MemoryInfo ) NULL) { (void) ThrowMagickException(exception,GetMagickModule(), ResourceLimitError,"MemoryAllocationFailed","`%s'",image->filename); return(MagickFalse); } source_pixels=(double ) GetVirtualMemoryBlob(source_info); value=GetImageArtifact(image,"fourier:normalize"); if (LocaleCompare(value,"inverse") == 0) { double gamma; / Normalize inverse transform. / i=0L; gamma=PerceptibleReciprocal((double) fourier_info->width fourier_info->height); for (y=0L; y < (ssize_t) fourier_info->height; y++) for (x=0L; x < (ssize_t) fourier_info->center; x++) { #if defined(MAGICKCORE_HAVE_COMPLEX_H) fourier_pixels[i]=gamma; #else fourier_pixels[i][0]=gamma; fourier_pixels[i][1]=gamma; #endif i++; } } #if defined(MAGICKCORE_OPENMP_SUPPORT) #pragma omp critical (MagickCore_InverseFourierTransform) #endif fftw_c2r_plan=fftw_plan_dft_c2r_2d(fourier_info->width,fourier_info->height, fourier_pixels,source_pixels,FFTW_ESTIMATE); fftw_execute_dft_c2r(fftw_c2r_plan,fourier_pixels,source_pixels); fftw_destroy_plan(fftw_c2r_plan); i=0L; image_view=AcquireAuthenticCacheView(image,exception); for (y=0L; y < (ssize_t) fourier_info->height; y++) { if (y >= (ssize_t) image->rows) break; q=GetCacheViewAuthenticPixels(image_view,0L,y,fourier_info->width > image->columns ? image->columns : fourier_info->width,1UL,exception); if (q == (Quantum ) NULL) break; for (x=0L; x < (ssize_t) fourier_info->width; x++) { if (x < (ssize_t) image->columns) switch (fourier_info->channel) { case RedPixelChannel: default: { SetPixelRed(image,ClampToQuantum(QuantumRangesource_pixels[i]),q); break; } case GreenPixelChannel: { SetPixelGreen(image,ClampToQuantum(QuantumRangesource_pixels[i]), q); break; } case BluePixelChannel: { SetPixelBlue(image,ClampToQuantum(QuantumRangesource_pixels[i]), q); break; } case BlackPixelChannel: { SetPixelBlack(image,ClampToQuantum(QuantumRangesource_pixels[i]), q); break; } case AlphaPixelChannel: { SetPixelAlpha(image,ClampToQuantum(QuantumRangesource_pixels[i]), q); break; } } i++; q+=GetPixelChannels(image); } if (SyncCacheViewAuthenticPixels(image_view,exception) == MagickFalse) break; } image_view=DestroyCacheView(image_view); source_info=RelinquishVirtualMemory(source_info); return(MagickTrue); } static MagickBooleanType InverseFourierTransformChannel( const Image magnitude_image,const Image phase_image, const PixelChannel channel,const MagickBooleanType modulus, Image fourier_image,ExceptionInfo exception) { fftw_complex inverse_pixels; FourierInfo fourier_info; MagickBooleanType status; MemoryInfo inverse_info; fourier_info.width=magnitude_image->columns; fourier_info.height=magnitude_image->rows; if ((magnitude_image->columns != magnitude_image->rows) \|\| ((magnitude_image->columns % 2) != 0) \|\| ((magnitude_image->rows % 2) != 0)) { size_t extent=magnitude_image->columns < magnitude_image->rows ? magnitude_image->rows : magnitude_image->columns; fourier_info.width=(extent & 0x01) == 1 ? extent+1UL : extent; } fourier_info.height=fourier_info.width; fourier_info.center=(ssize_t) (fourier_info.width/2L)+1L; fourier_info.channel=channel; fourier_info.modulus=modulus; inverse_info=AcquireVirtualMemory((size_t) fourier_info.width, (fourier_info.height/2+1)sizeof(inverse_pixels)); if (inverse_info == (MemoryInfo ) NULL) { (void) ThrowMagickException(exception,GetMagickModule(), ResourceLimitError,"MemoryAllocationFailed","`%s'", magnitude_image->filename); return(MagickFalse); } inverse_pixels=(fftw_complex ) GetVirtualMemoryBlob(inverse_info); status=InverseFourier(&fourier_info,magnitude_image,phase_image, inverse_pixels,exception); if (status != MagickFalse) status=InverseFourierTransform(&fourier_info,inverse_pixels,fourier_image, exception); inverse_info=RelinquishVirtualMemory(inverse_info); return(status); } #endif MagickExport Image InverseFourierTransformImage(const Image magnitude_image, const Image phase_image,const MagickBooleanType modulus, ExceptionInfo exception) { Image fourier_image; assert(magnitude_image != (Image ) NULL); assert(magnitude_image->signature == MagickCoreSignature); if (magnitude_image->debug != MagickFalse) (void) LogMagickEvent(TraceEvent,GetMagickModule(),"%s", magnitude_image->filename); if (phase_image == (Image ) NULL) { (void) ThrowMagickException(exception,GetMagickModule(),ImageError, "ImageSequenceRequired","`%s'",magnitude_image->filename); return((Image ) NULL); } #if !defined(MAGICKCORE_FFTW_DELEGATE) fourier_image=(Image ) NULL; (void) modulus; (void) ThrowMagickException(exception,GetMagickModule(), MissingDelegateWarning,"DelegateLibrarySupportNotBuiltIn","`%s' (FFTW)", magnitude_image->filename); #else { fourier_image=CloneImage(magnitude_image,magnitude_image->columns, magnitude_image->rows,MagickTrue,exception); if (fourier_image != (Image *) NULL) { MagickBooleanType is_gray, status; status=MagickTrue; is_gray=IsImageGray(magnitude_image); if (is_gray != MagickFalse) is_gray=IsImageGray(phase_image); #if defined(MAGICKCORE_OPENMP_SUPPORT) #pragma omp parallel sections #endif { #if defined(MAGICKCORE_OPENMP_SUPPORT) #pragma omp section #endif { MagickBooleanType thread_status; if (is_gray != MagickFalse) thread_status=InverseFourierTransformChannel(magnitude_image, phase_image,GrayPixelChannel,modulus,fourier_image,exception); else thread_status=InverseFourierTransformChannel(magnitude_image, phase_image,RedPixelChannel,modulus,fourier_image,exception); if (thread_status == MagickFalse) status=thread_status; } #if defined(MAGICKCORE_OPENMP_SUPPORT) #pragma omp section #endif { MagickBooleanType thread_status; thread_status=MagickTrue; if (is_gray == MagickFalse) thread_status=InverseFourierTransformChannel(magnitude_image, phase_image,GreenPixelChannel,modulus,fourier_image,exception); if (thread_status == MagickFalse) status=thread_status; } #if defined(MAGICKCORE_OPENMP_SUPPORT) #pragma omp section #endif { MagickBooleanType thread_status; thread_status=MagickTrue; if (is_gray == MagickFalse) thread_status=InverseFourierTransformChannel(magnitude_image, phase_image,BluePixelChannel,modulus,fourier_image,exception); if (thread_status == MagickFalse) status=thread_status; } #if defined(MAGICKCORE_OPENMP_SUPPORT) #pragma omp section #endif { MagickBooleanType thread_status; thread_status=MagickTrue; if (magnitude_image->colorspace == CMYKColorspace) thread_status=InverseFourierTransformChannel(magnitude_image, phase_image,BlackPixelChannel,modulus,fourier_image,exception); if (thread_status == MagickFalse) status=thread_status; } #if defined(MAGICKCORE_OPENMP_SUPPORT) #pragma omp section #endif { MagickBooleanType thread_status; thread_status=MagickTrue; if (magnitude_image->alpha_trait != UndefinedPixelTrait) thread_status=InverseFourierTransformChannel(magnitude_image, phase_image,AlphaPixelChannel,modulus,fourier_image,exception); if (thread_status == MagickFalse) status=thread_status; } } if (status == MagickFalse) fourier_image=DestroyImage(fourier_image); } fftw_cleanup(); } #endif return(fourier_image); }
GB_unop__acos_fc64_fc64.c	//------------------------------------------------------------------------------ // GB_unop: hard-coded functions for each built-in unary operator //------------------------------------------------------------------------------ // SuiteSparse:GraphBLAS, Timothy A. Davis, (c) 2017-2021, All Rights Reserved. // SPDX-License-Identifier: Apache-2.0 //------------------------------------------------------------------------------ // If this file is in the Generated/ folder, do not edit it (auto-generated). #include "GB.h" #ifndef GBCOMPACT #include "GB_control.h" #include "GB_atomics.h" #include "GB_unop__include.h" // C=unop(A) is defined by the following types and operators: // op(A) function: GB (_unop_apply__acos_fc64_fc64) // op(A') function: GB (_unop_tran__acos_fc64_fc64) // C type: GxB_FC64_t // A type: GxB_FC64_t // cast: GxB_FC64_t cij = aij // unaryop: cij = cacos (aij) #define GB_ATYPE \ GxB_FC64_t #define GB_CTYPE \ GxB_FC64_t // aij = Ax [pA] #define GB_GETA(aij,Ax,pA) \ GxB_FC64_t aij = Ax [pA] #define GB_CX(p) Cx [p] // unary operator #define GB_OP(z, x) \ z = cacos (x) ; // casting #define GB_CAST(z, aij) \ GxB_FC64_t z = aij ; // cij = op (aij) #define GB_CAST_OP(pC,pA) \ { \ /* aij = Ax [pA] / \ GxB_FC64_t aij = Ax [pA] ; \ / Cx [pC] = op (cast (aij)) / \ GxB_FC64_t z = aij ; \ Cx [pC] = cacos (z) ; \ } // true if operator is the identity op with no typecasting #define GB_OP_IS_IDENTITY_WITH_NO_TYPECAST \ 0 // disable this operator and use the generic case if these conditions hold #define GB_DISABLE \ (GxB_NO_ACOS \|\| GxB_NO_FC64) //------------------------------------------------------------------------------ // Cx = op (cast (Ax)): apply a unary operator //------------------------------------------------------------------------------ GrB_Info GB (_unop_apply__acos_fc64_fc64) ( GxB_FC64_t Cx, // Cx and Ax may be aliased const GxB_FC64_t Ax, const int8_t restrict Ab, // A->b if A is bitmap int64_t anz, int nthreads ) { #if GB_DISABLE return (GrB_NO_VALUE) ; #else int64_t p ; // TODO: if OP is ONE and uniform-valued matrices are exploited, then // do this in O(1) time if (Ab == NULL) { #if ( GB_OP_IS_IDENTITY_WITH_NO_TYPECAST ) GB_memcpy (Cx, Ax, anz * sizeof (GxB_FC64_t), nthreads) ; #else #pragma omp parallel for num_threads(nthreads) schedule(static) for (p = 0 ; p < anz ; p++) { GxB_FC64_t aij = Ax [p] ; GxB_FC64_t z = aij ; Cx [p] = cacos (z) ; } #endif } else { // bitmap case, no transpose; A->b already memcpy'd into C->b #pragma omp parallel for num_threads(nthreads) schedule(static) for (p = 0 ; p < anz ; p++) { if (!Ab [p]) continue ; GxB_FC64_t aij = Ax [p] ; GxB_FC64_t z = aij ; Cx [p] = cacos (z) ; } } return (GrB_SUCCESS) ; #endif } //------------------------------------------------------------------------------ // C = op (cast (A')): transpose, typecast, and apply a unary operator //------------------------------------------------------------------------------ GrB_Info GB (_unop_tran__acos_fc64_fc64) ( GrB_Matrix C, const GrB_Matrix A, int64_t restrict Workspaces, const int64_t *restrict A_slice, int nworkspaces, int nthreads ) { #if GB_DISABLE return (GrB_NO_VALUE) ; #else #include "GB_unop_transpose.c" return (GrB_SUCCESS) ; #endif } #endif
critical.c	////////////////////////////////////////////////////////////// // // critical.c // // Copyright (c) 2017, Hassan Salehe Matar // All rights reserved. // // This file is part of Clanomp. For details, see // https://github.com/hassansalehe/Clanomp. Please also // see the LICENSE file for additional BSD notice // // Redistribution and use in source and binary forms, with // or without modification, are permitted provided that // the following conditions are met: // // * Redistributions of source code must retain the above // copyright notice, this list of conditions and the // following disclaimer. // // * Redistributions in binary form must reproduce the // above copyright notice, this list of conditions and // the following disclaimer in the documentation and/or // other materials provided with the distribution. // // * Neither the name of the copyright holder nor the names // of its contributors may be used to endorse or promote // products derived from this software without specific // prior written permission. // // THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND // CONTRIBUTORS "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, // INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF // MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE // DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT HOLDER OR // CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, // SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, // BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR // SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS // INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, // WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING // NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE // OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF // SUCH DAMAGE. // ////////////////////////////////////////////////////////////// // From the OpenMP specification: // The critical construct restricts execution of the // associated structured block to a single thread at a time. // // References: // 1. http://www.openmp.org/wp-content/uploads/openmp-examples-4.5.0.pdf // 2. http://www.openmp.org/wp-content/uploads/openmp-4.5.pdf #include <stdio.h> #include <omp.h> int main() { int count = 0; #pragma omp parallel shared(count) { #pragma omp critical { count++; } } printf("Value of count: %d, construct: <critical>\n", count); return 0; }
GB_binop__isge_uint8.c	//------------------------------------------------------------------------------ // GB_binop: hard-coded functions for each built-in binary operator //------------------------------------------------------------------------------ // SuiteSparse:GraphBLAS, Timothy A. Davis, (c) 2017-2020, All Rights Reserved. // http://suitesparse.com See GraphBLAS/Doc/License.txt for license. //------------------------------------------------------------------------------ // If this file is in the Generated/ folder, do not edit it (auto-generated). #include "GB.h" #ifndef GBCOMPACT #include "GB_control.h" #include "GB_ek_slice.h" #include "GB_dense.h" #include "GB_mkl.h" #include "GB_binop__include.h" // C=binop(A,B) is defined by the following types and operators: // A+B function (eWiseAdd): GB_AaddB__isge_uint8 // A.B function (eWiseMult): GB_AemultB__isge_uint8 // AD function (colscale): GB_AxD__isge_uint8 // DA function (rowscale): GB_DxB__isge_uint8 // C+=B function (dense accum): GB_Cdense_accumB__isge_uint8 // C+=b function (dense accum): GB_Cdense_accumb__isge_uint8 // C+=A+B function (dense ewise3): (none) // C=A+B function (dense ewise3): GB_Cdense_ewise3_noaccum__isge_uint8 // C=scalar+B GB_bind1st__isge_uint8 // C=scalar+B' GB_bind1st_tran__isge_uint8 // C=A+scalar GB_bind2nd__isge_uint8 // C=A'+scalar GB_bind2nd_tran__isge_uint8 // C type: uint8_t // A type: uint8_t // B,b type: uint8_t // BinaryOp: cij = (aij >= bij) #define GB_ATYPE \ uint8_t #define GB_BTYPE \ uint8_t #define GB_CTYPE \ uint8_t // true if the types of A and B are identical #define GB_ATYPE_IS_BTYPE \ 1 // true if the types of C and A are identical #define GB_CTYPE_IS_ATYPE \ 1 // true if the types of C and B are identical #define GB_CTYPE_IS_BTYPE \ 1 // aij = Ax [pA] #define GB_GETA(aij,Ax,pA) \ uint8_t aij = Ax [pA] // bij = Bx [pB] #define GB_GETB(bij,Bx,pB) \ uint8_t bij = Bx [pB] // declare scalar of the same type as C #define GB_CTYPE_SCALAR(t) \ uint8_t t // cij = Ax [pA] #define GB_COPY_A_TO_C(cij,Ax,pA) \ cij = Ax [pA] // cij = Bx [pB] #define GB_COPY_B_TO_C(cij,Bx,pB) \ cij = Bx [pB] #define GB_CX(p) Cx [p] // binary operator #define GB_BINOP(z, x, y) \ z = (x >= y) ; // op is second #define GB_OP_IS_SECOND \ 0 // op is plus_fp32 or plus_fp64 #define GB_OP_IS_PLUS_REAL \ 0 // op is minus_fp32 or minus_fp64 #define GB_OP_IS_MINUS_REAL \ 0 // GB_cblas_axpy gateway routine, if it exists for this operator and type: #define GB_CBLAS_AXPY \ (none) // do the numerical phases of GB_add and GB_emult #define GB_PHASE_2_OF_2 // hard-coded loops can be vectorized #define GB_PRAGMA_SIMD_VECTORIZE GB_PRAGMA_SIMD // disable this operator and use the generic case if these conditions hold #define GB_DISABLE \ (GxB_NO_ISGE \|\| GxB_NO_UINT8 \|\| GxB_NO_ISGE_UINT8) //------------------------------------------------------------------------------ // C += A+B, all 3 matrices dense //------------------------------------------------------------------------------ #if 0 // The op must be MIN, MAX, PLUS, MINUS, RMINUS, TIMES, DIV, or RDIV. void (none) ( GrB_Matrix C, const GrB_Matrix A, const GrB_Matrix B, const int nthreads ) { #include "GB_dense_ewise3_accum_template.c" } #endif //------------------------------------------------------------------------------ // C = A+B, all 3 matrices dense //------------------------------------------------------------------------------ GrB_Info GB_Cdense_ewise3_noaccum__isge_uint8 ( GrB_Matrix C, const GrB_Matrix A, const GrB_Matrix B, const int nthreads ) { #if GB_DISABLE return (GrB_NO_VALUE) ; #else #include "GB_dense_ewise3_noaccum_template.c" return (GrB_SUCCESS) ; #endif } //------------------------------------------------------------------------------ // C += B, accumulate a sparse matrix into a dense matrix //------------------------------------------------------------------------------ GrB_Info GB_Cdense_accumB__isge_uint8 ( GrB_Matrix C, const GrB_Matrix B, const int64_t GB_RESTRICT kfirst_slice, const int64_t GB_RESTRICT klast_slice, const int64_t GB_RESTRICT pstart_slice, const int ntasks, const int nthreads ) { #if GB_DISABLE return (GrB_NO_VALUE) ; #else { #include "GB_dense_subassign_23_template.c" } return (GrB_SUCCESS) ; #endif } //------------------------------------------------------------------------------ // C += b, accumulate a scalar into a dense matrix //------------------------------------------------------------------------------ GrB_Info GB_Cdense_accumb__isge_uint8 ( GrB_Matrix C, const GB_void p_bwork, const int nthreads ) { #if GB_DISABLE return (GrB_NO_VALUE) ; #else { // get the scalar b for C += b, of type uint8_t uint8_t bwork = (((uint8_t ) p_bwork)) ; #include "GB_dense_subassign_22_template.c" return (GrB_SUCCESS) ; } return (GrB_SUCCESS) ; #endif } //------------------------------------------------------------------------------ // C = AD, column scale with diagonal D matrix //------------------------------------------------------------------------------ GrB_Info GB_AxD__isge_uint8 ( GrB_Matrix C, const GrB_Matrix A, bool A_is_pattern, const GrB_Matrix D, bool D_is_pattern, const int64_t GB_RESTRICT kfirst_slice, const int64_t GB_RESTRICT klast_slice, const int64_t GB_RESTRICT pstart_slice, const int ntasks, const int nthreads ) { #if GB_DISABLE return (GrB_NO_VALUE) ; #else uint8_t GB_RESTRICT Cx = (uint8_t ) C->x ; #include "GB_AxB_colscale_meta.c" return (GrB_SUCCESS) ; #endif } //------------------------------------------------------------------------------ // C = DB, row scale with diagonal D matrix //------------------------------------------------------------------------------ GrB_Info GB_DxB__isge_uint8 ( GrB_Matrix C, const GrB_Matrix D, bool D_is_pattern, const GrB_Matrix B, bool B_is_pattern, int nthreads ) { #if GB_DISABLE return (GrB_NO_VALUE) ; #else uint8_t GB_RESTRICT Cx = (uint8_t ) C->x ; #include "GB_AxB_rowscale_meta.c" return (GrB_SUCCESS) ; #endif } //------------------------------------------------------------------------------ // eWiseAdd: C = A+B or C<M> = A+B //------------------------------------------------------------------------------ GrB_Info GB_AaddB__isge_uint8 ( GrB_Matrix C, const GrB_Matrix M, const bool Mask_struct, const GrB_Matrix A, const GrB_Matrix B, const bool Ch_is_Mh, const int64_t GB_RESTRICT C_to_M, const int64_t GB_RESTRICT C_to_A, const int64_t GB_RESTRICT C_to_B, const GB_task_struct GB_RESTRICT TaskList, const int ntasks, const int nthreads ) { #if GB_DISABLE return (GrB_NO_VALUE) ; #else #include "GB_add_template.c" return (GrB_SUCCESS) ; #endif } //------------------------------------------------------------------------------ // eWiseMult: C = A.B or C<M> = A.B //------------------------------------------------------------------------------ GrB_Info GB_AemultB__isge_uint8 ( GrB_Matrix C, const GrB_Matrix M, const bool Mask_struct, const GrB_Matrix A, const GrB_Matrix B, const int64_t GB_RESTRICT C_to_M, const int64_t GB_RESTRICT C_to_A, const int64_t GB_RESTRICT C_to_B, const GB_task_struct GB_RESTRICT TaskList, const int ntasks, const int nthreads ) { #if GB_DISABLE return (GrB_NO_VALUE) ; #else #include "GB_emult_template.c" return (GrB_SUCCESS) ; #endif } //------------------------------------------------------------------------------ // Cx = op (x,Bx): apply a binary operator to a matrix with scalar bind1st //------------------------------------------------------------------------------ GrB_Info GB_bind1st__isge_uint8 ( GB_void Cx_output, // Cx and Bx may be aliased const GB_void x_input, const GB_void Bx_input, int64_t anz, int nthreads ) { #if GB_DISABLE return (GrB_NO_VALUE) ; #else uint8_t Cx = (uint8_t ) Cx_output ; uint8_t x = (((uint8_t ) x_input)) ; uint8_t Bx = (uint8_t ) Bx_input ; int64_t p ; #pragma omp parallel for num_threads(nthreads) schedule(static) for (p = 0 ; p < anz ; p++) { uint8_t bij = Bx [p] ; Cx [p] = (x >= bij) ; } return (GrB_SUCCESS) ; #endif } //------------------------------------------------------------------------------ // Cx = op (Ax,y): apply a binary operator to a matrix with scalar bind2nd //------------------------------------------------------------------------------ GrB_Info GB_bind2nd__isge_uint8 ( GB_void Cx_output, // Cx and Ax may be aliased const GB_void Ax_input, const GB_void y_input, int64_t anz, int nthreads ) { #if GB_DISABLE return (GrB_NO_VALUE) ; #else int64_t p ; uint8_t Cx = (uint8_t ) Cx_output ; uint8_t Ax = (uint8_t ) Ax_input ; uint8_t y = (((uint8_t ) y_input)) ; #pragma omp parallel for num_threads(nthreads) schedule(static) for (p = 0 ; p < anz ; p++) { uint8_t aij = Ax [p] ; Cx [p] = (aij >= y) ; } return (GrB_SUCCESS) ; #endif } //------------------------------------------------------------------------------ // C = op (x, A'): transpose and apply a binary operator //------------------------------------------------------------------------------ // cij = op (x, aij), no typcasting (in spite of the macro name) #undef GB_CAST_OP #define GB_CAST_OP(pC,pA) \ { \ uint8_t aij = Ax [pA] ; \ Cx [pC] = (x >= aij) ; \ } GrB_Info GB_bind1st_tran__isge_uint8 ( GrB_Matrix C, const GB_void x_input, const GrB_Matrix A, int64_t GB_RESTRICT Rowcounts, GBI_single_iterator Iter, const int64_t GB_RESTRICT A_slice, int naslice ) { // GB_unop_transpose.c uses GB_ATYPE, but A is // the 2nd input to binary operator z=f(x,y). #undef GB_ATYPE #define GB_ATYPE \ uint8_t #if GB_DISABLE return (GrB_NO_VALUE) ; #else uint8_t x = (((const uint8_t ) x_input)) ; #define GB_PHASE_2_OF_2 #include "GB_unop_transpose.c" return (GrB_SUCCESS) ; #endif #undef GB_ATYPE #define GB_ATYPE \ uint8_t } //------------------------------------------------------------------------------ // C = op (A', y): transpose and apply a binary operator //------------------------------------------------------------------------------ // cij = op (aij, y), no typcasting (in spite of the macro name) #undef GB_CAST_OP #define GB_CAST_OP(pC,pA) \ { \ uint8_t aij = Ax [pA] ; \ Cx [pC] = (aij >= y) ; \ } GrB_Info GB_bind2nd_tran__isge_uint8 ( GrB_Matrix C, const GrB_Matrix A, const GB_void y_input, int64_t GB_RESTRICT Rowcounts, GBI_single_iterator Iter, const int64_t GB_RESTRICT A_slice, int naslice ) { #if GB_DISABLE return (GrB_NO_VALUE) ; #else uint8_t y = (((const uint8_t *) y_input)) ; #define GB_PHASE_2_OF_2 #include "GB_unop_transpose.c" return (GrB_SUCCESS) ; #endif } #endif
weird_another_fmt_plug.c	/* Hacked together during March, 2013 by Dhiru Kholia <dhiru.kholia at gmail.com>. * * This software is Copyright (c) 2013, Dhiru Kholia <dhiru.kholia at gmail.com>, * and it is hereby released to the general public under the following terms: * Redistribution and use in source and binary forms, with or without modification, * are permitted. * * Algorithm : md5(md5(t)+md5(e)+md5(s)+md5(t)) for "test" / #if FMT_EXTERNS_H extern struct fmt_main weird_fmt; #elif FMT_REGISTERS_H john_register_one(&weird_fmt); #else #include <unistd.h> #ifdef _OPENMP static int omp_t = 1; #include <omp.h> #define OMP_SCALE 64 #endif #include <string.h> #include <assert.h> #include <errno.h> #include "arch.h" #include "md5.h" #include "misc.h" #include "common.h" #include "formats.h" #include "params.h" #include "options.h" #include "memdbg.h" #define FORMAT_LABEL "weird" #define FORMAT_NAME "weird md5(md5(t)+md5(e)+md5(s)+md5(t)) for \"test\"" #define ALGORITHM_NAME "32/" ARCH_BITS_STR #define BENCHMARK_COMMENT "" #define BENCHMARK_LENGTH -1 #define PLAINTEXT_LENGTH 25 #define BINARY_SIZE 16 #define SALT_SIZE 0 #define MIN_KEYS_PER_CRYPT 1 #define MAX_KEYS_PER_CRYPT 1 unsigned char map[256][33]; static struct fmt_tests weird_tests[] = { {"$weird$46d37e540dbfda624c38e3cc70bb5fa7", "password"}, {"$weird$be6d87f17a719b57518c61d40ce0b72d", "071883"}, {NULL} }; static inline void hex_encode(unsigned char str, int len, unsigned char out) { int i; for (i = 0; i < len; ++i) { out[0] = itoa16[str[i]>>4]; out[1] = itoa16[str[i]&0xF]; out += 2; } } static char (saved_key)[PLAINTEXT_LENGTH + 1]; static ARCH_WORD_32 (crypt_out)[BINARY_SIZE / sizeof(ARCH_WORD_32)]; static void init(struct fmt_main self) { MD5_CTX ctx; int i; unsigned char c; unsigned char hash[16]; unsigned char out[33]; #ifdef _OPENMP omp_t = omp_get_max_threads(); self->params.min_keys_per_crypt = omp_t; omp_t = OMP_SCALE; self->params.max_keys_per_crypt = omp_t; #endif saved_key = mem_calloc_tiny(sizeof(saved_key) * self->params.max_keys_per_crypt, MEM_ALIGN_WORD); crypt_out = mem_calloc_tiny(sizeof(crypt_out) self->params.max_keys_per_crypt, MEM_ALIGN_WORD); for(i = 0; i < 256; i++) { c = i; MD5_Init(&ctx); MD5_Update(&ctx, &c, 1); MD5_Final(hash, &ctx); hex_encode(hash, 16, out); memcpy(map[i], out, 32); } } static int valid(char ciphertext, struct fmt_main self) { if (strncmp(ciphertext, "$weird$", 7) != 0) return 0; return 1; } static void get_binary(char ciphertext) { static union { unsigned char c[BINARY_SIZE]; ARCH_WORD dummy; } buf; unsigned char out = buf.c; char p; int i; p = strrchr(ciphertext, '$') + 1; for (i = 0; i < BINARY_SIZE; i++) { out[i] = (atoi16[ARCH_INDEX(p)] << 4) \| atoi16[ARCH_INDEX(p[1])]; p += 2; } return out; } static int binary_hash_0(void binary) { return (ARCH_WORD_32 )binary & 0xf; } static int binary_hash_1(void binary) { return (ARCH_WORD_32 )binary & 0xff; } static int binary_hash_2(void binary) { return (ARCH_WORD_32 )binary & 0xfff; } static int binary_hash_3(void binary) { return (ARCH_WORD_32 )binary & 0xffff; } static int binary_hash_4(void binary) { return (ARCH_WORD_32 )binary & 0xfffff; } static int binary_hash_5(void binary) { return (ARCH_WORD_32 )binary & 0xffffff; } static int binary_hash_6(void binary) { return (ARCH_WORD_32 )binary & 0x7ffffff; } static int get_hash_0(int index) { return crypt_out[index][0] & 0xf; } static int get_hash_1(int index) { return crypt_out[index][0] & 0xff; } static int get_hash_2(int index) { return crypt_out[index][0] & 0xfff; } static int get_hash_3(int index) { return crypt_out[index][0] & 0xffff; } static int get_hash_4(int index) { return crypt_out[index][0] & 0xfffff; } static int get_hash_5(int index) { return crypt_out[index][0] & 0xffffff; } static int get_hash_6(int index) { return crypt_out[index][0] & 0x7ffffff; } static void crypt_all(int count) { int index = 0; #ifdef _OPENMP #pragma omp parallel for for (index = 0; index < count; index++) #endif { int i; MD5_CTX ctx; unsigned char hash[16]; unsigned char store[PLAINTEXT_LENGTH * 16 * 2] = { 0 }; unsigned char p = store; int idx; for(i = 0; i < strlen(saved_key[index]); i++) { idx = saved_key[index][i]; memcpy(p, map[idx], 32); p += 32; } MD5_Init(&ctx); MD5_Update(&ctx, store, strlen(saved_key[index]) 32); MD5_Final(hash, &ctx); memcpy(crypt_out[index], hash, 16); } } static int cmp_all(void binary, int count) { int index = 0; #ifdef _OPENMP for (; index < count; index++) #endif if (!memcmp(binary, crypt_out[index], 15)) return 1; return 0; } static int cmp_one(void binary, int index) { return !memcmp(binary, crypt_out[index], 15); } static int cmp_exact(char source, int index) { return 1; } static void weird_set_key(char key, int index) { int saved_key_length = strlen(key); if (saved_key_length > PLAINTEXT_LENGTH) saved_key_length = PLAINTEXT_LENGTH; memcpy(saved_key[index], key, saved_key_length); saved_key[index][saved_key_length] = 0; } static char get_key(int index) { return saved_key[index]; } struct fmt_main weird_fmt = { { FORMAT_LABEL, FORMAT_NAME, ALGORITHM_NAME, BENCHMARK_COMMENT, BENCHMARK_LENGTH, PLAINTEXT_LENGTH, BINARY_SIZE, BINARY_ALIGN, SALT_SIZE, SALT_ALIGN, MIN_KEYS_PER_CRYPT, MAX_KEYS_PER_CRYPT, FMT_CASE \| FMT_8_BIT \| FMT_OMP, #if FMT_MAIN_VERSION > 11 { NULL }, #endif weird_tests }, { init, fmt_default_prepare, valid, fmt_default_split, get_binary, fmt_default_salt, #if FMT_MAIN_VERSION > 11 { NULL }, #endif fmt_default_source, { binary_hash_0, binary_hash_1, binary_hash_2, binary_hash_3, binary_hash_4, binary_hash_5, binary_hash_6 }, fmt_default_salt_hash, fmt_default_set_salt, weird_set_key, get_key, fmt_default_clear_keys, crypt_all, { get_hash_0, get_hash_1, get_hash_2, get_hash_3, get_hash_4, get_hash_5, get_hash_6 }, cmp_all, cmp_one, cmp_exact } }; #endif / plugin stanza */
stencil.c	// RUN: ${CATO_ROOT}/src/scripts/cexecute_pass.py %s -o %t // RUN: diff <(mpirun -np 4 %t) %s.reference_output #include <stdlib.h> #include <stdio.h> #include <omp.h> #define DIM 10 int main() { float Matrix = (float)malloc(sizeof(float) DIM); float Matrix2 = (float)malloc(sizeof(float) DIM); for(int i = 0; i < DIM; i++) { Matrix[i] = (float)malloc(sizeof(float) DIM); Matrix2[i] = (float)malloc(sizeof(float) DIM); } for(int i = 0; i < DIM; i++) { Matrix[0][i] = 1.0; Matrix[DIM-1][i] = 1.0; Matrix[i][0] = 1.0; Matrix[i][DIM-1] = 1.0; Matrix2[0][i] = 1.0; Matrix2[DIM-1][i] = 1.0; Matrix2[i][0] = 1.0; Matrix2[i][DIM-1] = 1.0; } #pragma omp parallel for { for(int i = 1; i < DIM-1; i++) { for(int j = 1; j < DIM-1; j++) { float star = 4 * Matrix[i][j] - Matrix[i-1][j] - Matrix[i+1][j] - Matrix[i][j-1] - Matrix[i][j+1]; Matrix2[i][j] = star * star; } } } #pragma omp parallel { if(omp_get_thread_num() == 0) { for(int i = 0; i < DIM; i++) { for(int j = 0; j < DIM; j++) { printf("%.4f ", Matrix2[i][j]); } printf("\n"); } } } for(int i = 0; i < DIM; i++) { free(Matrix[i]); free(Matrix2[i]); } free(Matrix); free(Matrix2); return 0; }
orphan1.c	#include <stdio.h> #include <stdlib.h> #include <omp.h> #include "update.c" double val1,val2; int update(int n, int iter); int main(int argc, char **argv) { int n=10; int max, locmax; max = -999; int count = 0; #pragma omp parallel num_threads(4) default(none) shared(n, max,count) private(locmax) reduction(+: val2) for (int iter=0; iter<3; iter++) { count++; #pragma omp single { printf("---iteration %d---\n", iter); } #pragma omp barrier locmax = update(n, iter); #pragma omp critical { if (locmax > max) max=locmax; } #pragma omp barrier #pragma omp flush #pragma omp single printf("---iteration %d's max value = %d---\n", iter, max); } printf("%d", count); return 0; }
quantize.c	/* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % QQQ U U AAA N N TTTTT IIIII ZZZZZ EEEEE % % Q Q U U A A NN N T I ZZ E % % Q Q U U AAAAA N N N T I ZZZ EEEEE % % Q QQ U U A A N NN T I ZZ E % % QQQQ UUU A A N N T IIIII ZZZZZ EEEEE % % % % % % MagickCore Methods to Reduce the Number of Unique Colors in an Image % % % % Software Design % % Cristy % % July 1992 % % % % % % Copyright 1999-2021 ImageMagick Studio LLC, a non-profit organization % % dedicated to making software imaging solutions freely available. % % % % You may not use this file except in compliance with the License. You may % % obtain a copy of the License at % % % % https://imagemagick.org/script/license.php % % % % Unless required by applicable law or agreed to in writing, software % % distributed under the License is distributed on an "AS IS" BASIS, % % WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. % % See the License for the specific language governing permissions and % % limitations under the License. % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % Realism in computer graphics typically requires using 24 bits/pixel to % generate an image. Yet many graphic display devices do not contain the % amount of memory necessary to match the spatial and color resolution of % the human eye. The Quantize methods takes a 24 bit image and reduces % the number of colors so it can be displayed on raster device with less % bits per pixel. In most instances, the quantized image closely % resembles the original reference image. % % A reduction of colors in an image is also desirable for image % transmission and real-time animation. % % QuantizeImage() takes a standard RGB or monochrome images and quantizes % them down to some fixed number of colors. % % For purposes of color allocation, an image is a set of n pixels, where % each pixel is a point in RGB space. RGB space is a 3-dimensional % vector space, and each pixel, Pi, is defined by an ordered triple of % red, green, and blue coordinates, (Ri, Gi, Bi). % % Each primary color component (red, green, or blue) represents an % intensity which varies linearly from 0 to a maximum value, Cmax, which % corresponds to full saturation of that color. Color allocation is % defined over a domain consisting of the cube in RGB space with opposite % vertices at (0,0,0) and (Cmax, Cmax, Cmax). QUANTIZE requires Cmax = % 255. % % The algorithm maps this domain onto a tree in which each node % represents a cube within that domain. In the following discussion % these cubes are defined by the coordinate of two opposite vertices (vertex % nearest the origin in RGB space and the vertex farthest from the origin). % % The tree's root node represents the entire domain, (0,0,0) through % (Cmax,Cmax,Cmax). Each lower level in the tree is generated by % subdividing one node's cube into eight smaller cubes of equal size. % This corresponds to bisecting the parent cube with planes passing % through the midpoints of each edge. % % The basic algorithm operates in three phases: Classification, % Reduction, and Assignment. Classification builds a color description % tree for the image. Reduction collapses the tree until the number it % represents, at most, the number of colors desired in the output image. % Assignment defines the output image's color map and sets each pixel's % color by restorage_class in the reduced tree. Our goal is to minimize % the numerical discrepancies between the original colors and quantized % colors (quantization error). % % Classification begins by initializing a color description tree of % sufficient depth to represent each possible input color in a leaf. % However, it is impractical to generate a fully-formed color description % tree in the storage_class phase for realistic values of Cmax. If % colors components in the input image are quantized to k-bit precision, % so that Cmax= 2k-1, the tree would need k levels below the root node to % allow representing each possible input color in a leaf. This becomes % prohibitive because the tree's total number of nodes is 1 + % sum(i=1, k, 8k). % % A complete tree would require 19,173,961 nodes for k = 8, Cmax = 255. % Therefore, to avoid building a fully populated tree, QUANTIZE: (1) % Initializes data structures for nodes only as they are needed; (2) % Chooses a maximum depth for the tree as a function of the desired % number of colors in the output image (currently log2(colormap size)). % % For each pixel in the input image, storage_class scans downward from % the root of the color description tree. At each level of the tree it % identifies the single node which represents a cube in RGB space % containing the pixel's color. It updates the following data for each % such node: % % n1: Number of pixels whose color is contained in the RGB cube which % this node represents; % % n2: Number of pixels whose color is not represented in a node at % lower depth in the tree; initially, n2 = 0 for all nodes except % leaves of the tree. % % Sr, Sg, Sb: Sums of the red, green, and blue component values for all % pixels not classified at a lower depth. The combination of these sums % and n2 will ultimately characterize the mean color of a set of pixels % represented by this node. % % E: the distance squared in RGB space between each pixel contained % within a node and the nodes' center. This represents the % quantization error for a node. % % Reduction repeatedly prunes the tree until the number of nodes with n2 % > 0 is less than or equal to the maximum number of colors allowed in % the output image. On any given iteration over the tree, it selects % those nodes whose E count is minimal for pruning and merges their color % statistics upward. It uses a pruning threshold, Ep, to govern node % selection as follows: % % Ep = 0 % while number of nodes with (n2 > 0) > required maximum number of colors % prune all nodes such that E <= Ep % Set Ep to minimum E in remaining nodes % % This has the effect of minimizing any quantization error when merging % two nodes together. % % When a node to be pruned has offspring, the pruning procedure invokes % itself recursively in order to prune the tree from the leaves upward. % n2, Sr, Sg, and Sb in a node being pruned are always added to the % corresponding data in that node's parent. This retains the pruned % node's color characteristics for later averaging. % % For each node, n2 pixels exist for which that node represents the % smallest volume in RGB space containing those pixel's colors. When n2 % > 0 the node will uniquely define a color in the output image. At the % beginning of reduction, n2 = 0 for all nodes except a the leaves of % the tree which represent colors present in the input image. % % The other pixel count, n1, indicates the total number of colors within % the cubic volume which the node represents. This includes n1 - n2 % pixels whose colors should be defined by nodes at a lower level in the % tree. % % Assignment generates the output image from the pruned tree. The output % image consists of two parts: (1) A color map, which is an array of % color descriptions (RGB triples) for each color present in the output % image; (2) A pixel array, which represents each pixel as an index % into the color map array. % % First, the assignment phase makes one pass over the pruned color % description tree to establish the image's color map. For each node % with n2 > 0, it divides Sr, Sg, and Sb by n2 . This produces the mean % color of all pixels that classify no lower than this node. Each of % these colors becomes an entry in the color map. % % Finally, the assignment phase reclassifies each pixel in the pruned % tree to identify the deepest node containing the pixel's color. The % pixel's value in the pixel array becomes the index of this node's mean % color in the color map. % % This method is based on a similar algorithm written by Paul Raveling. % / / Include declarations. / #include "MagickCore/studio.h" #include "MagickCore/artifact.h" #include "MagickCore/attribute.h" #include "MagickCore/cache-view.h" #include "MagickCore/color.h" #include "MagickCore/color-private.h" #include "MagickCore/colormap.h" #include "MagickCore/colorspace.h" #include "MagickCore/colorspace-private.h" #include "MagickCore/compare.h" #include "MagickCore/enhance.h" #include "MagickCore/exception.h" #include "MagickCore/exception-private.h" #include "MagickCore/histogram.h" #include "MagickCore/image.h" #include "MagickCore/image-private.h" #include "MagickCore/list.h" #include "MagickCore/memory_.h" #include "MagickCore/memory-private.h" #include "MagickCore/monitor.h" #include "MagickCore/monitor-private.h" #include "MagickCore/option.h" #include "MagickCore/pixel-accessor.h" #include "MagickCore/pixel-private.h" #include "MagickCore/quantize.h" #include "MagickCore/quantum.h" #include "MagickCore/quantum-private.h" #include "MagickCore/random_.h" #include "MagickCore/resource_.h" #include "MagickCore/string_.h" #include "MagickCore/string-private.h" #include "MagickCore/thread-private.h" / Define declarations. / #if !defined(__APPLE__) && !defined(TARGET_OS_IPHONE) #define CacheShift 2 #else #define CacheShift 3 #endif #define ErrorQueueLength 16 #define ErrorRelativeWeight PerceptibleReciprocal(16) #define MaxNodes 266817 #define MaxTreeDepth 8 #define NodesInAList 1920 / Typdef declarations. / typedef struct _DoublePixelPacket { double red, green, blue, alpha; } DoublePixelPacket; typedef struct _NodeInfo { struct _NodeInfo parent, child[16]; MagickSizeType number_unique; DoublePixelPacket total_color; double quantize_error; size_t color_number, id, level; } NodeInfo; typedef struct _Nodes { NodeInfo nodes; struct _Nodes next; } Nodes; typedef struct _CubeInfo { NodeInfo root; size_t colors, maximum_colors; ssize_t transparent_index; MagickSizeType transparent_pixels; DoublePixelPacket target; double distance, pruning_threshold, next_threshold; size_t nodes, free_nodes, color_number; NodeInfo next_node; Nodes node_queue; MemoryInfo memory_info; ssize_t cache; DoublePixelPacket error[ErrorQueueLength]; double diffusion, weights[ErrorQueueLength]; QuantizeInfo quantize_info; MagickBooleanType associate_alpha; ssize_t x, y; size_t depth; MagickOffsetType offset; MagickSizeType span; } CubeInfo; / Method prototypes. / static CubeInfo GetCubeInfo(const QuantizeInfo ,const size_t,const size_t); static NodeInfo GetNodeInfo(CubeInfo ,const size_t,const size_t,NodeInfo ); static MagickBooleanType AssignImageColors(Image ,CubeInfo ,ExceptionInfo ), ClassifyImageColors(CubeInfo ,const Image ,ExceptionInfo ), DitherImage(Image ,CubeInfo ,ExceptionInfo ), SetGrayscaleImage(Image ,ExceptionInfo ), SetImageColormap(Image ,CubeInfo ,ExceptionInfo ); static void ClosestColor(const Image ,CubeInfo ,const NodeInfo ), DefineImageColormap(Image ,CubeInfo ,NodeInfo ), DestroyCubeInfo(CubeInfo ), PruneLevel(CubeInfo ,const NodeInfo ), PruneToCubeDepth(CubeInfo ,const NodeInfo ), ReduceImageColors(const Image ,CubeInfo ); / %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % A c q u i r e Q u a n t i z e I n f o % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % AcquireQuantizeInfo() allocates the QuantizeInfo structure. % % The format of the AcquireQuantizeInfo method is: % % QuantizeInfo AcquireQuantizeInfo(const ImageInfo image_info) % % A description of each parameter follows: % % o image_info: the image info. % / MagickExport QuantizeInfo AcquireQuantizeInfo(const ImageInfo image_info) { QuantizeInfo quantize_info; quantize_info=(QuantizeInfo ) AcquireCriticalMemory(sizeof(quantize_info)); GetQuantizeInfo(quantize_info); if (image_info != (ImageInfo ) NULL) { const char option; quantize_info->dither_method=image_info->dither == MagickFalse ? NoDitherMethod : RiemersmaDitherMethod; option=GetImageOption(image_info,"dither"); if (option != (const char ) NULL) quantize_info->dither_method=(DitherMethod) ParseCommandOption( MagickDitherOptions,MagickFalse,option); quantize_info->measure_error=image_info->verbose; } return(quantize_info); } / %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % + A s s i g n I m a g e C o l o r s % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % AssignImageColors() generates the output image from the pruned tree. The % output image consists of two parts: (1) A color map, which is an array % of color descriptions (RGB triples) for each color present in the % output image; (2) A pixel array, which represents each pixel as an % index into the color map array. % % First, the assignment phase makes one pass over the pruned color % description tree to establish the image's color map. For each node % with n2 > 0, it divides Sr, Sg, and Sb by n2 . This produces the mean % color of all pixels that classify no lower than this node. Each of % these colors becomes an entry in the color map. % % Finally, the assignment phase reclassifies each pixel in the pruned % tree to identify the deepest node containing the pixel's color. The % pixel's value in the pixel array becomes the index of this node's mean % color in the color map. % % The format of the AssignImageColors() method is: % % MagickBooleanType AssignImageColors(Image image,CubeInfo cube_info) % % A description of each parameter follows. % % o image: the image. % % o cube_info: A pointer to the Cube structure. % / static inline void AssociateAlphaPixel(const Image image, const CubeInfo cube_info,const Quantum pixel,DoublePixelPacket alpha_pixel) { double alpha; if ((cube_info->associate_alpha == MagickFalse) \|\| (GetPixelAlpha(image,pixel) == OpaqueAlpha)) { alpha_pixel->red=(double) GetPixelRed(image,pixel); alpha_pixel->green=(double) GetPixelGreen(image,pixel); alpha_pixel->blue=(double) GetPixelBlue(image,pixel); alpha_pixel->alpha=(double) GetPixelAlpha(image,pixel); return; } alpha=(double) (QuantumScaleGetPixelAlpha(image,pixel)); alpha_pixel->red=alphaGetPixelRed(image,pixel); alpha_pixel->green=alphaGetPixelGreen(image,pixel); alpha_pixel->blue=alphaGetPixelBlue(image,pixel); alpha_pixel->alpha=(double) GetPixelAlpha(image,pixel); } static inline void AssociateAlphaPixelInfo(const CubeInfo cube_info, const PixelInfo pixel,DoublePixelPacket alpha_pixel) { double alpha; if ((cube_info->associate_alpha == MagickFalse) \|\| (pixel->alpha == OpaqueAlpha)) { alpha_pixel->red=(double) pixel->red; alpha_pixel->green=(double) pixel->green; alpha_pixel->blue=(double) pixel->blue; alpha_pixel->alpha=(double) pixel->alpha; return; } alpha=(double) (QuantumScalepixel->alpha); alpha_pixel->red=alphapixel->red; alpha_pixel->green=alphapixel->green; alpha_pixel->blue=alphapixel->blue; alpha_pixel->alpha=(double) pixel->alpha; } static inline size_t ColorToNodeId(const CubeInfo cube_info, const DoublePixelPacket pixel,size_t index) { size_t id; id=(size_t) (((ScaleQuantumToChar(ClampPixel(pixel->red)) >> index) & 0x01) \| ((ScaleQuantumToChar(ClampPixel(pixel->green)) >> index) & 0x01) << 1 \| ((ScaleQuantumToChar(ClampPixel(pixel->blue)) >> index) & 0x01) << 2); if (cube_info->associate_alpha != MagickFalse) id\|=((ScaleQuantumToChar(ClampPixel(pixel->alpha)) >> index) & 0x1) << 3; return(id); } static MagickBooleanType AssignImageColors(Image image,CubeInfo cube_info, ExceptionInfo exception) { #define AssignImageTag "Assign/Image" ColorspaceType colorspace; ssize_t y; / Allocate image colormap. / colorspace=image->colorspace; if (cube_info->quantize_info->colorspace != UndefinedColorspace) (void) TransformImageColorspace(image,cube_info->quantize_info->colorspace, exception); cube_info->transparent_pixels=0; cube_info->transparent_index=(-1); if (SetImageColormap(image,cube_info,exception) == MagickFalse) return(MagickFalse); / Create a reduced color image. / if (cube_info->quantize_info->dither_method != NoDitherMethod) (void) DitherImage(image,cube_info,exception); else { CacheView image_view; MagickBooleanType status; status=MagickTrue; image_view=AcquireAuthenticCacheView(image,exception); #if defined(MAGICKCORE_OPENMP_SUPPORT) #pragma omp parallel for schedule(static) shared(status) \ magick_number_threads(image,image,image->rows,1) #endif for (y=0; y < (ssize_t) image->rows; y++) { CubeInfo cube; Quantum magick_restrict q; ssize_t count, x; if (status == MagickFalse) continue; q=GetCacheViewAuthenticPixels(image_view,0,y,image->columns,1, exception); if (q == (Quantum ) NULL) { status=MagickFalse; continue; } cube=(cube_info); for (x=0; x < (ssize_t) image->columns; x+=count) { DoublePixelPacket pixel; const NodeInfo node_info; ssize_t i; size_t id, index; /* Identify the deepest node containing the pixel's color. / for (count=1; (x+count) < (ssize_t) image->columns; count++) { PixelInfo packet; GetPixelInfoPixel(image,q+countGetPixelChannels(image),&packet); if (IsPixelEquivalent(image,q,&packet) == MagickFalse) break; } AssociateAlphaPixel(image,&cube,q,&pixel); node_info=cube.root; for (index=MaxTreeDepth-1; (ssize_t) index > 0; index--) { id=ColorToNodeId(&cube,&pixel,index); if (node_info->child[id] == (NodeInfo ) NULL) break; node_info=node_info->child[id]; } / Find closest color among siblings and their children. / cube.target=pixel; cube.distance=(double) (4.0(QuantumRange+1.0)(QuantumRange+1.0)+ 1.0); ClosestColor(image,&cube,node_info->parent); index=cube.color_number; for (i=0; i < (ssize_t) count; i++) { if (image->storage_class == PseudoClass) SetPixelIndex(image,(Quantum) index,q); if (cube.quantize_info->measure_error == MagickFalse) { SetPixelRed(image,ClampToQuantum( image->colormap[index].red),q); SetPixelGreen(image,ClampToQuantum( image->colormap[index].green),q); SetPixelBlue(image,ClampToQuantum( image->colormap[index].blue),q); if (cube.associate_alpha != MagickFalse) SetPixelAlpha(image,ClampToQuantum( image->colormap[index].alpha),q); } q+=GetPixelChannels(image); } } if (SyncCacheViewAuthenticPixels(image_view,exception) == MagickFalse) status=MagickFalse; if (image->progress_monitor != (MagickProgressMonitor) NULL) { MagickBooleanType proceed; proceed=SetImageProgress(image,AssignImageTag,(MagickOffsetType) y, image->rows); if (proceed == MagickFalse) status=MagickFalse; } } image_view=DestroyCacheView(image_view); } if (cube_info->quantize_info->measure_error != MagickFalse) (void) GetImageQuantizeError(image,exception); if ((cube_info->quantize_info->number_colors == 2) && (IsGrayColorspace(cube_info->quantize_info->colorspace))) { double intensity; / Monochrome image. / intensity=GetPixelInfoLuma(image->colormap+0) < QuantumRange/2.0 ? 0.0 : QuantumRange; if (image->colors > 1) { intensity=0.0; if (GetPixelInfoLuma(image->colormap+0) > GetPixelInfoLuma(image->colormap+1)) intensity=(double) QuantumRange; } image->colormap[0].red=intensity; image->colormap[0].green=intensity; image->colormap[0].blue=intensity; if (image->colors > 1) { image->colormap[1].red=(double) QuantumRange-intensity; image->colormap[1].green=(double) QuantumRange-intensity; image->colormap[1].blue=(double) QuantumRange-intensity; } } (void) SyncImage(image,exception); if ((cube_info->quantize_info->colorspace != UndefinedColorspace) && (IssRGBCompatibleColorspace(colorspace) == MagickFalse)) (void) TransformImageColorspace(image,colorspace,exception); return(MagickTrue); } / %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % + C l a s s i f y I m a g e C o l o r s % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % ClassifyImageColors() begins by initializing a color description tree % of sufficient depth to represent each possible input color in a leaf. % However, it is impractical to generate a fully-formed color % description tree in the storage_class phase for realistic values of % Cmax. If colors components in the input image are quantized to k-bit % precision, so that Cmax= 2k-1, the tree would need k levels below the % root node to allow representing each possible input color in a leaf. % This becomes prohibitive because the tree's total number of nodes is % 1 + sum(i=1,k,8k). % % A complete tree would require 19,173,961 nodes for k = 8, Cmax = 255. % Therefore, to avoid building a fully populated tree, QUANTIZE: (1) % Initializes data structures for nodes only as they are needed; (2) % Chooses a maximum depth for the tree as a function of the desired % number of colors in the output image (currently log2(colormap size)). % % For each pixel in the input image, storage_class scans downward from % the root of the color description tree. At each level of the tree it % identifies the single node which represents a cube in RGB space % containing It updates the following data for each such node: % % n1 : Number of pixels whose color is contained in the RGB cube % which this node represents; % % n2 : Number of pixels whose color is not represented in a node at % lower depth in the tree; initially, n2 = 0 for all nodes except % leaves of the tree. % % Sr, Sg, Sb : Sums of the red, green, and blue component values for % all pixels not classified at a lower depth. The combination of % these sums and n2 will ultimately characterize the mean color of a % set of pixels represented by this node. % % E: the distance squared in RGB space between each pixel contained % within a node and the nodes' center. This represents the quantization % error for a node. % % The format of the ClassifyImageColors() method is: % % MagickBooleanType ClassifyImageColors(CubeInfo cube_info, % const Image image,ExceptionInfo exception) % % A description of each parameter follows. % % o cube_info: A pointer to the Cube structure. % % o image: the image. % / static inline void SetAssociatedAlpha(const Image image,CubeInfo cube_info) { MagickBooleanType associate_alpha; associate_alpha=image->alpha_trait != UndefinedPixelTrait ? MagickTrue : MagickFalse; if ((cube_info->quantize_info->number_colors == 2) && ((cube_info->quantize_info->colorspace == LinearGRAYColorspace) \|\| (cube_info->quantize_info->colorspace == GRAYColorspace))) associate_alpha=MagickFalse; cube_info->associate_alpha=associate_alpha; } static MagickBooleanType ClassifyImageColors(CubeInfo cube_info, const Image image,ExceptionInfo exception) { #define ClassifyImageTag "Classify/Image" CacheView image_view; double bisect; DoublePixelPacket error, mid, midpoint, pixel; MagickBooleanType proceed; NodeInfo node_info; size_t count, id, index, level; ssize_t y; / Classify the first cube_info->maximum_colors colors to a tree depth of 8. / SetAssociatedAlpha(image,cube_info); if (cube_info->quantize_info->colorspace != image->colorspace) { if ((cube_info->quantize_info->colorspace != UndefinedColorspace) && (cube_info->quantize_info->colorspace != CMYKColorspace)) (void) TransformImageColorspace((Image ) image, cube_info->quantize_info->colorspace,exception); else if (IssRGBCompatibleColorspace(image->colorspace) == MagickFalse) (void) TransformImageColorspace((Image ) image,sRGBColorspace, exception); } midpoint.red=(double) QuantumRange/2.0; midpoint.green=(double) QuantumRange/2.0; midpoint.blue=(double) QuantumRange/2.0; midpoint.alpha=(double) QuantumRange/2.0; error.alpha=0.0; image_view=AcquireVirtualCacheView(image,exception); for (y=0; y < (ssize_t) image->rows; y++) { const Quantum magick_restrict p; ssize_t x; p=GetCacheViewVirtualPixels(image_view,0,y,image->columns,1,exception); if (p == (const Quantum ) NULL) break; if (cube_info->nodes > MaxNodes) { / Prune one level if the color tree is too large. / PruneLevel(cube_info,cube_info->root); cube_info->depth--; } for (x=0; x < (ssize_t) image->columns; x+=(ssize_t) count) { / Start at the root and descend the color cube tree. / for (count=1; (x+(ssize_t) count) < (ssize_t) image->columns; count++) { PixelInfo packet; GetPixelInfoPixel(image,p+countGetPixelChannels(image),&packet); if (IsPixelEquivalent(image,p,&packet) == MagickFalse) break; } AssociateAlphaPixel(image,cube_info,p,&pixel); index=MaxTreeDepth-1; bisect=((double) QuantumRange+1.0)/2.0; mid=midpoint; node_info=cube_info->root; for (level=1; level <= MaxTreeDepth; level++) { double distance; bisect=0.5; id=ColorToNodeId(cube_info,&pixel,index); mid.red+=(id & 1) != 0 ? bisect : -bisect; mid.green+=(id & 2) != 0 ? bisect : -bisect; mid.blue+=(id & 4) != 0 ? bisect : -bisect; mid.alpha+=(id & 8) != 0 ? bisect : -bisect; if (node_info->child[id] == (NodeInfo ) NULL) { /* Set colors of new node to contain pixel. / node_info->child[id]=GetNodeInfo(cube_info,id,level,node_info); if (node_info->child[id] == (NodeInfo ) NULL) { (void) ThrowMagickException(exception,GetMagickModule(), ResourceLimitError,"MemoryAllocationFailed","`%s'", image->filename); continue; } if (level == MaxTreeDepth) cube_info->colors++; } /* Approximate the quantization error represented by this node. / node_info=node_info->child[id]; error.red=QuantumScale(pixel.red-mid.red); error.green=QuantumScale(pixel.green-mid.green); error.blue=QuantumScale(pixel.blue-mid.blue); if (cube_info->associate_alpha != MagickFalse) error.alpha=QuantumScale(pixel.alpha-mid.alpha); distance=(double) (error.rederror.red+error.greenerror.green+ error.blueerror.blue+error.alphaerror.alpha); if (IsNaN(distance) != 0) distance=0.0; node_info->quantize_error+=countsqrt(distance); cube_info->root->quantize_error+=node_info->quantize_error; index--; } /* Sum RGB for this leaf for later derivation of the mean cube color. / node_info->number_unique+=count; node_info->total_color.red+=countQuantumScaleClampPixel(pixel.red); node_info->total_color.green+=countQuantumScaleClampPixel(pixel.green); node_info->total_color.blue+=countQuantumScaleClampPixel(pixel.blue); if (cube_info->associate_alpha != MagickFalse) node_info->total_color.alpha+=countQuantumScale* ClampPixel(pixel.alpha); else node_info->total_color.alpha+=countQuantumScale ClampPixel((MagickRealType) OpaqueAlpha); p+=countGetPixelChannels(image); } if (cube_info->colors > cube_info->maximum_colors) { PruneToCubeDepth(cube_info,cube_info->root); break; } proceed=SetImageProgress(image,ClassifyImageTag,(MagickOffsetType) y, image->rows); if (proceed == MagickFalse) break; } for (y++; y < (ssize_t) image->rows; y++) { const Quantum magick_restrict p; ssize_t x; p=GetCacheViewVirtualPixels(image_view,0,y,image->columns,1,exception); if (p == (const Quantum ) NULL) break; if (cube_info->nodes > MaxNodes) { / Prune one level if the color tree is too large. / PruneLevel(cube_info,cube_info->root); cube_info->depth--; } for (x=0; x < (ssize_t) image->columns; x+=(ssize_t) count) { / Start at the root and descend the color cube tree. / for (count=1; (x+(ssize_t) count) < (ssize_t) image->columns; count++) { PixelInfo packet; GetPixelInfoPixel(image,p+countGetPixelChannels(image),&packet); if (IsPixelEquivalent(image,p,&packet) == MagickFalse) break; } AssociateAlphaPixel(image,cube_info,p,&pixel); index=MaxTreeDepth-1; bisect=((double) QuantumRange+1.0)/2.0; mid=midpoint; node_info=cube_info->root; for (level=1; level <= cube_info->depth; level++) { double distance; bisect=0.5; id=ColorToNodeId(cube_info,&pixel,index); mid.red+=(id & 1) != 0 ? bisect : -bisect; mid.green+=(id & 2) != 0 ? bisect : -bisect; mid.blue+=(id & 4) != 0 ? bisect : -bisect; mid.alpha+=(id & 8) != 0 ? bisect : -bisect; if (node_info->child[id] == (NodeInfo ) NULL) { /* Set colors of new node to contain pixel. / node_info->child[id]=GetNodeInfo(cube_info,id,level,node_info); if (node_info->child[id] == (NodeInfo ) NULL) { (void) ThrowMagickException(exception,GetMagickModule(), ResourceLimitError,"MemoryAllocationFailed","%s", image->filename); continue; } if (level == cube_info->depth) cube_info->colors++; } /* Approximate the quantization error represented by this node. / node_info=node_info->child[id]; error.red=QuantumScale(pixel.red-mid.red); error.green=QuantumScale(pixel.green-mid.green); error.blue=QuantumScale(pixel.blue-mid.blue); if (cube_info->associate_alpha != MagickFalse) error.alpha=QuantumScale(pixel.alpha-mid.alpha); distance=(double) (error.rederror.red+error.greenerror.green+ error.blueerror.blue+error.alphaerror.alpha); if (IsNaN(distance) != 0) distance=0.0; node_info->quantize_error+=countsqrt(distance); cube_info->root->quantize_error+=node_info->quantize_error; index--; } /* Sum RGB for this leaf for later derivation of the mean cube color. / node_info->number_unique+=count; node_info->total_color.red+=countQuantumScaleClampPixel(pixel.red); node_info->total_color.green+=countQuantumScaleClampPixel(pixel.green); node_info->total_color.blue+=countQuantumScaleClampPixel(pixel.blue); if (cube_info->associate_alpha != MagickFalse) node_info->total_color.alpha+=countQuantumScale* ClampPixel(pixel.alpha); else node_info->total_color.alpha+=countQuantumScale ClampPixel((MagickRealType) OpaqueAlpha); p+=countGetPixelChannels(image); } proceed=SetImageProgress(image,ClassifyImageTag,(MagickOffsetType) y, image->rows); if (proceed == MagickFalse) break; } image_view=DestroyCacheView(image_view); if (cube_info->quantize_info->colorspace != image->colorspace) if ((cube_info->quantize_info->colorspace != UndefinedColorspace) && (cube_info->quantize_info->colorspace != CMYKColorspace)) (void) TransformImageColorspace((Image ) image,sRGBColorspace,exception); return(y < (ssize_t) image->rows ? MagickFalse : MagickTrue); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % C l o n e Q u a n t i z e I n f o % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % CloneQuantizeInfo() makes a duplicate of the given quantize info structure, % or if quantize info is NULL, a new one. % % The format of the CloneQuantizeInfo method is: % % QuantizeInfo CloneQuantizeInfo(const QuantizeInfo quantize_info) % % A description of each parameter follows: % % o clone_info: Method CloneQuantizeInfo returns a duplicate of the given % quantize info, or if image info is NULL a new one. % % o quantize_info: a structure of type info. % / MagickExport QuantizeInfo CloneQuantizeInfo(const QuantizeInfo quantize_info) { QuantizeInfo clone_info; clone_info=(QuantizeInfo ) AcquireCriticalMemory(sizeof(clone_info)); GetQuantizeInfo(clone_info); if (quantize_info == (QuantizeInfo ) NULL) return(clone_info); clone_info->number_colors=quantize_info->number_colors; clone_info->tree_depth=quantize_info->tree_depth; clone_info->dither_method=quantize_info->dither_method; clone_info->colorspace=quantize_info->colorspace; clone_info->measure_error=quantize_info->measure_error; return(clone_info); } / %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % + C l o s e s t C o l o r % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % ClosestColor() traverses the color cube tree at a particular node and % determines which colormap entry best represents the input color. % % The format of the ClosestColor method is: % % void ClosestColor(const Image image,CubeInfo cube_info, % const NodeInfo node_info) % % A description of each parameter follows. % % o image: the image. % % o cube_info: A pointer to the Cube structure. % % o node_info: the address of a structure of type NodeInfo which points to a % node in the color cube tree that is to be pruned. % / static void ClosestColor(const Image image,CubeInfo cube_info, const NodeInfo node_info) { size_t number_children; ssize_t i; / Traverse any children. / number_children=cube_info->associate_alpha == MagickFalse ? 8UL : 16UL; for (i=0; i < (ssize_t) number_children; i++) if (node_info->child[i] != (NodeInfo ) NULL) ClosestColor(image,cube_info,node_info->child[i]); if (node_info->number_unique != 0) { double alpha, beta, distance, pixel; DoublePixelPacket magick_restrict q; PixelInfo magick_restrict p; /* Determine if this color is "closest". / p=image->colormap+node_info->color_number; q=(&cube_info->target); alpha=1.0; beta=1.0; if (cube_info->associate_alpha != MagickFalse) { alpha=(MagickRealType) (QuantumScalep->alpha); beta=(MagickRealType) (QuantumScaleq->alpha); } pixel=alphap->red-betaq->red; distance=pixelpixel; if (distance <= cube_info->distance) { pixel=alphap->green-betaq->green; distance+=pixelpixel; if (distance <= cube_info->distance) { pixel=alphap->blue-betaq->blue; distance+=pixelpixel; if (distance <= cube_info->distance) { if (cube_info->associate_alpha != MagickFalse) { pixel=p->alpha-q->alpha; distance+=pixelpixel; } if (distance <= cube_info->distance) { cube_info->distance=distance; cube_info->color_number=node_info->color_number; } } } } } } / %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % C o m p r e s s I m a g e C o l o r m a p % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % CompressImageColormap() compresses an image colormap by removing any % duplicate or unused color entries. % % The format of the CompressImageColormap method is: % % MagickBooleanType CompressImageColormap(Image image, % ExceptionInfo exception) % % A description of each parameter follows: % % o image: the image. % % o exception: return any errors or warnings in this structure. % / MagickExport MagickBooleanType CompressImageColormap(Image image, ExceptionInfo exception) { QuantizeInfo quantize_info; assert(image != (Image ) NULL); assert(image->signature == MagickCoreSignature); if (image->debug != MagickFalse) (void) LogMagickEvent(TraceEvent,GetMagickModule(),"%s",image->filename); if (IsPaletteImage(image) == MagickFalse) return(MagickFalse); GetQuantizeInfo(&quantize_info); quantize_info.number_colors=image->colors; quantize_info.tree_depth=MaxTreeDepth; return(QuantizeImage(&quantize_info,image,exception)); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % + D e f i n e I m a g e C o l o r m a p % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % DefineImageColormap() traverses the color cube tree and notes each colormap % entry. A colormap entry is any node in the color cube tree where the % of unique colors is not zero. % % The format of the DefineImageColormap method is: % % void DefineImageColormap(Image image,CubeInfo cube_info, % NodeInfo node_info) % % A description of each parameter follows. % % o image: the image. % % o cube_info: A pointer to the Cube structure. % % o node_info: the address of a structure of type NodeInfo which points to a % node in the color cube tree that is to be pruned. % / static void DefineImageColormap(Image image,CubeInfo cube_info, NodeInfo node_info) { size_t number_children; ssize_t i; / Traverse any children. / number_children=cube_info->associate_alpha == MagickFalse ? 8UL : 16UL; for (i=0; i < (ssize_t) number_children; i++) if (node_info->child[i] != (NodeInfo ) NULL) DefineImageColormap(image,cube_info,node_info->child[i]); if (node_info->number_unique != 0) { double alpha; PixelInfo magick_restrict q; / Colormap entry is defined by the mean color in this cube. / q=image->colormap+image->colors; alpha=(double) ((MagickOffsetType) node_info->number_unique); alpha=PerceptibleReciprocal(alpha); if (cube_info->associate_alpha == MagickFalse) { q->red=(double) ClampToQuantum(alphaQuantumRange* node_info->total_color.red); q->green=(double) ClampToQuantum(alphaQuantumRange node_info->total_color.green); q->blue=(double) ClampToQuantum(alphaQuantumRange node_info->total_color.blue); q->alpha=(double) OpaqueAlpha; } else { double opacity; opacity=(double) (alphaQuantumRangenode_info->total_color.alpha); q->alpha=(double) ClampToQuantum(opacity); if (q->alpha == OpaqueAlpha) { q->red=(double) ClampToQuantum(alphaQuantumRange node_info->total_color.red); q->green=(double) ClampToQuantum(alphaQuantumRange node_info->total_color.green); q->blue=(double) ClampToQuantum(alphaQuantumRange node_info->total_color.blue); } else { double gamma; gamma=(double) (QuantumScaleq->alpha); gamma=PerceptibleReciprocal(gamma); q->red=(double) ClampToQuantum(alphagammaQuantumRange node_info->total_color.red); q->green=(double) ClampToQuantum(alphagammaQuantumRange* node_info->total_color.green); q->blue=(double) ClampToQuantum(alphagammaQuantumRange* node_info->total_color.blue); if (node_info->number_unique > cube_info->transparent_pixels) { cube_info->transparent_pixels=node_info->number_unique; cube_info->transparent_index=(ssize_t) image->colors; } } } node_info->color_number=image->colors++; } } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % + D e s t r o y C u b e I n f o % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % DestroyCubeInfo() deallocates memory associated with an image. % % The format of the DestroyCubeInfo method is: % % DestroyCubeInfo(CubeInfo cube_info) % % A description of each parameter follows: % % o cube_info: the address of a structure of type CubeInfo. % / static void DestroyCubeInfo(CubeInfo cube_info) { Nodes nodes; /* Release color cube tree storage. / do { nodes=cube_info->node_queue->next; cube_info->node_queue->nodes=(NodeInfo ) RelinquishMagickMemory( cube_info->node_queue->nodes); cube_info->node_queue=(Nodes ) RelinquishMagickMemory( cube_info->node_queue); cube_info->node_queue=nodes; } while (cube_info->node_queue != (Nodes ) NULL); if (cube_info->memory_info != (MemoryInfo ) NULL) cube_info->memory_info=RelinquishVirtualMemory(cube_info->memory_info); cube_info->quantize_info=DestroyQuantizeInfo(cube_info->quantize_info); cube_info=(CubeInfo ) RelinquishMagickMemory(cube_info); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % D e s t r o y Q u a n t i z e I n f o % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % DestroyQuantizeInfo() deallocates memory associated with an QuantizeInfo % structure. % % The format of the DestroyQuantizeInfo method is: % % QuantizeInfo DestroyQuantizeInfo(QuantizeInfo quantize_info) % % A description of each parameter follows: % % o quantize_info: Specifies a pointer to an QuantizeInfo structure. % / MagickExport QuantizeInfo DestroyQuantizeInfo(QuantizeInfo quantize_info) { (void) LogMagickEvent(TraceEvent,GetMagickModule(),"..."); assert(quantize_info != (QuantizeInfo ) NULL); assert(quantize_info->signature == MagickCoreSignature); quantize_info->signature=(~MagickCoreSignature); quantize_info=(QuantizeInfo ) RelinquishMagickMemory(quantize_info); return(quantize_info); } / %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % + D i t h e r I m a g e % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % DitherImage() distributes the difference between an original image and % the corresponding color reduced algorithm to neighboring pixels using % serpentine-scan Floyd-Steinberg error diffusion. DitherImage returns % MagickTrue if the image is dithered otherwise MagickFalse. % % The format of the DitherImage method is: % % MagickBooleanType DitherImage(Image image,CubeInfo cube_info, % ExceptionInfo exception) % % A description of each parameter follows. % % o image: the image. % % o cube_info: A pointer to the Cube structure. % % o exception: return any errors or warnings in this structure. % / static DoublePixelPacket DestroyPixelThreadSet(DoublePixelPacket pixels) { ssize_t i; assert(pixels != (DoublePixelPacket *) NULL); for (i=0; i < (ssize_t) GetMagickResourceLimit(ThreadResource); i++) if (pixels[i] != (DoublePixelPacket ) NULL) pixels[i]=(DoublePixelPacket ) RelinquishMagickMemory(pixels[i]); pixels=(DoublePixelPacket ) RelinquishMagickMemory(pixels); return(pixels); } static DoublePixelPacket AcquirePixelThreadSet(const size_t count) { DoublePixelPacket pixels; size_t number_threads; ssize_t i; number_threads=(size_t) GetMagickResourceLimit(ThreadResource); pixels=(DoublePixelPacket ) AcquireQuantumMemory(number_threads, sizeof(pixels)); if (pixels == (DoublePixelPacket ) NULL) return((DoublePixelPacket ) NULL); (void) memset(pixels,0,number_threadssizeof(pixels)); for (i=0; i < (ssize_t) number_threads; i++) { pixels[i]=(DoublePixelPacket ) AcquireQuantumMemory(count,2 sizeof(*pixels)); if (pixels[i] == (DoublePixelPacket ) NULL) return(DestroyPixelThreadSet(pixels)); } return(pixels); } static inline ssize_t CacheOffset(CubeInfo cube_info, const DoublePixelPacket pixel) { #define RedShift(pixel) (((pixel) >> CacheShift) << (0(8-CacheShift))) #define GreenShift(pixel) (((pixel) >> CacheShift) << (1(8-CacheShift))) #define BlueShift(pixel) (((pixel) >> CacheShift) << (2(8-CacheShift))) #define AlphaShift(pixel) (((pixel) >> CacheShift) << (3(8-CacheShift))) ssize_t offset; offset=(ssize_t) (RedShift(ScaleQuantumToChar(ClampPixel(pixel->red))) \| GreenShift(ScaleQuantumToChar(ClampPixel(pixel->green))) \| BlueShift(ScaleQuantumToChar(ClampPixel(pixel->blue)))); if (cube_info->associate_alpha != MagickFalse) offset\|=AlphaShift(ScaleQuantumToChar(ClampPixel(pixel->alpha))); return(offset); } static MagickBooleanType FloydSteinbergDither(Image image,CubeInfo cube_info, ExceptionInfo exception) { #define DitherImageTag "Dither/Image" CacheView image_view; DoublePixelPacket *pixels; MagickBooleanType status; ssize_t y; / Distribute quantization error using Floyd-Steinberg. / pixels=AcquirePixelThreadSet(image->columns); if (pixels == (DoublePixelPacket ) NULL) return(MagickFalse); status=MagickTrue; image_view=AcquireAuthenticCacheView(image,exception); for (y=0; y < (ssize_t) image->rows; y++) { const int id = GetOpenMPThreadId(); CubeInfo cube; DoublePixelPacket current, previous; Quantum magick_restrict q; size_t index; ssize_t x, v; if (status == MagickFalse) continue; q=GetCacheViewAuthenticPixels(image_view,0,y,image->columns,1,exception); if (q == (Quantum ) NULL) { status=MagickFalse; continue; } cube=(cube_info); current=pixels[id]+(y & 0x01)image->columns; previous=pixels[id]+((y+1) & 0x01)image->columns; v=(ssize_t) ((y & 0x01) != 0 ? -1 : 1); for (x=0; x < (ssize_t) image->columns; x++) { DoublePixelPacket color, pixel; ssize_t i; ssize_t u; u=(y & 0x01) != 0 ? (ssize_t) image->columns-1-x : x; AssociateAlphaPixel(image,&cube,q+uGetPixelChannels(image),&pixel); if (x > 0) { pixel.red+=7.0cube_info->diffusioncurrent[u-v].red/16; pixel.green+=7.0cube_info->diffusioncurrent[u-v].green/16; pixel.blue+=7.0cube_info->diffusioncurrent[u-v].blue/16; if (cube.associate_alpha != MagickFalse) pixel.alpha+=7.0cube_info->diffusioncurrent[u-v].alpha/16; } if (y > 0) { if (x < (ssize_t) (image->columns-1)) { pixel.red+=cube_info->diffusionprevious[u+v].red/16; pixel.green+=cube_info->diffusionprevious[u+v].green/16; pixel.blue+=cube_info->diffusionprevious[u+v].blue/16; if (cube.associate_alpha != MagickFalse) pixel.alpha+=cube_info->diffusionprevious[u+v].alpha/16; } pixel.red+=5.0cube_info->diffusionprevious[u].red/16; pixel.green+=5.0cube_info->diffusionprevious[u].green/16; pixel.blue+=5.0cube_info->diffusionprevious[u].blue/16; if (cube.associate_alpha != MagickFalse) pixel.alpha+=5.0cube_info->diffusionprevious[u].alpha/16; if (x > 0) { pixel.red+=3.0cube_info->diffusionprevious[u-v].red/16; pixel.green+=3.0cube_info->diffusionprevious[u-v].green/16; pixel.blue+=3.0cube_info->diffusionprevious[u-v].blue/16; if (cube.associate_alpha != MagickFalse) pixel.alpha+=3.0cube_info->diffusionprevious[u-v].alpha/16; } } pixel.red=(double) ClampPixel(pixel.red); pixel.green=(double) ClampPixel(pixel.green); pixel.blue=(double) ClampPixel(pixel.blue); if (cube.associate_alpha != MagickFalse) pixel.alpha=(double) ClampPixel(pixel.alpha); i=CacheOffset(&cube,&pixel); if (cube.cache[i] < 0) { NodeInfo node_info; size_t node_id; /* Identify the deepest node containing the pixel's color. / node_info=cube.root; for (index=MaxTreeDepth-1; (ssize_t) index > 0; index--) { node_id=ColorToNodeId(&cube,&pixel,index); if (node_info->child[node_id] == (NodeInfo ) NULL) break; node_info=node_info->child[node_id]; } /* Find closest color among siblings and their children. / cube.target=pixel; cube.distance=(double) (4.0(QuantumRange+1.0)(QuantumRange+1.0)+ 1.0); ClosestColor(image,&cube,node_info->parent); cube.cache[i]=(ssize_t) cube.color_number; } / Assign pixel to closest colormap entry. / index=(size_t) cube.cache[i]; if (image->storage_class == PseudoClass) SetPixelIndex(image,(Quantum) index,q+uGetPixelChannels(image)); if (cube.quantize_info->measure_error == MagickFalse) { SetPixelRed(image,ClampToQuantum(image->colormap[index].red), q+uGetPixelChannels(image)); SetPixelGreen(image,ClampToQuantum(image->colormap[index].green), q+uGetPixelChannels(image)); SetPixelBlue(image,ClampToQuantum(image->colormap[index].blue), q+uGetPixelChannels(image)); if (cube.associate_alpha != MagickFalse) SetPixelAlpha(image,ClampToQuantum(image->colormap[index].alpha), q+uGetPixelChannels(image)); } if (SyncCacheViewAuthenticPixels(image_view,exception) == MagickFalse) status=MagickFalse; /* Store the error. / AssociateAlphaPixelInfo(&cube,image->colormap+index,&color); current[u].red=pixel.red-color.red; current[u].green=pixel.green-color.green; current[u].blue=pixel.blue-color.blue; if (cube.associate_alpha != MagickFalse) current[u].alpha=pixel.alpha-color.alpha; if (image->progress_monitor != (MagickProgressMonitor) NULL) { MagickBooleanType proceed; proceed=SetImageProgress(image,DitherImageTag,(MagickOffsetType) y, image->rows); if (proceed == MagickFalse) status=MagickFalse; } } } image_view=DestroyCacheView(image_view); pixels=DestroyPixelThreadSet(pixels); return(MagickTrue); } static MagickBooleanType RiemersmaDither(Image image,CacheView image_view, CubeInfo cube_info,const unsigned int direction,ExceptionInfo exception) { #define DitherImageTag "Dither/Image" CubeInfo p; DoublePixelPacket color, pixel; MagickBooleanType proceed; size_t index; p=cube_info; if ((p->x >= 0) && (p->x < (ssize_t) image->columns) && (p->y >= 0) && (p->y < (ssize_t) image->rows)) { Quantum magick_restrict q; ssize_t i; / Distribute error. / q=GetCacheViewAuthenticPixels(image_view,p->x,p->y,1,1,exception); if (q == (Quantum ) NULL) return(MagickFalse); AssociateAlphaPixel(image,cube_info,q,&pixel); for (i=0; i < ErrorQueueLength; i++) { pixel.red+=ErrorRelativeWeightcube_info->diffusionp->weights[i]* p->error[i].red; pixel.green+=ErrorRelativeWeightcube_info->diffusionp->weights[i]* p->error[i].green; pixel.blue+=ErrorRelativeWeightcube_info->diffusionp->weights[i]* p->error[i].blue; if (cube_info->associate_alpha != MagickFalse) pixel.alpha+=ErrorRelativeWeightcube_info->diffusionp->weights[i]* p->error[i].alpha; } pixel.red=(double) ClampPixel(pixel.red); pixel.green=(double) ClampPixel(pixel.green); pixel.blue=(double) ClampPixel(pixel.blue); if (cube_info->associate_alpha != MagickFalse) pixel.alpha=(double) ClampPixel(pixel.alpha); i=CacheOffset(cube_info,&pixel); if (p->cache[i] < 0) { NodeInfo node_info; size_t id; / Identify the deepest node containing the pixel's color. / node_info=p->root; for (index=MaxTreeDepth-1; (ssize_t) index > 0; index--) { id=ColorToNodeId(cube_info,&pixel,index); if (node_info->child[id] == (NodeInfo ) NULL) break; node_info=node_info->child[id]; } /* Find closest color among siblings and their children. / p->target=pixel; p->distance=(double) (4.0(QuantumRange+1.0)((double) QuantumRange+1.0)+1.0); ClosestColor(image,p,node_info->parent); p->cache[i]=(ssize_t) p->color_number; } / Assign pixel to closest colormap entry. / index=(size_t) p->cache[i]; if (image->storage_class == PseudoClass) SetPixelIndex(image,(Quantum) index,q); if (cube_info->quantize_info->measure_error == MagickFalse) { SetPixelRed(image,ClampToQuantum(image->colormap[index].red),q); SetPixelGreen(image,ClampToQuantum(image->colormap[index].green),q); SetPixelBlue(image,ClampToQuantum(image->colormap[index].blue),q); if (cube_info->associate_alpha != MagickFalse) SetPixelAlpha(image,ClampToQuantum(image->colormap[index].alpha),q); } if (SyncCacheViewAuthenticPixels(image_view,exception) == MagickFalse) return(MagickFalse); / Propagate the error as the last entry of the error queue. / (void) memmove(p->error,p->error+1,(ErrorQueueLength-1) sizeof(p->error[0])); AssociateAlphaPixelInfo(cube_info,image->colormap+index,&color); p->error[ErrorQueueLength-1].red=pixel.red-color.red; p->error[ErrorQueueLength-1].green=pixel.green-color.green; p->error[ErrorQueueLength-1].blue=pixel.blue-color.blue; if (cube_info->associate_alpha != MagickFalse) p->error[ErrorQueueLength-1].alpha=pixel.alpha-color.alpha; proceed=SetImageProgress(image,DitherImageTag,p->offset,p->span); if (proceed == MagickFalse) return(MagickFalse); p->offset++; } switch (direction) { case WestGravity: p->x--; break; case EastGravity: p->x++; break; case NorthGravity: p->y--; break; case SouthGravity: p->y++; break; } return(MagickTrue); } static MagickBooleanType Riemersma(Image image,CacheView image_view, CubeInfo cube_info,const size_t level,const unsigned int direction, ExceptionInfo exception) { MagickBooleanType status; status=MagickTrue; if (level == 1) switch (direction) { case WestGravity: { status=RiemersmaDither(image,image_view,cube_info,EastGravity, exception); if (status != MagickFalse) status=RiemersmaDither(image,image_view,cube_info,SouthGravity, exception); if (status != MagickFalse) status=RiemersmaDither(image,image_view,cube_info,WestGravity, exception); break; } case EastGravity: { status=RiemersmaDither(image,image_view,cube_info,WestGravity, exception); if (status != MagickFalse) status=RiemersmaDither(image,image_view,cube_info,NorthGravity, exception); if (status != MagickFalse) status=RiemersmaDither(image,image_view,cube_info,EastGravity, exception); break; } case NorthGravity: { status=RiemersmaDither(image,image_view,cube_info,SouthGravity, exception); if (status != MagickFalse) status=RiemersmaDither(image,image_view,cube_info,EastGravity, exception); if (status != MagickFalse) status=RiemersmaDither(image,image_view,cube_info,NorthGravity, exception); break; } case SouthGravity: { status=RiemersmaDither(image,image_view,cube_info,NorthGravity, exception); if (status != MagickFalse) status=RiemersmaDither(image,image_view,cube_info,WestGravity, exception); if (status != MagickFalse) status=RiemersmaDither(image,image_view,cube_info,SouthGravity, exception); break; } default: break; } else switch (direction) { case WestGravity: { status=Riemersma(image,image_view,cube_info,level-1,NorthGravity, exception); if (status != MagickFalse) status=RiemersmaDither(image,image_view,cube_info,EastGravity, exception); if (status != MagickFalse) status=Riemersma(image,image_view,cube_info,level-1,WestGravity, exception); if (status != MagickFalse) status=RiemersmaDither(image,image_view,cube_info,SouthGravity, exception); if (status != MagickFalse) status=Riemersma(image,image_view,cube_info,level-1,WestGravity, exception); if (status != MagickFalse) status=RiemersmaDither(image,image_view,cube_info,WestGravity, exception); if (status != MagickFalse) status=Riemersma(image,image_view,cube_info,level-1,SouthGravity, exception); break; } case EastGravity: { status=Riemersma(image,image_view,cube_info,level-1,SouthGravity, exception); if (status != MagickFalse) status=RiemersmaDither(image,image_view,cube_info,WestGravity, exception); if (status != MagickFalse) status=Riemersma(image,image_view,cube_info,level-1,EastGravity, exception); if (status != MagickFalse) status=RiemersmaDither(image,image_view,cube_info,NorthGravity, exception); if (status != MagickFalse) status=Riemersma(image,image_view,cube_info,level-1,EastGravity, exception); if (status != MagickFalse) status=RiemersmaDither(image,image_view,cube_info,EastGravity, exception); if (status != MagickFalse) status=Riemersma(image,image_view,cube_info,level-1,NorthGravity, exception); break; } case NorthGravity: { status=Riemersma(image,image_view,cube_info,level-1,WestGravity, exception); if (status != MagickFalse) status=RiemersmaDither(image,image_view,cube_info,SouthGravity, exception); if (status != MagickFalse) status=Riemersma(image,image_view,cube_info,level-1,NorthGravity, exception); if (status != MagickFalse) status=RiemersmaDither(image,image_view,cube_info,EastGravity, exception); if (status != MagickFalse) status=Riemersma(image,image_view,cube_info,level-1,NorthGravity, exception); if (status != MagickFalse) status=RiemersmaDither(image,image_view,cube_info,NorthGravity, exception); if (status != MagickFalse) status=Riemersma(image,image_view,cube_info,level-1,EastGravity, exception); break; } case SouthGravity: { status=Riemersma(image,image_view,cube_info,level-1,EastGravity, exception); if (status != MagickFalse) status=RiemersmaDither(image,image_view,cube_info,NorthGravity, exception); if (status != MagickFalse) status=Riemersma(image,image_view,cube_info,level-1,SouthGravity, exception); if (status != MagickFalse) status=RiemersmaDither(image,image_view,cube_info,WestGravity, exception); if (status != MagickFalse) status=Riemersma(image,image_view,cube_info,level-1,SouthGravity, exception); if (status != MagickFalse) status=RiemersmaDither(image,image_view,cube_info,SouthGravity, exception); if (status != MagickFalse) status=Riemersma(image,image_view,cube_info,level-1,WestGravity, exception); break; } default: break; } return(status); } static MagickBooleanType DitherImage(Image image,CubeInfo cube_info, ExceptionInfo exception) { CacheView image_view; const char artifact; MagickBooleanType status; size_t extent, level; artifact=GetImageArtifact(image,"dither:diffusion-amount"); if (artifact != (const char ) NULL) cube_info->diffusion=StringToDoubleInterval(artifact,1.0); if (cube_info->quantize_info->dither_method != RiemersmaDitherMethod) return(FloydSteinbergDither(image,cube_info,exception)); /* Distribute quantization error along a Hilbert curve. / (void) memset(cube_info->error,0,ErrorQueueLengthsizeof(cube_info->error)); cube_info->x=0; cube_info->y=0; extent=MagickMax(image->columns,image->rows); level=(size_t) log2((double) extent); if (((size_t) 1UL << level) < extent) level++; cube_info->offset=0; cube_info->span=(MagickSizeType) image->columnsimage->rows; image_view=AcquireAuthenticCacheView(image,exception); status=MagickTrue; if (level > 0) status=Riemersma(image,image_view,cube_info,level,NorthGravity,exception); if (status != MagickFalse) status=RiemersmaDither(image,image_view,cube_info,ForgetGravity,exception); image_view=DestroyCacheView(image_view); return(status); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % + G e t C u b e I n f o % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % GetCubeInfo() initialize the Cube data structure. % % The format of the GetCubeInfo method is: % % CubeInfo GetCubeInfo(const QuantizeInfo quantize_info, % const size_t depth,const size_t maximum_colors) % % A description of each parameter follows. % % o quantize_info: Specifies a pointer to an QuantizeInfo structure. % % o depth: Normally, this integer value is zero or one. A zero or % one tells Quantize to choose a optimal tree depth of Log4(number_colors). % A tree of this depth generally allows the best representation of the % reference image with the least amount of memory and the fastest % computational speed. In some cases, such as an image with low color % dispersion (a few number of colors), a value other than % Log4(number_colors) is required. To expand the color tree completely, % use a value of 8. % % o maximum_colors: maximum colors. % / static CubeInfo GetCubeInfo(const QuantizeInfo quantize_info, const size_t depth,const size_t maximum_colors) { CubeInfo cube_info; double weight; size_t length; ssize_t i; / Initialize tree to describe color cube_info. / cube_info=(CubeInfo ) AcquireMagickMemory(sizeof(cube_info)); if (cube_info == (CubeInfo ) NULL) return((CubeInfo ) NULL); (void) memset(cube_info,0,sizeof(cube_info)); cube_info->depth=depth; if (cube_info->depth > MaxTreeDepth) cube_info->depth=MaxTreeDepth; if (cube_info->depth < 2) cube_info->depth=2; cube_info->maximum_colors=maximum_colors; /* Initialize root node. / cube_info->root=GetNodeInfo(cube_info,0,0,(NodeInfo ) NULL); if (cube_info->root == (NodeInfo ) NULL) return((CubeInfo ) NULL); cube_info->root->parent=cube_info->root; cube_info->quantize_info=CloneQuantizeInfo(quantize_info); if (cube_info->quantize_info->dither_method == NoDitherMethod) return(cube_info); /* Initialize dither resources. / length=(size_t) (1UL << (4(8-CacheShift))); cube_info->memory_info=AcquireVirtualMemory(length,sizeof(cube_info->cache)); if (cube_info->memory_info == (MemoryInfo ) NULL) return((CubeInfo ) NULL); cube_info->cache=(ssize_t ) GetVirtualMemoryBlob(cube_info->memory_info); /* Initialize color cache. / (void) memset(cube_info->cache,(-1),sizeof(cube_info->cache)length); / Distribute weights along a curve of exponential decay. / weight=1.0; for (i=0; i < ErrorQueueLength; i++) { cube_info->weights[i]=PerceptibleReciprocal(weight); weight=exp(log(1.0/ErrorRelativeWeight)/(ErrorQueueLength-1.0)); } cube_info->diffusion=1.0; return(cube_info); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % + G e t N o d e I n f o % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % GetNodeInfo() allocates memory for a new node in the color cube tree and % presets all fields to zero. % % The format of the GetNodeInfo method is: % % NodeInfo GetNodeInfo(CubeInfo cube_info,const size_t id, % const size_t level,NodeInfo parent) % % A description of each parameter follows. % % o node: The GetNodeInfo method returns a pointer to a queue of nodes. % % o id: Specifies the child number of the node. % % o level: Specifies the level in the storage_class the node resides. % / static NodeInfo GetNodeInfo(CubeInfo cube_info,const size_t id, const size_t level,NodeInfo parent) { NodeInfo node_info; if (cube_info->free_nodes == 0) { Nodes nodes; / Allocate a new queue of nodes. / nodes=(Nodes ) AcquireMagickMemory(sizeof(nodes)); if (nodes == (Nodes ) NULL) return((NodeInfo ) NULL); nodes->nodes=(NodeInfo ) AcquireQuantumMemory(NodesInAList, sizeof(nodes->nodes)); if (nodes->nodes == (NodeInfo ) NULL) return((NodeInfo ) NULL); nodes->next=cube_info->node_queue; cube_info->node_queue=nodes; cube_info->next_node=nodes->nodes; cube_info->free_nodes=NodesInAList; } cube_info->nodes++; cube_info->free_nodes--; node_info=cube_info->next_node++; (void) memset(node_info,0,sizeof(node_info)); node_info->parent=parent; node_info->id=id; node_info->level=level; return(node_info); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % G e t I m a g e Q u a n t i z e E r r o r % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % GetImageQuantizeError() measures the difference between the original % and quantized images. This difference is the total quantization error. % The error is computed by summing over all pixels in an image the distance % squared in RGB space between each reference pixel value and its quantized % value. These values are computed: % % o mean_error_per_pixel: This value is the mean error for any single % pixel in the image. % % o normalized_mean_square_error: This value is the normalized mean % quantization error for any single pixel in the image. This distance % measure is normalized to a range between 0 and 1. It is independent % of the range of red, green, and blue values in the image. % % o normalized_maximum_square_error: Thsi value is the normalized % maximum quantization error for any single pixel in the image. This % distance measure is normalized to a range between 0 and 1. It is % independent of the range of red, green, and blue values in your image. % % The format of the GetImageQuantizeError method is: % % MagickBooleanType GetImageQuantizeError(Image image, % ExceptionInfo exception) % % A description of each parameter follows. % % o image: the image. % % o exception: return any errors or warnings in this structure. % / MagickExport MagickBooleanType GetImageQuantizeError(Image image, ExceptionInfo exception) { CacheView image_view; double alpha, area, beta, distance, maximum_error, mean_error, mean_error_per_pixel; ssize_t index, y; assert(image != (Image ) NULL); assert(image->signature == MagickCoreSignature); if (image->debug != MagickFalse) (void) LogMagickEvent(TraceEvent,GetMagickModule(),"%s",image->filename); image->total_colors=GetNumberColors(image,(FILE ) NULL,exception); (void) memset(&image->error,0,sizeof(image->error)); if (image->storage_class == DirectClass) return(MagickTrue); alpha=1.0; beta=1.0; area=3.0image->columnsimage->rows; maximum_error=0.0; mean_error_per_pixel=0.0; mean_error=0.0; image_view=AcquireVirtualCacheView(image,exception); for (y=0; y < (ssize_t) image->rows; y++) { const Quantum magick_restrict p; ssize_t x; p=GetCacheViewVirtualPixels(image_view,0,y,image->columns,1,exception); if (p == (const Quantum ) NULL) break; for (x=0; x < (ssize_t) image->columns; x++) { index=(ssize_t) GetPixelIndex(image,p); if (image->alpha_trait != UndefinedPixelTrait) { alpha=(double) (QuantumScaleGetPixelAlpha(image,p)); beta=(double) (QuantumScaleimage->colormap[index].alpha); } distance=fabs((double) (alphaGetPixelRed(image,p)-beta image->colormap[index].red)); mean_error_per_pixel+=distance; mean_error+=distancedistance; if (distance > maximum_error) maximum_error=distance; distance=fabs((double) (alphaGetPixelGreen(image,p)-beta* image->colormap[index].green)); mean_error_per_pixel+=distance; mean_error+=distancedistance; if (distance > maximum_error) maximum_error=distance; distance=fabs((double) (alphaGetPixelBlue(image,p)-beta* image->colormap[index].blue)); mean_error_per_pixel+=distance; mean_error+=distancedistance; if (distance > maximum_error) maximum_error=distance; p+=GetPixelChannels(image); } } image_view=DestroyCacheView(image_view); image->error.mean_error_per_pixel=(double) mean_error_per_pixel/area; image->error.normalized_mean_error=(double) QuantumScaleQuantumScale* mean_error/area; image->error.normalized_maximum_error=(double) QuantumScalemaximum_error; return(MagickTrue); } / %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % G e t Q u a n t i z e I n f o % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % GetQuantizeInfo() initializes the QuantizeInfo structure. % % The format of the GetQuantizeInfo method is: % % GetQuantizeInfo(QuantizeInfo quantize_info) % % A description of each parameter follows: % % o quantize_info: Specifies a pointer to a QuantizeInfo structure. % / MagickExport void GetQuantizeInfo(QuantizeInfo quantize_info) { (void) LogMagickEvent(TraceEvent,GetMagickModule(),"..."); assert(quantize_info != (QuantizeInfo ) NULL); (void) memset(quantize_info,0,sizeof(quantize_info)); quantize_info->number_colors=256; quantize_info->dither_method=RiemersmaDitherMethod; quantize_info->colorspace=UndefinedColorspace; quantize_info->measure_error=MagickFalse; quantize_info->signature=MagickCoreSignature; } / %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % K m e a n s I m a g e % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % KmeansImage() applies k-means color reduction to an image. This is a % colorspace clustering or segmentation technique. % % The format of the KmeansImage method is: % % MagickBooleanType KmeansImage(Image image,const size_t number_colors, % const size_t max_iterations,const double tolerance, % ExceptionInfo exception) % % A description of each parameter follows: % % o image: the image. % % o number_colors: number of colors to use as seeds. % % o max_iterations: maximum number of iterations while converging. % % o tolerance: the maximum tolerance. % % o exception: return any errors or warnings in this structure. % / typedef struct _KmeansInfo { double red, green, blue, alpha, black, count, distortion; } KmeansInfo; static KmeansInfo DestroyKmeansThreadSet(KmeansInfo kmeans_info) { ssize_t i; assert(kmeans_info != (KmeansInfo ) NULL); for (i=0; i < (ssize_t) GetMagickResourceLimit(ThreadResource); i++) if (kmeans_info[i] != (KmeansInfo ) NULL) kmeans_info[i]=(KmeansInfo ) RelinquishMagickMemory(kmeans_info[i]); kmeans_info=(KmeansInfo ) RelinquishMagickMemory(kmeans_info); return(kmeans_info); } static KmeansInfo AcquireKmeansThreadSet(const size_t number_colors) { KmeansInfo kmeans_info; ssize_t i; size_t number_threads; number_threads=(size_t) GetMagickResourceLimit(ThreadResource); kmeans_info=(KmeansInfo ) AcquireQuantumMemory(number_threads, sizeof(kmeans_info)); if (kmeans_info == (KmeansInfo ) NULL) return((KmeansInfo ) NULL); (void) memset(kmeans_info,0,number_threadssizeof(kmeans_info)); for (i=0; i < (ssize_t) number_threads; i++) { kmeans_info[i]=(KmeansInfo ) AcquireQuantumMemory(number_colors, sizeof(kmeans_info)); if (kmeans_info[i] == (KmeansInfo ) NULL) return(DestroyKmeansThreadSet(kmeans_info)); } return(kmeans_info); } static inline double KmeansMetric(const Image magick_restrict image, const Quantum magick_restrict p,const PixelInfo magick_restrict q) { double gamma, metric, pixel; gamma=1.0; metric=0.0; if ((image->alpha_trait != UndefinedPixelTrait) \|\| (q->alpha_trait != UndefinedPixelTrait)) { pixel=GetPixelAlpha(image,p)-(q->alpha_trait != UndefinedPixelTrait ? q->alpha : OpaqueAlpha); metric+=pixelpixel; if (image->alpha_trait != UndefinedPixelTrait) gamma=QuantumScaleGetPixelAlpha(image,p); if (q->alpha_trait != UndefinedPixelTrait) gamma=QuantumScaleq->alpha; } if (image->colorspace == CMYKColorspace) { pixel=QuantumScale(GetPixelBlack(image,p)-q->black); metric+=gammapixelpixel; gamma=QuantumScale(QuantumRange-GetPixelBlack(image,p)); gamma=QuantumScale(QuantumRange-q->black); } metric=3.0; pixel=QuantumScale(GetPixelRed(image,p)-q->red); if (IsHueCompatibleColorspace(image->colorspace) != MagickFalse) { if (fabs((double) pixel) > 0.5) pixel-=0.5; pixel=2.0; } metric+=gammapixelpixel; pixel=QuantumScale(GetPixelGreen(image,p)-q->green); metric+=gammapixelpixel; pixel=QuantumScale(GetPixelBlue(image,p)-q->blue); metric+=gammapixelpixel; return(metric); } MagickExport MagickBooleanType KmeansImage(Image image, const size_t number_colors,const size_t max_iterations,const double tolerance, ExceptionInfo exception) { #define KmeansImageTag "Kmeans/Image" #define RandomColorComponent(info) (QuantumRangeGetPseudoRandomValue(info)) CacheView image_view; const char colors; double previous_tolerance; KmeansInfo kmeans_pixels; MagickBooleanType verbose, status; ssize_t n; size_t number_threads; assert(image != (Image ) NULL); assert(image->signature == MagickCoreSignature); if (image->debug != MagickFalse) (void) LogMagickEvent(TraceEvent,GetMagickModule(),"%s",image->filename); assert(exception != (ExceptionInfo ) NULL); assert(exception->signature == MagickCoreSignature); colors=GetImageArtifact(image,"kmeans:seed-colors"); if (colors == (const char ) NULL) { CubeInfo cube_info; QuantizeInfo quantize_info; size_t depth; /* Seed clusters from color quantization. / quantize_info=AcquireQuantizeInfo((ImageInfo ) NULL); quantize_info->colorspace=image->colorspace; quantize_info->number_colors=number_colors; quantize_info->dither_method=NoDitherMethod; n=number_colors; for (depth=1; n != 0; depth++) n>>=2; cube_info=GetCubeInfo(quantize_info,depth,number_colors); if (cube_info == (CubeInfo ) NULL) { quantize_info=DestroyQuantizeInfo(quantize_info); ThrowBinaryException(ResourceLimitError,"MemoryAllocationFailed", image->filename); } status=ClassifyImageColors(cube_info,image,exception); if (status != MagickFalse) { if (cube_info->colors > cube_info->maximum_colors) ReduceImageColors(image,cube_info); status=SetImageColormap(image,cube_info,exception); } DestroyCubeInfo(cube_info); quantize_info=DestroyQuantizeInfo(quantize_info); if (status == MagickFalse) return(status); } else { char color[MagickPathExtent]; const char p; /* Seed clusters from color list (e.g. red;green;blue). / status=AcquireImageColormap(image,number_colors,exception); if (status == MagickFalse) return(status); for (n=0, p=colors; n < (ssize_t) image->colors; n++) { const char q; for (q=p; q != '\0'; q++) if (q == ';') break; (void) CopyMagickString(color,p,(size_t) MagickMin(q-p+1, MagickPathExtent)); (void) QueryColorCompliance(color,AllCompliance,image->colormap+n, exception); if (q == '\0') { n++; break; } p=q+1; } if (n < (ssize_t) image->colors) { RandomInfo random_info; /* Seed clusters from random values. / random_info=AcquireRandomInfo(); for ( ; n < (ssize_t) image->colors; n++) { (void) QueryColorCompliance("#000",AllCompliance,image->colormap+n, exception); image->colormap[n].red=RandomColorComponent(random_info); image->colormap[n].green=RandomColorComponent(random_info); image->colormap[n].blue=RandomColorComponent(random_info); if (image->alpha_trait != UndefinedPixelTrait) image->colormap[n].alpha=RandomColorComponent(random_info); if (image->colorspace == CMYKColorspace) image->colormap[n].black=RandomColorComponent(random_info); } random_info=DestroyRandomInfo(random_info); } } / Iterative refinement. / kmeans_pixels=AcquireKmeansThreadSet(number_colors); if (kmeans_pixels == (KmeansInfo ) NULL) ThrowBinaryException(ResourceLimitError,"MemoryAllocationFailed", image->filename); previous_tolerance=0.0; verbose=IsStringTrue(GetImageArtifact(image,"debug")); number_threads=(size_t) GetMagickResourceLimit(ThreadResource); image_view=AcquireAuthenticCacheView(image,exception); for (n=0; n < (ssize_t) max_iterations; n++) { double distortion; ssize_t j, y; for (j=0; j < (ssize_t) number_threads; j++) (void) memset(kmeans_pixels[j],0,image->colorssizeof(kmeans_pixels[j])); #if defined(MAGICKCORE_OPENMP_SUPPORT) #pragma omp parallel for schedule(dynamic) shared(status) \ magick_number_threads(image,image,image->rows,1) #endif for (y=0; y < (ssize_t) image->rows; y++) { const int id = GetOpenMPThreadId(); Quantum magick_restrict q; ssize_t x; if (status == MagickFalse) continue; q=GetCacheViewAuthenticPixels(image_view,0,y,image->columns,1,exception); if (q == (Quantum ) NULL) { status=MagickFalse; continue; } for (x=0; x < (ssize_t) image->columns; x++) { double min_distance; ssize_t i, k; / Assign each pixel whose mean has the least squared color distance. / k=0; min_distance=KmeansMetric(image,q,image->colormap+0); for (i=1; i < (ssize_t) image->colors; i++) { double distance; if (min_distance <= MagickEpsilon) break; distance=KmeansMetric(image,q,image->colormap+i); if (distance < min_distance) { min_distance=distance; k=i; } } kmeans_pixels[id][k].red+=QuantumScaleGetPixelRed(image,q); kmeans_pixels[id][k].green+=QuantumScaleGetPixelGreen(image,q); kmeans_pixels[id][k].blue+=QuantumScaleGetPixelBlue(image,q); if (image->alpha_trait != UndefinedPixelTrait) kmeans_pixels[id][k].alpha+=QuantumScaleGetPixelAlpha(image,q); if (image->colorspace == CMYKColorspace) kmeans_pixels[id][k].black+=QuantumScaleGetPixelBlack(image,q); kmeans_pixels[id][k].count++; kmeans_pixels[id][k].distortion+=min_distance; SetPixelIndex(image,(Quantum) k,q); q+=GetPixelChannels(image); } if (SyncCacheViewAuthenticPixels(image_view,exception) == MagickFalse) status=MagickFalse; } if (status == MagickFalse) break; /* Reduce sums to [0] entry. / for (j=1; j < (ssize_t) number_threads; j++) { ssize_t k; for (k=0; k < (ssize_t) image->colors; k++) { kmeans_pixels[0][k].red+=kmeans_pixels[j][k].red; kmeans_pixels[0][k].green+=kmeans_pixels[j][k].green; kmeans_pixels[0][k].blue+=kmeans_pixels[j][k].blue; if (image->alpha_trait != UndefinedPixelTrait) kmeans_pixels[0][k].alpha+=kmeans_pixels[j][k].alpha; if (image->colorspace == CMYKColorspace) kmeans_pixels[0][k].black+=kmeans_pixels[j][k].black; kmeans_pixels[0][k].count+=kmeans_pixels[j][k].count; kmeans_pixels[0][k].distortion+=kmeans_pixels[j][k].distortion; } } / Calculate the new means (centroids) of the pixels in the new clusters. / distortion=0.0; for (j=0; j < (ssize_t) image->colors; j++) { double gamma; gamma=PerceptibleReciprocal((double) kmeans_pixels[0][j].count); image->colormap[j].red=gammaQuantumRangekmeans_pixels[0][j].red; image->colormap[j].green=gammaQuantumRangekmeans_pixels[0][j].green; image->colormap[j].blue=gammaQuantumRangekmeans_pixels[0][j].blue; if (image->alpha_trait != UndefinedPixelTrait) image->colormap[j].alpha=gammaQuantumRangekmeans_pixels[0][j].alpha; if (image->colorspace == CMYKColorspace) image->colormap[j].black=gammaQuantumRangekmeans_pixels[0][j].black; distortion+=kmeans_pixels[0][j].distortion; } if (verbose != MagickFalse) (void) FormatLocaleFile(stderr,"distortion[%.20g]: %g %g\n",(double) n, GetMagickPrecision(),distortion,GetMagickPrecision(), fabs(distortion-previous_tolerance)); if (fabs(distortion-previous_tolerance) <= tolerance) break; previous_tolerance=distortion; if (image->progress_monitor != (MagickProgressMonitor) NULL) { MagickBooleanType proceed; proceed=SetImageProgress(image,KmeansImageTag,(MagickOffsetType) n, max_iterations); if (proceed == MagickFalse) status=MagickFalse; } } image_view=DestroyCacheView(image_view); kmeans_pixels=DestroyKmeansThreadSet(kmeans_pixels); if (image->progress_monitor != (MagickProgressMonitor) NULL) (void) SetImageProgress(image,KmeansImageTag,(MagickOffsetType) max_iterations-1,max_iterations); if (status == MagickFalse) return(status); return(SyncImage(image,exception)); } / %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % P o s t e r i z e I m a g e % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % PosterizeImage() reduces the image to a limited number of colors for a % "poster" effect. % % The format of the PosterizeImage method is: % % MagickBooleanType PosterizeImage(Image image,const size_t levels, % const DitherMethod dither_method,ExceptionInfo exception) % % A description of each parameter follows: % % o image: Specifies a pointer to an Image structure. % % o levels: Number of color levels allowed in each channel. Very low values % (2, 3, or 4) have the most visible effect. % % o dither_method: choose from UndefinedDitherMethod, NoDitherMethod, % RiemersmaDitherMethod, FloydSteinbergDitherMethod. % % o exception: return any errors or warnings in this structure. % / static inline double MagickRound(double x) { / Round the fraction to nearest integer. / if ((x-floor(x)) < (ceil(x)-x)) return(floor(x)); return(ceil(x)); } MagickExport MagickBooleanType PosterizeImage(Image image,const size_t levels, const DitherMethod dither_method,ExceptionInfo exception) { #define PosterizeImageTag "Posterize/Image" #define PosterizePixel(pixel) ClampToQuantum((MagickRealType) QuantumRange( \ MagickRound(QuantumScalepixel(levels-1)))/MagickMax((ssize_t) levels-1,1)) CacheView image_view; MagickBooleanType status; MagickOffsetType progress; QuantizeInfo quantize_info; ssize_t i; ssize_t y; assert(image != (Image ) NULL); assert(image->signature == MagickCoreSignature); if (image->debug != MagickFalse) (void) LogMagickEvent(TraceEvent,GetMagickModule(),"%s",image->filename); assert(exception != (ExceptionInfo ) NULL); assert(exception->signature == MagickCoreSignature); if (image->storage_class == PseudoClass) #if defined(MAGICKCORE_OPENMP_SUPPORT) #pragma omp parallel for schedule(static) shared(progress,status) \ magick_number_threads(image,image,image->colors,1) #endif for (i=0; i < (ssize_t) image->colors; i++) { /* Posterize colormap. / if ((GetPixelRedTraits(image) & UpdatePixelTrait) != 0) image->colormap[i].red=(double) PosterizePixel(image->colormap[i].red); if ((GetPixelGreenTraits(image) & UpdatePixelTrait) != 0) image->colormap[i].green=(double) PosterizePixel(image->colormap[i].green); if ((GetPixelBlueTraits(image) & UpdatePixelTrait) != 0) image->colormap[i].blue=(double) PosterizePixel(image->colormap[i].blue); if ((GetPixelAlphaTraits(image) & UpdatePixelTrait) != 0) image->colormap[i].alpha=(double) PosterizePixel(image->colormap[i].alpha); } / Posterize image. / status=MagickTrue; progress=0; image_view=AcquireAuthenticCacheView(image,exception); #if defined(MAGICKCORE_OPENMP_SUPPORT) #pragma omp parallel for schedule(static) shared(progress,status) \ magick_number_threads(image,image,image->rows,1) #endif for (y=0; y < (ssize_t) image->rows; y++) { Quantum magick_restrict q; ssize_t x; if (status == MagickFalse) continue; q=GetCacheViewAuthenticPixels(image_view,0,y,image->columns,1,exception); if (q == (Quantum ) NULL) { status=MagickFalse; continue; } for (x=0; x < (ssize_t) image->columns; x++) { if ((GetPixelRedTraits(image) & UpdatePixelTrait) != 0) SetPixelRed(image,PosterizePixel(GetPixelRed(image,q)),q); if ((GetPixelGreenTraits(image) & UpdatePixelTrait) != 0) SetPixelGreen(image,PosterizePixel(GetPixelGreen(image,q)),q); if ((GetPixelBlueTraits(image) & UpdatePixelTrait) != 0) SetPixelBlue(image,PosterizePixel(GetPixelBlue(image,q)),q); if (((GetPixelBlackTraits(image) & UpdatePixelTrait) != 0) && (image->colorspace == CMYKColorspace)) SetPixelBlack(image,PosterizePixel(GetPixelBlack(image,q)),q); if (((GetPixelAlphaTraits(image) & UpdatePixelTrait) != 0) && (image->alpha_trait != UndefinedPixelTrait)) SetPixelAlpha(image,PosterizePixel(GetPixelAlpha(image,q)),q); q+=GetPixelChannels(image); } if (SyncCacheViewAuthenticPixels(image_view,exception) == MagickFalse) status=MagickFalse; if (image->progress_monitor != (MagickProgressMonitor) NULL) { MagickBooleanType proceed; #if defined(MAGICKCORE_OPENMP_SUPPORT) #pragma omp atomic #endif progress++; proceed=SetImageProgress(image,PosterizeImageTag,progress,image->rows); if (proceed == MagickFalse) status=MagickFalse; } } image_view=DestroyCacheView(image_view); quantize_info=AcquireQuantizeInfo((ImageInfo ) NULL); quantize_info->number_colors=(size_t) MagickMin((ssize_t) levelslevels levels,MaxColormapSize+1); quantize_info->dither_method=dither_method; quantize_info->tree_depth=MaxTreeDepth; status=QuantizeImage(quantize_info,image,exception); quantize_info=DestroyQuantizeInfo(quantize_info); return(status); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % + P r u n e C h i l d % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % PruneChild() deletes the given node and merges its statistics into its % parent. % % The format of the PruneSubtree method is: % % PruneChild(CubeInfo cube_info,const NodeInfo node_info) % % A description of each parameter follows. % % o cube_info: A pointer to the Cube structure. % % o node_info: pointer to node in color cube tree that is to be pruned. % / static void PruneChild(CubeInfo cube_info,const NodeInfo node_info) { NodeInfo parent; size_t number_children; ssize_t i; /* Traverse any children. / number_children=cube_info->associate_alpha == MagickFalse ? 8UL : 16UL; for (i=0; i < (ssize_t) number_children; i++) if (node_info->child[i] != (NodeInfo ) NULL) PruneChild(cube_info,node_info->child[i]); if (cube_info->nodes > cube_info->maximum_colors) { /* Merge color statistics into parent. / parent=node_info->parent; parent->number_unique+=node_info->number_unique; parent->total_color.red+=node_info->total_color.red; parent->total_color.green+=node_info->total_color.green; parent->total_color.blue+=node_info->total_color.blue; parent->total_color.alpha+=node_info->total_color.alpha; parent->child[node_info->id]=(NodeInfo ) NULL; cube_info->nodes--; } } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % + P r u n e L e v e l % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % PruneLevel() deletes all nodes at the bottom level of the color tree merging % their color statistics into their parent node. % % The format of the PruneLevel method is: % % PruneLevel(CubeInfo cube_info,const NodeInfo node_info) % % A description of each parameter follows. % % o cube_info: A pointer to the Cube structure. % % o node_info: pointer to node in color cube tree that is to be pruned. % / static void PruneLevel(CubeInfo cube_info,const NodeInfo node_info) { size_t number_children; ssize_t i; / Traverse any children. / number_children=cube_info->associate_alpha == MagickFalse ? 8UL : 16UL; for (i=0; i < (ssize_t) number_children; i++) if (node_info->child[i] != (NodeInfo ) NULL) PruneLevel(cube_info,node_info->child[i]); if (node_info->level == cube_info->depth) PruneChild(cube_info,node_info); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % + P r u n e T o C u b e D e p t h % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % PruneToCubeDepth() deletes any nodes at a depth greater than % cube_info->depth while merging their color statistics into their parent % node. % % The format of the PruneToCubeDepth method is: % % PruneToCubeDepth(CubeInfo cube_info,const NodeInfo node_info) % % A description of each parameter follows. % % o cube_info: A pointer to the Cube structure. % % o node_info: pointer to node in color cube tree that is to be pruned. % / static void PruneToCubeDepth(CubeInfo cube_info,const NodeInfo node_info) { size_t number_children; ssize_t i; / Traverse any children. / number_children=cube_info->associate_alpha == MagickFalse ? 8UL : 16UL; for (i=0; i < (ssize_t) number_children; i++) if (node_info->child[i] != (NodeInfo ) NULL) PruneToCubeDepth(cube_info,node_info->child[i]); if (node_info->level > cube_info->depth) PruneChild(cube_info,node_info); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % Q u a n t i z e I m a g e % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % QuantizeImage() analyzes the colors within a reference image and chooses a % fixed number of colors to represent the image. The goal of the algorithm % is to minimize the color difference between the input and output image while % minimizing the processing time. % % The format of the QuantizeImage method is: % % MagickBooleanType QuantizeImage(const QuantizeInfo quantize_info, % Image image,ExceptionInfo exception) % % A description of each parameter follows: % % o quantize_info: Specifies a pointer to an QuantizeInfo structure. % % o image: the image. % % o exception: return any errors or warnings in this structure. % / MagickExport MagickBooleanType QuantizeImage(const QuantizeInfo quantize_info, Image image,ExceptionInfo exception) { CubeInfo cube_info; ImageType type; MagickBooleanType status; size_t depth, maximum_colors; assert(quantize_info != (const QuantizeInfo ) NULL); assert(quantize_info->signature == MagickCoreSignature); assert(image != (Image ) NULL); assert(image->signature == MagickCoreSignature); if (image->debug != MagickFalse) (void) LogMagickEvent(TraceEvent,GetMagickModule(),"%s",image->filename); assert(exception != (ExceptionInfo ) NULL); assert(exception->signature == MagickCoreSignature); maximum_colors=quantize_info->number_colors; if (maximum_colors == 0) maximum_colors=MaxColormapSize; if (maximum_colors > MaxColormapSize) maximum_colors=MaxColormapSize; type=IdentifyImageGray(image,exception); if (IsGrayImageType(type) != MagickFalse) (void) SetGrayscaleImage(image,exception); depth=quantize_info->tree_depth; if (depth == 0) { size_t colors; / Depth of color tree is: Log4(colormap size)+2. / colors=maximum_colors; for (depth=1; colors != 0; depth++) colors>>=2; if ((quantize_info->dither_method != NoDitherMethod) && (depth > 2)) depth--; if ((image->alpha_trait != UndefinedPixelTrait) && (depth > 5)) depth--; if (IsGrayImageType(type) != MagickFalse) depth=MaxTreeDepth; } / Initialize color cube. / cube_info=GetCubeInfo(quantize_info,depth,maximum_colors); if (cube_info == (CubeInfo ) NULL) ThrowBinaryException(ResourceLimitError,"MemoryAllocationFailed", image->filename); status=ClassifyImageColors(cube_info,image,exception); if (status != MagickFalse) { /* Reduce the number of colors in the image. / if (cube_info->colors > cube_info->maximum_colors) ReduceImageColors(image,cube_info); status=AssignImageColors(image,cube_info,exception); } DestroyCubeInfo(cube_info); return(status); } / %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % Q u a n t i z e I m a g e s % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % QuantizeImages() analyzes the colors within a set of reference images and % chooses a fixed number of colors to represent the set. The goal of the % algorithm is to minimize the color difference between the input and output % images while minimizing the processing time. % % The format of the QuantizeImages method is: % % MagickBooleanType QuantizeImages(const QuantizeInfo quantize_info, % Image images,ExceptionInfo exception) % % A description of each parameter follows: % % o quantize_info: Specifies a pointer to an QuantizeInfo structure. % % o images: Specifies a pointer to a list of Image structures. % % o exception: return any errors or warnings in this structure. % / MagickExport MagickBooleanType QuantizeImages(const QuantizeInfo quantize_info, Image images,ExceptionInfo exception) { CubeInfo cube_info; Image image; MagickBooleanType proceed, status; MagickProgressMonitor progress_monitor; size_t depth, maximum_colors, number_images; ssize_t i; assert(quantize_info != (const QuantizeInfo ) NULL); assert(quantize_info->signature == MagickCoreSignature); assert(images != (Image ) NULL); assert(images->signature == MagickCoreSignature); if (images->debug != MagickFalse) (void) LogMagickEvent(TraceEvent,GetMagickModule(),"%s",images->filename); assert(exception != (ExceptionInfo ) NULL); assert(exception->signature == MagickCoreSignature); if (GetNextImageInList(images) == (Image ) NULL) { / Handle a single image with QuantizeImage. / status=QuantizeImage(quantize_info,images,exception); return(status); } status=MagickFalse; maximum_colors=quantize_info->number_colors; if (maximum_colors == 0) maximum_colors=MaxColormapSize; if (maximum_colors > MaxColormapSize) maximum_colors=MaxColormapSize; depth=quantize_info->tree_depth; if (depth == 0) { size_t colors; / Depth of color tree is: Log4(colormap size)+2. / colors=maximum_colors; for (depth=1; colors != 0; depth++) colors>>=2; if (quantize_info->dither_method != NoDitherMethod) depth--; } / Initialize color cube. / cube_info=GetCubeInfo(quantize_info,depth,maximum_colors); if (cube_info == (CubeInfo ) NULL) { (void) ThrowMagickException(exception,GetMagickModule(), ResourceLimitError,"MemoryAllocationFailed","`%s'",images->filename); return(MagickFalse); } number_images=GetImageListLength(images); image=images; for (i=0; image != (Image ) NULL; i++) { progress_monitor=SetImageProgressMonitor(image,(MagickProgressMonitor) NULL, image->client_data); status=ClassifyImageColors(cube_info,image,exception); if (status == MagickFalse) break; (void) SetImageProgressMonitor(image,progress_monitor,image->client_data); proceed=SetImageProgress(image,AssignImageTag,(MagickOffsetType) i, number_images); if (proceed == MagickFalse) break; image=GetNextImageInList(image); } if (status != MagickFalse) { / Reduce the number of colors in an image sequence. / ReduceImageColors(images,cube_info); image=images; for (i=0; image != (Image ) NULL; i++) { progress_monitor=SetImageProgressMonitor(image,(MagickProgressMonitor) NULL,image->client_data); status=AssignImageColors(image,cube_info,exception); if (status == MagickFalse) break; (void) SetImageProgressMonitor(image,progress_monitor, image->client_data); proceed=SetImageProgress(image,AssignImageTag,(MagickOffsetType) i, number_images); if (proceed == MagickFalse) break; image=GetNextImageInList(image); } } DestroyCubeInfo(cube_info); return(status); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % + Q u a n t i z e E r r o r F l a t t e n % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % QuantizeErrorFlatten() traverses the color cube and flattens the quantization % error into a sorted 1D array. This accelerates the color reduction process. % % Contributed by Yoya. % % The format of the QuantizeErrorFlatten method is: % % size_t QuantizeErrorFlatten(const CubeInfo cube_info, % const NodeInfo node_info,const ssize_t offset, % double quantize_error) % % A description of each parameter follows. % % o cube_info: A pointer to the Cube structure. % % o node_info: pointer to node in color cube tree that is current pointer. % % o offset: quantize error offset. % % o quantize_error: the quantization error vector. % / static size_t QuantizeErrorFlatten(const CubeInfo cube_info, const NodeInfo node_info,const ssize_t offset,double quantize_error) { size_t n, number_children; ssize_t i; if (offset >= (ssize_t) cube_info->nodes) return(0); quantize_error[offset]=node_info->quantize_error; n=1; number_children=cube_info->associate_alpha == MagickFalse ? 8UL : 16UL; for (i=0; i < (ssize_t) number_children ; i++) if (node_info->child[i] != (NodeInfo ) NULL) n+=QuantizeErrorFlatten(cube_info,node_info->child[i],offset+n, quantize_error); return(n); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % + R e d u c e % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % Reduce() traverses the color cube tree and prunes any node whose % quantization error falls below a particular threshold. % % The format of the Reduce method is: % % Reduce(CubeInfo cube_info,const NodeInfo node_info) % % A description of each parameter follows. % % o cube_info: A pointer to the Cube structure. % % o node_info: pointer to node in color cube tree that is to be pruned. % / static void Reduce(CubeInfo cube_info,const NodeInfo node_info) { size_t number_children; ssize_t i; / Traverse any children. / number_children=cube_info->associate_alpha == MagickFalse ? 8UL : 16UL; for (i=0; i < (ssize_t) number_children; i++) if (node_info->child[i] != (NodeInfo ) NULL) Reduce(cube_info,node_info->child[i]); if (node_info->quantize_error <= cube_info->pruning_threshold) PruneChild(cube_info,node_info); else { /* Find minimum pruning threshold. / if (node_info->number_unique > 0) cube_info->colors++; if (node_info->quantize_error < cube_info->next_threshold) cube_info->next_threshold=node_info->quantize_error; } } / %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % + R e d u c e I m a g e C o l o r s % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % ReduceImageColors() repeatedly prunes the tree until the number of nodes % with n2 > 0 is less than or equal to the maximum number of colors allowed % in the output image. On any given iteration over the tree, it selects % those nodes whose E value is minimal for pruning and merges their % color statistics upward. It uses a pruning threshold, Ep, to govern % node selection as follows: % % Ep = 0 % while number of nodes with (n2 > 0) > required maximum number of colors % prune all nodes such that E <= Ep % Set Ep to minimum E in remaining nodes % % This has the effect of minimizing any quantization error when merging % two nodes together. % % When a node to be pruned has offspring, the pruning procedure invokes % itself recursively in order to prune the tree from the leaves upward. % n2, Sr, Sg, and Sb in a node being pruned are always added to the % corresponding data in that node's parent. This retains the pruned % node's color characteristics for later averaging. % % For each node, n2 pixels exist for which that node represents the % smallest volume in RGB space containing those pixel's colors. When n2 % > 0 the node will uniquely define a color in the output image. At the % beginning of reduction, n2 = 0 for all nodes except a the leaves of % the tree which represent colors present in the input image. % % The other pixel count, n1, indicates the total number of colors % within the cubic volume which the node represents. This includes n1 - % n2 pixels whose colors should be defined by nodes at a lower level in % the tree. % % The format of the ReduceImageColors method is: % % ReduceImageColors(const Image image,CubeInfo cube_info) % % A description of each parameter follows. % % o image: the image. % % o cube_info: A pointer to the Cube structure. % / static int QuantizeErrorCompare(const void error_p,const void error_q) { double p, q; p=(double ) error_p; q=(double ) error_q; if (p > q) return(1); if (fabs(q-p) <= MagickEpsilon) return(0); return(-1); } static void ReduceImageColors(const Image image,CubeInfo cube_info) { #define ReduceImageTag "Reduce/Image" MagickBooleanType proceed; MagickOffsetType offset; size_t span; cube_info->next_threshold=0.0; if (cube_info->colors > cube_info->maximum_colors) { double quantize_error; /* Enable rapid reduction of the number of unique colors. / quantize_error=(double ) AcquireQuantumMemory(cube_info->nodes, sizeof(quantize_error)); if (quantize_error != (double ) NULL) { (void) QuantizeErrorFlatten(cube_info,cube_info->root,0, quantize_error); qsort(quantize_error,cube_info->nodes,sizeof(double), QuantizeErrorCompare); if (cube_info->nodes > (110(cube_info->maximum_colors+1)/100)) cube_info->next_threshold=quantize_error[cube_info->nodes-110 (cube_info->maximum_colors+1)/100]; quantize_error=(double ) RelinquishMagickMemory(quantize_error); } } for (span=cube_info->colors; cube_info->colors > cube_info->maximum_colors; ) { cube_info->pruning_threshold=cube_info->next_threshold; cube_info->next_threshold=cube_info->root->quantize_error-1; cube_info->colors=0; Reduce(cube_info,cube_info->root); offset=(MagickOffsetType) span-cube_info->colors; proceed=SetImageProgress(image,ReduceImageTag,offset,span- cube_info->maximum_colors+1); if (proceed == MagickFalse) break; } } / %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % R e m a p I m a g e % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % RemapImage() replaces the colors of an image with the closest of the colors % from the reference image. % % The format of the RemapImage method is: % % MagickBooleanType RemapImage(const QuantizeInfo quantize_info, % Image image,const Image remap_image,ExceptionInfo exception) % % A description of each parameter follows: % % o quantize_info: Specifies a pointer to an QuantizeInfo structure. % % o image: the image. % % o remap_image: the reference image. % % o exception: return any errors or warnings in this structure. % / MagickExport MagickBooleanType RemapImage(const QuantizeInfo quantize_info, Image image,const Image remap_image,ExceptionInfo exception) { CubeInfo cube_info; MagickBooleanType status; /* Initialize color cube. / assert(image != (Image ) NULL); assert(image->signature == MagickCoreSignature); if (image->debug != MagickFalse) (void) LogMagickEvent(TraceEvent,GetMagickModule(),"%s",image->filename); assert(remap_image != (Image ) NULL); assert(remap_image->signature == MagickCoreSignature); assert(exception != (ExceptionInfo ) NULL); assert(exception->signature == MagickCoreSignature); cube_info=GetCubeInfo(quantize_info,MaxTreeDepth, quantize_info->number_colors); if (cube_info == (CubeInfo ) NULL) ThrowBinaryException(ResourceLimitError,"MemoryAllocationFailed", image->filename); status=ClassifyImageColors(cube_info,remap_image,exception); if (status != MagickFalse) { / Classify image colors from the reference image. / cube_info->quantize_info->number_colors=cube_info->colors; status=AssignImageColors(image,cube_info,exception); } DestroyCubeInfo(cube_info); return(status); } / %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % R e m a p I m a g e s % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % RemapImages() replaces the colors of a sequence of images with the % closest color from a reference image. % % The format of the RemapImage method is: % % MagickBooleanType RemapImages(const QuantizeInfo quantize_info, % Image images,Image remap_image,ExceptionInfo exception) % % A description of each parameter follows: % % o quantize_info: Specifies a pointer to an QuantizeInfo structure. % % o images: the image sequence. % % o remap_image: the reference image. % % o exception: return any errors or warnings in this structure. % / MagickExport MagickBooleanType RemapImages(const QuantizeInfo quantize_info, Image images,const Image remap_image,ExceptionInfo exception) { CubeInfo cube_info; Image image; MagickBooleanType status; assert(images != (Image ) NULL); assert(images->signature == MagickCoreSignature); if (images->debug != MagickFalse) (void) LogMagickEvent(TraceEvent,GetMagickModule(),"%s",images->filename); assert(exception != (ExceptionInfo ) NULL); assert(exception->signature == MagickCoreSignature); image=images; if (remap_image == (Image ) NULL) { /* Create a global colormap for an image sequence. / status=QuantizeImages(quantize_info,images,exception); return(status); } / Classify image colors from the reference image. / cube_info=GetCubeInfo(quantize_info,MaxTreeDepth, quantize_info->number_colors); if (cube_info == (CubeInfo ) NULL) ThrowBinaryException(ResourceLimitError,"MemoryAllocationFailed", image->filename); status=ClassifyImageColors(cube_info,remap_image,exception); if (status != MagickFalse) { /* Classify image colors from the reference image. / cube_info->quantize_info->number_colors=cube_info->colors; image=images; for ( ; image != (Image ) NULL; image=GetNextImageInList(image)) { status=AssignImageColors(image,cube_info,exception); if (status == MagickFalse) break; } } DestroyCubeInfo(cube_info); return(status); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % S e t G r a y s c a l e I m a g e % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % SetGrayscaleImage() converts an image to a PseudoClass grayscale image. % % The format of the SetGrayscaleImage method is: % % MagickBooleanType SetGrayscaleImage(Image image, % ExceptionInfo exception) % % A description of each parameter follows: % % o image: The image. % % o exception: return any errors or warnings in this structure. % / #if defined(__cplusplus) \|\| defined(c_plusplus) extern "C" { #endif static int IntensityCompare(const void x,const void y) { double intensity; PixelInfo color_1, color_2; color_1=(PixelInfo ) x; color_2=(PixelInfo ) y; intensity=GetPixelInfoIntensity((const Image ) NULL,color_1)- GetPixelInfoIntensity((const Image ) NULL,color_2); if (intensity < (double) INT_MIN) intensity=(double) INT_MIN; if (intensity > (double) INT_MAX) intensity=(double) INT_MAX; return((int) intensity); } #if defined(__cplusplus) \|\| defined(c_plusplus) } #endif static MagickBooleanType SetGrayscaleImage(Image image, ExceptionInfo exception) { CacheView image_view; MagickBooleanType status; PixelInfo colormap; size_t extent; ssize_t colormap_index, i, j, y; assert(image != (Image ) NULL); assert(image->signature == MagickCoreSignature); if (image->type != GrayscaleType) (void) TransformImageColorspace(image,GRAYColorspace,exception); extent=MagickMax(image->colors+1,MagickMax(MaxColormapSize,MaxMap+1)); colormap_index=(ssize_t ) AcquireQuantumMemory(extent, sizeof(colormap_index)); if (colormap_index == (ssize_t ) NULL) ThrowBinaryException(ResourceLimitError,"MemoryAllocationFailed", image->filename); if (image->storage_class != PseudoClass) { (void) memset(colormap_index,(-1),extentsizeof(colormap_index)); if (AcquireImageColormap(image,MaxColormapSize,exception) == MagickFalse) { colormap_index=(ssize_t ) RelinquishMagickMemory(colormap_index); ThrowBinaryException(ResourceLimitError,"MemoryAllocationFailed", image->filename); } image->colors=0; status=MagickTrue; image_view=AcquireAuthenticCacheView(image,exception); #if defined(MAGICKCORE_OPENMP_SUPPORT) #pragma omp parallel for schedule(static) shared(status) \ magick_number_threads(image,image,image->rows,1) #endif for (y=0; y < (ssize_t) image->rows; y++) { Quantum magick_restrict q; ssize_t x; if (status == MagickFalse) continue; q=GetCacheViewAuthenticPixels(image_view,0,y,image->columns,1, exception); if (q == (Quantum ) NULL) { status=MagickFalse; continue; } for (x=0; x < (ssize_t) image->columns; x++) { size_t intensity; intensity=ScaleQuantumToMap(GetPixelRed(image,q)); if (colormap_index[intensity] < 0) { #if defined(MAGICKCORE_OPENMP_SUPPORT) #pragma omp critical (MagickCore_SetGrayscaleImage) #endif if (colormap_index[intensity] < 0) { colormap_index[intensity]=(ssize_t) image->colors; image->colormap[image->colors].red=(double) GetPixelRed(image,q); image->colormap[image->colors].green=(double) GetPixelGreen(image,q); image->colormap[image->colors].blue=(double) GetPixelBlue(image,q); image->colors++; } } SetPixelIndex(image,(Quantum) colormap_index[intensity],q); q+=GetPixelChannels(image); } if (SyncCacheViewAuthenticPixels(image_view,exception) == MagickFalse) status=MagickFalse; } image_view=DestroyCacheView(image_view); } (void) memset(colormap_index,0,extentsizeof(colormap_index)); for (i=0; i < (ssize_t) image->colors; i++) image->colormap[i].alpha=(double) i; qsort((void ) image->colormap,image->colors,sizeof(PixelInfo), IntensityCompare); colormap=(PixelInfo ) AcquireQuantumMemory(image->colors,sizeof(colormap)); if (colormap == (PixelInfo ) NULL) { colormap_index=(ssize_t ) RelinquishMagickMemory(colormap_index); ThrowBinaryException(ResourceLimitError,"MemoryAllocationFailed", image->filename); } j=0; colormap[j]=image->colormap[0]; for (i=0; i < (ssize_t) image->colors; i++) { if (IsPixelInfoEquivalent(&colormap[j],&image->colormap[i]) == MagickFalse) { j++; colormap[j]=image->colormap[i]; } colormap_index[(ssize_t) image->colormap[i].alpha]=j; } image->colors=(size_t) (j+1); image->colormap=(PixelInfo ) RelinquishMagickMemory(image->colormap); image->colormap=colormap; status=MagickTrue; image_view=AcquireAuthenticCacheView(image,exception); #if defined(MAGICKCORE_OPENMP_SUPPORT) #pragma omp parallel for schedule(static) shared(status) \ magick_number_threads(image,image,image->rows,1) #endif for (y=0; y < (ssize_t) image->rows; y++) { Quantum magick_restrict q; ssize_t x; if (status == MagickFalse) continue; q=GetCacheViewAuthenticPixels(image_view,0,y,image->columns,1,exception); if (q == (Quantum ) NULL) { status=MagickFalse; continue; } for (x=0; x < (ssize_t) image->columns; x++) { SetPixelIndex(image,(Quantum) colormap_index[ScaleQuantumToMap( GetPixelIndex(image,q))],q); q+=GetPixelChannels(image); } if (SyncCacheViewAuthenticPixels(image_view,exception) == MagickFalse) status=MagickFalse; } image_view=DestroyCacheView(image_view); colormap_index=(ssize_t ) RelinquishMagickMemory(colormap_index); image->type=GrayscaleType; if (SetImageMonochrome(image,exception) != MagickFalse) image->type=BilevelType; return(status); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % + S e t I m a g e C o l o r m a p % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % SetImageColormap() traverses the color cube tree and sets the colormap of % the image. A colormap entry is any node in the color cube tree where the % of unique colors is not zero. % % The format of the SetImageColormap method is: % % MagickBooleanType SetImageColormap(Image image,CubeInfo cube_info, % ExceptionInfo node_info) % % A description of each parameter follows. % % o image: the image. % % o cube_info: A pointer to the Cube structure. % % o exception: return any errors or warnings in this structure. % / MagickBooleanType SetImageColormap(Image image,CubeInfo cube_info, ExceptionInfo exception) { size_t number_colors; number_colors=MagickMax(cube_info->maximum_colors,cube_info->colors); if (AcquireImageColormap(image,number_colors,exception) == MagickFalse) ThrowBinaryException(ResourceLimitError,"MemoryAllocationFailed", image->filename); image->colors=0; DefineImageColormap(image,cube_info,cube_info->root); if (image->colors != number_colors) { image->colormap=(PixelInfo ) ResizeQuantumMemory(image->colormap, image->colors+1,sizeof(image->colormap)); if (image->colormap == (PixelInfo ) NULL) ThrowBinaryException(ResourceLimitError,"MemoryAllocationFailed", image->filename); } return(MagickTrue); }
GB_bitmap_assign_M_row_template.c	//------------------------------------------------------------------------------ // GB_bitmap_assign_M_row_template: traverse M for GB_ROW_ASSIGN //------------------------------------------------------------------------------ // SuiteSparse:GraphBLAS, Timothy A. Davis, (c) 2017-2021, All Rights Reserved. // SPDX-License-Identifier: Apache-2.0 //------------------------------------------------------------------------------ // M is a 1-by-(C->vdim) hypersparse or sparse matrix, not a vector, for // GrB_Row_assign (if C is CSC) or GrB_Col_assign (if C is CSR). // C is bitmap/full. M is sparse/hyper, and can be jumbled. { const int64_t restrict kfirst_Mslice = M_ek_slicing ; const int64_t restrict klast_Mslice = M_ek_slicing + M_ntasks ; const int64_t restrict pstart_Mslice = M_ek_slicing + M_ntasks 2 ; ASSERT (mvlen == 1) ; int64_t iC = I [0] ; int tid ; #pragma omp parallel for num_threads(M_nthreads) schedule(dynamic,1) \ reduction(+:cnvals) for (tid = 0 ; tid < M_ntasks ; tid++) { int64_t kfirst = kfirst_Mslice [tid] ; int64_t klast = klast_Mslice [tid] ; int64_t task_cnvals = 0 ; //---------------------------------------------------------------------- // traverse over M (0,kfirst:klast) //---------------------------------------------------------------------- for (int64_t k = kfirst ; k <= klast ; k++) { //------------------------------------------------------------------ // find the part of M(0,k) for this task //------------------------------------------------------------------ int64_t jM = GBH (Mh, k) ; int64_t pM_start, pM_end ; GB_get_pA (&pM_start, &pM_end, tid, k, kfirst, klast, pstart_Mslice, Mp, mvlen) ; //------------------------------------------------------------------ // traverse over M(0,jM), the kth vector of M //------------------------------------------------------------------ // for row_assign: M is a single row, iC = I [0] // It has either 0 or 1 entry. int64_t pM = pM_start ; if (pM < pM_end) { bool mij = GB_mcast (Mx, pM, msize) ; if (mij) { int64_t jC = jM ; int64_t pC = iC + jC * cvlen ; GB_MASK_WORK (pC) ; } } } cnvals += task_cnvals ; } }
gather.c	#include "../../shared.h" #include "hale.h" #include <float.h> #include <math.h> #include <stdio.h> // Gathers all of the subcell quantities on the mesh void gather_subcell_mass_and_energy( const int ncells, const int nnodes, double* cell_centroids_x, double* cell_centroids_y, double* cell_centroids_z, int* cells_to_nodes_offsets, const double* nodes_x, const double* nodes_y, const double* nodes_z, const double* cell_volume, double* energy, double* density, double* velocity_x, double* velocity_y, double* velocity_z, double* ke_mass, double* cell_mass, double* subcell_mass, double* subcell_volume, double* subcell_ie_mass, double* subcell_ke_mass, double* subcell_centroids_x, double* subcell_centroids_y, double* subcell_centroids_z, int* faces_to_cells0, int* faces_to_cells1, int* cells_to_faces_offsets, int* cells_to_faces, int* cells_to_nodes, int* nodes_to_cells_offsets, int* nodes_to_cells, double* initial_mass, double* initial_ie_mass, double* initial_ke_mass); // Gathers the momentum into the subcells void gather_subcell_momentum( const int nnodes, const double* nodal_volumes, const double* nodal_mass, int* nodes_to_cells, const double* nodes_x, const double* nodes_y, const double* nodes_z, double* velocity_x, double* velocity_y, double* velocity_z, double* subcell_volume, double* cell_centroids_x, double* cell_centroids_y, double* cell_centroids_z, double* subcell_momentum_x, double* subcell_momentum_y, double* subcell_momentum_z, double* subcell_centroids_x, double* subcell_centroids_y, double* subcell_centroids_z, int* nodes_to_cells_offsets, int* cells_to_nodes_offsets, int* cells_to_nodes, int* nodes_to_nodes_offsets, int* nodes_to_nodes, vec_t* initial_momentum); // gathers all of the subcell quantities on the mesh void gather_subcell_quantities(UnstructuredMesh* umesh, HaleData* hale_data, vec_t* initial_momentum, double* initial_mass, double* initial_ie_mass, double* initial_ke_mass) { /* * GATHERING STAGE OF THE REMAP / // Calculates the cell volume, subcell volume and the subcell centroids calc_volumes_centroids( umesh->ncells, umesh->nnodes, hale_data->nnodes_by_subcell, umesh->cells_to_nodes_offsets, umesh->cells_to_nodes, hale_data->subcells_to_faces_offsets, hale_data->subcells_to_faces, umesh->faces_to_nodes, umesh->faces_to_nodes_offsets, umesh->faces_cclockwise_cell, umesh->nodes_x0, umesh->nodes_y0, umesh->nodes_z0, hale_data->subcell_centroids_x, hale_data->subcell_centroids_y, hale_data->subcell_centroids_z, hale_data->subcell_volume, hale_data->cell_volume, hale_data->nodal_volumes, umesh->nodes_to_cells_offsets, umesh->nodes_to_cells); // Gathers all of the subcell quantities on the mesh gather_subcell_mass_and_energy( umesh->ncells, umesh->nnodes, umesh->cell_centroids_x, umesh->cell_centroids_y, umesh->cell_centroids_z, umesh->cells_to_nodes_offsets, umesh->nodes_x0, umesh->nodes_y0, umesh->nodes_z0, hale_data->cell_volume, hale_data->energy0, hale_data->density0, hale_data->velocity_x0, hale_data->velocity_y0, hale_data->velocity_z0, hale_data->ke_mass, hale_data->cell_mass, hale_data->subcell_mass, hale_data->subcell_volume, hale_data->subcell_ie_mass, hale_data->subcell_ke_mass, hale_data->subcell_centroids_x, hale_data->subcell_centroids_y, hale_data->subcell_centroids_z, umesh->faces_to_cells0, umesh->faces_to_cells1, umesh->cells_to_faces_offsets, umesh->cells_to_faces, umesh->cells_to_nodes, umesh->nodes_to_cells_offsets, umesh->nodes_to_cells, initial_mass, initial_ie_mass, initial_ke_mass); // Gathers the momentum the subcells gather_subcell_momentum( umesh->nnodes, hale_data->nodal_volumes, hale_data->nodal_mass, umesh->nodes_to_cells, umesh->nodes_x0, umesh->nodes_y0, umesh->nodes_z0, hale_data->velocity_x0, hale_data->velocity_y0, hale_data->velocity_z0, hale_data->subcell_volume, umesh->cell_centroids_x, umesh->cell_centroids_y, umesh->cell_centroids_z, hale_data->subcell_momentum_x, hale_data->subcell_momentum_y, hale_data->subcell_momentum_z, hale_data->subcell_centroids_x, hale_data->subcell_centroids_y, hale_data->subcell_centroids_z, umesh->nodes_to_cells_offsets, umesh->cells_to_nodes_offsets, umesh->cells_to_nodes, umesh->nodes_to_nodes_offsets, umesh->nodes_to_nodes, initial_momentum); } // Gathers all of the subcell quantities on the mesh void gather_subcell_mass_and_energy( const int ncells, const int nnodes, double cell_centroids_x, double* cell_centroids_y, double* cell_centroids_z, int* cells_to_nodes_offsets, const double* nodes_x, const double* nodes_y, const double* nodes_z, const double* cell_volume, double* energy, double* density, double* velocity_x, double* velocity_y, double* velocity_z, double* ke_mass, double* cell_mass, double* subcell_mass, double* subcell_volume, double* subcell_ie_mass, double* subcell_ke_mass, double* subcell_centroids_x, double* subcell_centroids_y, double* subcell_centroids_z, int* faces_to_cells0, int* faces_to_cells1, int* cells_to_faces_offsets, int* cells_to_faces, int* cells_to_nodes, int* nodes_to_cells_offsets, int* nodes_to_cells, double* initial_mass, double* initial_ie_mass, double* initial_ke_mass) { double total_mass = 0.0; double total_ie_mass = 0.0; double total_ke_mass = 0.0; // We first have to determine the cell centered kinetic energy #pragma omp parallel for reduction(+ : total_ke_mass) for (int cc = 0; cc < ncells; ++cc) { const int cell_to_nodes_off = cells_to_nodes_offsets[(cc)]; const int nnodes_by_cell = cells_to_nodes_offsets[(cc + 1)] - cell_to_nodes_off; ke_mass[(cc)] = 0.0; // Subcells are ordered with the nodes on a face for (int nn = 0; nn < nnodes_by_cell; ++nn) { const int node_index = cells_to_nodes[(cell_to_nodes_off + nn)]; const int subcell_index = cell_to_nodes_off + nn; ke_mass[(cc)] += subcell_mass[(subcell_index)] * 0.5 * (velocity_x[(node_index)] * velocity_x[(node_index)] + velocity_y[(node_index)] * velocity_y[(node_index)] + velocity_z[(node_index)] * velocity_z[(node_index)]); } total_ke_mass += ke_mass[(cc)]; } double total_ie_in_subcells = 0.0; double total_ke_in_subcells = 0.0; // Calculate the sub-cell internal and kinetic energies #pragma omp parallel for reduction(+ : total_mass, total_ie_mass, \ total_ie_in_subcells, total_ke_in_subcells) for (int cc = 0; cc < ncells; ++cc) { // Calculating the volume dist necessary for the least squares // regression const int cell_to_faces_off = cells_to_faces_offsets[(cc)]; const int nfaces_by_cell = cells_to_faces_offsets[(cc + 1)] - cell_to_faces_off; const int cell_to_nodes_off = cells_to_nodes_offsets[(cc)]; const int nnodes_by_cell = cells_to_nodes_offsets[(cc + 1)] - cell_to_nodes_off; const double cell_ie = density[(cc)] * energy[(cc)]; const double cell_ke = ke_mass[(cc)] / cell_volume[(cc)]; vec_t cell_c = {0.0, 0.0, 0.0}; calc_centroid(nnodes_by_cell, nodes_x, nodes_y, nodes_z, cells_to_nodes, cell_to_nodes_off, &cell_c); vec_t ie_rhs = {0.0, 0.0, 0.0}; vec_t ke_rhs = {0.0, 0.0, 0.0}; vec_t coeff[3] = {{0.0, 0.0, 0.0}}; total_mass += cell_mass[(cc)]; total_ie_mass += cell_mass[(cc)] * energy[(cc)]; // Determine the weighted volume dist for neighbouring cells double gmax_ie = -DBL_MAX; double gmin_ie = DBL_MAX; double gmax_ke = -DBL_MAX; double gmin_ke = DBL_MAX; for (int ff = 0; ff < nfaces_by_cell; ++ff) { const int face_index = cells_to_faces[(cell_to_faces_off + ff)]; const int neighbour_index = (faces_to_cells0[(face_index)] == cc) ? faces_to_cells1[(face_index)] : faces_to_cells0[(face_index)]; // Check if boundary face if (neighbour_index == -1) { continue; } vec_t dist = {cell_centroids_x[(neighbour_index)] - cell_c.x, cell_centroids_y[(neighbour_index)] - cell_c.y, cell_centroids_z[(neighbour_index)] - cell_c.z}; // Store the neighbouring cell's contribution to the coefficients double neighbour_vol = cell_volume[(neighbour_index)]; coeff[0].x += 2.0 * (dist.x * dist.x) / (neighbour_vol * neighbour_vol); coeff[0].y += 2.0 * (dist.x * dist.y) / (neighbour_vol * neighbour_vol); coeff[0].z += 2.0 * (dist.x * dist.z) / (neighbour_vol * neighbour_vol); coeff[1].x += 2.0 * (dist.y * dist.x) / (neighbour_vol * neighbour_vol); coeff[1].y += 2.0 * (dist.y * dist.y) / (neighbour_vol * neighbour_vol); coeff[1].z += 2.0 * (dist.y * dist.z) / (neighbour_vol * neighbour_vol); coeff[2].x += 2.0 * (dist.z * dist.x) / (neighbour_vol * neighbour_vol); coeff[2].y += 2.0 * (dist.z * dist.y) / (neighbour_vol * neighbour_vol); coeff[2].z += 2.0 * (dist.z * dist.z) / (neighbour_vol * neighbour_vol); const double neighbour_ie = density[(neighbour_index)] * energy[(neighbour_index)]; const double neighbour_ke = ke_mass[(neighbour_index)] / neighbour_vol; gmax_ie = max(gmax_ie, neighbour_ie); gmin_ie = min(gmin_ie, neighbour_ie); gmax_ke = max(gmax_ke, neighbour_ke); gmin_ke = min(gmin_ke, neighbour_ke); // Prepare the RHS, which includes energy differential const double die = (neighbour_ie - cell_ie); const double dke = (neighbour_ke - cell_ke); ie_rhs.x += 2.0 * (dist.x * die) / neighbour_vol; ie_rhs.y += 2.0 * (dist.y * die) / neighbour_vol; ie_rhs.z += 2.0 * (dist.z * die) / neighbour_vol; ke_rhs.x += 2.0 * (dist.x * dke) / neighbour_vol; ke_rhs.y += 2.0 * (dist.y * dke) / neighbour_vol; ke_rhs.z += 2.0 * (dist.z * dke) / neighbour_vol; } // Determine the inverse of the coefficient matrix vec_t inv[3]; calc_3x3_inverse(&coeff, &inv); // Solve for the internal and kinetic energy gradients vec_t grad_ie = { inv[0].x * ie_rhs.x + inv[0].y * ie_rhs.y + inv[0].z * ie_rhs.z, inv[1].x * ie_rhs.x + inv[1].y * ie_rhs.y + inv[1].z * ie_rhs.z, inv[2].x * ie_rhs.x + inv[2].y * ie_rhs.y + inv[2].z * ie_rhs.z}; vec_t grad_ke = { inv[0].x * ke_rhs.x + inv[0].y * ke_rhs.y + inv[0].z * ke_rhs.z, inv[1].x * ke_rhs.x + inv[1].y * ke_rhs.y + inv[1].z * ke_rhs.z, inv[2].x * ke_rhs.x + inv[2].y * ke_rhs.y + inv[2].z * ke_rhs.z}; // Calculate the limiter for the gradient double limiter = 1.0; for (int nn = 0; nn < nnodes_by_cell; ++nn) { const int node_index = cells_to_nodes[(cell_to_nodes_off + nn)]; limiter = min(limiter, calc_cell_limiter(cell_ie, gmax_ie, gmin_ie, &grad_ie, nodes_x[(node_index)], nodes_y[(node_index)], nodes_z[(node_index)], &cell_c)); } // This stops extrema from worsening as part of the gather. Is it // conservative? grad_ie.x = limiter; grad_ie.y = limiter; grad_ie.z = limiter; // Calculate the limiter for the gradient limiter = 1.0; for (int nn = 0; nn < nnodes_by_cell; ++nn) { const int node_index = cells_to_nodes[(cell_to_nodes_off + nn)]; limiter = min(limiter, calc_cell_limiter(cell_ke, gmax_ke, gmin_ke, &grad_ke, nodes_x[(node_index)], nodes_y[(node_index)], nodes_z[(node_index)], &cell_c)); } // This stops extrema from worsening as part of the gather. Is it // conservative? grad_ie.x = limiter; grad_ie.y = limiter; grad_ie.z = limiter; // Subcells are ordered with the nodes on a face for (int nn = 0; nn < nnodes_by_cell; ++nn) { const int subcell_index = cell_to_nodes_off + nn; // Calculate the center of mass distance const double dx = subcell_centroids_x[(subcell_index)] - cell_c.x; const double dy = subcell_centroids_y[(subcell_index)] - cell_c.y; const double dz = subcell_centroids_z[(subcell_index)] - cell_c.z; // Subcell internal and kinetic energy from linear function at cell subcell_ie_mass[(subcell_index)] = subcell_volume[(subcell_index)] * (cell_ie + grad_ie.x * dx + grad_ie.y * dy + grad_ie.z * dz); subcell_ke_mass[(subcell_index)] = subcell_volume[(subcell_index)] * (cell_ke + grad_ke.x * dx + grad_ke.y * dy + grad_ke.z * dz); total_ie_in_subcells += subcell_ie_mass[(subcell_index)]; total_ke_in_subcells += subcell_ke_mass[(subcell_index)]; if (subcell_ie_mass[(subcell_index)] < -EPS \|\| subcell_ke_mass[(subcell_index)] < -EPS) { printf("Negative energy mass %d %.12f %.12f\n", subcell_index, subcell_ie_mass[(subcell_index)], subcell_ke_mass[(subcell_index)]); } } } initial_mass = total_mass; initial_ie_mass = total_ie_in_subcells; initial_ke_mass = total_ke_in_subcells; printf("Total Energy in Cells %.12f\n", total_ie_mass + total_ke_mass); printf("Total Energy in Subcells %.12f\n", total_ie_in_subcells + total_ke_in_subcells); printf("Difference %.12f\n\n", (total_ie_mass + total_ke_mass) - (total_ie_in_subcells + total_ke_in_subcells)); } // Gathers the momentum into the subcells void gather_subcell_momentum( const int nnodes, const double nodal_volumes, const double* nodal_mass, int* nodes_to_cells, const double* nodes_x, const double* nodes_y, const double* nodes_z, double* velocity_x, double* velocity_y, double* velocity_z, double* subcell_volume, double* cell_centroids_x, double* cell_centroids_y, double* cell_centroids_z, double* subcell_momentum_x, double* subcell_momentum_y, double* subcell_momentum_z, double* subcell_centroids_x, double* subcell_centroids_y, double* subcell_centroids_z, int* nodes_to_cells_offsets, int* cells_to_nodes_offsets, int* cells_to_nodes, int* nodes_to_nodes_offsets, int* nodes_to_nodes, vec_t* initial_momentum) { double initial_momentum_x = 0.0; double initial_momentum_y = 0.0; double initial_momentum_z = 0.0; double total_subcell_vx = 0.0; double total_subcell_vy = 0.0; double total_subcell_vz = 0.0; #pragma omp parallel for reduction(+ : initial_momentum_x, initial_momentum_y, \ initial_momentum_z, total_subcell_vx, \ total_subcell_vy, total_subcell_vz) for (int nn = 0; nn < nnodes; ++nn) { // Calculate the gradient for the nodal momentum vec_t rhsx = {0.0, 0.0, 0.0}; vec_t rhsy = {0.0, 0.0, 0.0}; vec_t rhsz = {0.0, 0.0, 0.0}; vec_t coeff[3] = {{0.0, 0.0, 0.0}}; vec_t gmin = {DBL_MAX, DBL_MAX, DBL_MAX}; vec_t gmax = {-DBL_MAX, -DBL_MAX, -DBL_MAX}; vec_t node = {nodes_x[(nn)], nodes_y[(nn)], nodes_z[(nn)]}; const double nodal_density = nodal_mass[(nn)] / nodal_volumes[(nn)]; vec_t node_mom_density = {nodal_density * velocity_x[(nn)], nodal_density * velocity_y[(nn)], nodal_density * velocity_z[(nn)]}; initial_momentum_x += nodal_mass[(nn)] * velocity_x[(nn)]; initial_momentum_y += nodal_mass[(nn)] * velocity_y[(nn)]; initial_momentum_z += nodal_mass[(nn)] * velocity_z[(nn)]; const int node_to_nodes_off = nodes_to_nodes_offsets[(nn)]; const int nnodes_by_node = nodes_to_nodes_offsets[(nn + 1)] - node_to_nodes_off; for (int nn2 = 0; nn2 < nnodes_by_node; ++nn2) { const int neighbour_index = nodes_to_nodes[(node_to_nodes_off + nn2)]; if (neighbour_index == -1) { continue; } // Calculate the center of mass distance vec_t i = {nodes_x[(neighbour_index)] - node.x, nodes_y[(neighbour_index)] - node.y, nodes_z[(neighbour_index)] - node.z}; // Store the neighbouring cell's contribution to the coefficients double neighbour_vol = nodal_volumes[(neighbour_index)]; coeff[0].x += 2.0 * (i.x * i.x) / (neighbour_vol * neighbour_vol); coeff[0].y += 2.0 * (i.x * i.y) / (neighbour_vol * neighbour_vol); coeff[0].z += 2.0 * (i.x * i.z) / (neighbour_vol * neighbour_vol); coeff[1].x += 2.0 * (i.y * i.x) / (neighbour_vol * neighbour_vol); coeff[1].y += 2.0 * (i.y * i.y) / (neighbour_vol * neighbour_vol); coeff[1].z += 2.0 * (i.y * i.z) / (neighbour_vol * neighbour_vol); coeff[2].x += 2.0 * (i.z * i.x) / (neighbour_vol * neighbour_vol); coeff[2].y += 2.0 * (i.z * i.y) / (neighbour_vol * neighbour_vol); coeff[2].z += 2.0 * (i.z * i.z) / (neighbour_vol * neighbour_vol); const double neighbour_nodal_density = nodal_mass[(neighbour_index)] / nodal_volumes[(neighbour_index)]; vec_t neighbour_mom_density = { neighbour_nodal_density * velocity_x[(neighbour_index)], neighbour_nodal_density * velocity_y[(neighbour_index)], neighbour_nodal_density * velocity_z[(neighbour_index)]}; gmax.x = max(gmax.x, neighbour_mom_density.x); gmin.x = min(gmin.x, neighbour_mom_density.x); gmax.y = max(gmax.y, neighbour_mom_density.y); gmin.y = min(gmin.y, neighbour_mom_density.y); gmax.z = max(gmax.z, neighbour_mom_density.z); gmin.z = min(gmin.z, neighbour_mom_density.z); vec_t dv = {(neighbour_mom_density.x - node_mom_density.x), (neighbour_mom_density.y - node_mom_density.y), (neighbour_mom_density.z - node_mom_density.z)}; rhsx.x += 2.0 * i.x * dv.x / neighbour_vol; rhsx.y += 2.0 * i.y * dv.x / neighbour_vol; rhsx.z += 2.0 * i.z * dv.x / neighbour_vol; rhsy.x += 2.0 * i.x * dv.y / neighbour_vol; rhsy.y += 2.0 * i.y * dv.y / neighbour_vol; rhsy.z += 2.0 * i.z * dv.y / neighbour_vol; rhsz.x += 2.0 * i.x * dv.z / neighbour_vol; rhsz.y += 2.0 * i.y * dv.z / neighbour_vol; rhsz.z += 2.0 * i.z * dv.z / neighbour_vol; } // Determine the inverse of the coefficient matrix vec_t inv[3]; calc_3x3_inverse(&coeff, &inv); // Solve for the velocity density gradients vec_t grad_vx = {inv[0].x * rhsx.x + inv[0].y * rhsx.y + inv[0].z * rhsx.z, inv[1].x * rhsx.x + inv[1].y * rhsx.y + inv[1].z * rhsx.z, inv[2].x * rhsx.x + inv[2].y * rhsx.y + inv[2].z * rhsx.z}; vec_t grad_vy = {inv[0].x * rhsy.x + inv[0].y * rhsy.y + inv[0].z * rhsy.z, inv[1].x * rhsy.x + inv[1].y * rhsy.y + inv[1].z * rhsy.z, inv[2].x * rhsy.x + inv[2].y * rhsy.y + inv[2].z * rhsy.z}; vec_t grad_vz = {inv[0].x * rhsz.x + inv[0].y * rhsz.y + inv[0].z * rhsz.z, inv[1].x * rhsz.x + inv[1].y * rhsz.y + inv[1].z * rhsz.z, inv[2].x * rhsz.x + inv[2].y * rhsz.y + inv[2].z * rhsz.z}; // Limit the gradients double vx_limiter = 1.0; double vy_limiter = 1.0; double vz_limiter = 1.0; const int node_to_cells_off = nodes_to_cells_offsets[(nn)]; const int ncells_by_node = nodes_to_cells_offsets[(nn + 1)] - node_to_cells_off; for (int cc = 0; cc < ncells_by_node; ++cc) { const int cell_index = nodes_to_cells[(node_to_cells_off + cc)]; vec_t cell_c = {cell_centroids_x[(cell_index)], cell_centroids_y[(cell_index)], cell_centroids_z[(cell_index)]}; vx_limiter = min(vx_limiter, calc_cell_limiter(node_mom_density.x, gmax.x, gmin.x, &grad_vx, cell_c.x, cell_c.y, cell_c.z, &node)); vy_limiter = min(vy_limiter, calc_cell_limiter(node_mom_density.y, gmax.y, gmin.y, &grad_vy, cell_c.x, cell_c.y, cell_c.z, &node)); vz_limiter = min(vz_limiter, calc_cell_limiter(node_mom_density.z, gmax.z, gmin.z, &grad_vz, cell_c.x, cell_c.y, cell_c.z, &node)); } // This stops extrema from worsening as part of the gather. Is it // conservative? grad_vx.x = vx_limiter; grad_vx.y = vx_limiter; grad_vx.z = vx_limiter; grad_vy.x = vy_limiter; grad_vy.y = vy_limiter; grad_vy.z = vy_limiter; grad_vz.x = vz_limiter; grad_vz.y = vz_limiter; grad_vz.z = vz_limiter; for (int cc = 0; cc < ncells_by_node; ++cc) { const int cell_index = nodes_to_cells[(node_to_cells_off + cc)]; const int cell_to_nodes_off = cells_to_nodes_offsets[(cell_index)]; const int nnodes_by_cell = cells_to_nodes_offsets[(cell_index + 1)] - cell_to_nodes_off; // Determine the position of the node in the cell int nn2; for (nn2 = 0; nn2 < nnodes_by_cell; ++nn2) { if (cells_to_nodes[(cell_to_nodes_off + nn2)] == nn) { break; } } const int subcell_index = cell_to_nodes_off + nn2; const double vol = subcell_volume[(subcell_index)]; const double dx = subcell_centroids_x[(subcell_index)] - nodes_x[(nn)]; const double dy = subcell_centroids_y[(subcell_index)] - nodes_y[(nn)]; const double dz = subcell_centroids_z[(subcell_index)] - nodes_z[(nn)]; subcell_momentum_x[(subcell_index)] = vol (node_mom_density.x + grad_vx.x * dx + grad_vx.y * dy + grad_vx.z * dz); subcell_momentum_y[(subcell_index)] = vol * (node_mom_density.y + grad_vy.x * dx + grad_vy.y * dy + grad_vy.z * dz); subcell_momentum_z[(subcell_index)] = vol * (node_mom_density.z + grad_vz.x * dx + grad_vz.y * dy + grad_vz.z * dz); total_subcell_vx += subcell_momentum_x[(subcell_index)]; total_subcell_vy += subcell_momentum_y[(subcell_index)]; total_subcell_vz += subcell_momentum_z[(subcell_index)]; } } initial_momentum->x = total_subcell_vx; initial_momentum->y = total_subcell_vy; initial_momentum->z = total_subcell_vz; printf("Total Momentum in Cells (%.12f,%.12f,%.12f)\n", initial_momentum_x, initial_momentum_y, initial_momentum_z); printf("Total Momentum in Subcells (%.12f,%.12f,%.12f)\n", total_subcell_vx, total_subcell_vy, total_subcell_vz); printf("Difference (%.12f,%.12f,%.12f)\n\n", initial_momentum_x - total_subcell_vx, initial_momentum_y - total_subcell_vy, initial_momentum_z - total_subcell_vz); }
totientRangeParallel.c	// TotientRangePar.c - Parallel Euler Totient Function (C Version) // compile: gcc -Wall -O2 -o TotientRangePar TotientRangePar.c // run: ./TotientRangePar lower_num upper_num num_threads(optional) // Author: Max Kirker Burton 2260452b 13/11/19 // This program calculates the sum of the totients between a lower and an // upper limit using C longs, and can be run with several Goroutines either set as an argument or // as an environment variable // It is based on earlier work by: // Phil Trinder, Nathan Charles, Hans-Wolfgang Loidl and Colin Runciman // The comments provide (executable) Haskell specifications of the functions #include <stdio.h> #include <omp.h> #include <sys/time.h> // hcf x 0 = x // hcf x y = hcf y (rem x y) long hcf(long x, long y) { long t; while (y != 0) { t = x % y; x = y; y = t; } return x; } // relprime x y = hcf x y == 1 int relprime(long x, long y) { return hcf(x, y) == 1; } // euler n = length (filter (relprime n) [1 .. n-1]) long euler(long n) { long length, i; length = 0; for (i = 1; i < n; i++) if (relprime(n, i)) length += 1; return length; } // sumTotient lower upper = sum (map euler [lower, lower+1 .. upper]) long sumTotient(long lower, long upper, int n_threads) { long sum = 0, i; #pragma omp parallel for schedule(guided) reduction(+: sum) num_threads(n_threads) for (i = lower; i <= upper; i++){ sum += euler(i); } return sum; } int main(int argc, char ** argv) { long lower, upper; int num_threads = omp_get_num_threads(); float msec; struct timeval start, stop; if (argc < 3) { printf("fewer than 2 arguments\n"); return 1; } sscanf(argv[1], "%ld", &lower); sscanf(argv[2], "%ld", &upper); if (argc == 4){ sscanf(argv[3], "%d", &num_threads); } gettimeofday(&start, NULL); printf("C: Sum of Totients between [%ld..%ld] is %ld\n", lower, upper, sumTotient(lower, upper, num_threads)); gettimeofday(&stop, NULL); if (stop.tv_usec < start.tv_usec) { stop.tv_usec += 1000000; stop.tv_sec--; } msec = 1000 * (stop.tv_sec - start.tv_sec) + (stop.tv_usec - start.tv_usec) / 1000; printf("%f\n", msec); // Rename to elapsed time: return 0; }
ragf2.c	/* Copyright 2014-2020 The PySCF Developers. All Rights Reserved. Licensed under the Apache License, Version 2.0 (the "License"); you may not use this file except in compliance with the License. You may obtain a copy of the License at http://www.apache.org/licenses/LICENSE-2.0 Unless required by applicable law or agreed to in writing, software distributed under the License is distributed on an "AS IS" BASIS, WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. See the License for the specific language governing permissions and limitations under the License. * * Author: Oliver J. Backhouse <olbackhouse@gmail.com> * Alejandro Santana-Bonilla <alejandro.santana_bonilla@kcl.ac.uk> * George H. Booth <george.booth@kcl.ac.uk> / #include<stdlib.h> #include<assert.h> #include<math.h> //#include "omp.h" #include "config.h" #include "vhf/fblas.h" / * b_x = alpha * a_x + beta * b_x / void AGF2sum_inplace(double a, double b, int x, double alpha, double beta) { int i; for (i = 0; i < x; i++) { b[i] = beta; b[i] += alpha * a[i]; } } /* * b_x = a_x * b_x / void AGF2prod_inplace(double a, double b, int x) { int i; for (i = 0; i < x; i++) { b[i] = a[i]; } } /* * c_x = a_x * b_x / void AGF2prod_outplace(double a, double b, int x, double c) { int i; for (i = 0; i < x; i++) { c[i] = a[i] * b[i]; } } /* * b_xz = a_xiz / void AGF2slice_0i2(double a, int x, int y, int z, int idx, double b) { double pa, pb; int i, k; for (i = 0; i < x; i++) { pb = b + iz; pa = a + iyz + idxz; for (k = 0; k < z; k++) { pb[k] = pa[k]; } } } / * b_xy = a_xyi / void AGF2slice_01i(double a, int x, int y, int z, int idx, double b) { double pa, pb; int i, j; for (i = 0; i < x; i++) { pb = b + iy; pa = a + iyz + idx; for (j = 0; j < y; j++) { pb[j] = pa[jz]; } } } / * d_xy = a + b_x - c_y / void AGF2sum_inplace_ener(double a, double b, double c, int x, int y, double d) { double pd; int i, j; for (i = 0; i < x; i++) { pd = d + iy; for (j = 0; j < y; j++) { pd[j] = a + b[i] - c[j]; } } } /* * b_xy = a_y * b_xy / void AGF2prod_inplace_ener(double a, double b, int x, int y) { double pb; int i; for (i = 0; i < x; i++) { pb = b + iy; AGF2prod_inplace(a, pb, y); } } / * c_xy = a_y * b_xy / void AGF2prod_outplace_ener(double a, double b, int x, int y, double c) { double pb, pc; int i; for (i = 0; i < x; i++) { pb = b + iy; pc = c + iy; AGF2prod_outplace(a, pb, y, pc); } } /* * exact ERI * vv_xy = (xi\|ja) [2(yi\|ja) - (yj\|ia)] * vev_xy = (xi\|ja) [2(yi\|ja) - (yj\|ia)] (ei + ej - ea) / void AGF2ee_vv_vev_islice(double xija, double e_i, double e_a, double os_factor, double ss_factor, int nmo, int nocc, int nvir, int istart, int iend, double vv, double vev) { const double D1 = 1; const char TRANS_T = 'T'; const char TRANS_N = 'N'; const int nja = nocc * nvir; const int nxi = nmo * nocc; const double fpos = os_factor + ss_factor; const double fneg = -1.0 * ss_factor; #pragma omp parallel { double eja = calloc(noccnvir, sizeof(double)); double xia = calloc(nmonoccnvir, sizeof(double)); double xja = calloc(nmonoccnvir, sizeof(double)); double vv_priv = calloc(nmonmo, sizeof(double)); double vev_priv = calloc(nmonmo, sizeof(double)); int i; #pragma omp for for (i = istart; i < iend; i++) { // build xija AGF2slice_0i2(xija, nmo, nocc, nja, i, xja); // build xjia AGF2slice_0i2(xija, nxi, nocc, nvir, i, xia); // build eija = ei + ej - ea AGF2sum_inplace_ener(e_i[i], e_i, e_a, nocc, nvir, eja); // inplace xjia = 2 * xija - xjia AGF2sum_inplace(xja, xia, nmonja, fpos, fneg); // vv_xy += xija (2 yija - yjia) dgemm_(&TRANS_T, &TRANS_N, &nmo, &nmo, &nja, &D1, xia, &nja, xja, &nja, &D1, vv_priv, &nmo); // inplace xija = eija * xija AGF2prod_inplace_ener(eja, xja, nmo, nja); // vev_xy += xija * eija * (2 yija - yjia) dgemm_(&TRANS_T, &TRANS_N, &nmo, &nmo, &nja, &D1, xia, &nja, xja, &nja, &D1, vev_priv, &nmo); } free(eja); free(xia); free(xja); #pragma omp critical for (i = 0; i < (nmonmo); i++) { vv[i] += vv_priv[i]; vev[i] += vev_priv[i]; } free(vv_priv); free(vev_priv); } } / * density fitting * (xi\|ja) = (xi\|Q)(Q\|ja) * vv_xy = (xi\|ja) [2(yi\|ja) - (yj\|ia)] * vev_xy = (xi\|ja) [2(yi\|ja) - (yj\|ia)] (ei + ej - ea) / void AGF2df_vv_vev_islice(double qxi, double qja, double e_i, double e_a, double os_factor, double ss_factor, int nmo, int nocc, int nvir, int naux, int istart, int iend, double vv, double vev) { const double D0 = 0.0; const double D1 = 1.0; const char TRANS_T = 'T'; const char TRANS_N = 'N'; const int nja = nocc nvir; const int nxi = nmo * nocc; const double fpos = os_factor + ss_factor; const double fneg = -1.0 * ss_factor; #pragma omp parallel { double qa = calloc(nauxnvir, sizeof(double)); double qx = calloc(nauxnmo, sizeof(double)); double eja = calloc(noccnvir, sizeof(double)); double xia = calloc(nmonoccnvir, sizeof(double)); double xja = calloc(nmonoccnvir, sizeof(double)); double vv_priv = calloc(nmonmo, sizeof(double)); double vev_priv = calloc(nmonmo, sizeof(double)); int i; #pragma omp for for (i = istart; i < iend; i++) { // build qx AGF2slice_01i(qxi, naux, nmo, nocc, i, qx); // build qa AGF2slice_0i2(qja, naux, nocc, nvir, i, qa); // build xija = xq * qja dgemm_(&TRANS_N, &TRANS_T, &nja, &nmo, &naux, &D1, qja, &nja, qx, &nmo, &D0, xja, &nja); // build xjia = xiq * qa dgemm_(&TRANS_N, &TRANS_T, &nvir, &nxi, &naux, &D1, qa, &nvir, qxi, &nxi, &D0, xia, &nvir); //printf("%13.9f %13.9f\n", xja[10], xia[10]); fflush(stdout); // build eija = ei + ej - ea AGF2sum_inplace_ener(e_i[i], e_i, e_a, nocc, nvir, eja); // inplace xjia = 2 * xija - xjia AGF2sum_inplace(xja, xia, nmonja, fpos, fneg); // vv_xy += xija (2 yija - yjia) dgemm_(&TRANS_T, &TRANS_N, &nmo, &nmo, &nja, &D1, xia, &nja, xja, &nja, &D1, vv_priv, &nmo); // inplace xija = eija * xija AGF2prod_inplace_ener(eja, xja, nmo, nja); // vev_xy += xija * eija * (2 yija - yjia) dgemm_(&TRANS_T, &TRANS_N, &nmo, &nmo, &nja, &D1, xia, &nja, xja, &nja, &D1, vev_priv, &nmo); } free(qa); free(qx); free(eja); free(xia); free(xja); #pragma omp critical for (i = 0; i < (nmonmo); i++) { vv[i] += vv_priv[i]; vev[i] += vev_priv[i]; } free(vv_priv); free(vev_priv); } } / * Removes an index from DGEMM and into a for loop to reduce the * thread-private memory overhead, at the cost of serial speed / void AGF2df_vv_vev_islice_lowmem(double qxi, double qja, double e_i, double e_a, double os_factor, double ss_factor, int nmo, int nocc, int nvir, int naux, int start, int end, double vv, double vev) { const double D0 = 0.0; const double D1 = 1.0; const char TRANS_T = 'T'; const char TRANS_N = 'N'; const int one = 1; const double fpos = os_factor + ss_factor; const double fneg = -1.0 ss_factor; //#pragma omp parallel //{ // double xj = calloc(nmonocc, sizeof(double)); // double xi = calloc(nmonocc, sizeof(double)); // double qx = calloc(nauxnmo, sizeof(double)); // double qj = calloc(nauxnocc, sizeof(double)); // double ej = calloc(nocc, sizeof(double)); // // double vv_priv = calloc(nmonmo, sizeof(double)); // double vev_priv = calloc(nmonmo, sizeof(double)); // // int i, a, ia; // //#pragma omp for // for (ia = start; ia < end; ia++) { // i = ia / nvir; // a = ia % nvir; // // // build qx // AGF2slice_01i(qxi, naux, nmo, nocc, i, qx); // // // build qj // AGF2slice_01i(qja, naux, nocc, nvir, a, qj); // // // build xj = xq qj // dgemm_(&TRANS_N, &TRANS_T, &nocc, &nmo, &naux, &D1, qj, &nocc, qx, &nmo, &D0, xj, &nocc); // // // build xi = xiq * q is this slow without incx=1? // dgemv_(&TRANS_N, &nxi, &naux, &D1, qxi, &nxi, &(qja[invir+a]), &nja, &D0, xi, &one); // // // build eija = ei + ej - ea // AGF2sum_inplace_ener(e_i[i], e_i, &(e_a[a]), nocc, one, ej); // // // inplace xi = 2 xj - xi // AGF2sum_inplace(xi, xj, nxi, fpos, fneg); // // // vv_xy += xj * (2 * yj - yi) // dgemm_(&TRANS_T, &TRANS_N, &nmo, &nmo, &nocc, &D1, xi, &nocc, xj, &nocc, &D1, vv_priv, &nmo); // // // inplace xj = ej * xj // AGF2prod_inplace_ener(ej, xj, nmo, nocc); // // // vev_xy += xj * ej * (2 * yj - yi) // dgemm_(&TRANS_T, &TRANS_N, &nmo, &nmo, &nocc, &D1, xi, &nocc, xj, &nocc, &D1, vev_priv, &nmo); // } // // free(xj); // free(xi); // free(qx); // free(qj); // free(ej); #pragma omp parallel { double qx_i = calloc(nauxnmo, sizeof(double)); double qx_j = calloc(nauxnmo, sizeof(double)); double qa_i = calloc(nauxnvir, sizeof(double)); double qa_j = calloc(nauxnvir, sizeof(double)); double xa_i = calloc(nmonvir, sizeof(double)); double xa_j = calloc(nmonvir, sizeof(double)); double ea = calloc(nvir, sizeof(double)); double vv_priv = calloc(nmonmo, sizeof(double)); double vev_priv = calloc(nmonmo, sizeof(double)); int i, j, ij; #pragma omp for for (ij = start; ij < end; ij++) { i = ij / nocc; j = ij % nocc; // build qx_i AGF2slice_01i(qxi, naux, nmo, nocc, i, qx_i); // build qx_j AGF2slice_01i(qxi, naux, nmo, nocc, j, qx_j); // build qa_i AGF2slice_0i2(qja, naux, nocc, nvir, i, qa_i); // build qa_j AGF2slice_0i2(qja, naux, nocc, nvir, j, qa_j); // build xija dgemm_(&TRANS_N, &TRANS_T, &nvir, &nmo, &naux, &D1, qa_i, &nvir, qx_j, &nmo, &D0, xa_i, &nvir); // build xjia dgemm_(&TRANS_N, &TRANS_T, &nvir, &nmo, &naux, &D1, qa_j, &nvir, qx_i, &nmo, &D0, xa_j, &nvir); // build eija = ei + ej - ea AGF2sum_inplace_ener(e_i[i], &(e_i[j]), e_a, one, nvir, ea); // inplace xjia = 2 xija - xjia AGF2sum_inplace(xa_j, xa_i, nmonvir, fpos, fneg); // vv_xy += xija (2 * yija - yjia) dgemm_(&TRANS_T, &TRANS_N, &nmo, &nmo, &nvir, &D1, xa_j, &nvir, xa_i, &nvir, &D1, vv_priv, &nmo); // inplace xija = eija * xija AGF2prod_inplace_ener(ea, xa_i, nmo, nvir); // vv_xy += xija * (2 * yija - yjia) dgemm_(&TRANS_T, &TRANS_N, &nmo, &nmo, &nvir, &D1, xa_j, &nvir, xa_i, &nvir, &D1, vev_priv, &nmo); } free(qx_i); free(qx_j); free(qa_i); free(qa_j); free(xa_i); free(xa_j); free(ea); #pragma omp critical for (i = 0; i < (nmo*nmo); i++) { vv[i] += vv_priv[i]; vev[i] += vev_priv[i]; } free(vv_priv); free(vev_priv); } }
strlib_akechi.h	#pragma once #ifndef AKECHI_LIB_9f8vy8hhdsh93 #define AKECHI_LIB_9f8vy8hhdsh93 #include <algorithm> #include <iostream> #include <thread> #include <string> #include <vector> #include <map> #include <mutex> #include <unordered_map> #include <set> #include <unordered_set> #include <stack> #include <sstream> #include <fstream> #include <memory> #include <iomanip> #include <functional> #include <experimental/filesystem> #include <array> #include <chrono> namespace akechi_akihide { namespace filesystem = std::experimental::filesystem; class dcout { private: bool ms_isd; public: template<typename tc> dcout& operator<<(tc cmd) { if (ms_isd) { std::cout << cmd << std::flush; } return this; } void enable() { ms_isd = true; } void disable() { ms_isd = false; } }; extern dcout cout; class CRecTime { private: std::chrono::time_point<std::chrono::high_resolution_clock> t1; std::chrono::time_point<std::chrono::high_resolution_clock> t0; std::chrono::time_point<std::chrono::high_resolution_clock> tt; double mwidth; double vtotal; public: CRecTime() { mwidth = 1000 1000; t0 = std::chrono::high_resolution_clock::now(); t1 = std::chrono::high_resolution_clock::now(); vtotal = 0; }; void begin() { t1 = std::chrono::high_resolution_clock::now(); } void end() { tt = std::chrono::high_resolution_clock::now(); vtotal += std::chrono::duration_cast<std::chrono::microseconds>(tt - t1).count(); } double getdiff() { auto diff = tt - t1; double ta = std::chrono::duration_cast<std::chrono::microseconds>(diff).count(); return ta / mwidth; } double gettotal() { auto diff = tt - t0; double ta = std::chrono::duration_cast<std::chrono::microseconds>(diff).count(); return ta / mwidth; } double get_valid_total() { return vtotal / mwidth; } }; inline void parallel_for(int32_t nth, int32_t N, std::function<void(int32_t)> fth) { if (nth < 1) return; if (nth > N) nth = N; #pragma omp parallel for for (int32_t ith = 0; ith < nth; ith++) { int32_t ibegin = N ith / nth; int32_t iend = N (ith + 1) / nth; for (int32_t i = ibegin; i < iend; i++) { fth(i); } } } class fstreamE : public std::fstream { //this class is for writing in bigendian order. private: std::vector<char> m_vbuff; public: template<class Tc> void writeB(const Tc &data) { m_vbuff.resize(0); for (size_t i = 1; i <= sizeof(Tc); i++) { m_vbuff.push_back(((const char)&data)[sizeof(Tc) - i]); } write(m_vbuff.data(), m_vbuff.size()); } template<class Tc> void readB(Tc &data) { m_vbuff.resize(sizeof(Tc)); read(m_vbuff.data(), m_vbuff.size()); for (size_t i = 1; i <= sizeof(Tc); i++) { ((char)&data)[i - 1] = m_vbuff[sizeof(Tc) - i]; } } template<class Tc> void writeL(const Tc &data) { write((const char)&data, sizeof(Tc)); } template<class Tc> void readL(Tc &data) { read((char)&data, sizeof(Tc)); } }; std::string mGetModulePath(std::string path); std::vector<std::string> GetCmdLine(std::string scmd); std::vector<std::string> DirExtFileSplitter(std::string path);//split the path to directory,extention,and filename. corresoponding to both character of '\' and '/' for directory symbol. void strReplace(std::string& str, const std::string& from, const std::string& to); std::vector<std::string> split(const std::string &str, const std::string &delim); //Timer Class. this class enable to run rambda function with given interval [ms]. class CTimer { private: bool is; std::thread th; std::function<void(double)> m_f; double m_interval; public: CTimer(double interval, std::function<void(double)> f)//[s] { is = true; m_interval = interval1000; m_f = f; th = std::thread([&]() { std::chrono::high_resolution_clock::time_point st = std::chrono::high_resolution_clock::now(); std::chrono::high_resolution_clock::time_point t1 = std::chrono::high_resolution_clock::now(); while (is) { std::this_thread::sleep_for(std::chrono::milliseconds(1)); std::chrono::high_resolution_clock::time_point t2 = std::chrono::high_resolution_clock::now(); double diff = std::chrono::duration_cast<std::chrono::milliseconds>(t2 - t1).count(); if (diff > m_interval) { t1 = t2; double t = std::chrono::duration_cast<std::chrono::milliseconds>(t2 - st).count(); m_f(t/1000); } } }); } ~CTimer() { is = false; if (th.joinable()) { th.join(); } } }; //-----UUID generation class which support 128bit comparesion operation. so this class can be used as key of std contaner. class myUUID { private: static bool m_isseq; static size_t ms_cSequentialID; static std::mutex ms_Mutex; public: static const int uuidlen = 16; static void setDefSeuquential(); static void setDefRandom(); static myUUID GetUUIDv4(); static myUUID GetUUIDSeq(); unsigned char m_UUIDa() { return (unsigned char)m_pi64.data(); }; unsigned int m_pi32() { return (unsigned int)m_pi64.data(); }; std::array<size_t, 2> m_pi64; static myUUID NULLID; myUUID() { m_pi64[0] = 0; m_pi64[1] = 0; } ~myUUID(); myUUID(const myUUID &obj); const myUUID& operator=(const myUUID& u1); std::string getuuidbyASCII(); std::string getuuidbyASCII_non0pack(); myUUID(std::string str); myUUID(const std::vector<char>& str); myUUID(const std::vector<unsigned char>& str); }; inline bool operator==(const myUUID &id1, const myUUID &id2) { return id1.m_pi64 == id2.m_pi64; } inline bool operator!=(const myUUID &id1, const myUUID &id2) { return id1.m_pi64 != id2.m_pi64; } inline bool operator<(const myUUID &id1, const myUUID &id2) { return id1.m_pi64 < id2.m_pi64; } inline bool operator>(const myUUID &id1, const myUUID &id2) { return id1.m_pi64 > id2.m_pi64; } inline bool operator <= (const myUUID &id1, const myUUID &id2) { return id2.m_pi64 <= id1.m_pi64; } inline bool operator>=(const myUUID &id1, const myUUID &id2) { return id2.m_pi64 >= id1.m_pi64; } class CMT { private: const unsigned int M = 397; const unsigned int MATRIX_A = 0x9908b0dfUL; / constant vector a / const unsigned int UPPER_MASK = 0x80000000UL; / most significant w-r bits / const unsigned int LOWER_MASK = 0x7fffffffUL; / least significant r bits / std::array<unsigned long, 624> mt; / the array for the state vector / int mti; / initializes mt[N] with a seed / public: CMT(unsigned long s = 91516) { mt[0] = s & 0xffffffffUL; for (mti = 1; mti < mt.size(); mti++) { mt[mti] = (1812433253UL (mt[mti - 1] ^ (mt[mti - 1] >> 30)) + mti); /* See Knuth TAOCP Vol2. 3rd Ed. P.106 for multiplier. / / In the previous versions, MSBs of the seed affect / / only MSBs of the array mt[]. / / 2002/01/09 modified by Makoto Matsumoto / mt[mti] &= 0xffffffffUL; / for >32 bit machines / } } unsigned long genrand_int32CPU(void) { unsigned long y; static unsigned long mag01[2] = { 0x0UL, MATRIX_A }; / mag01[x] = x * MATRIX_A for x=0,1 / if (mti >= mt.size()) { / generate N words at one time / int kk; for (kk = 0; kk < mt.size() - M; kk++) { y = (mt[kk] & UPPER_MASK) \| (mt[kk + 1] & LOWER_MASK); mt[kk] = mt[kk + M] ^ (y >> 1) ^ mag01[y & 0x1UL]; } for (; kk < mt.size() - 1; kk++) { y = (mt[kk] & UPPER_MASK) \| (mt[kk + 1] & LOWER_MASK); mt[kk] = mt[kk + (M - mt.size())] ^ (y >> 1) ^ mag01[y & 0x1UL]; } y = (mt[mt.size() - 1] & UPPER_MASK) \| (mt[0] & LOWER_MASK); mt[mt.size() - 1] = mt[M - 1] ^ (y >> 1) ^ mag01[y & 0x1UL]; mti = 0; } y = mt[mti++]; / Tempering / y ^= (y >> 11); y ^= (y << 7) & 0x9d2c5680UL; y ^= (y << 15) & 0xefc60000UL; y ^= (y >> 18); return y; } }; template<class Tc> class CInsertOnly { private: Tc m_v; public: Tc operator=(const Tc& ms) { m_v = ms; } Tc operator=(Tc&& ms) { m_v = std::move(ms); } CInsertOnly operator=(const CInsertOnly& ms) = delete; CInsertOnly& operator&() = delete; CInsertOnly(const CInsertOnly& t) = delete; CInsertOnly(CInsertOnly&& t) = delete; CInsertOnly(Tc& t) { m_v = &t; } operator Tc() { return m_v; } }; class CValueS { public: private: class CValue { protected: public: virtual CValue CreteCopy() = 0; CValue() { } virtual ~CValue() { } protected: }; class CAUUID final : public CValue { private: public: myUUID m_v; CValue* CreteCopy() override { CAUUID* pn = new CAUUID(); pn->m_v = m_v; return pn; } CAUUID() { } }; class CNumber final : public CValue { private: public: double m_v; CValue* CreteCopy() override { CNumber* pn = new CNumber(); pn->m_v = m_v; return pn; } CNumber() { m_v = 0; } }; class CBool final : public CValue { private: public: bool m_v; CValue* CreteCopy() override { CBool* pn = new CBool(); pn->m_v = m_v; return pn; } CBool() { m_v = false; } bool cbool() { return false; }; }; class CString final : public CValue { private: public: std::string m_v; CValue* CreteCopy() override { CString* pn = new CString(); pn->m_v = m_v; return pn; } CString() { } }; class CNUL final : public CValue { private: public: CValue* CreteCopy() override { CNUL* pn = new CNUL(); return pn; } }; class CEmpty final : public CValue { private: public: CValue* CreteCopy() override { CEmpty* pn = new CEmpty(); return pn; } }; class CObject final : public CValue { private: public: std::map<std::string, CValueS> m_v; CValue* CreteCopy() override { CObject* pn = new CObject(); pn->m_v = m_v; return pn; } }; class CArray final : public CValue { private: public: std::vector<CValueS> m_v; CValue* CreteCopy() override { CArray* pn = new CArray(); pn->m_v = m_v; return pn; } }; std::unique_ptr<CValue> m_p; void Empty_value() { CEmpty* ps = new CEmpty(); m_p.reset(ps); } bool is_empty() { auto& pr = m_p.get(); return typeid(pr) == typeid(CEmpty); }; public: CValueS() { m_p.reset(new CNUL); } CValueS& operator=(const CValueS& ts) { m_p.reset(ts.m_p->CreteCopy()); return this; } CValueS& operator=(CValueS&& ts) { m_p = std::move(ts.m_p); ts.m_p.reset(new CNUL); return this; } CValueS(const CValueS& ts) { m_p.reset(ts.m_p->CreteCopy()); } CValueS(CValueS&& ts) { m_p = std::move(ts.m_p); ts.m_p.reset(new CNUL); } ~CValueS() { } std::string& string_value() { CString ps; if (!is_string()) { ps = new CString(); m_p.reset(ps); } else { ps = (CString)m_p.get(); } return ps->m_v; } double& number_value() { CNumber ps; if (!is_number()) { ps = new CNumber(); m_p.reset(ps); } else { ps = (CNumber)m_p.get(); } return ps->m_v; } myUUID& UUID_value() { CAUUID ps; if (!is_uuid()) { ps = new CAUUID(); m_p.reset(ps); } else { ps = (CAUUID)m_p.get(); } return ps->m_v; } bool& bool_value() { CBool ps; if (!is_bool()) { ps = new CBool(); m_p.reset(ps); } else { ps = (CBool)m_p.get(); } return ps->m_v; } void Nul_value() { CNUL ps = new CNUL(); m_p.reset(ps); } std::map<std::string, CValueS>& object_items() { CObject* ps; if (!is_object()) { ps = new CObject(); m_p.reset(ps); } else { ps = (CObject)m_p.get(); } return ps->m_v; } std::vector<CValueS>& array_items() { CArray ps; if (!is_array()) { ps = new CArray(); m_p.reset(ps); } else { ps = (CArray)m_p.get(); } return ps->m_v; } bool is_string() { auto& pr = m_p.get(); return typeid(pr) == typeid(CString); }; bool is_number() { auto& pr = m_p.get(); return typeid(pr) == typeid(CNumber); }; bool is_nul() { auto& pr = m_p.get(); return typeid(pr) == typeid(CNUL); }; bool is_object() { auto& pr = m_p.get(); return typeid(pr) == typeid(CObject); }; bool is_bool() { auto& pr = m_p.get(); return typeid(pr) == typeid(CBool); }; bool is_array() { auto& pr = m_p.get(); return typeid(pr) == typeid(CArray); }; bool is_uuid() { auto& pr = m_p.get(); return typeid(pr) == typeid(CAUUID); }; void push_back(const CValueS& a) { CArray* ps; if (!is_array()) { ps = new CArray(); m_p.reset(ps); } else { ps = (CArray)m_p.get(); } ps->m_v.push_back(a); } void push_back(CValueS&& a) { CArray ps; if (!is_array()) { ps = new CArray(); m_p.reset(ps); } else { ps = (CArray)m_p.get(); } ps->m_v.push_back(std::move(a)); } CValueS& push_back() { CArray ps; if (!is_array()) { ps = new CArray(); m_p.reset(ps); } else { ps = (CArray)m_p.get(); } ps->m_v.push_back(CValueS()); return ps->m_v.back(); } CValueS& operator [](const std::string& s) { CObject ps; if (!is_object()) { ps = new CObject(); m_p.reset(ps); } else { ps = (CObject)m_p.get(); } return ps->m_v[s]; } CValueS& operator [](size_t i) { CArray ps; if (!is_array()) { ps = new CArray(); m_p.reset(ps); } else { ps = (CArray*)m_p.get(); } if (ps->m_v.size() <= i) { ps->m_v.resize(i + 1); } return ps->m_v[i]; } bool write_json(std::string& str, std::string& err); bool read_json(std::string str, std::string& err); void read_CSV_comma(std::string str); void read_CSV_semicolon(std::string str); bool read_json_file(std::string fname, std::string& err) { std::fstream fs; fs.open(fname, std::ios::in \| std::ios::binary); if (!fs.is_open()) { err = "cannot open the file :" + fname; return false; } std::vector<char> dat(filesystem::file_size(fname)); fs.read(dat.data(), dat.size()); fs.close(); dat.push_back(0); return this->read_json(dat.data(), err); } bool read_CSV_file_comma(std::string fname, std::string& err) { std::fstream fs; fs.open(fname, std::ios::in \| std::ios::binary); if (!fs.is_open()) { err = "cannot open the file :" + fname; return false; } std::vector<char> dat(filesystem::file_size(fname)); fs.read(dat.data(), dat.size()); fs.close(); dat.push_back(0); this->read_CSV_comma(dat.data()); return true; } bool read_CSV_file_semicolon(std::string fname, std::string& err) { std::fstream fs; fs.open(fname, std::ios::in \| std::ios::binary); if (!fs.is_open()) { err = "cannot open the file :" + fname; return false; } std::vector<char> dat(filesystem::file_size(fname)); fs.read(dat.data(), dat.size()); fs.close(); dat.push_back(0); this->read_CSV_semicolon(dat.data()); return true; } bool write_json_file(std::string path, std::string& err) { std::fstream fs; std::string str; fs.open(path, std::ios::out \| std::ios::binary); if (!fs.is_open()) { err = "cannot open the file :" + path; return false; } write_json(str, err); fs << str; return true; } }; class KATO { //this class can deal with csv formated time depedent result data. std::vector<std::pair<std::string, std::vector<akechi_akihide::CValueS>>> m_mapvalue; public: KATO(std::vector<std::string> vnames) { for (auto& it : vnames) { m_mapvalue.push_back(std::make_pair(it, std::vector<akechi_akihide::CValueS>())); } } void addNext(const std::function<akechi_akihide::CValueS(std::string)> &f) { for (auto& itv : m_mapvalue) { itv.second.push_back(std::move(f(itv.first))); } } void OutPut(std::string filepath) { if (m_mapvalue.begin() == m_mapvalue.end()) { return; } std::fstream fs; std::experimental::filesystem::path p2 = filepath; for (int i = 0; i < 100; i++) { std::experimental::filesystem::path p3; if (i == 0) { p3 = p2; } else { p3 = p2.parent_path() / std::experimental::filesystem::path(p2.stem().string() + std::to_string(i - 1) + p2.extension().string()); } fs.open(p3, std::ios::binary \| std::ios::out); if (fs.is_open()) { std::cout << p3 << "\n"; break; } } for (auto& itv : m_mapvalue) { fs << "\"" << itv.first << "\","; } fs << "\r\n"; int64_t cs = m_mapvalue.begin()->second.size() ; for (int64_t c=0; c< cs; c++) { for (auto& itv : m_mapvalue) { fs << itv.second[c].number_value() << ","; } fs << "\r\n"; } } }; } #endif
op_openmp4_rt_support.c	// // header files // #include <math.h> #include <stdio.h> #include <stdlib.h> #include <string.h> #include <omp.h> #include <op_lib_c.h> #include <op_lib_core.h> #include <op_rt_support.h> // // routines to move arrays to/from GPU device // void op_mvHostToDevice(void *map, int size) { if (!OP_hybrid_gpu) return; char temp = (char)map; #pragma omp target enter data map(to: temp[:size]) #pragma omp target update to(temp[:size]) //TODO test } void op_cpHostToDevice(void data_d, void data_h, int size) { if (!OP_hybrid_gpu) return; data_d = (char)op_malloc(size); memcpy(data_d, data_h, size); char tmp = (char )data_d; //TODO jo igy? decl miatt kell az enter data elm. #pragma omp target enter data map(to: tmp[:size]) #pragma omp target update to(tmp[:size]) } op_plan op_plan_get(char const name, op_set set, int part_size, int nargs, op_arg args, int ninds, int inds) { return op_plan_get_stage(name, set, part_size, nargs, args, ninds, inds, OP_STAGE_ALL); } op_plan op_plan_get_stage(char const name, op_set set, int part_size, int nargs, op_arg args, int ninds, int inds, int staging) { return op_plan_get_stage_upload(name, set, part_size, nargs, args, ninds, inds, staging, 1); } op_plan op_plan_get_stage_upload(char const name, op_set set, int part_size, int nargs, op_arg args, int ninds, int inds, int staging, int upload) { op_plan plan = op_plan_core(name, set, part_size, nargs, args, ninds, inds, staging); if (!OP_hybrid_gpu \|\| !upload) return plan; int set_size = set->size; for (int i = 0; i < nargs; i++) { if (args[i].idx != -1 && args[i].acc != OP_READ) { set_size += set->exec_size; break; } } if (plan->count == 1) { int offsets = (int )malloc((plan->ninds_staged + 1) * sizeof(int)); offsets[0] = 0; for (int m = 0; m < plan->ninds_staged; m++) { int count = 0; for (int m2 = 0; m2 < nargs; m2++) if (plan->inds_staged[m2] == m) count++; offsets[m + 1] = offsets[m] + count; } op_mvHostToDevice((void *)&(plan->ind_map), offsets[plan->ninds_staged] set_size * sizeof(int)); for (int m = 0; m < plan->ninds_staged; m++) { plan->ind_maps[m] = &plan->ind_map[set_size * offsets[m]]; } free(offsets); int counter = 0; for (int m = 0; m < nargs; m++) if (plan->loc_maps[m] != NULL) counter++; op_mvHostToDevice((void *)&(plan->loc_map), sizeof(short) counter * set_size); counter = 0; for (int m = 0; m < nargs; m++) if (plan->loc_maps[m] != NULL) { plan->loc_maps[m] = &plan->loc_map[set_size * counter]; counter++; } op_mvHostToDevice((void *)&(plan->ind_sizes), sizeof(int) plan->nblocks * plan->ninds_staged); op_mvHostToDevice((void *)&(plan->ind_offs), sizeof(int) plan->nblocks * plan->ninds_staged); op_mvHostToDevice((void *)&(plan->nthrcol), sizeof(int) plan->nblocks); op_mvHostToDevice((void *)&(plan->thrcol), sizeof(int) set_size); op_mvHostToDevice((void *)&(plan->col_reord), sizeof(int) set_size); op_mvHostToDevice((void *)&(plan->offset), sizeof(int) plan->nblocks); plan->offset_d = plan->offset; op_mvHostToDevice((void *)&(plan->nelems), sizeof(int) plan->nblocks); plan->nelems_d = plan->nelems; op_mvHostToDevice((void *)&(plan->blkmap), sizeof(int) plan->nblocks); plan->blkmap_d = plan->blkmap; } return plan; } void op_cuda_exit() { if (!OP_hybrid_gpu) return; op_dat_entry item; TAILQ_FOREACH(item, &OP_dat_list, entries) { #pragma omp target exit data map(from: (item->dat)->data_d) free((item->dat)->data_d); } / for (int ip = 0; ip < OP_plan_index; ip++) { OP_plans[ip].ind_map = NULL; OP_plans[ip].loc_map = NULL; OP_plans[ip].ind_sizes = NULL; OP_plans[ip].ind_offs = NULL; OP_plans[ip].nthrcol = NULL; OP_plans[ip].thrcol = NULL; OP_plans[ip].col_reord = NULL; OP_plans[ip].offset = NULL; OP_plans[ip].nelems = NULL; OP_plans[ip].blkmap = NULL; } / // cudaDeviceReset ( ); } // // routines to resize constant/reduct arrays, if necessary // void reallocConstArrays(int consts_bytes) { (void) consts_bytes; } void reallocReductArrays(int reduct_bytes) { (void) reduct_bytes; } // // routines to move constant/reduct arrays // void mvConstArraysToDevice(int consts_bytes) { (void) consts_bytes; } void mvReductArraysToDevice(int reduct_bytes) { (void) reduct_bytes; } void mvReductArraysToHost(int reduct_bytes) { (void) reduct_bytes; } // // routine to fetch data from GPU to CPU (with transposing SoA to AoS if needed) // void op_cuda_get_data(op_dat dat) { if (!OP_hybrid_gpu) return; if (dat->dirty_hd == 2) dat->dirty_hd = 0; else return; #pragma omp target update from(dat->data_d[:dat->size dat->set->size]) // transpose data if (strstr(dat->type, ":soa") != NULL \|\| (OP_auto_soa && dat->dim > 1)) { int element_size = dat->size / dat->dim; for (int i = 0; i < dat->dim; i++) { for (int j = 0; j < dat->set->size; j++) { for (int c = 0; c < element_size; c++) { dat->data[dat->size * j + element_size * i + c] = dat->data_d[element_size * i * dat->set->size + element_size * j + c]; } } } } else { memcpy(dat->data,dat->data_d,dat->size * dat->set->size); } } void deviceSync() { // cutilSafeCall(cudaDeviceSynchronize()); } #ifndef OPMPI void cutilDeviceInit(int argc, char *argv) { (void)argc; (void)argv; // copy one scalar to initialize OpenMP env. // Improvement: later we can set default device. int tmp=0; #pragma omp target enter data map(to:tmp) OP_hybrid_gpu = 1; } void op_upload_dat(op_dat dat) { if (!OP_hybrid_gpu) return; int set_size = dat->set->size; if (strstr(dat->type, ":soa") != NULL \|\| (OP_auto_soa && dat->dim > 1)) { int element_size = dat->size / dat->dim; for (int i = 0; i < dat->dim; i++) { for (int j = 0; j < set_size; j++) { for (int c = 0; c < element_size; c++) { dat->data_d[element_size i * set_size + element_size * j + c] = dat->data[dat->size * j + element_size * i + c]; } } } } else { memcpy(dat->data_d,dat->data,dat->size * dat->set->size); } #pragma omp target update to(dat->data_d[:set_sizedat->size]) } void op_download_dat(op_dat dat) { if (!OP_hybrid_gpu) return; #pragma omp target update from(dat->data_d[:dat->size dat->set->size]) int set_size = dat->set->size; if (strstr(dat->type, ":soa") != NULL \|\| (OP_auto_soa && dat->dim > 1)) { int element_size = dat->size / dat->dim; for (int i = 0; i < dat->dim; i++) { for (int j = 0; j < set_size; j++) { for (int c = 0; c < element_size; c++) { dat->data[dat->size * j + element_size * i + c] = dat->data_d[element_size * i * set_size + element_size * j + c]; } } } } else { memcpy(dat->data,dat->data_d,dat->size * dat->set->size); } } int op_mpi_halo_exchanges(op_set set, int nargs, op_arg args) { //TODO itt a download + dirty allitas ekv egy getdata hivassal for (int n = 0; n < nargs; n++) if (args[n].opt && args[n].argtype == OP_ARG_DAT && args[n].dat->dirty_hd == 2) { op_download_dat(args[n].dat); args[n].dat->dirty_hd = 0; } return set->size; } void op_mpi_set_dirtybit(int nargs, op_arg args) { for (int n = 0; n < nargs; n++) { if ((args[n].opt == 1) && (args[n].argtype == OP_ARG_DAT) && (args[n].acc == OP_INC \|\| args[n].acc == OP_WRITE \|\| args[n].acc == OP_RW)) { args[n].dat->dirty_hd = 1; } } } int op_mpi_halo_exchanges_cuda(op_set set, int nargs, op_arg args) { for (int n = 0; n < nargs; n++) if (args[n].opt && args[n].argtype == OP_ARG_DAT && args[n].dat->dirty_hd == 1) { op_upload_dat(args[n].dat); args[n].dat->dirty_hd = 0; } return set->size; } void op_mpi_set_dirtybit_cuda(int nargs, op_arg args) { for (int n = 0; n < nargs; n++) { if ((args[n].opt == 1) && (args[n].argtype == OP_ARG_DAT) && (args[n].acc == OP_INC \|\| args[n].acc == OP_WRITE \|\| args[n].acc == OP_RW)) { args[n].dat->dirty_hd = 2; } } } void op_mpi_wait_all(int nargs, op_arg args) { (void)nargs; (void)args; } void op_mpi_wait_all_cuda(int nargs, op_arg args) { (void)nargs; (void)args; } void op_mpi_reset_halos(int nargs, op_arg args) { (void)nargs; (void)args; } void op_mpi_barrier() {} void op_mpi_perf_time(const char name, double time) { (void)name; (void)time; return (void )name; } #ifdef COMM_PERF void op_mpi_perf_comms(void k_i, int nargs, op_arg args) { (void)k_i; (void)nargs; (void)args; } #endif void op_mpi_reduce_float(op_arg args, float data) { (void)args; (void)data; } void op_mpi_reduce_double(op_arg args, double data) { (void)args; (void)data; } void op_mpi_reduce_int(op_arg args, int data) { (void)args; (void)data; } void op_mpi_reduce_bool(op_arg args, bool data) { (void)args; (void)data; } void op_partition(const char lib_name, const char lib_routine, op_set prime_set, op_map prime_map, op_dat coords) { (void)lib_name; (void)lib_routine; (void)prime_set; (void)prime_map; (void)coords; } void op_partition_reverse() {} void op_compute_moment(double t, double first, double second) { first = t; second = t * t; } void op_compute_moment_across_times(double* times, int ntimes, bool ignore_zeros, double first, double second) { first = 0.0; second = 0.0f; int n = 0; for (int i=0; i<ntimes; i++) { if (ignore_zeros && (times[i] == 0.0f)) { continue; } first += times[i]; second += times[i] * times[i]; n++; } if (n != 0) { first /= (double)n; second /= (double)n; } } int op_is_root() { return 1; } #endif
dihedral.c	#include <stdio.h> #include <math.h> inline void crossProduct3(double a[], const double b[], const double c[]) { //Calculate the cross product between length-three vectors b and c, storing //the result in a (a)[0] = (b)[1] * (c)[2] - (c)[1] * (b)[2]; (a)[1] = (b)[2] * (c)[0] - (c)[2] * (b)[0]; (a)[2] = (b)[0] * (c)[1] - (c)[0] * (b)[1]; } inline double dotProduct3(const double b[], const double c[]) { //Calculate the dot product between length-three vectors b and c return b[0] * c[0] + b[1] * c[1] + b[2] * c[2]; } double dihedral(const double x0, const double x1, const double x2, const double x3) { //Calculate the signed dihedral angle between four points. //Result in radians //x0, x1, x2, x3 should be length three arrays int i; double b1[3], b2[3], b3[3], c1[3], c2[3]; double arg1, arg2, b2_norm; for (i = 0; i < 3; i++) { b1[i] = x1[i] - x0[i]; b2[i] = x2[i] - x1[i]; b3[i] = x3[i] - x2[i]; } crossProduct3(c1, b2, b3); crossProduct3(c2, b1, b2); arg1 = dotProduct3(b1, c1); b2_norm = sqrt(dotProduct3(b2, b2)); arg1 = arg1 * b2_norm; arg2 = dotProduct3(c2, c1); return atan2(arg1, arg2); } void dihedrals_from_traj(double results, const double xyzlist, const long quartets, int traj_length, int num_atoms, int num_quartets) { // results is a 2D array (traj_length x num_quartets). xyzlist is a 3D // array (traj_length x num_atoms x 3). quartets is a 2D array (num_quartets // x 4) where each row is the four atomindices of the atoms to calculate the // dihedral angle between // results are storted in the results array int i,j,k; long e[4] = {0,0,0,0}; double x[4] = {0,0,0,0}; double result_ptr; #pragma omp parallel for default(none) shared(results, xyzlist, quartets, traj_length, num_atoms, num_quartets) private(j, k, e, x, result_ptr) for (i = 0; i < traj_length; i++) { for (j = 0; j < num_quartets; j++) { for (k = 0; k < 4; k++) { e[k] = quartets[4j + k]; x[k] = xyzlist + inum_atoms3 + e[k]3; } /printf("i: %d -- j %d\n", i, j); printf("first %f", (xyzlist + i traj_length3 + 43)); printf("e -- %d %d %d %d\n", e[0], e[1], e[2], e[3]); printf("x0: %f\n", (x[0])); printf("x1: %f\n", (x[1])); printf("x2: %f\n", (x[2])); printf("Calculated %f\n", dihedral(x[0], x[1], x[2], x[3]));/ result_ptr = results + i * num_quartets + j; result_ptr = dihedral(x[0], x[1], x[2], x[3]); } } } / Another version of the code that uses floats instead of doubles / inline void crossProduct3_float(float a[], const float b[], const float c[]) { //Calculate the cross product between length-three vectors b and c, storing //the result in a (a)[0] = (b)[1] (c)[2] - (c)[1] * (b)[2]; (a)[1] = (b)[2] * (c)[0] - (c)[2] * (b)[0]; (a)[2] = (b)[0] * (c)[1] - (c)[0] * (b)[1]; } inline double dotProduct3_float(const float b[], const float c[]) { //Calculate the dot product between length-three vectors b and c return b[0] * c[0] + b[1] * c[1] + b[2] * c[2]; } double dihedral_float(const float x0, const float x1, const float x2, const float x3) { //Calculate the signed dihedral angle between four points. //Result in radians //x0, x1, x2, x3 should be length three arrays int i; float b1[3], b2[3], b3[3], c1[3], c2[3]; float arg1, arg2, b2_norm; for (i = 0; i < 3; i++) { b1[i] = x1[i] - x0[i]; b2[i] = x2[i] - x1[i]; b3[i] = x3[i] - x2[i]; } crossProduct3_float(c1, b2, b3); crossProduct3_float(c2, b1, b2); arg1 = dotProduct3_float(b1, c1); b2_norm = sqrt(dotProduct3_float(b2, b2)); arg1 = arg1 * b2_norm; arg2 = dotProduct3_float(c2, c1); return atan2(arg1, arg2); } void dihedrals_from_traj_float(float results, const float xyzlist, const long quartets, int traj_length, int num_atoms, int num_quartets) { // results is a 2D array (traj_length x num_quartets). xyzlist is a 3D // array (traj_length x num_atoms x 3). quartets is a 2D array (num_quartets // x 4) where each row is the four atomindices of the atoms to calculate the // dihedral angle between // results are storted in the results array int i,j,k; long e[4] = {0,0,0,0}; float x[4] = {0,0,0,0}; float result_ptr; #pragma omp parallel for default(none) shared(results, xyzlist, quartets, traj_length, num_atoms, num_quartets) private(j, k, e, x, result_ptr) for (i = 0; i < traj_length; i++) { for (j = 0; j < num_quartets; j++) { for (k = 0; k < 4; k++) { e[k] = quartets[4j + k]; x[k] = xyzlist + inum_atoms3 + e[k]3; } /printf("i: %d -- j %d\n", i, j); printf("first %f", (xyzlist + i traj_length3 + 43)); printf("e -- %d %d %d %d\n", e[0], e[1], e[2], e[3]); printf("x0: %f\n", (x[0])); printf("x1: %f\n", (x[1])); printf("x2: %f\n", (x[2])); printf("Calculated %f\n", dihedral(x[0], x[1], x[2], x[3]));/ result_ptr = results + i * num_quartets + j; *result_ptr = dihedral_float(x[0], x[1], x[2], x[3]); } } }
cvAdvDiff_bnd_omp.c	/* ----------------------------------------------------------------- * Programmer(s): Daniel Reynolds and Ting Yan @ SMU * Based on cvAdvDiff_bnd.c and parallelized with OpenMP * ----------------------------------------------------------------- * SUNDIALS Copyright Start * Copyright (c) 2002-2020, Lawrence Livermore National Security * and Southern Methodist University. * All rights reserved. * * See the top-level LICENSE and NOTICE files for details. * * SPDX-License-Identifier: BSD-3-Clause * SUNDIALS Copyright End * ----------------------------------------------------------------- * Example problem: * * The following is a simple example problem with a banded Jacobian, * solved using CVODE. * The problem is the semi-discrete form of the advection-diffusion * equation in 2-D: * du/dt = d^2 u / dx^2 + .5 du/dx + d^2 u / dy^2 * on the rectangle 0 <= x <= 2, 0 <= y <= 1, and the time * interval 0 <= t <= 1. Homogeneous Dirichlet boundary conditions * are posed, and the initial condition is * u(x,y,t=0) = x(2-x)y(1-y)exp(5xy). * The PDE is discretized on a uniform MX+2 by MY+2 grid with * central differencing, and with boundary values eliminated, * leaving an ODE system of size NEQ = MXMY. This program solves the problem with the BDF method, Newton * iteration with the SUNBAND linear solver, and a user-supplied * Jacobian routine. * It uses scalar relative and absolute tolerances. * Output is printed at t = .1, .2, ..., 1. * Run statistics (optional outputs) are printed at the end. * * Optionally, we can set the number of threads from environment * variable or command line. To check the current value for number * of threads from environment: * % echo $OMP_NUM_THREADS * * Execution: * * To use the default value or the number of threads from the * environment value, run without arguments: * % ./cvAdvDiff_bnd_omp * The environment variable can be over-ridden with a command line * argument specifying the number of threads to use, e.g: * % ./cvAdvDiff_bnd_omp 5 * ----------------------------------------------------------------- / #include <stdio.h> #include <stdlib.h> #include <math.h> / Header files with a description of contents / #include <cvode/cvode.h> / prototypes for CVODE fcts., consts. / #include <nvector/nvector_openmp.h> / serial N_Vector types, fcts., macros / #include <sunmatrix/sunmatrix_band.h> / access to band SUNMatrix / #include <sunlinsol/sunlinsol_band.h> / access to band SUNLinearSolver / #include <sundials/sundials_types.h> / definition of type realtype / #ifdef _OPENMP #include <omp.h> #endif / Problem Constants / #define XMAX RCONST(2.0) / domain boundaries / #define YMAX RCONST(1.0) #define MX 10 / mesh dimensions / #define MY 5 #define NEQ MXMY /* number of equations / #define ATOL RCONST(1.0e-5) / scalar absolute tolerance / #define T0 RCONST(0.0) / initial time / #define T1 RCONST(0.1) / first output time / #define DTOUT RCONST(0.1) / output time increment / #define NOUT 10 / number of output times / #define ZERO RCONST(0.0) #define HALF RCONST(0.5) #define ONE RCONST(1.0) #define TWO RCONST(2.0) #define FIVE RCONST(5.0) / User-defined vector access macro IJth / / IJth is defined in order to isolate the translation from the mathematical 2-dimensional structure of the dependent variable vector to the underlying 1-dimensional storage. IJth(vdata,i,j) references the element in the vdata array for u at mesh point (i,j), where 1 <= i <= MX, 1 <= j <= MY. The vdata array is obtained via the macro call vdata = NV_DATA_S(v), where v is an N_Vector. The variables are ordered by the y index j, then by the x index i. / #define IJth(vdata,i,j) (vdata[(j-1) + (i-1)MY]) /* Type : UserData (contains grid constants) / typedef struct { realtype dx, dy, hdcoef, hacoef, vdcoef; int nthreads; } UserData; /* Private Helper Functions / static void SetIC(N_Vector u, UserData data); static void PrintHeader(realtype reltol, realtype abstol, realtype umax); static void PrintOutput(realtype t, realtype umax, long int nst); static void PrintFinalStats(void cvode_mem); /* Private function to check function return values / static int check_retval(void returnvalue, const char funcname, int opt); / Functions Called by the Solver / static int f(realtype t, N_Vector u, N_Vector udot, void user_data); static int Jac(realtype t, N_Vector u, N_Vector fu, SUNMatrix J, void user_data, N_Vector tmp1, N_Vector tmp2, N_Vector tmp3); / ------------------------------- Main Program ------------------------------- / int main(int argc, char argv[]) { realtype dx, dy, reltol, abstol, t, tout, umax; N_Vector u; UserData data; SUNMatrix A; SUNLinearSolver LS; void cvode_mem; int iout, retval; long int nst; int num_threads; u = NULL; data = NULL; A = NULL; LS = NULL; cvode_mem = NULL; /* Set the number of threads to use / num_threads = 1; / default value / #ifdef _OPENMP num_threads = omp_get_max_threads(); / Overwrite with OMP_NUM_THREADS environment variable / #endif if (argc > 1) / overwrite with command line value, if supplied / num_threads = (int) strtol(argv[1], NULL, 0); / Create an OpenMP vector / u = N_VNew_OpenMP(NEQ, num_threads); / Allocate u vector / if(check_retval((void)u, "N_VNew_OpenMP", 0)) return(1); reltol = ZERO; /* Set the tolerances / abstol = ATOL; data = (UserData) malloc(sizeof data); /* Allocate data memory / if(check_retval((void )data, "malloc", 2)) return(1); dx = data->dx = XMAX/(MX+1); /* Set grid coefficients in data / dy = data->dy = YMAX/(MY+1); data->hdcoef = ONE/(dxdx); data->hacoef = HALF/(TWOdx); data->vdcoef = ONE/(dydy); data->nthreads = num_threads; SetIC(u, data); /* Initialize u vector / / Call CVodeCreate to create the solver memory and specify the * Backward Differentiation Formula / cvode_mem = CVodeCreate(CV_BDF); if(check_retval((void )cvode_mem, "CVodeCreate", 0)) return(1); /* Call CVodeInit to initialize the integrator memory and specify the * user's right hand side function in u'=f(t,u), the inital time T0, and * the initial dependent variable vector u. / retval = CVodeInit(cvode_mem, f, T0, u); if(check_retval(&retval, "CVodeInit", 1)) return(1); / Call CVodeSStolerances to specify the scalar relative tolerance * and scalar absolute tolerance / retval = CVodeSStolerances(cvode_mem, reltol, abstol); if (check_retval(&retval, "CVodeSStolerances", 1)) return(1); / Set the pointer to user-defined data / retval = CVodeSetUserData(cvode_mem, data); if(check_retval(&retval, "CVodeSetUserData", 1)) return(1); / Create banded SUNMatrix for use in linear solves -- since this will be factored, set the storage bandwidth to be the sum of upper and lower bandwidths / A = SUNBandMatrix(NEQ, MY, MY); if(check_retval((void )A, "SUNBandMatrix", 0)) return(1); /* Create banded SUNLinearSolver object for use by CVode / LS = SUNLinSol_Band(u, A); if(check_retval((void )LS, "SUNLinSol_Band", 0)) return(1); /* Call CVodeSetLinearSolver to attach the matrix and linear solver to CVode / retval = CVodeSetLinearSolver(cvode_mem, LS, A); if(check_retval(&retval, "CVodeSetLinearSolver", 1)) return(1); / Set the user-supplied Jacobian routine Jac / retval = CVodeSetJacFn(cvode_mem, Jac); if(check_retval(&retval, "CVodeSetJacFn", 1)) return(1); / In loop over output points: call CVode, print results, test for errors / umax = N_VMaxNorm(u); PrintHeader(reltol, abstol, umax); for(iout=1, tout=T1; iout <= NOUT; iout++, tout += DTOUT) { retval = CVode(cvode_mem, tout, u, &t, CV_NORMAL); if(check_retval(&retval, "CVode", 1)) break; umax = N_VMaxNorm(u); retval = CVodeGetNumSteps(cvode_mem, &nst); check_retval(&retval, "CVodeGetNumSteps", 1); PrintOutput(t, umax, nst); } PrintFinalStats(cvode_mem); / Print some final statistics / printf("num_threads = %i\n\n", num_threads); N_VDestroy(u); / Free the u vector / CVodeFree(&cvode_mem); / Free the integrator memory / SUNLinSolFree(LS); / Free the linear solver memory / SUNMatDestroy(A); / Free the matrix memory / free(data); / Free the user data / return(0); } / ------------------------------- Functions called by the solver ------------------------------- / /* f routine. Compute f(t,u). / static int f(realtype t, N_Vector u,N_Vector udot, void user_data) { realtype uij, udn, uup, ult, urt, hordc, horac, verdc, hdiff, hadv, vdiff; realtype udata, dudata; sunindextype i, j; UserData data; i = j = 0; udata = NV_DATA_OMP(u); dudata = NV_DATA_OMP(udot); /* Extract needed constants from data / data = (UserData) user_data; hordc = data->hdcoef; horac = data->hacoef; verdc = data->vdcoef; / Loop over all grid points. / #pragma omp parallel for default(shared) private(j, i, uij, udn, uup, ult, urt, hdiff, hadv, vdiff) num_threads(data->nthreads) for (j=1; j <= MY; j++) { for (i=1; i <= MX; i++) { / Extract u at x_i, y_j and four neighboring points / uij = IJth(udata, i, j); udn = (j == 1) ? ZERO : IJth(udata, i, j-1); uup = (j == MY) ? ZERO : IJth(udata, i, j+1); ult = (i == 1) ? ZERO : IJth(udata, i-1, j); urt = (i == MX) ? ZERO : IJth(udata, i+1, j); / Set diffusion and advection terms and load into udot / hdiff = hordc(ult - TWOuij + urt); hadv = horac(urt - ult); vdiff = verdc(uup - TWOuij + udn); IJth(dudata, i, j) = hdiff + hadv + vdiff; } } return(0); } /* Jacobian routine. Compute J(t,u). / static int Jac(realtype t, N_Vector u, N_Vector fu, SUNMatrix J, void user_data, N_Vector tmp1, N_Vector tmp2, N_Vector tmp3) { sunindextype i, j, k; realtype kthCol, hordc, horac, verdc; UserData data; / The components of f = udot that depend on u(i,j) are f(i,j), f(i-1,j), f(i+1,j), f(i,j-1), f(i,j+1), with df(i,j)/du(i,j) = -2 (1/dx^2 + 1/dy^2) df(i-1,j)/du(i,j) = 1/dx^2 + .25/dx (if i > 1) df(i+1,j)/du(i,j) = 1/dx^2 - .25/dx (if i < MX) df(i,j-1)/du(i,j) = 1/dy^2 (if j > 1) df(i,j+1)/du(i,j) = 1/dy^2 (if j < MY) / i = j = 0; data = (UserData) user_data; hordc = data->hdcoef; horac = data->hacoef; verdc = data->vdcoef; #pragma omp parallel for collapse(2) default(shared) private(i, j, k, kthCol) num_threads(data->nthreads) for (j=1; j <= MY; j++) { for (i=1; i <= MX; i++) { k = j-1 + (i-1)MY; kthCol = SUNBandMatrix_Column(J,k); /* set the kth column of J / SM_COLUMN_ELEMENT_B(kthCol,k,k) = -TWO(verdc+hordc); if (i != 1) SM_COLUMN_ELEMENT_B(kthCol,k-MY,k) = hordc + horac; if (i != MX) SM_COLUMN_ELEMENT_B(kthCol,k+MY,k) = hordc - horac; if (j != 1) SM_COLUMN_ELEMENT_B(kthCol,k-1,k) = verdc; if (j != MY) SM_COLUMN_ELEMENT_B(kthCol,k+1,k) = verdc; } } return(0); } /* ------------------------------- Private helper functions ------------------------------- / /* Set initial conditions in u vector / static void SetIC(N_Vector u, UserData data) { sunindextype i, j; realtype x, y, dx, dy; realtype udata; i = j = 0; /* Extract needed constants from data / dx = data->dx; dy = data->dy; / Set pointer to data array in vector u. / udata = NV_DATA_OMP(u); / Load initial profile into u vector / #pragma omp parallel for default(shared) private(j, i, y, x) for (j=1; j <= MY; j++) { y = jdy; for (i=1; i <= MX; i++) { x = idx; IJth(udata,i,j) = x(XMAX - x)y(YMAX - y)exp(FIVExy); } } } / Print first lines of output (problem description) / static void PrintHeader(realtype reltol, realtype abstol, realtype umax) { printf("\n2-D Advection-Diffusion Equation\n"); printf("Mesh dimensions = %d X %d\n", MX, MY); printf("Total system size = %d\n", NEQ); #if defined(SUNDIALS_EXTENDED_PRECISION) printf("Tolerance parameters: reltol = %Lg abstol = %Lg\n\n", reltol, abstol); printf("At t = %Lg max.norm(u) =%14.6Le \n", T0, umax); #elif defined(SUNDIALS_DOUBLE_PRECISION) printf("Tolerance parameters: reltol = %g abstol = %g\n\n", reltol, abstol); printf("At t = %g max.norm(u) =%14.6e \n", T0, umax); #else printf("Tolerance parameters: reltol = %g abstol = %g\n\n", reltol, abstol); printf("At t = %g max.norm(u) =%14.6e \n", T0, umax); #endif return; } / Print current value / static void PrintOutput(realtype t, realtype umax, long int nst) { #if defined(SUNDIALS_EXTENDED_PRECISION) printf("At t = %4.2Lf max.norm(u) =%14.6Le nst = %4ld\n", t, umax, nst); #elif defined(SUNDIALS_DOUBLE_PRECISION) printf("At t = %4.2f max.norm(u) =%14.6e nst = %4ld\n", t, umax, nst); #else printf("At t = %4.2f max.norm(u) =%14.6e nst = %4ld\n", t, umax, nst); #endif return; } / Get and print some final statistics / static void PrintFinalStats(void cvode_mem) { int retval; long int nst, nfe, nsetups, netf, nni, ncfn, nje, nfeLS; retval = CVodeGetNumSteps(cvode_mem, &nst); check_retval(&retval, "CVodeGetNumSteps", 1); retval = CVodeGetNumRhsEvals(cvode_mem, &nfe); check_retval(&retval, "CVodeGetNumRhsEvals", 1); retval = CVodeGetNumLinSolvSetups(cvode_mem, &nsetups); check_retval(&retval, "CVodeGetNumLinSolvSetups", 1); retval = CVodeGetNumErrTestFails(cvode_mem, &netf); check_retval(&retval, "CVodeGetNumErrTestFails", 1); retval = CVodeGetNumNonlinSolvIters(cvode_mem, &nni); check_retval(&retval, "CVodeGetNumNonlinSolvIters", 1); retval = CVodeGetNumNonlinSolvConvFails(cvode_mem, &ncfn); check_retval(&retval, "CVodeGetNumNonlinSolvConvFails", 1); retval = CVodeGetNumJacEvals(cvode_mem, &nje); check_retval(&retval, "CVodeGetNumJacEvals", 1); retval = CVodeGetNumLinRhsEvals(cvode_mem, &nfeLS); check_retval(&retval, "CVodeGetNumLinRhsEvals", 1); printf("\nFinal Statistics:\n"); printf("nst = %-6ld nfe = %-6ld nsetups = %-6ld nfeLS = %-6ld nje = %ld\n", nst, nfe, nsetups, nfeLS, nje); printf("nni = %-6ld ncfn = %-6ld netf = %ld\n", nni, ncfn, netf); return; } /* Check function return value... opt == 0 means SUNDIALS function allocates memory so check if returned NULL pointer opt == 1 means SUNDIALS function returns an integer value so check if retval < 0 opt == 2 means function allocates memory so check if returned NULL pointer / static int check_retval(void returnvalue, const char funcname, int opt) { int retval; /* Check if SUNDIALS function returned NULL pointer - no memory allocated / if (opt == 0 && returnvalue == NULL) { fprintf(stderr, "\nSUNDIALS_ERROR: %s() failed - returned NULL pointer\n\n", funcname); return(1); } / Check if retval < 0 / else if (opt == 1) { retval = (int ) returnvalue; if (retval < 0) { fprintf(stderr, "\nSUNDIALS_ERROR: %s() failed with retval = %d\n\n", funcname, retval); return(1); }} /* Check if function returned NULL pointer - no memory allocated */ else if (opt == 2 && returnvalue == NULL) { fprintf(stderr, "\nMEMORY_ERROR: %s() failed - returned NULL pointer\n\n", funcname); return(1); } return(0); }
common.h	#ifndef LIGHTGBM_UTILS_COMMON_FUN_H_ #define LIGHTGBM_UTILS_COMMON_FUN_H_ #include <LightGBM/utils/log.h> #include <LightGBM/utils/openmp_wrapper.h> #include <cstdio> #include <string> #include <vector> #include <sstream> #include <cstdint> #include <algorithm> #include <cmath> #include <functional> #include <memory> #include <iterator> #include <type_traits> #include <iomanip> namespace LightGBM { namespace Common { inline char tolower(char in) { if (in <= 'Z' && in >= 'A') return in - ('Z' - 'z'); return in; } inline static std::string Trim(std::string str) { if (str.empty()) { return str; } str.erase(str.find_last_not_of(" \f\n\r\t\v") + 1); str.erase(0, str.find_first_not_of(" \f\n\r\t\v")); return str; } inline static std::string RemoveQuotationSymbol(std::string str) { if (str.empty()) { return str; } str.erase(str.find_last_not_of("'\"") + 1); str.erase(0, str.find_first_not_of("'\"")); return str; } inline static bool StartsWith(const std::string& str, const std::string prefix) { if (str.substr(0, prefix.size()) == prefix) { return true; } else { return false; } } inline static std::vector<std::string> Split(const char* c_str, char delimiter) { std::vector<std::string> ret; std::string str(c_str); size_t i = 0; size_t pos = 0; while (pos < str.length()) { if (str[pos] == delimiter) { if (i < pos) { ret.push_back(str.substr(i, pos - i)); } ++pos; i = pos; } else { ++pos; } } if (i < pos) { ret.push_back(str.substr(i)); } return ret; } inline static std::vector<std::string> SplitLines(const char* c_str) { std::vector<std::string> ret; std::string str(c_str); size_t i = 0; size_t pos = 0; while (pos < str.length()) { if (str[pos] == '\n' \|\| str[pos] == '\r') { if (i < pos) { ret.push_back(str.substr(i, pos - i)); } // skip the line endings while (str[pos] == '\n' \|\| str[pos] == '\r') ++pos; // new begin i = pos; } else { ++pos; } } if (i < pos) { ret.push_back(str.substr(i)); } return ret; } inline static std::vector<std::string> Split(const char* c_str, const char* delimiters) { std::vector<std::string> ret; std::string str(c_str); size_t i = 0; size_t pos = 0; while (pos < str.length()) { bool met_delimiters = false; for (int j = 0; delimiters[j] != '\0'; ++j) { if (str[pos] == delimiters[j]) { met_delimiters = true; break; } } if (met_delimiters) { if (i < pos) { ret.push_back(str.substr(i, pos - i)); } ++pos; i = pos; } else { ++pos; } } if (i < pos) { ret.push_back(str.substr(i)); } return ret; } inline static std::string FindFromLines(const std::vector<std::string>& lines, const char* key_word) { for (auto& line : lines) { size_t find_pos = line.find(key_word); if (find_pos != std::string::npos) { return line; } } return ""; } inline static const char* Atoi(const char* p, int* out) { int sign, value; while (p == ' ') { ++p; } sign = 1; if (p == '-') { sign = -1; ++p; } else if (p == '+') { ++p; } for (value = 0; p >= '0' && p <= '9'; ++p) { value = value 10 + (p - '0'); } out = sign * value; while (p == ' ') { ++p; } return p; } inline static const char Atof(const char* p, double* out) { int frac; double sign, value, scale; out = NAN; // Skip leading white space, if any. while (p == ' ') { ++p; } // Get sign, if any. sign = 1.0; if (p == '-') { sign = -1.0; ++p; } else if (p == '+') { ++p; } // is a number if ((p >= '0' && p <= '9') \|\| p == '.' \|\| p == 'e' \|\| p == 'E') { // Get digits before decimal point or exponent, if any. for (value = 0.0; p >= '0' && p <= '9'; ++p) { value = value 10.0 + (p - '0'); } // Get digits after decimal point, if any. if (p == '.') { double pow10 = 10.0; ++p; while (p >= '0' && p <= '9') { value += (p - '0') / pow10; pow10 = 10.0; ++p; } } // Handle exponent, if any. frac = 0; scale = 1.0; if ((p == 'e') \|\| (p == 'E')) { uint32_t expon; // Get sign of exponent, if any. ++p; if (p == '-') { frac = 1; ++p; } else if (p == '+') { ++p; } // Get digits of exponent, if any. for (expon = 0; p >= '0' && p <= '9'; ++p) { expon = expon * 10 + (p - '0'); } if (expon > 308) expon = 308; // Calculate scaling factor. while (expon >= 50) { scale = 1E50; expon -= 50; } while (expon >= 8) { scale = 1E8; expon -= 8; } while (expon > 0) { scale = 10.0; expon -= 1; } } // Return signed and scaled floating point result. out = sign (frac ? (value / scale) : (value * scale)); } else { size_t cnt = 0; while ((p + cnt) != '\0' && (p + cnt) != ' ' && (p + cnt) != '\t' && (p + cnt) != ',' && (p + cnt) != '\n' && (p + cnt) != '\r' && (p + cnt) != ':') { ++cnt; } if (cnt > 0) { std::string tmp_str(p, cnt); std::transform(tmp_str.begin(), tmp_str.end(), tmp_str.begin(), Common::tolower); if (tmp_str == std::string("na") \|\| tmp_str == std::string("nan")) { out = NAN; } else if (tmp_str == std::string("inf") \|\| tmp_str == std::string("infinity")) { out = sign 1e308; } else { Log::Fatal("Unknown token %s in data file", tmp_str.c_str()); } p += cnt; } } while (p == ' ') { ++p; } return p; } inline bool AtoiAndCheck(const char p, int* out) { const char* after = Atoi(p, out); if (after != '\0') { return false; } return true; } inline bool AtofAndCheck(const char p, double* out) { const char* after = Atof(p, out); if (after != '\0') { return false; } return true; } inline static const char SkipSpaceAndTab(const char* p) { while (p == ' ' \|\| p == '\t') { ++p; } return p; } inline static const char* SkipReturn(const char* p) { while (p == '\n' \|\| p == '\r' \|\| p == ' ') { ++p; } return p; } template<typename T, typename T2> inline static std::vector<T2> ArrayCast(const std::vector<T>& arr) { std::vector<T2> ret; for (size_t i = 0; i < arr.size(); ++i) { ret.push_back(static_cast<T2>(arr[i])); } return ret; } template<typename T> inline static std::string ArrayToString(const std::vector<T>& arr, char delimiter) { if (arr.empty()) { return std::string(""); } std::stringstream str_buf; str_buf << std::setprecision(std::numeric_limits<double>::digits10 + 2); str_buf << arr[0]; for (size_t i = 1; i < arr.size(); ++i) { str_buf << delimiter; str_buf << arr[i]; } return str_buf.str(); } template<typename T> inline static std::string ArrayToString(const std::vector<T>& arr, size_t n, char delimiter) { if (arr.empty() \|\| n == 0) { return std::string(""); } std::stringstream str_buf; str_buf << std::setprecision(std::numeric_limits<double>::digits10 + 2); str_buf << arr[0]; for (size_t i = 1; i < std::min(n, arr.size()); ++i) { str_buf << delimiter; str_buf << arr[i]; } return str_buf.str(); } template<typename T, bool is_float> struct __StringToTHelper { T operator()(const std::string& str) const { return static_cast<T>(std::stoll(str)); } }; template<typename T> struct __StringToTHelper<T, true> { T operator()(const std::string& str) const { return static_cast<T>(std::stod(str)); } }; template<typename T> inline static std::vector<T> StringToArray(const std::string& str, char delimiter, size_t n) { if (n == 0) { return std::vector<T>(); } std::vector<std::string> strs = Split(str.c_str(), delimiter); if (strs.size() != n) { Log::Fatal("StringToArray error, size doesn't match."); } std::vector<T> ret(n); __StringToTHelper<T, std::is_floating_point<T>::value> helper; for (size_t i = 0; i < n; ++i) { ret[i] = helper(strs[i]); } return ret; } template<typename T> inline static std::vector<T> StringToArray(const std::string& str, char delimiter) { std::vector<std::string> strs = Split(str.c_str(), delimiter); std::vector<T> ret; ret.reserve(strs.size()); __StringToTHelper<T, std::is_floating_point<T>::value> helper; for (const auto& s : strs) { ret.push_back(helper(s)); } return ret; } template<typename T> inline static std::string Join(const std::vector<T>& strs, const char delimiter) { if (strs.empty()) { return std::string(""); } std::stringstream str_buf; str_buf << std::setprecision(std::numeric_limits<double>::digits10 + 2); str_buf << strs[0]; for (size_t i = 1; i < strs.size(); ++i) { str_buf << delimiter; str_buf << strs[i]; } return str_buf.str(); } template<typename T> inline static std::string Join(const std::vector<T>& strs, size_t start, size_t end, const char* delimiter) { if (end - start <= 0) { return std::string(""); } start = std::min(start, static_cast<size_t>(strs.size()) - 1); end = std::min(end, static_cast<size_t>(strs.size())); std::stringstream str_buf; str_buf << std::setprecision(std::numeric_limits<double>::digits10 + 2); str_buf << strs[start]; for (size_t i = start + 1; i < end; ++i) { str_buf << delimiter; str_buf << strs[i]; } return str_buf.str(); } static inline int64_t Pow2RoundUp(int64_t x) { int64_t t = 1; for (int i = 0; i < 64; ++i) { if (t >= x) { return t; } t <<= 1; } return 0; } /! \brief Do inplace softmax transformaton on p_rec * \param p_rec The input/output vector of the values. / inline void Softmax(std::vector<double> p_rec) { std::vector<double> &rec = p_rec; double wmax = rec[0]; for (size_t i = 1; i < rec.size(); ++i) { wmax = std::max(rec[i], wmax); } double wsum = 0.0f; for (size_t i = 0; i < rec.size(); ++i) { rec[i] = std::exp(rec[i] - wmax); wsum += rec[i]; } for (size_t i = 0; i < rec.size(); ++i) { rec[i] /= static_cast<double>(wsum); } } inline void Softmax(const double input, double* output, int len) { double wmax = input[0]; for (int i = 1; i < len; ++i) { wmax = std::max(input[i], wmax); } double wsum = 0.0f; for (int i = 0; i < len; ++i) { output[i] = std::exp(input[i] - wmax); wsum += output[i]; } for (int i = 0; i < len; ++i) { output[i] /= static_cast<double>(wsum); } } template<typename T> std::vector<const T> ConstPtrInVectorWrapper(const std::vector<std::unique_ptr<T>>& input) { std::vector<const T> ret; for (size_t i = 0; i < input.size(); ++i) { ret.push_back(input.at(i).get()); } return ret; } template<typename T1, typename T2> inline void SortForPair(std::vector<T1>& keys, std::vector<T2>& values, size_t start, bool is_reverse = false) { std::vector<std::pair<T1, T2>> arr; for (size_t i = start; i < keys.size(); ++i) { arr.emplace_back(keys[i], values[i]); } if (!is_reverse) { std::sort(arr.begin(), arr.end(), [](const std::pair<T1, T2>& a, const std::pair<T1, T2>& b) { return a.first < b.first; }); } else { std::sort(arr.begin(), arr.end(), [](const std::pair<T1, T2>& a, const std::pair<T1, T2>& b) { return a.first > b.first; }); } for (size_t i = start; i < arr.size(); ++i) { keys[i] = arr[i].first; values[i] = arr[i].second; } } /* * approximate hessians of absolute loss with Gaussian function * cf. https://en.wikipedia.org/wiki/Gaussian_function * * y is a prediction. * t means true target. * g means gradient. * eta is a parameter to control the width of Gaussian function. * w means weights. / inline static double ApproximateHessianWithGaussian(const double y, const double t, const double g, const double eta, const double w=1.0f) { const double diff = y - t; const double pi = 4.0 std::atan(1.0); const double x = std::fabs(diff); const double a = 2.0 * std::fabs(g) * w; // difference of two first derivatives, (zero to inf) and (zero to -inf). const double b = 0.0; const double c = std::max((std::fabs(y) + std::fabs(t)) * eta, 1.0e-10); return w * std::exp(-(x - b) * (x - b) / (2.0 * c * c)) * a / (c * std::sqrt(2 * pi)); } template <typename T> inline static std::vector<T> Vector2Ptr(std::vector<std::vector<T>>& data) { std::vector<T> ptr(data.size()); for (size_t i = 0; i < data.size(); ++i) { ptr[i] = data[i].data(); } return ptr; } template <typename T> inline static std::vector<int> VectorSize(const std::vector<std::vector<T>>& data) { std::vector<int> ret(data.size()); for (size_t i = 0; i < data.size(); ++i) { ret[i] = static_cast<int>(data[i].size()); } return ret; } inline static double AvoidInf(double x) { if (x >= 1e300) { return 1e300; } else if(x <= -1e300) { return -1e300; } else { return x; } } template<class _Iter> inline static typename std::iterator_traits<_Iter>::value_type* IteratorValType(_Iter) { return (0); } template<class _RanIt, class _Pr, class _VTRanIt> inline static void ParallelSort(_RanIt _First, _RanIt _Last, _Pr _Pred, _VTRanIt) { size_t len = _Last - _First; const size_t kMinInnerLen = 1024; int num_threads = 1; #pragma omp parallel #pragma omp master { num_threads = omp_get_num_threads(); } if (len <= kMinInnerLen \|\| num_threads <= 1) { std::sort(_First, _Last, _Pred); return; } size_t inner_size = (len + num_threads - 1) / num_threads; inner_size = std::max(inner_size, kMinInnerLen); num_threads = static_cast<int>((len + inner_size - 1) / inner_size); #pragma omp parallel for schedule(static,1) for (int i = 0; i < num_threads; ++i) { size_t left = inner_sizei; size_t right = left + inner_size; right = std::min(right, len); if (right > left) { std::sort(_First + left, _First + right, _Pred); } } // Buffer for merge. std::vector<_VTRanIt> temp_buf(len); _RanIt buf = temp_buf.begin(); size_t s = inner_size; // Recursive merge while (s < len) { int loop_size = static_cast<int>((len + s * 2 - 1) / (s * 2)); #pragma omp parallel for schedule(static,1) for (int i = 0; i < loop_size; ++i) { size_t left = i * 2 * s; size_t mid = left + s; size_t right = mid + s; right = std::min(len, right); if (mid >= right) { continue; } std::copy(_First + left, _First + mid, buf + left); std::merge(buf + left, buf + mid, _First + mid, _First + right, _First + left, _Pred); } s = 2; } } template<class _RanIt, class _Pr> inline static void ParallelSort(_RanIt _First, _RanIt _Last, _Pr _Pred) { return ParallelSort(_First, _Last, _Pred, IteratorValType(_First)); } // Check that all y[] are in interval [ymin, ymax] (end points included); throws error if not template <typename T> inline void CheckElementsIntervalClosed(const T y, T ymin, T ymax, int ny, const char callername) { for (int i = 0; i < ny; ++i) { if (y[i] < ymin \|\| y[i] > ymax) { std::ostringstream os; os << "[%s]: does not tolerate element [#%i = " << y[i] << "] outside [" << ymin << ", " << ymax << "]"; Log::Fatal(os.str().c_str(), callername, i); } } } // One-pass scan over array w with nw elements: find min, max and sum of elements; // this is useful for checking weight requirements. template <typename T1, typename T2> inline void ObtainMinMaxSum(const T1 w, int nw, T1 mi, T1 ma, T2 su) { T1 minw = w[0]; T1 maxw = w[0]; T2 sumw = static_cast<T2>(w[0]); for (int i = 1; i < nw; ++i) { sumw += w[i]; if (w[i] < minw) minw = w[i]; if (w[i] > maxw) maxw = w[i]; } if (mi != nullptr) mi = minw; if (ma != nullptr) ma = maxw; if (su != nullptr) su = sumw; } template<class T> inline std::vector<uint32_t> ConstructBitset(const T* vals, int n) { std::vector<uint32_t> ret; for (int i = 0; i < n; ++i) { int i1 = vals[i] / 32; int i2 = vals[i] % 32; if (static_cast<int>(ret.size()) < i1 + 1) { ret.resize(i1 + 1, 0); } ret[i1] \|= (1 << i2); } return ret; } template<class T> inline bool FindInBitset(const uint32_t* bits, int n, T pos) { int i1 = pos / 32; if (i1 >= n) { return false; } int i2 = pos % 32; return (bits[i1] >> i2) & 1; } } // namespace Common } // namespace LightGBM #endif // LightGBM_UTILS_COMMON_FUN_H_
rose_example1_OpenMP.c	#include <omp.h> #include <stdio.h> #include <sys/time.h> #define N 30000 int main() { int i; int j; double x[30002UL][30002UL]; double y[30002UL][30002UL]; double sum; double tmp; //for timing the code section struct timeval start; struct timeval end; float delta; for (i = 0; i <= 30000 + 1; i++) { for (j = 0; j <= 30000 + 1; j++) { x[i][j] = (((double )((i + j) % 3)) - 0.9999); } } printf("\nMemory allocation done successfully\n"); //start timer and calculation gettimeofday(&start,0); #pragma omp parallel default(none) shared(sum,x,y) private(j,i,tmp) { #pragma omp for reduction ( + :sum) for (j = 1; j < 30000 + 1; j++) { for (i = 1; i < 30000 + 1; i++) { tmp = (0.2 * ((((x[i][j] + x[i - 1][j]) + x[i + 1][j]) + x[i][j - 1]) + x[i][j + 1])); y[i][j] = tmp; sum = (sum + tmp); } } } //stop timer and calculation gettimeofday(&end,0); delta = (((((end.tv_sec - start.tv_sec) * 1000000u) + end.tv_usec) - start.tv_usec) / 1.e6); printf("\nThe total sum is: %lf\n",sum); //print time to completion printf("run time = %fs\n",delta); return 0; }
3d7pt.lbpar.c	#include <omp.h> #include <math.h> #define ceild(n,d) ceil(((double)(n))/((double)(d))) #define floord(n,d) floor(((double)(n))/((double)(d))) #define max(x,y) ((x) > (y)? (x) : (y)) #define min(x,y) ((x) < (y)? (x) : (y)) /* * Order-1, 3D 7 point stencil * Adapted from PLUTO and Pochoir test bench * * Tareq Malas / #include <stdio.h> #include <stdlib.h> #include <sys/time.h> #ifdef LIKWID_PERFMON #include <likwid.h> #endif #include "print_utils.h" #define TESTS 2 #define MAX(a,b) ((a) > (b) ? a : b) #define MIN(a,b) ((a) < (b) ? a : b) / Subtract the `struct timeval' values X and Y, * storing the result in RESULT. * * Return 1 if the difference is negative, otherwise 0. / int timeval_subtract(struct timeval result, struct timeval x, struct timeval y) { /* Perform the carry for the later subtraction by updating y. / if (x->tv_usec < y->tv_usec) { int nsec = (y->tv_usec - x->tv_usec) / 1000000 + 1; y->tv_usec -= 1000000 nsec; y->tv_sec += nsec; } if (x->tv_usec - y->tv_usec > 1000000) { int nsec = (x->tv_usec - y->tv_usec) / 1000000; y->tv_usec += 1000000 * nsec; y->tv_sec -= nsec; } /* Compute the time remaining to wait. * tv_usec is certainly positive. / result->tv_sec = x->tv_sec - y->tv_sec; result->tv_usec = x->tv_usec - y->tv_usec; / Return 1 if result is negative. / return x->tv_sec < y->tv_sec; } int main(int argc, char argv[]) { int t, i, j, k, test; int Nx, Ny, Nz, Nt; if (argc > 3) { Nx = atoi(argv[1])+2; Ny = atoi(argv[2])+2; Nz = atoi(argv[3])+2; } if (argc > 4) Nt = atoi(argv[4]); double **A = (double ) malloc(sizeof(double)2); A[0] = (double *) malloc(sizeof(double)Nz); A[1] = (double ) malloc(sizeof(double)Nz); for(i=0; i<Nz; i++){ A[0][i] = (double) malloc(sizeof(double)Ny); A[1][i] = (double) malloc(sizeof(double)Ny); for(j=0;j<Ny;j++){ A[0][i][j] = (double) malloc(sizeof(double)Nx); A[1][i][j] = (double) malloc(sizeof(double)Nx); } } // tile size information, including extra element to decide the list length int tile_size = (int) malloc(sizeof(int)); tile_size[0] = -1; // The list is modified here before source-to-source transformations tile_size = (int) realloc((void )tile_size, sizeof(int)5); tile_size[0] = 16; tile_size[1] = 16; tile_size[2] = 4; tile_size[3] = 256; tile_size[4] = -1; // for timekeeping int ts_return = -1; struct timeval start, end, result; double tdiff = 0.0, min_tdiff=1.e100; const int BASE = 1024; const double alpha = 0.0876; const double beta = 0.0765; // initialize variables // srand(42); for (i = 1; i < Nz; i++) { for (j = 1; j < Ny; j++) { for (k = 1; k < Nx; k++) { A[0][i][j][k] = 1.0 * (rand() % BASE); } } } #ifdef LIKWID_PERFMON LIKWID_MARKER_INIT; #pragma omp parallel { LIKWID_MARKER_THREADINIT; #pragma omp barrier LIKWID_MARKER_START("calc"); } #endif int num_threads = 1; #if defined(_OPENMP) num_threads = omp_get_max_threads(); #endif for(test=0; test<TESTS; test++){ gettimeofday(&start, 0); // serial execution - Addition: 6 && Multiplication: 2 /* Copyright (C) 1991-2014 Free Software Foundation, Inc. This file is part of the GNU C Library. The GNU C Library is free software; you can redistribute it and/or modify it under the terms of the GNU Lesser General Public License as published by the Free Software Foundation; either version 2.1 of the License, or (at your option) any later version. The GNU C Library is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU Lesser General Public License for more details. You should have received a copy of the GNU Lesser General Public License along with the GNU C Library; if not, see <http://www.gnu.org/licenses/>. / / This header is separate from features.h so that the compiler can include it implicitly at the start of every compilation. It must not itself include <features.h> or any other header that includes <features.h> because the implicit include comes before any feature test macros that may be defined in a source file before it first explicitly includes a system header. GCC knows the name of this header in order to preinclude it. / / glibc's intent is to support the IEC 559 math functionality, real and complex. If the GCC (4.9 and later) predefined macros specifying compiler intent are available, use them to determine whether the overall intent is to support these features; otherwise, presume an older compiler has intent to support these features and define these macros by default. / / wchar_t uses ISO/IEC 10646 (2nd ed., published 2011-03-15) / Unicode 6.0. / / We do not support C11 <threads.h>. / int t1, t2, t3, t4, t5, t6, t7, t8; int lb, ub, lbp, ubp, lb2, ub2; register int lbv, ubv; / Start of CLooG code / if ((Nt >= 2) && (Nx >= 3) && (Ny >= 3) && (Nz >= 3)) { for (t1=-1;t1<=floord(Nt-2,8);t1++) { lbp=max(ceild(t1,2),ceild(16t1-Nt+3,16)); ubp=min(floord(Nt+Nz-4,16),floord(8t1+Nz+5,16)); #pragma omp parallel for private(lbv,ubv,t3,t4,t5,t6,t7,t8) for (t2=lbp;t2<=ubp;t2++) { for (t3=max(max(0,ceild(16t2-Nz,4)),2t1);t3<=min(min(min(floord(Nt+Ny-4,4),floord(8t1+Ny+13,4)),floord(16t2+Ny+12,4)),floord(16t1-16t2+Nz+Ny+11,4));t3++) { for (t4=max(max(max(0,ceild(t1-31,32)),ceild(16t2-Nz-252,256)),ceild(4t3-Ny-252,256));t4<=min(min(min(min(floord(4t3+Nx,256),floord(Nt+Nx-4,256)),floord(8t1+Nx+13,256)),floord(16t2+Nx+12,256)),floord(16t1-16t2+Nz+Nx+11,256));t4++) { for (t5=max(max(max(max(max(0,8t1),16t1-16t2+1),16t2-Nz+2),4t3-Ny+2),256t4-Nx+2);t5<=min(min(min(min(min(Nt-2,8t1+15),16t2+14),4t3+2),256t4+254),16t1-16t2+Nz+13);t5++) { for (t6=max(max(16t2,t5+1),-16t1+16t2+2t5-15);t6<=min(min(16t2+15,-16t1+16t2+2t5),t5+Nz-2);t6++) { for (t7=max(4t3,t5+1);t7<=min(4t3+3,t5+Ny-2);t7++) { lbv=max(256t4,t5+1); ubv=min(256t4+255,t5+Nx-2); #pragma ivdep #pragma vector always for (t8=lbv;t8<=ubv;t8++) { A[( t5 + 1) % 2][ (-t5+t6)][ (-t5+t7)][ (-t5+t8)] = ((alpha * A[ t5 % 2][ (-t5+t6)][ (-t5+t7)][ (-t5+t8)]) + (beta * (((((A[ t5 % 2][ (-t5+t6) - 1][ (-t5+t7)][ (-t5+t8)] + A[ t5 % 2][ (-t5+t6)][ (-t5+t7) - 1][ (-t5+t8)]) + A[ t5 % 2][ (-t5+t6)][ (-t5+t7)][ (-t5+t8) - 1]) + A[ t5 % 2][ (-t5+t6) + 1][ (-t5+t7)][ (-t5+t8)]) + A[ t5 % 2][ (-t5+t6)][ (-t5+t7) + 1][ (-t5+t8)]) + A[ t5 % 2][ (-t5+t6)][ (-t5+t7)][ (-t5+t8) + 1])));; } } } } } } } } } /* End of CLooG code / gettimeofday(&end, 0); ts_return = timeval_subtract(&result, &end, &start); tdiff = (double) (result.tv_sec + result.tv_usec 1.0e-6); min_tdiff = min(min_tdiff, tdiff); printf("Rank 0 TEST# %d time: %f\n", test, tdiff); } PRINT_RESULTS(1, "constant") #ifdef LIKWID_PERFMON #pragma omp parallel { LIKWID_MARKER_STOP("calc"); } LIKWID_MARKER_CLOSE; #endif // Free allocated arrays (Causing performance degradation /* for(i=0; i<Nz; i++){ for(j=0;j<Ny;j++){ free(A[0][i][j]); free(A[1][i][j]); } free(A[0][i]); free(A[1][i]); } free(A[0]); free(A[1]); */ return 0; }
CFD_assembler_ExtForces.c	/* This file is part of redbKIT. * Copyright (c) 2016, Ecole Polytechnique Federale de Lausanne (EPFL) * Author: Federico Negri <federico.negri@epfl.ch> / #include "mex.h" #include <stdio.h> #include <math.h> #include "blas.h" #include <string.h> #ifdef _OPENMP #include <omp.h> #else #warning "OpenMP not enabled. Compile with mex CFD_assembler_ExtForces.c CFLAGS="\$CFLAGS -fopenmp" LDFLAGS="\$LDFLAGS -fopenmp"" #endif void mexFunction(int nlhs, mxArray plhs[], int nrhs, const mxArray* prhs[]) { /* Check for proper number of arguments. / if(nrhs!=6) { mexErrMsgTxt("6 inputs are required."); } else if(nlhs>2) { mexErrMsgTxt("Too many output arguments."); } double f = mxGetPr(prhs[0]); int noe = mxGetN(prhs[1]); int numRowsElements = mxGetM(prhs[1]); double* elements = mxGetPr(prhs[1]); double* nln_ptr = mxGetPr(prhs[2]); int nln = (int)(nln_ptr[0]); plhs[0] = mxCreateDoubleMatrix(nlnnoe,1, mxREAL); plhs[1] = mxCreateDoubleMatrix(nlnnoe,1, mxREAL); double* myRrows = mxGetPr(plhs[0]); double* myRcoef = mxGetPr(plhs[1]); int k,l; int q; int NumQuadPoints = mxGetN(prhs[3]); double* w = mxGetPr(prhs[3]); double* detjac = mxGetPr(prhs[4]); double* phi = mxGetPr(prhs[5]); /* Assembly: loop over the elements / int ie; int a; #pragma omp parallel for shared(detjac,elements,myRrows,myRcoef) private(ie,a,q) firstprivate(phi,w,numRowsElements,nln) for (ie = 0; ie < noe; ie = ie + 1 ) { int ii = 0; / loop over test functions --> a / for (a = 0; a < nln; a = a + 1 ) { double floc = 0; for (q = 0; q < NumQuadPoints; q = q + 1 ) { floc = floc + ( phi[a+qnln] * f[ie+qnoe] ) w[q]; } myRrows[ienln+ii] = elements[a+ienumRowsElements]; myRcoef[ienln+ii] = flocdetjac[ie]; ii = ii + 1; } } }
nstream-memcpy-target.c	/// /// Copyright (c) 2019, Intel Corporation /// Copyright (c) 2021, NVIDIA /// /// Redistribution and use in source and binary forms, with or without /// modification, are permitted provided that the following conditions /// are met: /// /// * Redistributions of source code must retain the above copyright /// notice, this list of conditions and the following disclaimer. /// * Redistributions in binary form must reproduce the above /// copyright notice, this list of conditions and the following /// disclaimer in the documentation and/or other materials provided /// with the distribution. /// * Neither the name of Intel Corporation nor the names of its /// contributors may be used to endorse or promote products /// derived from this software without specific prior written /// permission. /// /// THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS /// "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT /// LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS /// FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE /// COPYRIGHT OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, /// INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, /// BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; /// LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER /// CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT /// LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN /// ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE /// POSSIBILITY OF SUCH DAMAGE. ////////////////////////////////////////////////////////////////////// /// /// NAME: nstream /// /// PURPOSE: To compute memory bandwidth when adding a vector of a given /// number of double precision values to the scalar multiple of /// another vector of the same length, and storing the result in /// a third vector. /// /// USAGE: The program takes as input the number /// of iterations to loop over the triad vectors and /// the length of the vectors. /// /// <progname> <# iterations> <vector length> /// /// The output consists of diagnostics to make sure the /// algorithm worked, and of timing statistics. /// /// NOTES: Bandwidth is determined as the number of words read, plus the /// number of words written, times the size of the words, divided /// by the execution time. For a vector length of N, the total /// number of words read and written is 4Nsizeof(double). /// /// /// HISTORY: This code is loosely based on the Stream benchmark by John /// McCalpin, but does not follow all the Stream rules. Hence, /// reported results should not be associated with Stream in /// external publications /// /// Converted to C++11 by Jeff Hammond, November 2017. /// Converted to C11 by Jeff Hammond, February 2019. /// ////////////////////////////////////////////////////////////////////// #include "prk_util.h" #include "prk_openmp.h" OMP_REQUIRES(unified_address) int main(int argc, char * argv[]) { printf("Parallel Research Kernels version %d\n", PRKVERSION ); printf("C11/OpenMP TARGET STREAM triad: A = B + scalar * C\n"); ////////////////////////////////////////////////////////////////////// /// Read and test input parameters ////////////////////////////////////////////////////////////////////// if (argc < 3) { printf("Usage: <# iterations> <vector length>\n"); return 1; } int iterations = atoi(argv[1]); if (iterations < 1) { printf("ERROR: iterations must be >= 1\n"); return 1; } // length of a the vector size_t length = atol(argv[2]); if (length <= 0) { printf("ERROR: Vector length must be greater than 0\n"); return 1; } int device = (argc > 3) ? atol(argv[3]) : omp_get_default_device(); if ( (device < 0 \|\| omp_get_num_devices() <= device ) && (device != omp_get_default_device()) ) { printf("ERROR: device number %d is not valid.\n", device); return 1; } printf("Number of iterations = %d\n", iterations); printf("Vector length = %zu\n", length); printf("OpenMP Device = %d\n", device); ////////////////////////////////////////////////////////////////////// // Allocate space and perform the computation ////////////////////////////////////////////////////////////////////// double nstream_time = 0.0; int host = omp_get_initial_device(); size_t bytes = lengthsizeof(double); double restrict h_A = omp_target_alloc(bytes, host); double * restrict h_B = omp_target_alloc(bytes, host); double * restrict h_C = omp_target_alloc(bytes, host); double scalar = 3.0; #pragma omp parallel for simd schedule(static) for (size_t i=0; i<length; i++) { h_A[i] = 0.0; h_B[i] = 2.0; h_C[i] = 2.0; } double * restrict d_A = omp_target_alloc(bytes, device); double * restrict d_B = omp_target_alloc(bytes, device); double * restrict d_C = omp_target_alloc(bytes, device); int rc = 0; rc = omp_target_memcpy(d_A, h_A, bytes, 0, 0, device, host); if (rc) { printf("ERROR: omp_target_memcpy(A) returned %d\n", rc); abort(); } rc = omp_target_memcpy(d_B, h_B, bytes, 0, 0, device, host); if (rc) { printf("ERROR: omp_target_memcpy(B) returned %d\n", rc); abort(); } rc = omp_target_memcpy(d_C, h_C, bytes, 0, 0, device, host); if (rc) { printf("ERROR: omp_target_memcpy(C) returned %d\n", rc); abort(); } omp_target_free(h_C, host); omp_target_free(h_B, host); { for (int iter = 0; iter<=iterations; iter++) { if (iter==1) nstream_time = omp_get_wtime(); OMP_TARGET( teams distribute parallel for simd schedule(static) device(device) is_device_ptr(d_A,d_B,d_C) ) for (size_t i=0; i<length; i++) { d_A[i] += d_B[i] + scalar * d_C[i]; } } nstream_time = omp_get_wtime() - nstream_time; } rc = omp_target_memcpy(h_A, d_A, bytes, 0, 0, host, device); if (rc) { printf("ERROR: omp_target_memcpy(A) returned %d\n", rc); abort(); } omp_target_free(d_C, device); omp_target_free(d_B, device); omp_target_free(d_A, device); ////////////////////////////////////////////////////////////////////// /// Analyze and output results ////////////////////////////////////////////////////////////////////// double ar = 0.0; double br = 2.0; double cr = 2.0; for (int i=0; i<=iterations; i++) { ar += br + scalar * cr; } ar = length; double asum = 0.0; #pragma omp parallel for reduction(+:asum) for (size_t i=0; i<length; i++) { asum += fabs(h_A[i]); } omp_target_free(h_A, host); double epsilon=1.e-8; if (fabs(ar-asum)/asum > epsilon) { printf("Failed Validation on output array\n" " Expected checksum: %lf\n" " Observed checksum: %lf\n" "ERROR: solution did not validate\n", ar, asum); return 1; } else { printf("Solution validates\n"); double avgtime = nstream_time/iterations; double nbytes = 4.0 length * sizeof(double); printf("Rate (MB/s): %lf Avg time (s): %lf\n", 1.e-6*nbytes/avgtime, avgtime); } return 0; }
cpu_bound.c	/* * Copyright (c) 2009, 2010, 2011, ETH Zurich. * All rights reserved. * * This file is distributed under the terms in the attached LICENSE file. * If you do not find this file, copies can be found by writing to: * ETH Zurich D-INFK, Universitaetstrasse 6, CH-8092 Zurich. Attn: Systems Group. / #include <stdlib.h> #include <stdio.h> #include <time.h> #include <assert.h> #include <stdint.h> #include <omp.h> #include <arch/x86/barrelfish_kpi/asm_inlines_arch.h> #define WORK_PERIOD 5000000000UL #define STACK_SIZE (64 1024) int main(int argc, char argv[]) { uint64_t now, start; volatile uint64_t workcnt, workload = 0; int64_t workmax = 1000; int64_t i; if(argc == 1) { printf("calibrating...\n"); do { workload = 0; workmax = 2; start = rdtsc(); for(i = 0; i < workmax; i++) { workload++; } now = rdtsc(); } while(now - start < WORK_PERIOD); // Compute so the max number of CPUs would calc for WORK_PERIOD workmax *= omp_get_num_procs(); printf("workmax = %ld\n", workmax); return 0; } else { workmax = atol(argv[1]); } int nthreads = omp_get_max_threads(); if(argc == 3) { nthreads = atoi(argv[2]); bomp_bomp_init(nthreads); omp_set_num_threads(nthreads); } printf("threads %d, workmax %ld, CPUs %d\n", nthreads, workmax, omp_get_num_procs()); start = rdtsc(); // Do some work #pragma omp parallel for private(workcnt) for(i = 0; i < workmax; i++) { workcnt++; } now = rdtsc(); printf("%s: threads %d, compute time %lu ticks\n", argv[0], nthreads, now - start); for(;;); return 0; }
Sema.h	//===--- Sema.h - Semantic Analysis & AST Building --------------- C++ --===// // // Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions. // See https://llvm.org/LICENSE.txt for license information. // SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception // //===----------------------------------------------------------------------===// // // This file defines the Sema class, which performs semantic analysis and // builds ASTs. // //===----------------------------------------------------------------------===// #ifndef LLVM_CLANG_SEMA_SEMA_H #define LLVM_CLANG_SEMA_SEMA_H #include "clang/AST/ASTConcept.h" #include "clang/AST/ASTFwd.h" #include "clang/AST/Attr.h" #include "clang/AST/Availability.h" #include "clang/AST/ComparisonCategories.h" #include "clang/AST/DeclTemplate.h" #include "clang/AST/DeclarationName.h" #include "clang/AST/Expr.h" #include "clang/AST/ExprCXX.h" #include "clang/AST/ExprConcepts.h" #include "clang/AST/ExprObjC.h" #include "clang/AST/ExprOpenMP.h" #include "clang/AST/ExternalASTSource.h" #include "clang/AST/LocInfoType.h" #include "clang/AST/MangleNumberingContext.h" #include "clang/AST/NSAPI.h" #include "clang/AST/PrettyPrinter.h" #include "clang/AST/StmtCXX.h" #include "clang/AST/StmtOpenMP.h" #include "clang/AST/TypeLoc.h" #include "clang/AST/TypeOrdering.h" #include "clang/Basic/BitmaskEnum.h" #include "clang/Basic/Builtins.h" #include "clang/Basic/DarwinSDKInfo.h" #include "clang/Basic/DiagnosticSema.h" #include "clang/Basic/ExpressionTraits.h" #include "clang/Basic/Module.h" #include "clang/Basic/OpenCLOptions.h" #include "clang/Basic/OpenMPKinds.h" #include "clang/Basic/PragmaKinds.h" #include "clang/Basic/Specifiers.h" #include "clang/Basic/TemplateKinds.h" #include "clang/Basic/TypeTraits.h" #include "clang/Sema/AnalysisBasedWarnings.h" #include "clang/Sema/CleanupInfo.h" #include "clang/Sema/DeclSpec.h" #include "clang/Sema/ExternalSemaSource.h" #include "clang/Sema/IdentifierResolver.h" #include "clang/Sema/ObjCMethodList.h" #include "clang/Sema/Ownership.h" #include "clang/Sema/Scope.h" #include "clang/Sema/SemaConcept.h" #include "clang/Sema/TypoCorrection.h" #include "clang/Sema/Weak.h" #include "llvm/ADT/ArrayRef.h" #include "llvm/ADT/Optional.h" #include "llvm/ADT/SetVector.h" #include "llvm/ADT/SmallBitVector.h" #include "llvm/ADT/SmallPtrSet.h" #include "llvm/ADT/SmallSet.h" #include "llvm/ADT/SmallVector.h" #include "llvm/ADT/TinyPtrVector.h" #include "llvm/Frontend/OpenMP/OMPConstants.h" #include <deque> #include <memory> #include <string> #include <tuple> #include <vector> namespace llvm { class APSInt; template <typename ValueT> struct DenseMapInfo; template <typename ValueT, typename ValueInfoT> class DenseSet; class SmallBitVector; struct InlineAsmIdentifierInfo; } namespace clang { class ADLResult; class ASTConsumer; class ASTContext; class ASTMutationListener; class ASTReader; class ASTWriter; class ArrayType; class ParsedAttr; class BindingDecl; class BlockDecl; class CapturedDecl; class CXXBasePath; class CXXBasePaths; class CXXBindTemporaryExpr; typedef SmallVector<CXXBaseSpecifier, 4> CXXCastPath; class CXXConstructorDecl; class CXXConversionDecl; class CXXDeleteExpr; class CXXDestructorDecl; class CXXFieldCollector; class CXXMemberCallExpr; class CXXMethodDecl; class CXXScopeSpec; class CXXTemporary; class CXXTryStmt; class CallExpr; class ClassTemplateDecl; class ClassTemplatePartialSpecializationDecl; class ClassTemplateSpecializationDecl; class VarTemplatePartialSpecializationDecl; class CodeCompleteConsumer; class CodeCompletionAllocator; class CodeCompletionTUInfo; class CodeCompletionResult; class CoroutineBodyStmt; class Decl; class DeclAccessPair; class DeclContext; class DeclRefExpr; class DeclaratorDecl; class DeducedTemplateArgument; class DependentDiagnostic; class DesignatedInitExpr; class Designation; class EnableIfAttr; class EnumConstantDecl; class Expr; class ExtVectorType; class FormatAttr; class FriendDecl; class FunctionDecl; class FunctionProtoType; class FunctionTemplateDecl; class ImplicitConversionSequence; typedef MutableArrayRef<ImplicitConversionSequence> ConversionSequenceList; class InitListExpr; class InitializationKind; class InitializationSequence; class InitializedEntity; class IntegerLiteral; class LabelStmt; class LambdaExpr; class LangOptions; class LocalInstantiationScope; class LookupResult; class MacroInfo; typedef ArrayRef<std::pair<IdentifierInfo , SourceLocation>> ModuleIdPath; class ModuleLoader; class MultiLevelTemplateArgumentList; class NamedDecl; class ObjCCategoryDecl; class ObjCCategoryImplDecl; class ObjCCompatibleAliasDecl; class ObjCContainerDecl; class ObjCImplDecl; class ObjCImplementationDecl; class ObjCInterfaceDecl; class ObjCIvarDecl; template <class T> class ObjCList; class ObjCMessageExpr; class ObjCMethodDecl; class ObjCPropertyDecl; class ObjCProtocolDecl; class OMPThreadPrivateDecl; class OMPRequiresDecl; class OMPDeclareReductionDecl; class OMPDeclareSimdDecl; class OMPClause; struct OMPVarListLocTy; struct OverloadCandidate; enum class OverloadCandidateParamOrder : char; enum OverloadCandidateRewriteKind : unsigned; class OverloadCandidateSet; class OverloadExpr; class ParenListExpr; class ParmVarDecl; class Preprocessor; class PseudoDestructorTypeStorage; class PseudoObjectExpr; class QualType; class StandardConversionSequence; class Stmt; class StringLiteral; class SwitchStmt; class TemplateArgument; class TemplateArgumentList; class TemplateArgumentLoc; class TemplateDecl; class TemplateInstantiationCallback; class TemplateParameterList; class TemplatePartialOrderingContext; class TemplateTemplateParmDecl; class Token; class TypeAliasDecl; class TypedefDecl; class TypedefNameDecl; class TypeLoc; class TypoCorrectionConsumer; class UnqualifiedId; class UnresolvedLookupExpr; class UnresolvedMemberExpr; class UnresolvedSetImpl; class UnresolvedSetIterator; class UsingDecl; class UsingShadowDecl; class ValueDecl; class VarDecl; class VarTemplateSpecializationDecl; class VisibilityAttr; class VisibleDeclConsumer; class IndirectFieldDecl; struct DeductionFailureInfo; class TemplateSpecCandidateSet; namespace sema { class AccessedEntity; class BlockScopeInfo; class Capture; class CapturedRegionScopeInfo; class CapturingScopeInfo; class CompoundScopeInfo; class DelayedDiagnostic; class DelayedDiagnosticPool; class FunctionScopeInfo; class LambdaScopeInfo; class PossiblyUnreachableDiag; class SemaPPCallbacks; class TemplateDeductionInfo; } namespace threadSafety { class BeforeSet; void threadSafetyCleanup(BeforeSet* Cache); } // FIXME: No way to easily map from TemplateTypeParmTypes to // TemplateTypeParmDecls, so we have this horrible PointerUnion. typedef std::pair<llvm::PointerUnion<const TemplateTypeParmType, NamedDecl>, SourceLocation> UnexpandedParameterPack; /// Describes whether we've seen any nullability information for the given /// file. struct FileNullability { /// The first pointer declarator (of any pointer kind) in the file that does /// not have a corresponding nullability annotation. SourceLocation PointerLoc; /// The end location for the first pointer declarator in the file. Used for /// placing fix-its. SourceLocation PointerEndLoc; /// Which kind of pointer declarator we saw. uint8_t PointerKind; /// Whether we saw any type nullability annotations in the given file. bool SawTypeNullability = false; }; /// A mapping from file IDs to a record of whether we've seen nullability /// information in that file. class FileNullabilityMap { /// A mapping from file IDs to the nullability information for each file ID. llvm::DenseMap<FileID, FileNullability> Map; /// A single-element cache based on the file ID. struct { FileID File; FileNullability Nullability; } Cache; public: FileNullability &operator[](FileID file) { // Check the single-element cache. if (file == Cache.File) return Cache.Nullability; // It's not in the single-element cache; flush the cache if we have one. if (!Cache.File.isInvalid()) { Map[Cache.File] = Cache.Nullability; } // Pull this entry into the cache. Cache.File = file; Cache.Nullability = Map[file]; return Cache.Nullability; } }; // TODO SYCL Integration header approach relies on an assumption that kernel // lambda objects created by the host compiler and any of the device compilers // will be identical wrt to field types, order and offsets. Some verification // mechanism should be developed to enforce that. // TODO FIXME SYCL Support for SYCL in FE should be refactored: // - kernel identification and generation should be made a separate pass over // AST. RecursiveASTVisitor + VisitFunctionTemplateDecl + // FunctionTemplateDecl::getSpecializations() mechanism could be used for that. // - All SYCL stuff on Sema level should be encapsulated into a single Sema // field // - Move SYCL stuff into a separate header // Represents contents of a SYCL integration header file produced by a SYCL // device compiler and used by SYCL host compiler (via forced inclusion into // compiled SYCL source): // - SYCL kernel names // - SYCL kernel parameters and offsets of corresponding actual arguments class SYCLIntegrationHeader { public: // Kind of kernel's parameters as captured by the compiler in the // kernel lambda or function object enum kernel_param_kind_t { kind_first, kind_accessor = kind_first, kind_std_layout, kind_sampler, kind_pointer, kind_specialization_constants_buffer, kind_stream, kind_last = kind_stream }; public: SYCLIntegrationHeader(Sema &S); /// Emits contents of the header into given stream. void emit(raw_ostream &Out); /// Emits contents of the header into a file with given name. /// Returns true/false on success/failure. bool emit(StringRef MainSrc); /// Signals that subsequent parameter descriptor additions will go to /// the kernel with given name. Starts new kernel invocation descriptor. void startKernel(const FunctionDecl SyclKernel, QualType KernelNameType, SourceLocation Loc, bool IsESIMD, bool IsUnnamedKernel); /// Adds a kernel parameter descriptor to current kernel invocation /// descriptor. void addParamDesc(kernel_param_kind_t Kind, int Info, unsigned Offset); /// Signals that addition of parameter descriptors to current kernel /// invocation descriptor has finished. void endKernel(); /// Registers a specialization constant to emit info for it into the header. void addSpecConstant(StringRef IDName, QualType IDType); /// Update the names of a kernel description based on its SyclKernel. void updateKernelNames(const FunctionDecl SyclKernel, StringRef Name, StringRef StableName) { auto Itr = llvm::find_if(KernelDescs, [SyclKernel](const KernelDesc &KD) { return KD.SyclKernel == SyclKernel; }); assert(Itr != KernelDescs.end() && "Unknown kernel description"); Itr->updateKernelNames(Name, StableName); } /// Note which free functions (this_id, this_item, etc) are called within the /// kernel void setCallsThisId(bool B); void setCallsThisItem(bool B); void setCallsThisNDItem(bool B); void setCallsThisGroup(bool B); private: // Kernel actual parameter descriptor. struct KernelParamDesc { // Represents a parameter kind. kernel_param_kind_t Kind = kind_last; // If Kind is kind_scalar or kind_struct, then // denotes parameter size in bytes (includes padding for structs) // If Kind is kind_accessor // denotes access target; possible access targets are defined in // access/access.hpp int Info = 0; // Offset of the captured parameter value in the lambda or function object. unsigned Offset = 0; KernelParamDesc() = default; }; // there are four free functions the kernel may call (this_id, this_item, // this_nd_item, this_group) struct KernelCallsSYCLFreeFunction { bool CallsThisId = false; bool CallsThisItem = false; bool CallsThisNDItem = false; bool CallsThisGroup = false; }; // Kernel invocation descriptor struct KernelDesc { /// sycl_kernel function associated with this kernel. const FunctionDecl SyclKernel; /// Kernel name. std::string Name; /// Kernel name type. QualType NameType; /// Kernel name with stable lambda name mangling std::string StableName; SourceLocation KernelLocation; /// Whether this kernel is an ESIMD one. bool IsESIMDKernel; /// Descriptor of kernel actual parameters. SmallVector<KernelParamDesc, 8> Params; // Whether kernel calls any of the SYCL free functions (this_item(), // this_id(), etc) KernelCallsSYCLFreeFunction FreeFunctionCalls; // If we are in unnamed kernel/lambda mode AND this is one that the user // hasn't provided an explicit name for. bool IsUnnamedKernel; KernelDesc(const FunctionDecl SyclKernel, QualType NameType, SourceLocation KernelLoc, bool IsESIMD, bool IsUnnamedKernel) : SyclKernel(SyclKernel), NameType(NameType), KernelLocation(KernelLoc), IsESIMDKernel(IsESIMD), IsUnnamedKernel(IsUnnamedKernel) {} void updateKernelNames(StringRef Name, StringRef StableName) { this->Name = Name.str(); this->StableName = StableName.str(); } }; /// Returns the latest invocation descriptor started by /// SYCLIntegrationHeader::startKernel KernelDesc getCurKernelDesc() { return KernelDescs.size() > 0 ? &KernelDescs[KernelDescs.size() - 1] : nullptr; } private: /// Keeps invocation descriptors for each kernel invocation started by /// SYCLIntegrationHeader::startKernel SmallVector<KernelDesc, 4> KernelDescs; using SpecConstID = std::pair<QualType, std::string>; /// Keeps specialization constants met in the translation unit. Maps spec /// constant's ID type to generated unique name. Duplicates are removed at /// integration header emission time. llvm::SmallVector<SpecConstID, 4> SpecConsts; Sema &S; }; class SYCLIntegrationFooter { public: SYCLIntegrationFooter(Sema &S) : S(S) {} bool emit(StringRef MainSrc); void addVarDecl(const VarDecl VD); private: bool emit(raw_ostream &O); Sema &S; llvm::SmallVector<const VarDecl > SpecConstants; void emitSpecIDName(raw_ostream &O, const VarDecl VD); }; /// Tracks expected type during expression parsing, for use in code completion. /// The type is tied to a particular token, all functions that update or consume /// the type take a start location of the token they are looking at as a /// parameter. This avoids updating the type on hot paths in the parser. class PreferredTypeBuilder { public: PreferredTypeBuilder(bool Enabled) : Enabled(Enabled) {} void enterCondition(Sema &S, SourceLocation Tok); void enterReturn(Sema &S, SourceLocation Tok); void enterVariableInit(SourceLocation Tok, Decl D); /// Handles e.g. BaseType{ .D = Tok... void enterDesignatedInitializer(SourceLocation Tok, QualType BaseType, const Designation &D); /// Computing a type for the function argument may require running /// overloading, so we postpone its computation until it is actually needed. /// /// Clients should be very careful when using this funciton, as it stores a /// function_ref, clients should make sure all calls to get() with the same /// location happen while function_ref is alive. /// /// The callback should also emit signature help as a side-effect, but only /// if the completion point has been reached. void enterFunctionArgument(SourceLocation Tok, llvm::function_ref<QualType()> ComputeType); void enterParenExpr(SourceLocation Tok, SourceLocation LParLoc); void enterUnary(Sema &S, SourceLocation Tok, tok::TokenKind OpKind, SourceLocation OpLoc); void enterBinary(Sema &S, SourceLocation Tok, Expr LHS, tok::TokenKind Op); void enterMemAccess(Sema &S, SourceLocation Tok, Expr Base); void enterSubscript(Sema &S, SourceLocation Tok, Expr LHS); /// Handles all type casts, including C-style cast, C++ casts, etc. void enterTypeCast(SourceLocation Tok, QualType CastType); /// Get the expected type associated with this location, if any. /// /// If the location is a function argument, determining the expected type /// involves considering all function overloads and the arguments so far. /// In this case, signature help for these function overloads will be reported /// as a side-effect (only if the completion point has been reached). QualType get(SourceLocation Tok) const { if (!Enabled \|\| Tok != ExpectedLoc) return QualType(); if (!Type.isNull()) return Type; if (ComputeType) return ComputeType(); return QualType(); } private: bool Enabled; /// Start position of a token for which we store expected type. SourceLocation ExpectedLoc; /// Expected type for a token starting at ExpectedLoc. QualType Type; /// A function to compute expected type at ExpectedLoc. It is only considered /// if Type is null. llvm::function_ref<QualType()> ComputeType; }; /// Sema - This implements semantic analysis and AST building for C. class Sema final { Sema(const Sema &) = delete; void operator=(const Sema &) = delete; ///Source of additional semantic information. ExternalSemaSource ExternalSource; ///Whether Sema has generated a multiplexer and has to delete it. bool isMultiplexExternalSource; static bool mightHaveNonExternalLinkage(const DeclaratorDecl FD); bool isVisibleSlow(const NamedDecl D); /// Determine whether two declarations should be linked together, given that /// the old declaration might not be visible and the new declaration might /// not have external linkage. bool shouldLinkPossiblyHiddenDecl(const NamedDecl Old, const NamedDecl New) { if (isVisible(Old)) return true; // See comment in below overload for why it's safe to compute the linkage // of the new declaration here. if (New->isExternallyDeclarable()) { assert(Old->isExternallyDeclarable() && "should not have found a non-externally-declarable previous decl"); return true; } return false; } bool shouldLinkPossiblyHiddenDecl(LookupResult &Old, const NamedDecl New); void setupImplicitSpecialMemberType(CXXMethodDecl SpecialMem, QualType ResultTy, ArrayRef<QualType> Args); public: /// The maximum alignment, same as in llvm::Value. We duplicate them here /// because that allows us not to duplicate the constants in clang code, /// which we must to since we can't directly use the llvm constants. /// The value is verified against llvm here: lib/CodeGen/CGDecl.cpp /// /// This is the greatest alignment value supported by load, store, and alloca /// instructions, and global values. static const unsigned MaxAlignmentExponent = 32; static const uint64_t MaximumAlignment = 1ull << MaxAlignmentExponent; typedef OpaquePtr<DeclGroupRef> DeclGroupPtrTy; typedef OpaquePtr<TemplateName> TemplateTy; typedef OpaquePtr<QualType> TypeTy; OpenCLOptions OpenCLFeatures; FPOptions CurFPFeatures; const LangOptions &LangOpts; Preprocessor &PP; ASTContext &Context; ASTConsumer &Consumer; DiagnosticsEngine &Diags; SourceManager &SourceMgr; /// Flag indicating whether or not to collect detailed statistics. bool CollectStats; /// Code-completion consumer. CodeCompleteConsumer CodeCompleter; /// CurContext - This is the current declaration context of parsing. DeclContext CurContext; /// Generally null except when we temporarily switch decl contexts, /// like in \see ActOnObjCTemporaryExitContainerContext. DeclContext OriginalLexicalContext; /// VAListTagName - The declaration name corresponding to __va_list_tag. /// This is used as part of a hack to omit that class from ADL results. DeclarationName VAListTagName; bool MSStructPragmaOn; // True when \#pragma ms_struct on /// Controls member pointer representation format under the MS ABI. LangOptions::PragmaMSPointersToMembersKind MSPointerToMemberRepresentationMethod; /// Stack of active SEH __finally scopes. Can be empty. SmallVector<Scope, 2> CurrentSEHFinally; /// Source location for newly created implicit MSInheritanceAttrs SourceLocation ImplicitMSInheritanceAttrLoc; /// Holds TypoExprs that are created from `createDelayedTypo`. This is used by /// `TransformTypos` in order to keep track of any TypoExprs that are created /// recursively during typo correction and wipe them away if the correction /// fails. llvm::SmallVector<TypoExpr , 2> TypoExprs; /// pragma clang section kind enum PragmaClangSectionKind { PCSK_Invalid = 0, PCSK_BSS = 1, PCSK_Data = 2, PCSK_Rodata = 3, PCSK_Text = 4, PCSK_Relro = 5 }; enum PragmaClangSectionAction { PCSA_Set = 0, PCSA_Clear = 1 }; struct PragmaClangSection { std::string SectionName; bool Valid = false; SourceLocation PragmaLocation; }; PragmaClangSection PragmaClangBSSSection; PragmaClangSection PragmaClangDataSection; PragmaClangSection PragmaClangRodataSection; PragmaClangSection PragmaClangRelroSection; PragmaClangSection PragmaClangTextSection; enum PragmaMsStackAction { PSK_Reset = 0x0, // #pragma () PSK_Set = 0x1, // #pragma (value) PSK_Push = 0x2, // #pragma (push[, id]) PSK_Pop = 0x4, // #pragma (pop[, id]) PSK_Show = 0x8, // #pragma (show) -- only for "pack"! PSK_Push_Set = PSK_Push \| PSK_Set, // #pragma (push[, id], value) PSK_Pop_Set = PSK_Pop \| PSK_Set, // #pragma (pop[, id], value) }; // #pragma pack and align. class AlignPackInfo { public: // `Native` represents default align mode, which may vary based on the // platform. enum Mode : unsigned char { Native, Natural, Packed, Mac68k }; // #pragma pack info constructor AlignPackInfo(AlignPackInfo::Mode M, unsigned Num, bool IsXL) : PackAttr(true), AlignMode(M), PackNumber(Num), XLStack(IsXL) { assert(Num == PackNumber && "The pack number has been truncated."); } // #pragma align info constructor AlignPackInfo(AlignPackInfo::Mode M, bool IsXL) : PackAttr(false), AlignMode(M), PackNumber(M == Packed ? 1 : UninitPackVal), XLStack(IsXL) {} explicit AlignPackInfo(bool IsXL) : AlignPackInfo(Native, IsXL) {} AlignPackInfo() : AlignPackInfo(Native, false) {} // When a AlignPackInfo itself cannot be used, this returns an 32-bit // integer encoding for it. This should only be passed to // AlignPackInfo::getFromRawEncoding, it should not be inspected directly. static uint32_t getRawEncoding(const AlignPackInfo &Info) { std::uint32_t Encoding{}; if (Info.IsXLStack()) Encoding \|= IsXLMask; Encoding \|= static_cast<uint32_t>(Info.getAlignMode()) << 1; if (Info.IsPackAttr()) Encoding \|= PackAttrMask; Encoding \|= static_cast<uint32_t>(Info.getPackNumber()) << 4; return Encoding; } static AlignPackInfo getFromRawEncoding(unsigned Encoding) { bool IsXL = static_cast<bool>(Encoding & IsXLMask); AlignPackInfo::Mode M = static_cast<AlignPackInfo::Mode>((Encoding & AlignModeMask) >> 1); int PackNumber = (Encoding & PackNumMask) >> 4; if (Encoding & PackAttrMask) return AlignPackInfo(M, PackNumber, IsXL); return AlignPackInfo(M, IsXL); } bool IsPackAttr() const { return PackAttr; } bool IsAlignAttr() const { return !PackAttr; } Mode getAlignMode() const { return AlignMode; } unsigned getPackNumber() const { return PackNumber; } bool IsPackSet() const { // #pragma align, #pragma pack(), and #pragma pack(0) do not set the pack // attriute on a decl. return PackNumber != UninitPackVal && PackNumber != 0; } bool IsXLStack() const { return XLStack; } bool operator==(const AlignPackInfo &Info) const { return std::tie(AlignMode, PackNumber, PackAttr, XLStack) == std::tie(Info.AlignMode, Info.PackNumber, Info.PackAttr, Info.XLStack); } bool operator!=(const AlignPackInfo &Info) const { return !(this == Info); } private: /// \brief True if this is a pragma pack attribute, /// not a pragma align attribute. bool PackAttr; /// \brief The alignment mode that is in effect. Mode AlignMode; /// \brief The pack number of the stack. unsigned char PackNumber; /// \brief True if it is a XL #pragma align/pack stack. bool XLStack; /// \brief Uninitialized pack value. static constexpr unsigned char UninitPackVal = -1; // Masks to encode and decode an AlignPackInfo. static constexpr uint32_t IsXLMask{0x0000'0001}; static constexpr uint32_t AlignModeMask{0x0000'0006}; static constexpr uint32_t PackAttrMask{0x00000'0008}; static constexpr uint32_t PackNumMask{0x0000'01F0}; }; template<typename ValueType> struct PragmaStack { struct Slot { llvm::StringRef StackSlotLabel; ValueType Value; SourceLocation PragmaLocation; SourceLocation PragmaPushLocation; Slot(llvm::StringRef StackSlotLabel, ValueType Value, SourceLocation PragmaLocation, SourceLocation PragmaPushLocation) : StackSlotLabel(StackSlotLabel), Value(Value), PragmaLocation(PragmaLocation), PragmaPushLocation(PragmaPushLocation) {} }; void Act(SourceLocation PragmaLocation, PragmaMsStackAction Action, llvm::StringRef StackSlotLabel, ValueType Value) { if (Action == PSK_Reset) { CurrentValue = DefaultValue; CurrentPragmaLocation = PragmaLocation; return; } if (Action & PSK_Push) Stack.emplace_back(StackSlotLabel, CurrentValue, CurrentPragmaLocation, PragmaLocation); else if (Action & PSK_Pop) { if (!StackSlotLabel.empty()) { // If we've got a label, try to find it and jump there. auto I = llvm::find_if(llvm::reverse(Stack), [&](const Slot &x) { return x.StackSlotLabel == StackSlotLabel; }); // If we found the label so pop from there. if (I != Stack.rend()) { CurrentValue = I->Value; CurrentPragmaLocation = I->PragmaLocation; Stack.erase(std::prev(I.base()), Stack.end()); } } else if (!Stack.empty()) { // We do not have a label, just pop the last entry. CurrentValue = Stack.back().Value; CurrentPragmaLocation = Stack.back().PragmaLocation; Stack.pop_back(); } } if (Action & PSK_Set) { CurrentValue = Value; CurrentPragmaLocation = PragmaLocation; } } // MSVC seems to add artificial slots to #pragma stacks on entering a C++ // method body to restore the stacks on exit, so it works like this: // // struct S { // #pragma <name>(push, InternalPragmaSlot, <current_pragma_value>) // void Method {} // #pragma <name>(pop, InternalPragmaSlot) // }; // // It works even with #pragma vtordisp, although MSVC doesn't support // #pragma vtordisp(push [, id], n) // syntax. // // Push / pop a named sentinel slot. void SentinelAction(PragmaMsStackAction Action, StringRef Label) { assert((Action == PSK_Push \|\| Action == PSK_Pop) && "Can only push / pop #pragma stack sentinels!"); Act(CurrentPragmaLocation, Action, Label, CurrentValue); } // Constructors. explicit PragmaStack(const ValueType &Default) : DefaultValue(Default), CurrentValue(Default) {} bool hasValue() const { return CurrentValue != DefaultValue; } SmallVector<Slot, 2> Stack; ValueType DefaultValue; // Value used for PSK_Reset action. ValueType CurrentValue; SourceLocation CurrentPragmaLocation; }; // FIXME: We should serialize / deserialize these if they occur in a PCH (but // we shouldn't do so if they're in a module). /// Whether to insert vtordisps prior to virtual bases in the Microsoft /// C++ ABI. Possible values are 0, 1, and 2, which mean: /// /// 0: Suppress all vtordisps /// 1: Insert vtordisps in the presence of vbase overrides and non-trivial /// structors /// 2: Always insert vtordisps to support RTTI on partially constructed /// objects PragmaStack<MSVtorDispMode> VtorDispStack; PragmaStack<AlignPackInfo> AlignPackStack; // The current #pragma align/pack values and locations at each #include. struct AlignPackIncludeState { AlignPackInfo CurrentValue; SourceLocation CurrentPragmaLocation; bool HasNonDefaultValue, ShouldWarnOnInclude; }; SmallVector<AlignPackIncludeState, 8> AlignPackIncludeStack; // Segment #pragmas. PragmaStack<StringLiteral > DataSegStack; PragmaStack<StringLiteral > BSSSegStack; PragmaStack<StringLiteral > ConstSegStack; PragmaStack<StringLiteral > CodeSegStack; // This stack tracks the current state of Sema.CurFPFeatures. PragmaStack<FPOptionsOverride> FpPragmaStack; FPOptionsOverride CurFPFeatureOverrides() { FPOptionsOverride result; if (!FpPragmaStack.hasValue()) { result = FPOptionsOverride(); } else { result = FpPragmaStack.CurrentValue; } return result; } // RAII object to push / pop sentinel slots for all MS #pragma stacks. // Actions should be performed only if we enter / exit a C++ method body. class PragmaStackSentinelRAII { public: PragmaStackSentinelRAII(Sema &S, StringRef SlotLabel, bool ShouldAct); ~PragmaStackSentinelRAII(); private: Sema &S; StringRef SlotLabel; bool ShouldAct; }; /// A mapping that describes the nullability we've seen in each header file. FileNullabilityMap NullabilityMap; /// Last section used with #pragma init_seg. StringLiteral CurInitSeg; SourceLocation CurInitSegLoc; /// VisContext - Manages the stack for \#pragma GCC visibility. void VisContext; // Really a "PragmaVisStack" /// This an attribute introduced by \#pragma clang attribute. struct PragmaAttributeEntry { SourceLocation Loc; ParsedAttr Attribute; SmallVector<attr::SubjectMatchRule, 4> MatchRules; bool IsUsed; }; /// A push'd group of PragmaAttributeEntries. struct PragmaAttributeGroup { /// The location of the push attribute. SourceLocation Loc; /// The namespace of this push group. const IdentifierInfo Namespace; SmallVector<PragmaAttributeEntry, 2> Entries; }; SmallVector<PragmaAttributeGroup, 2> PragmaAttributeStack; /// The declaration that is currently receiving an attribute from the /// #pragma attribute stack. const Decl PragmaAttributeCurrentTargetDecl; /// This represents the last location of a "#pragma clang optimize off" /// directive if such a directive has not been closed by an "on" yet. If /// optimizations are currently "on", this is set to an invalid location. SourceLocation OptimizeOffPragmaLocation; /// Flag indicating if Sema is building a recovery call expression. /// /// This flag is used to avoid building recovery call expressions /// if Sema is already doing so, which would cause infinite recursions. bool IsBuildingRecoveryCallExpr; /// Used to control the generation of ExprWithCleanups. CleanupInfo Cleanup; /// ExprCleanupObjects - This is the stack of objects requiring /// cleanup that are created by the current full expression. SmallVector<ExprWithCleanups::CleanupObject, 8> ExprCleanupObjects; /// Store a set of either DeclRefExprs or MemberExprs that contain a reference /// to a variable (constant) that may or may not be odr-used in this Expr, and /// we won't know until all lvalue-to-rvalue and discarded value conversions /// have been applied to all subexpressions of the enclosing full expression. /// This is cleared at the end of each full expression. using MaybeODRUseExprSet = llvm::SetVector<Expr , SmallVector<Expr , 4>, llvm::SmallPtrSet<Expr , 4>>; MaybeODRUseExprSet MaybeODRUseExprs; std::unique_ptr<sema::FunctionScopeInfo> CachedFunctionScope; /// Stack containing information about each of the nested /// function, block, and method scopes that are currently active. SmallVector<sema::FunctionScopeInfo , 4> FunctionScopes; /// The index of the first FunctionScope that corresponds to the current /// context. unsigned FunctionScopesStart = 0; ArrayRef<sema::FunctionScopeInfo> getFunctionScopes() const { return llvm::makeArrayRef(FunctionScopes.begin() + FunctionScopesStart, FunctionScopes.end()); } /// Stack containing information needed when in C++2a an 'auto' is encountered /// in a function declaration parameter type specifier in order to invent a /// corresponding template parameter in the enclosing abbreviated function /// template. This information is also present in LambdaScopeInfo, stored in /// the FunctionScopes stack. SmallVector<InventedTemplateParameterInfo, 4> InventedParameterInfos; /// The index of the first InventedParameterInfo that refers to the current /// context. unsigned InventedParameterInfosStart = 0; ArrayRef<InventedTemplateParameterInfo> getInventedParameterInfos() const { return llvm::makeArrayRef(InventedParameterInfos.begin() + InventedParameterInfosStart, InventedParameterInfos.end()); } typedef LazyVector<TypedefNameDecl , ExternalSemaSource, &ExternalSemaSource::ReadExtVectorDecls, 2, 2> ExtVectorDeclsType; /// ExtVectorDecls - This is a list all the extended vector types. This allows /// us to associate a raw vector type with one of the ext_vector type names. /// This is only necessary for issuing pretty diagnostics. ExtVectorDeclsType ExtVectorDecls; /// FieldCollector - Collects CXXFieldDecls during parsing of C++ classes. std::unique_ptr<CXXFieldCollector> FieldCollector; typedef llvm::SmallSetVector<NamedDecl , 16> NamedDeclSetType; /// Set containing all declared private fields that are not used. NamedDeclSetType UnusedPrivateFields; /// Set containing all typedefs that are likely unused. llvm::SmallSetVector<const TypedefNameDecl , 4> UnusedLocalTypedefNameCandidates; /// Delete-expressions to be analyzed at the end of translation unit /// /// This list contains class members, and locations of delete-expressions /// that could not be proven as to whether they mismatch with new-expression /// used in initializer of the field. typedef std::pair<SourceLocation, bool> DeleteExprLoc; typedef llvm::SmallVector<DeleteExprLoc, 4> DeleteLocs; llvm::MapVector<FieldDecl , DeleteLocs> DeleteExprs; typedef llvm::SmallPtrSet<const CXXRecordDecl, 8> RecordDeclSetTy; /// PureVirtualClassDiagSet - a set of class declarations which we have /// emitted a list of pure virtual functions. Used to prevent emitting the /// same list more than once. std::unique_ptr<RecordDeclSetTy> PureVirtualClassDiagSet; /// ParsingInitForAutoVars - a set of declarations with auto types for which /// we are currently parsing the initializer. llvm::SmallPtrSet<const Decl, 4> ParsingInitForAutoVars; /// Look for a locally scoped extern "C" declaration by the given name. NamedDecl findLocallyScopedExternCDecl(DeclarationName Name); typedef LazyVector<VarDecl , ExternalSemaSource, &ExternalSemaSource::ReadTentativeDefinitions, 2, 2> TentativeDefinitionsType; /// All the tentative definitions encountered in the TU. TentativeDefinitionsType TentativeDefinitions; /// All the external declarations encoutered and used in the TU. SmallVector<VarDecl , 4> ExternalDeclarations; typedef LazyVector<const DeclaratorDecl , ExternalSemaSource, &ExternalSemaSource::ReadUnusedFileScopedDecls, 2, 2> UnusedFileScopedDeclsType; /// The set of file scoped decls seen so far that have not been used /// and must warn if not used. Only contains the first declaration. UnusedFileScopedDeclsType UnusedFileScopedDecls; typedef LazyVector<CXXConstructorDecl , ExternalSemaSource, &ExternalSemaSource::ReadDelegatingConstructors, 2, 2> DelegatingCtorDeclsType; /// All the delegating constructors seen so far in the file, used for /// cycle detection at the end of the TU. DelegatingCtorDeclsType DelegatingCtorDecls; /// All the overriding functions seen during a class definition /// that had their exception spec checks delayed, plus the overridden /// function. SmallVector<std::pair<const CXXMethodDecl, const CXXMethodDecl>, 2> DelayedOverridingExceptionSpecChecks; /// All the function redeclarations seen during a class definition that had /// their exception spec checks delayed, plus the prior declaration they /// should be checked against. Except during error recovery, the new decl /// should always be a friend declaration, as that's the only valid way to /// redeclare a special member before its class is complete. SmallVector<std::pair<FunctionDecl, FunctionDecl>, 2> DelayedEquivalentExceptionSpecChecks; typedef llvm::MapVector<const FunctionDecl , std::unique_ptr<LateParsedTemplate>> LateParsedTemplateMapT; LateParsedTemplateMapT LateParsedTemplateMap; /// Callback to the parser to parse templated functions when needed. typedef void LateTemplateParserCB(void P, LateParsedTemplate &LPT); typedef void LateTemplateParserCleanupCB(void P); LateTemplateParserCB LateTemplateParser; LateTemplateParserCleanupCB LateTemplateParserCleanup; void OpaqueParser; void SetLateTemplateParser(LateTemplateParserCB LTP, LateTemplateParserCleanupCB LTPCleanup, void P) { LateTemplateParser = LTP; LateTemplateParserCleanup = LTPCleanup; OpaqueParser = P; } class DelayedDiagnostics; class DelayedDiagnosticsState { sema::DelayedDiagnosticPool SavedPool; friend class Sema::DelayedDiagnostics; }; typedef DelayedDiagnosticsState ParsingDeclState; typedef DelayedDiagnosticsState ProcessingContextState; /// A class which encapsulates the logic for delaying diagnostics /// during parsing and other processing. class DelayedDiagnostics { /// The current pool of diagnostics into which delayed /// diagnostics should go. sema::DelayedDiagnosticPool CurPool; public: DelayedDiagnostics() : CurPool(nullptr) {} /// Adds a delayed diagnostic. void add(const sema::DelayedDiagnostic &diag); // in DelayedDiagnostic.h /// Determines whether diagnostics should be delayed. bool shouldDelayDiagnostics() { return CurPool != nullptr; } /// Returns the current delayed-diagnostics pool. sema::DelayedDiagnosticPool getCurrentPool() const { return CurPool; } /// Enter a new scope. Access and deprecation diagnostics will be /// collected in this pool. DelayedDiagnosticsState push(sema::DelayedDiagnosticPool &pool) { DelayedDiagnosticsState state; state.SavedPool = CurPool; CurPool = &pool; return state; } /// Leave a delayed-diagnostic state that was previously pushed. /// Do not emit any of the diagnostics. This is performed as part /// of the bookkeeping of popping a pool "properly". void popWithoutEmitting(DelayedDiagnosticsState state) { CurPool = state.SavedPool; } /// Enter a new scope where access and deprecation diagnostics are /// not delayed. DelayedDiagnosticsState pushUndelayed() { DelayedDiagnosticsState state; state.SavedPool = CurPool; CurPool = nullptr; return state; } /// Undo a previous pushUndelayed(). void popUndelayed(DelayedDiagnosticsState state) { assert(CurPool == nullptr); CurPool = state.SavedPool; } } DelayedDiagnostics; /// A RAII object to temporarily push a declaration context. class ContextRAII { private: Sema &S; DeclContext SavedContext; ProcessingContextState SavedContextState; QualType SavedCXXThisTypeOverride; unsigned SavedFunctionScopesStart; unsigned SavedInventedParameterInfosStart; public: ContextRAII(Sema &S, DeclContext ContextToPush, bool NewThisContext = true) : S(S), SavedContext(S.CurContext), SavedContextState(S.DelayedDiagnostics.pushUndelayed()), SavedCXXThisTypeOverride(S.CXXThisTypeOverride), SavedFunctionScopesStart(S.FunctionScopesStart), SavedInventedParameterInfosStart(S.InventedParameterInfosStart) { assert(ContextToPush && "pushing null context"); S.CurContext = ContextToPush; if (NewThisContext) S.CXXThisTypeOverride = QualType(); // Any saved FunctionScopes do not refer to this context. S.FunctionScopesStart = S.FunctionScopes.size(); S.InventedParameterInfosStart = S.InventedParameterInfos.size(); } void pop() { if (!SavedContext) return; S.CurContext = SavedContext; S.DelayedDiagnostics.popUndelayed(SavedContextState); S.CXXThisTypeOverride = SavedCXXThisTypeOverride; S.FunctionScopesStart = SavedFunctionScopesStart; S.InventedParameterInfosStart = SavedInventedParameterInfosStart; SavedContext = nullptr; } ~ContextRAII() { pop(); } }; /// Whether the AST is currently being rebuilt to correct immediate /// invocations. Immediate invocation candidates and references to consteval /// functions aren't tracked when this is set. bool RebuildingImmediateInvocation = false; /// Used to change context to isConstantEvaluated without pushing a heavy /// ExpressionEvaluationContextRecord object. bool isConstantEvaluatedOverride; bool isConstantEvaluated() { return ExprEvalContexts.back().isConstantEvaluated() \|\| isConstantEvaluatedOverride; } /// RAII object to handle the state changes required to synthesize /// a function body. class SynthesizedFunctionScope { Sema &S; Sema::ContextRAII SavedContext; bool PushedCodeSynthesisContext = false; public: SynthesizedFunctionScope(Sema &S, DeclContext DC) : S(S), SavedContext(S, DC) { S.PushFunctionScope(); S.PushExpressionEvaluationContext( Sema::ExpressionEvaluationContext::PotentiallyEvaluated); if (auto FD = dyn_cast<FunctionDecl>(DC)) FD->setWillHaveBody(true); else assert(isa<ObjCMethodDecl>(DC)); } void addContextNote(SourceLocation UseLoc) { assert(!PushedCodeSynthesisContext); Sema::CodeSynthesisContext Ctx; Ctx.Kind = Sema::CodeSynthesisContext::DefiningSynthesizedFunction; Ctx.PointOfInstantiation = UseLoc; Ctx.Entity = cast<Decl>(S.CurContext); S.pushCodeSynthesisContext(Ctx); PushedCodeSynthesisContext = true; } ~SynthesizedFunctionScope() { if (PushedCodeSynthesisContext) S.popCodeSynthesisContext(); if (auto FD = dyn_cast<FunctionDecl>(S.CurContext)) FD->setWillHaveBody(false); S.PopExpressionEvaluationContext(); S.PopFunctionScopeInfo(); } }; /// WeakUndeclaredIdentifiers - Identifiers contained in /// \#pragma weak before declared. rare. may alias another /// identifier, declared or undeclared llvm::MapVector<IdentifierInfo , WeakInfo> WeakUndeclaredIdentifiers; /// ExtnameUndeclaredIdentifiers - Identifiers contained in /// \#pragma redefine_extname before declared. Used in Solaris system headers /// to define functions that occur in multiple standards to call the version /// in the currently selected standard. llvm::DenseMap<IdentifierInfo,AsmLabelAttr> ExtnameUndeclaredIdentifiers; /// Load weak undeclared identifiers from the external source. void LoadExternalWeakUndeclaredIdentifiers(); /// WeakTopLevelDecl - Translation-unit scoped declarations generated by /// \#pragma weak during processing of other Decls. /// I couldn't figure out a clean way to generate these in-line, so /// we store them here and handle separately -- which is a hack. /// It would be best to refactor this. SmallVector<Decl,2> WeakTopLevelDecl; IdentifierResolver IdResolver; /// Translation Unit Scope - useful to Objective-C actions that need /// to lookup file scope declarations in the "ordinary" C decl namespace. /// For example, user-defined classes, built-in "id" type, etc. Scope TUScope; /// The C++ "std" namespace, where the standard library resides. LazyDeclPtr StdNamespace; /// The C++ "std::bad_alloc" class, which is defined by the C++ /// standard library. LazyDeclPtr StdBadAlloc; /// The C++ "std::align_val_t" enum class, which is defined by the C++ /// standard library. LazyDeclPtr StdAlignValT; /// The C++ "std::experimental" namespace, where the experimental parts /// of the standard library resides. NamespaceDecl StdExperimentalNamespaceCache; /// The C++ "std::initializer_list" template, which is defined in /// \<initializer_list>. ClassTemplateDecl StdInitializerList; /// The C++ "std::coroutine_traits" template, which is defined in /// \<coroutine_traits> ClassTemplateDecl StdCoroutineTraitsCache; /// The C++ "type_info" declaration, which is defined in \<typeinfo>. RecordDecl CXXTypeInfoDecl; /// The MSVC "_GUID" struct, which is defined in MSVC header files. RecordDecl MSVCGuidDecl; /// Caches identifiers/selectors for NSFoundation APIs. std::unique_ptr<NSAPI> NSAPIObj; /// The declaration of the Objective-C NSNumber class. ObjCInterfaceDecl NSNumberDecl; /// The declaration of the Objective-C NSValue class. ObjCInterfaceDecl NSValueDecl; /// Pointer to NSNumber type (NSNumber ). QualType NSNumberPointer; /// Pointer to NSValue type (NSValue ). QualType NSValuePointer; /// The Objective-C NSNumber methods used to create NSNumber literals. ObjCMethodDecl NSNumberLiteralMethods[NSAPI::NumNSNumberLiteralMethods]; /// The declaration of the Objective-C NSString class. ObjCInterfaceDecl NSStringDecl; /// Pointer to NSString type (NSString ). QualType NSStringPointer; /// The declaration of the stringWithUTF8String: method. ObjCMethodDecl StringWithUTF8StringMethod; /// The declaration of the valueWithBytes:objCType: method. ObjCMethodDecl ValueWithBytesObjCTypeMethod; /// The declaration of the Objective-C NSArray class. ObjCInterfaceDecl NSArrayDecl; /// The declaration of the arrayWithObjects:count: method. ObjCMethodDecl ArrayWithObjectsMethod; /// The declaration of the Objective-C NSDictionary class. ObjCInterfaceDecl NSDictionaryDecl; /// The declaration of the dictionaryWithObjects:forKeys:count: method. ObjCMethodDecl DictionaryWithObjectsMethod; /// id<NSCopying> type. QualType QIDNSCopying; /// will hold 'respondsToSelector:' Selector RespondsToSelectorSel; /// A flag to remember whether the implicit forms of operator new and delete /// have been declared. bool GlobalNewDeleteDeclared; /// Describes how the expressions currently being parsed are /// evaluated at run-time, if at all. enum class ExpressionEvaluationContext { /// The current expression and its subexpressions occur within an /// unevaluated operand (C++11 [expr]p7), such as the subexpression of /// \c sizeof, where the type of the expression may be significant but /// no code will be generated to evaluate the value of the expression at /// run time. Unevaluated, /// The current expression occurs within a braced-init-list within /// an unevaluated operand. This is mostly like a regular unevaluated /// context, except that we still instantiate constexpr functions that are /// referenced here so that we can perform narrowing checks correctly. UnevaluatedList, /// The current expression occurs within a discarded statement. /// This behaves largely similarly to an unevaluated operand in preventing /// definitions from being required, but not in other ways. DiscardedStatement, /// The current expression occurs within an unevaluated /// operand that unconditionally permits abstract references to /// fields, such as a SIZE operator in MS-style inline assembly. UnevaluatedAbstract, /// The current context is "potentially evaluated" in C++11 terms, /// but the expression is evaluated at compile-time (like the values of /// cases in a switch statement). ConstantEvaluated, /// In addition of being constant evaluated, the current expression /// occurs in an immediate function context - either a consteval function /// or a consteval if function. ImmediateFunctionContext, /// The current expression is potentially evaluated at run time, /// which means that code may be generated to evaluate the value of the /// expression at run time. PotentiallyEvaluated, /// The current expression is potentially evaluated, but any /// declarations referenced inside that expression are only used if /// in fact the current expression is used. /// /// This value is used when parsing default function arguments, for which /// we would like to provide diagnostics (e.g., passing non-POD arguments /// through varargs) but do not want to mark declarations as "referenced" /// until the default argument is used. PotentiallyEvaluatedIfUsed }; using ImmediateInvocationCandidate = llvm::PointerIntPair<ConstantExpr , 1>; /// Data structure used to record current or nested /// expression evaluation contexts. struct ExpressionEvaluationContextRecord { /// The expression evaluation context. ExpressionEvaluationContext Context; /// Whether the enclosing context needed a cleanup. CleanupInfo ParentCleanup; /// The number of active cleanup objects when we entered /// this expression evaluation context. unsigned NumCleanupObjects; /// The number of typos encountered during this expression evaluation /// context (i.e. the number of TypoExprs created). unsigned NumTypos; MaybeODRUseExprSet SavedMaybeODRUseExprs; /// The lambdas that are present within this context, if it /// is indeed an unevaluated context. SmallVector<LambdaExpr , 2> Lambdas; /// The declaration that provides context for lambda expressions /// and block literals if the normal declaration context does not /// suffice, e.g., in a default function argument. Decl ManglingContextDecl; /// If we are processing a decltype type, a set of call expressions /// for which we have deferred checking the completeness of the return type. SmallVector<CallExpr , 8> DelayedDecltypeCalls; /// If we are processing a decltype type, a set of temporary binding /// expressions for which we have deferred checking the destructor. SmallVector<CXXBindTemporaryExpr , 8> DelayedDecltypeBinds; llvm::SmallPtrSet<const Expr , 8> PossibleDerefs; /// Expressions appearing as the LHS of a volatile assignment in this /// context. We produce a warning for these when popping the context if /// they are not discarded-value expressions nor unevaluated operands. SmallVector<Expr, 2> VolatileAssignmentLHSs; /// Set of candidates for starting an immediate invocation. llvm::SmallVector<ImmediateInvocationCandidate, 4> ImmediateInvocationCandidates; /// Set of DeclRefExprs referencing a consteval function when used in a /// context not already known to be immediately invoked. llvm::SmallPtrSet<DeclRefExpr , 4> ReferenceToConsteval; /// \brief Describes whether we are in an expression constext which we have /// to handle differently. enum ExpressionKind { EK_Decltype, EK_TemplateArgument, EK_Other } ExprContext; ExpressionEvaluationContextRecord(ExpressionEvaluationContext Context, unsigned NumCleanupObjects, CleanupInfo ParentCleanup, Decl ManglingContextDecl, ExpressionKind ExprContext) : Context(Context), ParentCleanup(ParentCleanup), NumCleanupObjects(NumCleanupObjects), NumTypos(0), ManglingContextDecl(ManglingContextDecl), ExprContext(ExprContext) {} bool isUnevaluated() const { return Context == ExpressionEvaluationContext::Unevaluated \|\| Context == ExpressionEvaluationContext::UnevaluatedAbstract \|\| Context == ExpressionEvaluationContext::UnevaluatedList; } bool isConstantEvaluated() const { return Context == ExpressionEvaluationContext::ConstantEvaluated \|\| Context == ExpressionEvaluationContext::ImmediateFunctionContext; } bool isImmediateFunctionContext() const { return Context == ExpressionEvaluationContext::ImmediateFunctionContext; } }; /// A stack of expression evaluation contexts. SmallVector<ExpressionEvaluationContextRecord, 8> ExprEvalContexts; /// Emit a warning for all pending noderef expressions that we recorded. void WarnOnPendingNoDerefs(ExpressionEvaluationContextRecord &Rec); /// Compute the mangling number context for a lambda expression or /// block literal. Also return the extra mangling decl if any. /// /// \param DC - The DeclContext containing the lambda expression or /// block literal. std::tuple<MangleNumberingContext , Decl > getCurrentMangleNumberContext(const DeclContext DC); /// SpecialMemberOverloadResult - The overloading result for a special member /// function. /// /// This is basically a wrapper around PointerIntPair. The lowest bits of the /// integer are used to determine whether overload resolution succeeded. class SpecialMemberOverloadResult { public: enum Kind { NoMemberOrDeleted, Ambiguous, Success }; private: llvm::PointerIntPair<CXXMethodDecl, 2> Pair; public: SpecialMemberOverloadResult() : Pair() {} SpecialMemberOverloadResult(CXXMethodDecl MD) : Pair(MD, MD->isDeleted() ? NoMemberOrDeleted : Success) {} CXXMethodDecl getMethod() const { return Pair.getPointer(); } void setMethod(CXXMethodDecl MD) { Pair.setPointer(MD); } Kind getKind() const { return static_cast<Kind>(Pair.getInt()); } void setKind(Kind K) { Pair.setInt(K); } }; class SpecialMemberOverloadResultEntry : public llvm::FastFoldingSetNode, public SpecialMemberOverloadResult { public: SpecialMemberOverloadResultEntry(const llvm::FoldingSetNodeID &ID) : FastFoldingSetNode(ID) {} }; /// A cache of special member function overload resolution results /// for C++ records. llvm::FoldingSet<SpecialMemberOverloadResultEntry> SpecialMemberCache; /// A cache of the flags available in enumerations with the flag_bits /// attribute. mutable llvm::DenseMap<const EnumDecl, llvm::APInt> FlagBitsCache; /// The kind of translation unit we are processing. /// /// When we're processing a complete translation unit, Sema will perform /// end-of-translation-unit semantic tasks (such as creating /// initializers for tentative definitions in C) once parsing has /// completed. Modules and precompiled headers perform different kinds of /// checks. const TranslationUnitKind TUKind; llvm::BumpPtrAllocator BumpAlloc; /// The number of SFINAE diagnostics that have been trapped. unsigned NumSFINAEErrors; typedef llvm::DenseMap<ParmVarDecl , llvm::TinyPtrVector<ParmVarDecl >> UnparsedDefaultArgInstantiationsMap; /// A mapping from parameters with unparsed default arguments to the /// set of instantiations of each parameter. /// /// This mapping is a temporary data structure used when parsing /// nested class templates or nested classes of class templates, /// where we might end up instantiating an inner class before the /// default arguments of its methods have been parsed. UnparsedDefaultArgInstantiationsMap UnparsedDefaultArgInstantiations; // Contains the locations of the beginning of unparsed default // argument locations. llvm::DenseMap<ParmVarDecl , SourceLocation> UnparsedDefaultArgLocs; /// UndefinedInternals - all the used, undefined objects which require a /// definition in this translation unit. llvm::MapVector<NamedDecl , SourceLocation> UndefinedButUsed; /// Determine if VD, which must be a variable or function, is an external /// symbol that nonetheless can't be referenced from outside this translation /// unit because its type has no linkage and it's not extern "C". bool isExternalWithNoLinkageType(ValueDecl VD); /// Obtain a sorted list of functions that are undefined but ODR-used. void getUndefinedButUsed( SmallVectorImpl<std::pair<NamedDecl , SourceLocation> > &Undefined); /// Retrieves list of suspicious delete-expressions that will be checked at /// the end of translation unit. const llvm::MapVector<FieldDecl , DeleteLocs> & getMismatchingDeleteExpressions() const; class GlobalMethodPool { public: using Lists = std::pair<ObjCMethodList, ObjCMethodList>; using iterator = llvm::DenseMap<Selector, Lists>::iterator; iterator begin() { return Methods.begin(); } iterator end() { return Methods.end(); } iterator find(Selector Sel) { return Methods.find(Sel); } std::pair<iterator, bool> insert(std::pair<Selector, Lists> &&Val) { return Methods.insert(Val); } int count(Selector Sel) const { return Methods.count(Sel); } bool empty() const { return Methods.empty(); } private: llvm::DenseMap<Selector, Lists> Methods; }; /// Method Pool - allows efficient lookup when typechecking messages to "id". /// We need to maintain a list, since selectors can have differing signatures /// across classes. In Cocoa, this happens to be extremely uncommon (only 1% /// of selectors are "overloaded"). /// At the head of the list it is recorded whether there were 0, 1, or >= 2 /// methods inside categories with a particular selector. GlobalMethodPool MethodPool; /// Method selectors used in a \@selector expression. Used for implementation /// of -Wselector. llvm::MapVector<Selector, SourceLocation> ReferencedSelectors; /// List of SourceLocations where 'self' is implicitly retained inside a /// block. llvm::SmallVector<std::pair<SourceLocation, const BlockDecl >, 1> ImplicitlyRetainedSelfLocs; /// Kinds of C++ special members. enum CXXSpecialMember { CXXDefaultConstructor, CXXCopyConstructor, CXXMoveConstructor, CXXCopyAssignment, CXXMoveAssignment, CXXDestructor, CXXInvalid }; typedef llvm::PointerIntPair<CXXRecordDecl , 3, CXXSpecialMember> SpecialMemberDecl; /// The C++ special members which we are currently in the process of /// declaring. If this process recursively triggers the declaration of the /// same special member, we should act as if it is not yet declared. llvm::SmallPtrSet<SpecialMemberDecl, 4> SpecialMembersBeingDeclared; /// Kinds of defaulted comparison operator functions. enum class DefaultedComparisonKind : unsigned char { /// This is not a defaultable comparison operator. None, /// This is an operator== that should be implemented as a series of /// subobject comparisons. Equal, /// This is an operator<=> that should be implemented as a series of /// subobject comparisons. ThreeWay, /// This is an operator!= that should be implemented as a rewrite in terms /// of a == comparison. NotEqual, /// This is an <, <=, >, or >= that should be implemented as a rewrite in /// terms of a <=> comparison. Relational, }; /// The function definitions which were renamed as part of typo-correction /// to match their respective declarations. We want to keep track of them /// to ensure that we don't emit a "redefinition" error if we encounter a /// correctly named definition after the renamed definition. llvm::SmallPtrSet<const NamedDecl , 4> TypoCorrectedFunctionDefinitions; /// Stack of types that correspond to the parameter entities that are /// currently being copy-initialized. Can be empty. llvm::SmallVector<QualType, 4> CurrentParameterCopyTypes; void ReadMethodPool(Selector Sel); void updateOutOfDateSelector(Selector Sel); /// Private Helper predicate to check for 'self'. bool isSelfExpr(Expr RExpr); bool isSelfExpr(Expr RExpr, const ObjCMethodDecl Method); /// Cause the active diagnostic on the DiagosticsEngine to be /// emitted. This is closely coupled to the SemaDiagnosticBuilder class and /// should not be used elsewhere. void EmitCurrentDiagnostic(unsigned DiagID); /// Records and restores the CurFPFeatures state on entry/exit of compound /// statements. class FPFeaturesStateRAII { public: FPFeaturesStateRAII(Sema &S) : S(S), OldFPFeaturesState(S.CurFPFeatures) { OldOverrides = S.FpPragmaStack.CurrentValue; } ~FPFeaturesStateRAII() { S.CurFPFeatures = OldFPFeaturesState; S.FpPragmaStack.CurrentValue = OldOverrides; } FPOptionsOverride getOverrides() { return OldOverrides; } private: Sema& S; FPOptions OldFPFeaturesState; FPOptionsOverride OldOverrides; }; void addImplicitTypedef(StringRef Name, QualType T); bool WarnedStackExhausted = false; /// Increment when we find a reference; decrement when we find an ignored /// assignment. Ultimately the value is 0 if every reference is an ignored /// assignment. llvm::DenseMap<const VarDecl , int> RefsMinusAssignments; Optional<std::unique_ptr<DarwinSDKInfo>> CachedDarwinSDKInfo; public: Sema(Preprocessor &pp, ASTContext &ctxt, ASTConsumer &consumer, TranslationUnitKind TUKind = TU_Complete, CodeCompleteConsumer CompletionConsumer = nullptr); ~Sema(); /// Perform initialization that occurs after the parser has been /// initialized but before it parses anything. void Initialize(); /// This virtual key function only exists to limit the emission of debug info /// describing the Sema class. GCC and Clang only emit debug info for a class /// with a vtable when the vtable is emitted. Sema is final and not /// polymorphic, but the debug info size savings are so significant that it is /// worth adding a vtable just to take advantage of this optimization. virtual void anchor(); const LangOptions &getLangOpts() const { return LangOpts; } OpenCLOptions &getOpenCLOptions() { return OpenCLFeatures; } FPOptions &getCurFPFeatures() { return CurFPFeatures; } DiagnosticsEngine &getDiagnostics() const { return Diags; } SourceManager &getSourceManager() const { return SourceMgr; } Preprocessor &getPreprocessor() const { return PP; } ASTContext &getASTContext() const { return Context; } ASTConsumer &getASTConsumer() const { return Consumer; } ASTMutationListener getASTMutationListener() const; ExternalSemaSource* getExternalSource() const { return ExternalSource; } DarwinSDKInfo getDarwinSDKInfoForAvailabilityChecking(SourceLocation Loc, StringRef Platform); ///Registers an external source. If an external source already exists, /// creates a multiplex external source and appends to it. /// ///\param[in] E - A non-null external sema source. /// void addExternalSource(ExternalSemaSource E); void PrintStats() const; /// Warn that the stack is nearly exhausted. void warnStackExhausted(SourceLocation Loc); /// Run some code with "sufficient" stack space. (Currently, at least 256K is /// guaranteed). Produces a warning if we're low on stack space and allocates /// more in that case. Use this in code that may recurse deeply (for example, /// in template instantiation) to avoid stack overflow. void runWithSufficientStackSpace(SourceLocation Loc, llvm::function_ref<void()> Fn); /// Helper class that creates diagnostics with optional /// template instantiation stacks. /// /// This class provides a wrapper around the basic DiagnosticBuilder /// class that emits diagnostics. ImmediateDiagBuilder is /// responsible for emitting the diagnostic (as DiagnosticBuilder /// does) and, if the diagnostic comes from inside a template /// instantiation, printing the template instantiation stack as /// well. class ImmediateDiagBuilder : public DiagnosticBuilder { Sema &SemaRef; unsigned DiagID; public: ImmediateDiagBuilder(DiagnosticBuilder &DB, Sema &SemaRef, unsigned DiagID) : DiagnosticBuilder(DB), SemaRef(SemaRef), DiagID(DiagID) {} ImmediateDiagBuilder(DiagnosticBuilder &&DB, Sema &SemaRef, unsigned DiagID) : DiagnosticBuilder(DB), SemaRef(SemaRef), DiagID(DiagID) {} // This is a cunning lie. DiagnosticBuilder actually performs move // construction in its copy constructor (but due to varied uses, it's not // possible to conveniently express this as actual move construction). So // the default copy ctor here is fine, because the base class disables the // source anyway, so the user-defined ~ImmediateDiagBuilder is a safe no-op // in that case anwyay. ImmediateDiagBuilder(const ImmediateDiagBuilder &) = default; ~ImmediateDiagBuilder() { // If we aren't active, there is nothing to do. if (!isActive()) return; // Otherwise, we need to emit the diagnostic. First clear the diagnostic // builder itself so it won't emit the diagnostic in its own destructor. // // This seems wasteful, in that as written the DiagnosticBuilder dtor will // do its own needless checks to see if the diagnostic needs to be // emitted. However, because we take care to ensure that the builder // objects never escape, a sufficiently smart compiler will be able to // eliminate that code. Clear(); // Dispatch to Sema to emit the diagnostic. SemaRef.EmitCurrentDiagnostic(DiagID); } /// Teach operator<< to produce an object of the correct type. template <typename T> friend const ImmediateDiagBuilder & operator<<(const ImmediateDiagBuilder &Diag, const T &Value) { const DiagnosticBuilder &BaseDiag = Diag; BaseDiag << Value; return Diag; } // It is necessary to limit this to rvalue reference to avoid calling this // function with a bitfield lvalue argument since non-const reference to // bitfield is not allowed. template <typename T, typename = typename std::enable_if< !std::is_lvalue_reference<T>::value>::type> const ImmediateDiagBuilder &operator<<(T &&V) const { const DiagnosticBuilder &BaseDiag = this; BaseDiag << std::move(V); return this; } }; /// Bitmask to contain the list of reasons a single diagnostic should be /// emitted, based on its language. This permits multiple offload systems /// to coexist in the same translation unit. enum class DeviceDiagnosticReason { /// Diagnostic doesn't apply to anything. Included for completeness, but /// should make this a no-op. None = 0, /// OpenMP specific diagnostic. OmpDevice = 1 << 0, OmpHost = 1 << 1, OmpAll = OmpDevice \| OmpHost, /// CUDA specific diagnostics. CudaDevice = 1 << 2, CudaHost = 1 << 3, CudaAll = CudaDevice \| CudaHost, /// SYCL specific diagnostic. Sycl = 1 << 4, /// ESIMD specific diagnostic. Esimd = 1 << 5, /// A flag representing 'all'. This can be used to avoid the check /// all-together and make this behave as it did before the /// DiagnosticReason was added (that is, unconditionally emit). /// Note: This needs to be updated if any flags above are added. All = OmpAll \| CudaAll \| Sycl \| Esimd, LLVM_MARK_AS_BITMASK_ENUM(/LargestValue=/All) }; private: // A collection of a pair of undefined functions and their callers known // to be reachable from a routine on the device (kernel or device function). typedef std::pair<const FunctionDecl , const FunctionDecl > CallPair; llvm::SmallVector<CallPair> UndefinedReachableFromSyclDevice; public: // Helper routine to add a pair of Callee-Caller pair of FunctionDecl * // to UndefinedReachableFromSyclDevice. void addFDToReachableFromSyclDevice(const FunctionDecl Callee, const FunctionDecl Caller) { UndefinedReachableFromSyclDevice.push_back(std::make_pair(Callee, Caller)); } // Helper routine to check if a pair of Callee-Caller FunctionDecl * // is in UndefinedReachableFromSyclDevice. bool isFDReachableFromSyclDevice(const FunctionDecl Callee, const FunctionDecl Caller) { return llvm::any_of(UndefinedReachableFromSyclDevice, [Callee, Caller](const CallPair &P) { return P.first == Callee && P.second == Caller; }); } /// A generic diagnostic builder for errors which may or may not be deferred. /// /// In CUDA, there exist constructs (e.g. variable-length arrays, try/catch) /// which are not allowed to appear inside __device__ functions and are /// allowed to appear in __host__ __device__ functions only if the host+device /// function is never codegen'ed. /// /// To handle this, we use the notion of "deferred diagnostics", where we /// attach a diagnostic to a FunctionDecl that's emitted iff it's codegen'ed. /// /// This class lets you emit either a regular diagnostic, a deferred /// diagnostic, or no diagnostic at all, according to an argument you pass to /// its constructor, thus simplifying the process of creating these "maybe /// deferred" diagnostics. class SemaDiagnosticBuilder { public: enum Kind { /// Emit no diagnostics. K_Nop, /// Emit the diagnostic immediately (i.e., behave like Sema::Diag()). K_Immediate, /// Emit the diagnostic immediately, and, if it's a warning or error, also /// emit a call stack showing how this function can be reached by an a /// priori known-emitted function. K_ImmediateWithCallStack, /// Create a deferred diagnostic, which is emitted only if the function /// it's attached to is codegen'ed. Also emit a call stack as with /// K_ImmediateWithCallStack. K_Deferred }; SemaDiagnosticBuilder(Kind K, SourceLocation Loc, unsigned DiagID, FunctionDecl Fn, Sema &S, DeviceDiagnosticReason R); SemaDiagnosticBuilder(SemaDiagnosticBuilder &&D); SemaDiagnosticBuilder(const SemaDiagnosticBuilder &) = default; ~SemaDiagnosticBuilder(); bool isImmediate() const { return ImmediateDiag.hasValue(); } /// Convertible to bool: True if we immediately emitted an error, false if /// we didn't emit an error or we created a deferred error. /// /// Example usage: /// /// if (SemaDiagnosticBuilder(...) << foo << bar) /// return ExprError(); /// /// But see CUDADiagIfDeviceCode() and CUDADiagIfHostCode() -- you probably /// want to use these instead of creating a SemaDiagnosticBuilder yourself. operator bool() const { return isImmediate(); } template <typename T> friend const SemaDiagnosticBuilder & operator<<(const SemaDiagnosticBuilder &Diag, const T &Value) { if (Diag.ImmediateDiag.hasValue()) Diag.ImmediateDiag << Value; else if (Diag.PartialDiagId.hasValue()) Diag.S.DeviceDeferredDiags[Diag.Fn][Diag.PartialDiagId] .getDiag() .second << Value; return Diag; } // It is necessary to limit this to rvalue reference to avoid calling this // function with a bitfield lvalue argument since non-const reference to // bitfield is not allowed. template <typename T, typename = typename std::enable_if< !std::is_lvalue_reference<T>::value>::type> const SemaDiagnosticBuilder &operator<<(T &&V) const { if (ImmediateDiag.hasValue()) ImmediateDiag << std::move(V); else if (PartialDiagId.hasValue()) S.DeviceDeferredDiags[Fn][PartialDiagId].getDiag().second << std::move(V); return this; } friend const SemaDiagnosticBuilder & operator<<(const SemaDiagnosticBuilder &Diag, const PartialDiagnostic &PD) { if (Diag.ImmediateDiag.hasValue()) PD.Emit(Diag.ImmediateDiag); else if (Diag.PartialDiagId.hasValue()) Diag.S.DeviceDeferredDiags[Diag.Fn][Diag.PartialDiagId] .getDiag() .second = PD; return Diag; } void AddFixItHint(const FixItHint &Hint) const { if (ImmediateDiag.hasValue()) ImmediateDiag->AddFixItHint(Hint); else if (PartialDiagId.hasValue()) S.DeviceDeferredDiags[Fn][PartialDiagId].getDiag().second.AddFixItHint( Hint); } friend ExprResult ExprError(const SemaDiagnosticBuilder &) { return ExprError(); } friend StmtResult StmtError(const SemaDiagnosticBuilder &) { return StmtError(); } operator ExprResult() const { return ExprError(); } operator StmtResult() const { return StmtError(); } operator TypeResult() const { return TypeError(); } operator DeclResult() const { return DeclResult(true); } operator MemInitResult() const { return MemInitResult(true); } private: Sema &S; SourceLocation Loc; unsigned DiagID; FunctionDecl Fn; bool ShowCallStack; // Invariant: At most one of these Optionals has a value. // FIXME: Switch these to a Variant once that exists. llvm::Optional<ImmediateDiagBuilder> ImmediateDiag; llvm::Optional<unsigned> PartialDiagId; }; /// Is the last error level diagnostic immediate. This is used to determined /// whether the next info diagnostic should be immediate. bool IsLastErrorImmediate = true; /// Emit a diagnostic. SemaDiagnosticBuilder Diag(SourceLocation Loc, unsigned DiagID, bool DeferHint = false); /// Emit a partial diagnostic. SemaDiagnosticBuilder Diag(SourceLocation Loc, const PartialDiagnostic &PD, bool DeferHint = false); /// Build a partial diagnostic. PartialDiagnostic PDiag(unsigned DiagID = 0); // in SemaInternal.h /// Whether deferrable diagnostics should be deferred. bool DeferDiags = false; /// RAII class to control scope of DeferDiags. class DeferDiagsRAII { Sema &S; bool SavedDeferDiags = false; public: DeferDiagsRAII(Sema &S, bool DeferDiags) : S(S), SavedDeferDiags(S.DeferDiags) { S.DeferDiags = DeferDiags; } ~DeferDiagsRAII() { S.DeferDiags = SavedDeferDiags; } }; /// Whether uncompilable error has occurred. This includes error happens /// in deferred diagnostics. bool hasUncompilableErrorOccurred() const; bool findMacroSpelling(SourceLocation &loc, StringRef name); /// Get a string to suggest for zero-initialization of a type. std::string getFixItZeroInitializerForType(QualType T, SourceLocation Loc) const; std::string getFixItZeroLiteralForType(QualType T, SourceLocation Loc) const; /// Calls \c Lexer::getLocForEndOfToken() SourceLocation getLocForEndOfToken(SourceLocation Loc, unsigned Offset = 0); /// Retrieve the module loader associated with the preprocessor. ModuleLoader &getModuleLoader() const; /// Invent a new identifier for parameters of abbreviated templates. IdentifierInfo * InventAbbreviatedTemplateParameterTypeName(IdentifierInfo ParamName, unsigned Index); void emitAndClearUnusedLocalTypedefWarnings(); private: /// Function or variable declarations to be checked for whether the deferred /// diagnostics should be emitted. llvm::SmallSetVector<Decl , 4> DeclsToCheckForDeferredDiags; public: // Emit all deferred diagnostics. void emitDeferredDiags(); enum TUFragmentKind { /// The global module fragment, between 'module;' and a module-declaration. Global, /// A normal translation unit fragment. For a non-module unit, this is the /// entire translation unit. Otherwise, it runs from the module-declaration /// to the private-module-fragment (if any) or the end of the TU (if not). Normal, /// The private module fragment, between 'module :private;' and the end of /// the translation unit. Private }; void ActOnStartOfTranslationUnit(); void ActOnEndOfTranslationUnit(); void ActOnEndOfTranslationUnitFragment(TUFragmentKind Kind); void CheckDelegatingCtorCycles(); Scope getScopeForContext(DeclContext Ctx); void PushFunctionScope(); void PushBlockScope(Scope BlockScope, BlockDecl Block); sema::LambdaScopeInfo PushLambdaScope(); /// This is used to inform Sema what the current TemplateParameterDepth /// is during Parsing. Currently it is used to pass on the depth /// when parsing generic lambda 'auto' parameters. void RecordParsingTemplateParameterDepth(unsigned Depth); void PushCapturedRegionScope(Scope RegionScope, CapturedDecl CD, RecordDecl RD, CapturedRegionKind K, unsigned OpenMPCaptureLevel = 0); /// Custom deleter to allow FunctionScopeInfos to be kept alive for a short /// time after they've been popped. class PoppedFunctionScopeDeleter { Sema Self; public: explicit PoppedFunctionScopeDeleter(Sema Self) : Self(Self) {} void operator()(sema::FunctionScopeInfo Scope) const; }; using PoppedFunctionScopePtr = std::unique_ptr<sema::FunctionScopeInfo, PoppedFunctionScopeDeleter>; PoppedFunctionScopePtr PopFunctionScopeInfo(const sema::AnalysisBasedWarnings::Policy WP = nullptr, const Decl D = nullptr, QualType BlockType = QualType()); sema::FunctionScopeInfo getCurFunction() const { return FunctionScopes.empty() ? nullptr : FunctionScopes.back(); } sema::FunctionScopeInfo getEnclosingFunction() const; void setFunctionHasBranchIntoScope(); void setFunctionHasBranchProtectedScope(); void setFunctionHasIndirectGoto(); void setFunctionHasMustTail(); void PushCompoundScope(bool IsStmtExpr); void PopCompoundScope(); sema::CompoundScopeInfo &getCurCompoundScope() const; bool hasAnyUnrecoverableErrorsInThisFunction() const; /// Retrieve the current block, if any. sema::BlockScopeInfo getCurBlock(); /// Get the innermost lambda enclosing the current location, if any. This /// looks through intervening non-lambda scopes such as local functions and /// blocks. sema::LambdaScopeInfo getEnclosingLambda() const; /// Retrieve the current lambda scope info, if any. /// \param IgnoreNonLambdaCapturingScope true if should find the top-most /// lambda scope info ignoring all inner capturing scopes that are not /// lambda scopes. sema::LambdaScopeInfo getCurLambda(bool IgnoreNonLambdaCapturingScope = false); /// Retrieve the current generic lambda info, if any. sema::LambdaScopeInfo getCurGenericLambda(); /// Retrieve the current captured region, if any. sema::CapturedRegionScopeInfo getCurCapturedRegion(); /// Retrieve the current function, if any, that should be analyzed for /// potential availability violations. sema::FunctionScopeInfo getCurFunctionAvailabilityContext(); /// WeakTopLevelDeclDecls - access to \#pragma weak-generated Decls SmallVectorImpl<Decl > &WeakTopLevelDecls() { return WeakTopLevelDecl; } /// Called before parsing a function declarator belonging to a function /// declaration. void ActOnStartFunctionDeclarationDeclarator(Declarator &D, unsigned TemplateParameterDepth); /// Called after parsing a function declarator belonging to a function /// declaration. void ActOnFinishFunctionDeclarationDeclarator(Declarator &D); void ActOnComment(SourceRange Comment); //===--------------------------------------------------------------------===// // Type Analysis / Processing: SemaType.cpp. // QualType BuildQualifiedType(QualType T, SourceLocation Loc, Qualifiers Qs, const DeclSpec DS = nullptr); QualType BuildQualifiedType(QualType T, SourceLocation Loc, unsigned CVRA, const DeclSpec DS = nullptr); QualType BuildPointerType(QualType T, SourceLocation Loc, DeclarationName Entity); QualType BuildReferenceType(QualType T, bool LValueRef, SourceLocation Loc, DeclarationName Entity); QualType BuildArrayType(QualType T, ArrayType::ArraySizeModifier ASM, Expr ArraySize, unsigned Quals, SourceRange Brackets, DeclarationName Entity); QualType BuildVectorType(QualType T, Expr VecSize, SourceLocation AttrLoc); QualType BuildExtVectorType(QualType T, Expr ArraySize, SourceLocation AttrLoc); QualType BuildMatrixType(QualType T, Expr NumRows, Expr NumColumns, SourceLocation AttrLoc); QualType BuildAddressSpaceAttr(QualType &T, LangAS ASIdx, Expr AddrSpace, SourceLocation AttrLoc); /// Same as above, but constructs the AddressSpace index if not provided. QualType BuildAddressSpaceAttr(QualType &T, Expr AddrSpace, SourceLocation AttrLoc); SYCLIntelFPGAIVDepAttr BuildSYCLIntelFPGAIVDepAttr(const AttributeCommonInfo &CI, Expr Expr1, Expr Expr2); LoopUnrollHintAttr BuildLoopUnrollHintAttr(const AttributeCommonInfo &A, Expr E); OpenCLUnrollHintAttr * BuildOpenCLLoopUnrollHintAttr(const AttributeCommonInfo &A, Expr E); SYCLIntelFPGALoopCountAttr BuildSYCLIntelFPGALoopCountAttr(const AttributeCommonInfo &CI, Expr E); SYCLIntelFPGAInitiationIntervalAttr BuildSYCLIntelFPGAInitiationIntervalAttr(const AttributeCommonInfo &CI, Expr E); SYCLIntelFPGAMaxConcurrencyAttr BuildSYCLIntelFPGAMaxConcurrencyAttr(const AttributeCommonInfo &CI, Expr E); SYCLIntelFPGAMaxInterleavingAttr BuildSYCLIntelFPGAMaxInterleavingAttr(const AttributeCommonInfo &CI, Expr E); SYCLIntelFPGASpeculatedIterationsAttr BuildSYCLIntelFPGASpeculatedIterationsAttr(const AttributeCommonInfo &CI, Expr E); SYCLIntelFPGALoopCoalesceAttr BuildSYCLIntelFPGALoopCoalesceAttr(const AttributeCommonInfo &CI, Expr E); bool CheckQualifiedFunctionForTypeId(QualType T, SourceLocation Loc); bool CheckFunctionReturnType(QualType T, SourceLocation Loc); /// Build a function type. /// /// This routine checks the function type according to C++ rules and /// under the assumption that the result type and parameter types have /// just been instantiated from a template. It therefore duplicates /// some of the behavior of GetTypeForDeclarator, but in a much /// simpler form that is only suitable for this narrow use case. /// /// \param T The return type of the function. /// /// \param ParamTypes The parameter types of the function. This array /// will be modified to account for adjustments to the types of the /// function parameters. /// /// \param Loc The location of the entity whose type involves this /// function type or, if there is no such entity, the location of the /// type that will have function type. /// /// \param Entity The name of the entity that involves the function /// type, if known. /// /// \param EPI Extra information about the function type. Usually this will /// be taken from an existing function with the same prototype. /// /// \returns A suitable function type, if there are no errors. The /// unqualified type will always be a FunctionProtoType. /// Otherwise, returns a NULL type. QualType BuildFunctionType(QualType T, MutableArrayRef<QualType> ParamTypes, SourceLocation Loc, DeclarationName Entity, const FunctionProtoType::ExtProtoInfo &EPI); QualType BuildMemberPointerType(QualType T, QualType Class, SourceLocation Loc, DeclarationName Entity); QualType BuildBlockPointerType(QualType T, SourceLocation Loc, DeclarationName Entity); QualType BuildParenType(QualType T); QualType BuildAtomicType(QualType T, SourceLocation Loc); QualType BuildReadPipeType(QualType T, SourceLocation Loc); QualType BuildWritePipeType(QualType T, SourceLocation Loc); QualType BuildExtIntType(bool IsUnsigned, Expr BitWidth, SourceLocation Loc); TypeSourceInfo GetTypeForDeclarator(Declarator &D, Scope S); TypeSourceInfo GetTypeForDeclaratorCast(Declarator &D, QualType FromTy); /// Package the given type and TSI into a ParsedType. ParsedType CreateParsedType(QualType T, TypeSourceInfo TInfo); DeclarationNameInfo GetNameForDeclarator(Declarator &D); DeclarationNameInfo GetNameFromUnqualifiedId(const UnqualifiedId &Name); static QualType GetTypeFromParser(ParsedType Ty, TypeSourceInfo *TInfo = nullptr); CanThrowResult canThrow(const Stmt E); /// Determine whether the callee of a particular function call can throw. /// E, D and Loc are all optional. static CanThrowResult canCalleeThrow(Sema &S, const Expr E, const Decl D, SourceLocation Loc = SourceLocation()); const FunctionProtoType ResolveExceptionSpec(SourceLocation Loc, const FunctionProtoType FPT); void UpdateExceptionSpec(FunctionDecl FD, const FunctionProtoType::ExceptionSpecInfo &ESI); bool CheckSpecifiedExceptionType(QualType &T, SourceRange Range); bool CheckDistantExceptionSpec(QualType T); bool CheckEquivalentExceptionSpec(FunctionDecl Old, FunctionDecl New); bool CheckEquivalentExceptionSpec( const FunctionProtoType Old, SourceLocation OldLoc, const FunctionProtoType New, SourceLocation NewLoc); bool CheckEquivalentExceptionSpec( const PartialDiagnostic &DiagID, const PartialDiagnostic & NoteID, const FunctionProtoType Old, SourceLocation OldLoc, const FunctionProtoType New, SourceLocation NewLoc); bool handlerCanCatch(QualType HandlerType, QualType ExceptionType); bool CheckExceptionSpecSubset(const PartialDiagnostic &DiagID, const PartialDiagnostic &NestedDiagID, const PartialDiagnostic &NoteID, const PartialDiagnostic &NoThrowDiagID, const FunctionProtoType Superset, SourceLocation SuperLoc, const FunctionProtoType Subset, SourceLocation SubLoc); bool CheckParamExceptionSpec(const PartialDiagnostic &NestedDiagID, const PartialDiagnostic &NoteID, const FunctionProtoType Target, SourceLocation TargetLoc, const FunctionProtoType Source, SourceLocation SourceLoc); TypeResult ActOnTypeName(Scope S, Declarator &D); /// The parser has parsed the context-sensitive type 'instancetype' /// in an Objective-C message declaration. Return the appropriate type. ParsedType ActOnObjCInstanceType(SourceLocation Loc); /// Abstract class used to diagnose incomplete types. struct TypeDiagnoser { TypeDiagnoser() {} virtual void diagnose(Sema &S, SourceLocation Loc, QualType T) = 0; virtual ~TypeDiagnoser() {} }; static int getPrintable(int I) { return I; } static unsigned getPrintable(unsigned I) { return I; } static bool getPrintable(bool B) { return B; } static const char * getPrintable(const char S) { return S; } static StringRef getPrintable(StringRef S) { return S; } static const std::string &getPrintable(const std::string &S) { return S; } static const IdentifierInfo getPrintable(const IdentifierInfo II) { return II; } static DeclarationName getPrintable(DeclarationName N) { return N; } static QualType getPrintable(QualType T) { return T; } static SourceRange getPrintable(SourceRange R) { return R; } static SourceRange getPrintable(SourceLocation L) { return L; } static SourceRange getPrintable(const Expr E) { return E->getSourceRange(); } static SourceRange getPrintable(TypeLoc TL) { return TL.getSourceRange();} template <typename... Ts> class BoundTypeDiagnoser : public TypeDiagnoser { protected: unsigned DiagID; std::tuple<const Ts &...> Args; template <std::size_t... Is> void emit(const SemaDiagnosticBuilder &DB, std::index_sequence<Is...>) const { // Apply all tuple elements to the builder in order. bool Dummy[] = {false, (DB << getPrintable(std::get<Is>(Args)))...}; (void)Dummy; } public: BoundTypeDiagnoser(unsigned DiagID, const Ts &...Args) : TypeDiagnoser(), DiagID(DiagID), Args(Args...) { assert(DiagID != 0 && "no diagnostic for type diagnoser"); } void diagnose(Sema &S, SourceLocation Loc, QualType T) override { const SemaDiagnosticBuilder &DB = S.Diag(Loc, DiagID); emit(DB, std::index_sequence_for<Ts...>()); DB << T; } }; /// Do a check to make sure \p Name looks like a legal argument for the /// swift_name attribute applied to decl \p D. Raise a diagnostic if the name /// is invalid for the given declaration. /// /// \p AL is used to provide caret diagnostics in case of a malformed name. /// /// \returns true if the name is a valid swift name for \p D, false otherwise. bool DiagnoseSwiftName(Decl D, StringRef Name, SourceLocation Loc, const ParsedAttr &AL, bool IsAsync); /// A derivative of BoundTypeDiagnoser for which the diagnostic's type /// parameter is preceded by a 0/1 enum that is 1 if the type is sizeless. /// For example, a diagnostic with no other parameters would generally have /// the form "...%select{incomplete\|sizeless}0 type %1...". template <typename... Ts> class SizelessTypeDiagnoser : public BoundTypeDiagnoser<Ts...> { public: SizelessTypeDiagnoser(unsigned DiagID, const Ts &... Args) : BoundTypeDiagnoser<Ts...>(DiagID, Args...) {} void diagnose(Sema &S, SourceLocation Loc, QualType T) override { const SemaDiagnosticBuilder &DB = S.Diag(Loc, this->DiagID); this->emit(DB, std::index_sequence_for<Ts...>()); DB << T->isSizelessType() << T; } }; enum class CompleteTypeKind { /// Apply the normal rules for complete types. In particular, /// treat all sizeless types as incomplete. Normal, /// Relax the normal rules for complete types so that they include /// sizeless built-in types. AcceptSizeless, // FIXME: Eventually we should flip the default to Normal and opt in // to AcceptSizeless rather than opt out of it. Default = AcceptSizeless }; private: /// Methods for marking which expressions involve dereferencing a pointer /// marked with the 'noderef' attribute. Expressions are checked bottom up as /// they are parsed, meaning that a noderef pointer may not be accessed. For /// example, in `&p` where `p` is a noderef pointer, we will first parse the /// `p`, but need to check that `address of` is called on it. This requires /// keeping a container of all pending expressions and checking if the address /// of them are eventually taken. void CheckSubscriptAccessOfNoDeref(const ArraySubscriptExpr E); void CheckAddressOfNoDeref(const Expr E); void CheckMemberAccessOfNoDeref(const MemberExpr E); bool RequireCompleteTypeImpl(SourceLocation Loc, QualType T, CompleteTypeKind Kind, TypeDiagnoser Diagnoser); struct ModuleScope { SourceLocation BeginLoc; clang::Module Module = nullptr; bool ModuleInterface = false; bool ImplicitGlobalModuleFragment = false; VisibleModuleSet OuterVisibleModules; }; /// The modules we're currently parsing. llvm::SmallVector<ModuleScope, 16> ModuleScopes; /// Namespace definitions that we will export when they finish. llvm::SmallPtrSet<const NamespaceDecl, 8> DeferredExportedNamespaces; /// Get the module whose scope we are currently within. Module getCurrentModule() const { return ModuleScopes.empty() ? nullptr : ModuleScopes.back().Module; } VisibleModuleSet VisibleModules; public: /// Get the module owning an entity. Module getOwningModule(const Decl Entity) { return Entity->getOwningModule(); } /// Make a merged definition of an existing hidden definition \p ND /// visible at the specified location. void makeMergedDefinitionVisible(NamedDecl ND); bool isModuleVisible(const Module M, bool ModulePrivate = false); // When loading a non-modular PCH files, this is used to restore module // visibility. void makeModuleVisible(Module Mod, SourceLocation ImportLoc) { VisibleModules.setVisible(Mod, ImportLoc); } /// Determine whether a declaration is visible to name lookup. bool isVisible(const NamedDecl D) { return D->isUnconditionallyVisible() \|\| isVisibleSlow(D); } /// Determine whether any declaration of an entity is visible. bool hasVisibleDeclaration(const NamedDecl D, llvm::SmallVectorImpl<Module > Modules = nullptr) { return isVisible(D) \|\| hasVisibleDeclarationSlow(D, Modules); } bool hasVisibleDeclarationSlow(const NamedDecl D, llvm::SmallVectorImpl<Module > Modules); bool hasVisibleMergedDefinition(NamedDecl Def); bool hasMergedDefinitionInCurrentModule(NamedDecl Def); /// Determine if \p D and \p Suggested have a structurally compatible /// layout as described in C11 6.2.7/1. bool hasStructuralCompatLayout(Decl D, Decl Suggested); /// Determine if \p D has a visible definition. If not, suggest a declaration /// that should be made visible to expose the definition. bool hasVisibleDefinition(NamedDecl D, NamedDecl Suggested, bool OnlyNeedComplete = false); bool hasVisibleDefinition(const NamedDecl D) { NamedDecl Hidden; return hasVisibleDefinition(const_cast<NamedDecl>(D), &Hidden); } /// Determine if the template parameter \p D has a visible default argument. bool hasVisibleDefaultArgument(const NamedDecl D, llvm::SmallVectorImpl<Module > Modules = nullptr); /// Determine if there is a visible declaration of \p D that is an explicit /// specialization declaration for a specialization of a template. (For a /// member specialization, use hasVisibleMemberSpecialization.) bool hasVisibleExplicitSpecialization( const NamedDecl D, llvm::SmallVectorImpl<Module > Modules = nullptr); /// Determine if there is a visible declaration of \p D that is a member /// specialization declaration (as opposed to an instantiated declaration). bool hasVisibleMemberSpecialization( const NamedDecl D, llvm::SmallVectorImpl<Module > Modules = nullptr); /// Determine if \p A and \p B are equivalent internal linkage declarations /// from different modules, and thus an ambiguity error can be downgraded to /// an extension warning. bool isEquivalentInternalLinkageDeclaration(const NamedDecl A, const NamedDecl B); void diagnoseEquivalentInternalLinkageDeclarations( SourceLocation Loc, const NamedDecl D, ArrayRef<const NamedDecl > Equiv); bool isUsualDeallocationFunction(const CXXMethodDecl FD); bool isCompleteType(SourceLocation Loc, QualType T, CompleteTypeKind Kind = CompleteTypeKind::Default) { return !RequireCompleteTypeImpl(Loc, T, Kind, nullptr); } bool RequireCompleteType(SourceLocation Loc, QualType T, CompleteTypeKind Kind, TypeDiagnoser &Diagnoser); bool RequireCompleteType(SourceLocation Loc, QualType T, CompleteTypeKind Kind, unsigned DiagID); bool RequireCompleteType(SourceLocation Loc, QualType T, TypeDiagnoser &Diagnoser) { return RequireCompleteType(Loc, T, CompleteTypeKind::Default, Diagnoser); } bool RequireCompleteType(SourceLocation Loc, QualType T, unsigned DiagID) { return RequireCompleteType(Loc, T, CompleteTypeKind::Default, DiagID); } template <typename... Ts> bool RequireCompleteType(SourceLocation Loc, QualType T, unsigned DiagID, const Ts &...Args) { BoundTypeDiagnoser<Ts...> Diagnoser(DiagID, Args...); return RequireCompleteType(Loc, T, Diagnoser); } template <typename... Ts> bool RequireCompleteSizedType(SourceLocation Loc, QualType T, unsigned DiagID, const Ts &... Args) { SizelessTypeDiagnoser<Ts...> Diagnoser(DiagID, Args...); return RequireCompleteType(Loc, T, CompleteTypeKind::Normal, Diagnoser); } /// Get the type of expression E, triggering instantiation to complete the /// type if necessary -- that is, if the expression refers to a templated /// static data member of incomplete array type. /// /// May still return an incomplete type if instantiation was not possible or /// if the type is incomplete for a different reason. Use /// RequireCompleteExprType instead if a diagnostic is expected for an /// incomplete expression type. QualType getCompletedType(Expr E); void completeExprArrayBound(Expr E); bool RequireCompleteExprType(Expr E, CompleteTypeKind Kind, TypeDiagnoser &Diagnoser); bool RequireCompleteExprType(Expr E, unsigned DiagID); template <typename... Ts> bool RequireCompleteExprType(Expr E, unsigned DiagID, const Ts &...Args) { BoundTypeDiagnoser<Ts...> Diagnoser(DiagID, Args...); return RequireCompleteExprType(E, CompleteTypeKind::Default, Diagnoser); } template <typename... Ts> bool RequireCompleteSizedExprType(Expr E, unsigned DiagID, const Ts &... Args) { SizelessTypeDiagnoser<Ts...> Diagnoser(DiagID, Args...); return RequireCompleteExprType(E, CompleteTypeKind::Normal, Diagnoser); } bool RequireLiteralType(SourceLocation Loc, QualType T, TypeDiagnoser &Diagnoser); bool RequireLiteralType(SourceLocation Loc, QualType T, unsigned DiagID); template <typename... Ts> bool RequireLiteralType(SourceLocation Loc, QualType T, unsigned DiagID, const Ts &...Args) { BoundTypeDiagnoser<Ts...> Diagnoser(DiagID, Args...); return RequireLiteralType(Loc, T, Diagnoser); } QualType getElaboratedType(ElaboratedTypeKeyword Keyword, const CXXScopeSpec &SS, QualType T, TagDecl OwnedTagDecl = nullptr); QualType BuildTypeofExprType(Expr E, SourceLocation Loc); /// If AsUnevaluated is false, E is treated as though it were an evaluated /// context, such as when building a type for decltype(auto). QualType BuildDecltypeType(Expr E, SourceLocation Loc, bool AsUnevaluated = true); QualType BuildUnaryTransformType(QualType BaseType, UnaryTransformType::UTTKind UKind, SourceLocation Loc); //===--------------------------------------------------------------------===// // Symbol table / Decl tracking callbacks: SemaDecl.cpp. // struct SkipBodyInfo { SkipBodyInfo() : ShouldSkip(false), CheckSameAsPrevious(false), Previous(nullptr), New(nullptr) {} bool ShouldSkip; bool CheckSameAsPrevious; NamedDecl Previous; NamedDecl New; }; DeclGroupPtrTy ConvertDeclToDeclGroup(Decl Ptr, Decl OwnedType = nullptr); void DiagnoseUseOfUnimplementedSelectors(); bool isSimpleTypeSpecifier(tok::TokenKind Kind) const; ParsedType getTypeName(const IdentifierInfo &II, SourceLocation NameLoc, Scope S, CXXScopeSpec SS = nullptr, bool isClassName = false, bool HasTrailingDot = false, ParsedType ObjectType = nullptr, bool IsCtorOrDtorName = false, bool WantNontrivialTypeSourceInfo = false, bool IsClassTemplateDeductionContext = true, IdentifierInfo CorrectedII = nullptr); TypeSpecifierType isTagName(IdentifierInfo &II, Scope S); bool isMicrosoftMissingTypename(const CXXScopeSpec SS, Scope S); void DiagnoseUnknownTypeName(IdentifierInfo &II, SourceLocation IILoc, Scope S, CXXScopeSpec SS, ParsedType &SuggestedType, bool IsTemplateName = false); /// Attempt to behave like MSVC in situations where lookup of an unqualified /// type name has failed in a dependent context. In these situations, we /// automatically form a DependentTypeName that will retry lookup in a related /// scope during instantiation. ParsedType ActOnMSVCUnknownTypeName(const IdentifierInfo &II, SourceLocation NameLoc, bool IsTemplateTypeArg); /// Describes the result of the name lookup and resolution performed /// by \c ClassifyName(). enum NameClassificationKind { /// This name is not a type or template in this context, but might be /// something else. NC_Unknown, /// Classification failed; an error has been produced. NC_Error, /// The name has been typo-corrected to a keyword. NC_Keyword, /// The name was classified as a type. NC_Type, /// The name was classified as a specific non-type, non-template /// declaration. ActOnNameClassifiedAsNonType should be called to /// convert the declaration to an expression. NC_NonType, /// The name was classified as an ADL-only function name. /// ActOnNameClassifiedAsUndeclaredNonType should be called to convert the /// result to an expression. NC_UndeclaredNonType, /// The name denotes a member of a dependent type that could not be /// resolved. ActOnNameClassifiedAsDependentNonType should be called to /// convert the result to an expression. NC_DependentNonType, /// The name was classified as an overload set, and an expression /// representing that overload set has been formed. /// ActOnNameClassifiedAsOverloadSet should be called to form a suitable /// expression referencing the overload set. NC_OverloadSet, /// The name was classified as a template whose specializations are types. NC_TypeTemplate, /// The name was classified as a variable template name. NC_VarTemplate, /// The name was classified as a function template name. NC_FunctionTemplate, /// The name was classified as an ADL-only function template name. NC_UndeclaredTemplate, /// The name was classified as a concept name. NC_Concept, }; class NameClassification { NameClassificationKind Kind; union { ExprResult Expr; NamedDecl NonTypeDecl; TemplateName Template; ParsedType Type; }; explicit NameClassification(NameClassificationKind Kind) : Kind(Kind) {} public: NameClassification(ParsedType Type) : Kind(NC_Type), Type(Type) {} NameClassification(const IdentifierInfo Keyword) : Kind(NC_Keyword) {} static NameClassification Error() { return NameClassification(NC_Error); } static NameClassification Unknown() { return NameClassification(NC_Unknown); } static NameClassification OverloadSet(ExprResult E) { NameClassification Result(NC_OverloadSet); Result.Expr = E; return Result; } static NameClassification NonType(NamedDecl D) { NameClassification Result(NC_NonType); Result.NonTypeDecl = D; return Result; } static NameClassification UndeclaredNonType() { return NameClassification(NC_UndeclaredNonType); } static NameClassification DependentNonType() { return NameClassification(NC_DependentNonType); } static NameClassification TypeTemplate(TemplateName Name) { NameClassification Result(NC_TypeTemplate); Result.Template = Name; return Result; } static NameClassification VarTemplate(TemplateName Name) { NameClassification Result(NC_VarTemplate); Result.Template = Name; return Result; } static NameClassification FunctionTemplate(TemplateName Name) { NameClassification Result(NC_FunctionTemplate); Result.Template = Name; return Result; } static NameClassification Concept(TemplateName Name) { NameClassification Result(NC_Concept); Result.Template = Name; return Result; } static NameClassification UndeclaredTemplate(TemplateName Name) { NameClassification Result(NC_UndeclaredTemplate); Result.Template = Name; return Result; } NameClassificationKind getKind() const { return Kind; } ExprResult getExpression() const { assert(Kind == NC_OverloadSet); return Expr; } ParsedType getType() const { assert(Kind == NC_Type); return Type; } NamedDecl getNonTypeDecl() const { assert(Kind == NC_NonType); return NonTypeDecl; } TemplateName getTemplateName() const { assert(Kind == NC_TypeTemplate \|\| Kind == NC_FunctionTemplate \|\| Kind == NC_VarTemplate \|\| Kind == NC_Concept \|\| Kind == NC_UndeclaredTemplate); return Template; } TemplateNameKind getTemplateNameKind() const { switch (Kind) { case NC_TypeTemplate: return TNK_Type_template; case NC_FunctionTemplate: return TNK_Function_template; case NC_VarTemplate: return TNK_Var_template; case NC_Concept: return TNK_Concept_template; case NC_UndeclaredTemplate: return TNK_Undeclared_template; default: llvm_unreachable("unsupported name classification."); } } }; /// Perform name lookup on the given name, classifying it based on /// the results of name lookup and the following token. /// /// This routine is used by the parser to resolve identifiers and help direct /// parsing. When the identifier cannot be found, this routine will attempt /// to correct the typo and classify based on the resulting name. /// /// \param S The scope in which we're performing name lookup. /// /// \param SS The nested-name-specifier that precedes the name. /// /// \param Name The identifier. If typo correction finds an alternative name, /// this pointer parameter will be updated accordingly. /// /// \param NameLoc The location of the identifier. /// /// \param NextToken The token following the identifier. Used to help /// disambiguate the name. /// /// \param CCC The correction callback, if typo correction is desired. NameClassification ClassifyName(Scope S, CXXScopeSpec &SS, IdentifierInfo &Name, SourceLocation NameLoc, const Token &NextToken, CorrectionCandidateCallback CCC = nullptr); /// Act on the result of classifying a name as an undeclared (ADL-only) /// non-type declaration. ExprResult ActOnNameClassifiedAsUndeclaredNonType(IdentifierInfo Name, SourceLocation NameLoc); /// Act on the result of classifying a name as an undeclared member of a /// dependent base class. ExprResult ActOnNameClassifiedAsDependentNonType(const CXXScopeSpec &SS, IdentifierInfo Name, SourceLocation NameLoc, bool IsAddressOfOperand); /// Act on the result of classifying a name as a specific non-type /// declaration. ExprResult ActOnNameClassifiedAsNonType(Scope S, const CXXScopeSpec &SS, NamedDecl Found, SourceLocation NameLoc, const Token &NextToken); /// Act on the result of classifying a name as an overload set. ExprResult ActOnNameClassifiedAsOverloadSet(Scope S, Expr OverloadSet); /// Describes the detailed kind of a template name. Used in diagnostics. enum class TemplateNameKindForDiagnostics { ClassTemplate, FunctionTemplate, VarTemplate, AliasTemplate, TemplateTemplateParam, Concept, DependentTemplate }; TemplateNameKindForDiagnostics getTemplateNameKindForDiagnostics(TemplateName Name); /// Determine whether it's plausible that E was intended to be a /// template-name. bool mightBeIntendedToBeTemplateName(ExprResult E, bool &Dependent) { if (!getLangOpts().CPlusPlus \|\| E.isInvalid()) return false; Dependent = false; if (auto DRE = dyn_cast<DeclRefExpr>(E.get())) return !DRE->hasExplicitTemplateArgs(); if (auto ME = dyn_cast<MemberExpr>(E.get())) return !ME->hasExplicitTemplateArgs(); Dependent = true; if (auto DSDRE = dyn_cast<DependentScopeDeclRefExpr>(E.get())) return !DSDRE->hasExplicitTemplateArgs(); if (auto DSME = dyn_cast<CXXDependentScopeMemberExpr>(E.get())) return !DSME->hasExplicitTemplateArgs(); // Any additional cases recognized here should also be handled by // diagnoseExprIntendedAsTemplateName. return false; } void diagnoseExprIntendedAsTemplateName(Scope S, ExprResult TemplateName, SourceLocation Less, SourceLocation Greater); void warnOnReservedIdentifier(const NamedDecl D); Decl ActOnDeclarator(Scope S, Declarator &D); NamedDecl HandleDeclarator(Scope S, Declarator &D, MultiTemplateParamsArg TemplateParameterLists); bool tryToFixVariablyModifiedVarType(TypeSourceInfo &TInfo, QualType &T, SourceLocation Loc, unsigned FailedFoldDiagID); void RegisterLocallyScopedExternCDecl(NamedDecl ND, Scope S); bool DiagnoseClassNameShadow(DeclContext DC, DeclarationNameInfo Info); bool diagnoseQualifiedDeclaration(CXXScopeSpec &SS, DeclContext DC, DeclarationName Name, SourceLocation Loc, bool IsTemplateId); void diagnoseIgnoredQualifiers(unsigned DiagID, unsigned Quals, SourceLocation FallbackLoc, SourceLocation ConstQualLoc = SourceLocation(), SourceLocation VolatileQualLoc = SourceLocation(), SourceLocation RestrictQualLoc = SourceLocation(), SourceLocation AtomicQualLoc = SourceLocation(), SourceLocation UnalignedQualLoc = SourceLocation()); static bool adjustContextForLocalExternDecl(DeclContext &DC); void DiagnoseFunctionSpecifiers(const DeclSpec &DS); NamedDecl getShadowedDeclaration(const TypedefNameDecl D, const LookupResult &R); NamedDecl getShadowedDeclaration(const VarDecl D, const LookupResult &R); NamedDecl getShadowedDeclaration(const BindingDecl D, const LookupResult &R); void CheckShadow(NamedDecl D, NamedDecl ShadowedDecl, const LookupResult &R); void CheckShadow(Scope S, VarDecl D); /// Warn if 'E', which is an expression that is about to be modified, refers /// to a shadowing declaration. void CheckShadowingDeclModification(Expr E, SourceLocation Loc); void DiagnoseShadowingLambdaDecls(const sema::LambdaScopeInfo LSI); private: /// Map of current shadowing declarations to shadowed declarations. Warn if /// it looks like the user is trying to modify the shadowing declaration. llvm::DenseMap<const NamedDecl , const NamedDecl > ShadowingDecls; public: void CheckCastAlign(Expr Op, QualType T, SourceRange TRange); void handleTagNumbering(const TagDecl Tag, Scope TagScope); void setTagNameForLinkagePurposes(TagDecl TagFromDeclSpec, TypedefNameDecl NewTD); void CheckTypedefForVariablyModifiedType(Scope S, TypedefNameDecl D); NamedDecl ActOnTypedefDeclarator(Scope* S, Declarator& D, DeclContext* DC, TypeSourceInfo TInfo, LookupResult &Previous); NamedDecl ActOnTypedefNameDecl(Scope* S, DeclContext* DC, TypedefNameDecl D, LookupResult &Previous, bool &Redeclaration); NamedDecl ActOnVariableDeclarator(Scope S, Declarator &D, DeclContext DC, TypeSourceInfo TInfo, LookupResult &Previous, MultiTemplateParamsArg TemplateParamLists, bool &AddToScope, ArrayRef<BindingDecl > Bindings = None); NamedDecl * ActOnDecompositionDeclarator(Scope S, Declarator &D, MultiTemplateParamsArg TemplateParamLists); // Returns true if the variable declaration is a redeclaration bool CheckVariableDeclaration(VarDecl NewVD, LookupResult &Previous); void CheckVariableDeclarationType(VarDecl NewVD); bool DeduceVariableDeclarationType(VarDecl VDecl, bool DirectInit, Expr Init); void CheckCompleteVariableDeclaration(VarDecl VD); void CheckCompleteDecompositionDeclaration(DecompositionDecl DD); void MaybeSuggestAddingStaticToDecl(const FunctionDecl D); NamedDecl* ActOnFunctionDeclarator(Scope* S, Declarator& D, DeclContext* DC, TypeSourceInfo TInfo, LookupResult &Previous, MultiTemplateParamsArg TemplateParamLists, bool &AddToScope); bool AddOverriddenMethods(CXXRecordDecl DC, CXXMethodDecl MD); enum class CheckConstexprKind { /// Diagnose issues that are non-constant or that are extensions. Diagnose, /// Identify whether this function satisfies the formal rules for constexpr /// functions in the current lanugage mode (with no extensions). CheckValid }; bool CheckConstexprFunctionDefinition(const FunctionDecl FD, CheckConstexprKind Kind); void DiagnoseHiddenVirtualMethods(CXXMethodDecl MD); void FindHiddenVirtualMethods(CXXMethodDecl MD, SmallVectorImpl<CXXMethodDecl> &OverloadedMethods); void NoteHiddenVirtualMethods(CXXMethodDecl MD, SmallVectorImpl<CXXMethodDecl> &OverloadedMethods); // Returns true if the function declaration is a redeclaration bool CheckFunctionDeclaration(Scope S, FunctionDecl NewFD, LookupResult &Previous, bool IsMemberSpecialization); bool shouldLinkDependentDeclWithPrevious(Decl D, Decl OldDecl); bool canFullyTypeCheckRedeclaration(ValueDecl NewD, ValueDecl OldD, QualType NewT, QualType OldT); void CheckMain(FunctionDecl FD, const DeclSpec &D); void CheckMSVCRTEntryPoint(FunctionDecl FD); Attr getImplicitCodeSegOrSectionAttrForFunction(const FunctionDecl FD, bool IsDefinition); void CheckFunctionOrTemplateParamDeclarator(Scope S, Declarator &D); Decl ActOnParamDeclarator(Scope S, Declarator &D); ParmVarDecl BuildParmVarDeclForTypedef(DeclContext DC, SourceLocation Loc, QualType T); ParmVarDecl CheckParameter(DeclContext DC, SourceLocation StartLoc, SourceLocation NameLoc, IdentifierInfo Name, QualType T, TypeSourceInfo TSInfo, StorageClass SC); void ActOnParamDefaultArgument(Decl param, SourceLocation EqualLoc, Expr defarg); void ActOnParamUnparsedDefaultArgument(Decl param, SourceLocation EqualLoc, SourceLocation ArgLoc); void ActOnParamDefaultArgumentError(Decl param, SourceLocation EqualLoc); ExprResult ConvertParamDefaultArgument(ParmVarDecl Param, Expr DefaultArg, SourceLocation EqualLoc); void SetParamDefaultArgument(ParmVarDecl Param, Expr DefaultArg, SourceLocation EqualLoc); // Contexts where using non-trivial C union types can be disallowed. This is // passed to err_non_trivial_c_union_in_invalid_context. enum NonTrivialCUnionContext { // Function parameter. NTCUC_FunctionParam, // Function return. NTCUC_FunctionReturn, // Default-initialized object. NTCUC_DefaultInitializedObject, // Variable with automatic storage duration. NTCUC_AutoVar, // Initializer expression that might copy from another object. NTCUC_CopyInit, // Assignment. NTCUC_Assignment, // Compound literal. NTCUC_CompoundLiteral, // Block capture. NTCUC_BlockCapture, // lvalue-to-rvalue conversion of volatile type. NTCUC_LValueToRValueVolatile, }; /// Emit diagnostics if the initializer or any of its explicit or /// implicitly-generated subexpressions require copying or /// default-initializing a type that is or contains a C union type that is /// non-trivial to copy or default-initialize. void checkNonTrivialCUnionInInitializer(const Expr Init, SourceLocation Loc); // These flags are passed to checkNonTrivialCUnion. enum NonTrivialCUnionKind { NTCUK_Init = 0x1, NTCUK_Destruct = 0x2, NTCUK_Copy = 0x4, }; /// Emit diagnostics if a non-trivial C union type or a struct that contains /// a non-trivial C union is used in an invalid context. void checkNonTrivialCUnion(QualType QT, SourceLocation Loc, NonTrivialCUnionContext UseContext, unsigned NonTrivialKind); void AddInitializerToDecl(Decl dcl, Expr init, bool DirectInit); void ActOnUninitializedDecl(Decl dcl); void ActOnInitializerError(Decl Dcl); void ActOnPureSpecifier(Decl D, SourceLocation PureSpecLoc); void ActOnCXXForRangeDecl(Decl D); StmtResult ActOnCXXForRangeIdentifier(Scope S, SourceLocation IdentLoc, IdentifierInfo Ident, ParsedAttributes &Attrs, SourceLocation AttrEnd); void SetDeclDeleted(Decl dcl, SourceLocation DelLoc); void SetDeclDefaulted(Decl dcl, SourceLocation DefaultLoc); void CheckStaticLocalForDllExport(VarDecl VD); void FinalizeDeclaration(Decl D); DeclGroupPtrTy FinalizeDeclaratorGroup(Scope S, const DeclSpec &DS, ArrayRef<Decl > Group); DeclGroupPtrTy BuildDeclaratorGroup(MutableArrayRef<Decl > Group); /// Should be called on all declarations that might have attached /// documentation comments. void ActOnDocumentableDecl(Decl D); void ActOnDocumentableDecls(ArrayRef<Decl > Group); void ActOnFinishKNRParamDeclarations(Scope S, Declarator &D, SourceLocation LocAfterDecls); void CheckForFunctionRedefinition( FunctionDecl FD, const FunctionDecl EffectiveDefinition = nullptr, SkipBodyInfo SkipBody = nullptr); Decl ActOnStartOfFunctionDef(Scope S, Declarator &D, MultiTemplateParamsArg TemplateParamLists, SkipBodyInfo SkipBody = nullptr); Decl ActOnStartOfFunctionDef(Scope S, Decl D, SkipBodyInfo SkipBody = nullptr); void ActOnStartTrailingRequiresClause(Scope S, Declarator &D); ExprResult ActOnFinishTrailingRequiresClause(ExprResult ConstraintExpr); ExprResult ActOnRequiresClause(ExprResult ConstraintExpr); void ActOnStartOfObjCMethodDef(Scope S, Decl D); bool isObjCMethodDecl(Decl D) { return D && isa<ObjCMethodDecl>(D); } /// Determine whether we can delay parsing the body of a function or /// function template until it is used, assuming we don't care about emitting /// code for that function. /// /// This will be \c false if we may need the body of the function in the /// middle of parsing an expression (where it's impractical to switch to /// parsing a different function), for instance, if it's constexpr in C++11 /// or has an 'auto' return type in C++14. These cases are essentially bugs. bool canDelayFunctionBody(const Declarator &D); /// Determine whether we can skip parsing the body of a function /// definition, assuming we don't care about analyzing its body or emitting /// code for that function. /// /// This will be \c false only if we may need the body of the function in /// order to parse the rest of the program (for instance, if it is /// \c constexpr in C++11 or has an 'auto' return type in C++14). bool canSkipFunctionBody(Decl D); void computeNRVO(Stmt Body, sema::FunctionScopeInfo Scope); Decl ActOnFinishFunctionBody(Decl Decl, Stmt Body); Decl ActOnFinishFunctionBody(Decl Decl, Stmt Body, bool IsInstantiation); Decl ActOnSkippedFunctionBody(Decl Decl); void ActOnFinishInlineFunctionDef(FunctionDecl D); /// ActOnFinishDelayedAttribute - Invoked when we have finished parsing an /// attribute for which parsing is delayed. void ActOnFinishDelayedAttribute(Scope S, Decl D, ParsedAttributes &Attrs); /// Diagnose any unused parameters in the given sequence of /// ParmVarDecl pointers. void DiagnoseUnusedParameters(ArrayRef<ParmVarDecl > Parameters); /// Diagnose whether the size of parameters or return value of a /// function or obj-c method definition is pass-by-value and larger than a /// specified threshold. void DiagnoseSizeOfParametersAndReturnValue(ArrayRef<ParmVarDecl > Parameters, QualType ReturnTy, NamedDecl D); void DiagnoseInvalidJumps(Stmt Body); Decl ActOnFileScopeAsmDecl(Expr expr, SourceLocation AsmLoc, SourceLocation RParenLoc); /// Handle a C++11 empty-declaration and attribute-declaration. Decl ActOnEmptyDeclaration(Scope S, const ParsedAttributesView &AttrList, SourceLocation SemiLoc); enum class ModuleDeclKind { Interface, ///< 'export module X;' Implementation, ///< 'module X;' }; /// The parser has processed a module-declaration that begins the definition /// of a module interface or implementation. DeclGroupPtrTy ActOnModuleDecl(SourceLocation StartLoc, SourceLocation ModuleLoc, ModuleDeclKind MDK, ModuleIdPath Path, bool IsFirstDecl); /// The parser has processed a global-module-fragment declaration that begins /// the definition of the global module fragment of the current module unit. /// \param ModuleLoc The location of the 'module' keyword. DeclGroupPtrTy ActOnGlobalModuleFragmentDecl(SourceLocation ModuleLoc); /// The parser has processed a private-module-fragment declaration that begins /// the definition of the private module fragment of the current module unit. /// \param ModuleLoc The location of the 'module' keyword. /// \param PrivateLoc The location of the 'private' keyword. DeclGroupPtrTy ActOnPrivateModuleFragmentDecl(SourceLocation ModuleLoc, SourceLocation PrivateLoc); /// The parser has processed a module import declaration. /// /// \param StartLoc The location of the first token in the declaration. This /// could be the location of an '@', 'export', or 'import'. /// \param ExportLoc The location of the 'export' keyword, if any. /// \param ImportLoc The location of the 'import' keyword. /// \param Path The module access path. DeclResult ActOnModuleImport(SourceLocation StartLoc, SourceLocation ExportLoc, SourceLocation ImportLoc, ModuleIdPath Path); DeclResult ActOnModuleImport(SourceLocation StartLoc, SourceLocation ExportLoc, SourceLocation ImportLoc, Module M, ModuleIdPath Path = {}); /// The parser has processed a module import translated from a /// #include or similar preprocessing directive. void ActOnModuleInclude(SourceLocation DirectiveLoc, Module Mod); void BuildModuleInclude(SourceLocation DirectiveLoc, Module Mod); /// The parsed has entered a submodule. void ActOnModuleBegin(SourceLocation DirectiveLoc, Module Mod); /// The parser has left a submodule. void ActOnModuleEnd(SourceLocation DirectiveLoc, Module Mod); /// Create an implicit import of the given module at the given /// source location, for error recovery, if possible. /// /// This routine is typically used when an entity found by name lookup /// is actually hidden within a module that we know about but the user /// has forgotten to import. void createImplicitModuleImportForErrorRecovery(SourceLocation Loc, Module Mod); /// Kinds of missing import. Note, the values of these enumerators correspond /// to %select values in diagnostics. enum class MissingImportKind { Declaration, Definition, DefaultArgument, ExplicitSpecialization, PartialSpecialization }; /// Diagnose that the specified declaration needs to be visible but /// isn't, and suggest a module import that would resolve the problem. void diagnoseMissingImport(SourceLocation Loc, NamedDecl Decl, MissingImportKind MIK, bool Recover = true); void diagnoseMissingImport(SourceLocation Loc, NamedDecl Decl, SourceLocation DeclLoc, ArrayRef<Module > Modules, MissingImportKind MIK, bool Recover); Decl ActOnStartExportDecl(Scope S, SourceLocation ExportLoc, SourceLocation LBraceLoc); Decl ActOnFinishExportDecl(Scope S, Decl ExportDecl, SourceLocation RBraceLoc); /// We've found a use of a templated declaration that would trigger an /// implicit instantiation. Check that any relevant explicit specializations /// and partial specializations are visible, and diagnose if not. void checkSpecializationVisibility(SourceLocation Loc, NamedDecl Spec); /// Retrieve a suitable printing policy for diagnostics. PrintingPolicy getPrintingPolicy() const { return getPrintingPolicy(Context, PP); } /// Retrieve a suitable printing policy for diagnostics. static PrintingPolicy getPrintingPolicy(const ASTContext &Ctx, const Preprocessor &PP); /// Scope actions. void ActOnPopScope(SourceLocation Loc, Scope S); void ActOnTranslationUnitScope(Scope S); Decl ParsedFreeStandingDeclSpec(Scope S, AccessSpecifier AS, DeclSpec &DS, RecordDecl &AnonRecord); Decl ParsedFreeStandingDeclSpec(Scope S, AccessSpecifier AS, DeclSpec &DS, MultiTemplateParamsArg TemplateParams, bool IsExplicitInstantiation, RecordDecl &AnonRecord); Decl BuildAnonymousStructOrUnion(Scope S, DeclSpec &DS, AccessSpecifier AS, RecordDecl Record, const PrintingPolicy &Policy); Decl BuildMicrosoftCAnonymousStruct(Scope S, DeclSpec &DS, RecordDecl Record); /// Common ways to introduce type names without a tag for use in diagnostics. /// Keep in sync with err_tag_reference_non_tag. enum NonTagKind { NTK_NonStruct, NTK_NonClass, NTK_NonUnion, NTK_NonEnum, NTK_Typedef, NTK_TypeAlias, NTK_Template, NTK_TypeAliasTemplate, NTK_TemplateTemplateArgument, }; /// Given a non-tag type declaration, returns an enum useful for indicating /// what kind of non-tag type this is. NonTagKind getNonTagTypeDeclKind(const Decl D, TagTypeKind TTK); bool isAcceptableTagRedeclaration(const TagDecl Previous, TagTypeKind NewTag, bool isDefinition, SourceLocation NewTagLoc, const IdentifierInfo Name); enum TagUseKind { TUK_Reference, // Reference to a tag: 'struct foo X;' TUK_Declaration, // Fwd decl of a tag: 'struct foo;' TUK_Definition, // Definition of a tag: 'struct foo { int X; } Y;' TUK_Friend // Friend declaration: 'friend struct foo;' }; Decl ActOnTag(Scope S, unsigned TagSpec, TagUseKind TUK, SourceLocation KWLoc, CXXScopeSpec &SS, IdentifierInfo Name, SourceLocation NameLoc, const ParsedAttributesView &Attr, AccessSpecifier AS, SourceLocation ModulePrivateLoc, MultiTemplateParamsArg TemplateParameterLists, bool &OwnedDecl, bool &IsDependent, SourceLocation ScopedEnumKWLoc, bool ScopedEnumUsesClassTag, TypeResult UnderlyingType, bool IsTypeSpecifier, bool IsTemplateParamOrArg, SkipBodyInfo SkipBody = nullptr); Decl ActOnTemplatedFriendTag(Scope S, SourceLocation FriendLoc, unsigned TagSpec, SourceLocation TagLoc, CXXScopeSpec &SS, IdentifierInfo Name, SourceLocation NameLoc, const ParsedAttributesView &Attr, MultiTemplateParamsArg TempParamLists); TypeResult ActOnDependentTag(Scope S, unsigned TagSpec, TagUseKind TUK, const CXXScopeSpec &SS, IdentifierInfo Name, SourceLocation TagLoc, SourceLocation NameLoc); void ActOnDefs(Scope S, Decl TagD, SourceLocation DeclStart, IdentifierInfo ClassName, SmallVectorImpl<Decl > &Decls); Decl ActOnField(Scope S, Decl TagD, SourceLocation DeclStart, Declarator &D, Expr BitfieldWidth); FieldDecl HandleField(Scope S, RecordDecl TagD, SourceLocation DeclStart, Declarator &D, Expr BitfieldWidth, InClassInitStyle InitStyle, AccessSpecifier AS); MSPropertyDecl HandleMSProperty(Scope S, RecordDecl TagD, SourceLocation DeclStart, Declarator &D, Expr BitfieldWidth, InClassInitStyle InitStyle, AccessSpecifier AS, const ParsedAttr &MSPropertyAttr); FieldDecl CheckFieldDecl(DeclarationName Name, QualType T, TypeSourceInfo TInfo, RecordDecl Record, SourceLocation Loc, bool Mutable, Expr BitfieldWidth, InClassInitStyle InitStyle, SourceLocation TSSL, AccessSpecifier AS, NamedDecl PrevDecl, Declarator D = nullptr); bool CheckNontrivialField(FieldDecl FD); void DiagnoseNontrivial(const CXXRecordDecl Record, CXXSpecialMember CSM); enum TrivialABIHandling { /// The triviality of a method unaffected by "trivial_abi". TAH_IgnoreTrivialABI, /// The triviality of a method affected by "trivial_abi". TAH_ConsiderTrivialABI }; bool SpecialMemberIsTrivial(CXXMethodDecl MD, CXXSpecialMember CSM, TrivialABIHandling TAH = TAH_IgnoreTrivialABI, bool Diagnose = false); /// For a defaulted function, the kind of defaulted function that it is. class DefaultedFunctionKind { CXXSpecialMember SpecialMember : 8; DefaultedComparisonKind Comparison : 8; public: DefaultedFunctionKind() : SpecialMember(CXXInvalid), Comparison(DefaultedComparisonKind::None) { } DefaultedFunctionKind(CXXSpecialMember CSM) : SpecialMember(CSM), Comparison(DefaultedComparisonKind::None) {} DefaultedFunctionKind(DefaultedComparisonKind Comp) : SpecialMember(CXXInvalid), Comparison(Comp) {} bool isSpecialMember() const { return SpecialMember != CXXInvalid; } bool isComparison() const { return Comparison != DefaultedComparisonKind::None; } explicit operator bool() const { return isSpecialMember() \|\| isComparison(); } CXXSpecialMember asSpecialMember() const { return SpecialMember; } DefaultedComparisonKind asComparison() const { return Comparison; } /// Get the index of this function kind for use in diagnostics. unsigned getDiagnosticIndex() const { static_assert(CXXInvalid > CXXDestructor, "invalid should have highest index"); static_assert((unsigned)DefaultedComparisonKind::None == 0, "none should be equal to zero"); return SpecialMember + (unsigned)Comparison; } }; DefaultedFunctionKind getDefaultedFunctionKind(const FunctionDecl FD); CXXSpecialMember getSpecialMember(const CXXMethodDecl MD) { return getDefaultedFunctionKind(MD).asSpecialMember(); } DefaultedComparisonKind getDefaultedComparisonKind(const FunctionDecl FD) { return getDefaultedFunctionKind(FD).asComparison(); } void ActOnLastBitfield(SourceLocation DeclStart, SmallVectorImpl<Decl > &AllIvarDecls); Decl ActOnIvar(Scope S, SourceLocation DeclStart, Declarator &D, Expr BitfieldWidth, tok::ObjCKeywordKind visibility); // This is used for both record definitions and ObjC interface declarations. void ActOnFields(Scope S, SourceLocation RecLoc, Decl TagDecl, ArrayRef<Decl > Fields, SourceLocation LBrac, SourceLocation RBrac, const ParsedAttributesView &AttrList); /// ActOnTagStartDefinition - Invoked when we have entered the /// scope of a tag's definition (e.g., for an enumeration, class, /// struct, or union). void ActOnTagStartDefinition(Scope S, Decl TagDecl); /// Perform ODR-like check for C/ObjC when merging tag types from modules. /// Differently from C++, actually parse the body and reject / error out /// in case of a structural mismatch. bool ActOnDuplicateDefinition(DeclSpec &DS, Decl Prev, SkipBodyInfo &SkipBody); typedef void SkippedDefinitionContext; /// Invoked when we enter a tag definition that we're skipping. SkippedDefinitionContext ActOnTagStartSkippedDefinition(Scope S, Decl TD); Decl ActOnObjCContainerStartDefinition(Decl IDecl); /// ActOnStartCXXMemberDeclarations - Invoked when we have parsed a /// C++ record definition's base-specifiers clause and are starting its /// member declarations. void ActOnStartCXXMemberDeclarations(Scope S, Decl TagDecl, SourceLocation FinalLoc, bool IsFinalSpelledSealed, bool IsAbstract, SourceLocation LBraceLoc); /// ActOnTagFinishDefinition - Invoked once we have finished parsing /// the definition of a tag (enumeration, class, struct, or union). void ActOnTagFinishDefinition(Scope S, Decl TagDecl, SourceRange BraceRange); void ActOnTagFinishSkippedDefinition(SkippedDefinitionContext Context); void ActOnObjCContainerFinishDefinition(); /// Invoked when we must temporarily exit the objective-c container /// scope for parsing/looking-up C constructs. /// /// Must be followed by a call to \see ActOnObjCReenterContainerContext void ActOnObjCTemporaryExitContainerContext(DeclContext DC); void ActOnObjCReenterContainerContext(DeclContext DC); /// ActOnTagDefinitionError - Invoked when there was an unrecoverable /// error parsing the definition of a tag. void ActOnTagDefinitionError(Scope S, Decl TagDecl); EnumConstantDecl CheckEnumConstant(EnumDecl Enum, EnumConstantDecl LastEnumConst, SourceLocation IdLoc, IdentifierInfo Id, Expr val); bool CheckEnumUnderlyingType(TypeSourceInfo TI); bool CheckEnumRedeclaration(SourceLocation EnumLoc, bool IsScoped, QualType EnumUnderlyingTy, bool IsFixed, const EnumDecl Prev); /// Determine whether the body of an anonymous enumeration should be skipped. /// \param II The name of the first enumerator. SkipBodyInfo shouldSkipAnonEnumBody(Scope S, IdentifierInfo II, SourceLocation IILoc); Decl ActOnEnumConstant(Scope S, Decl EnumDecl, Decl LastEnumConstant, SourceLocation IdLoc, IdentifierInfo Id, const ParsedAttributesView &Attrs, SourceLocation EqualLoc, Expr Val); void ActOnEnumBody(SourceLocation EnumLoc, SourceRange BraceRange, Decl EnumDecl, ArrayRef<Decl > Elements, Scope S, const ParsedAttributesView &Attr); /// Set the current declaration context until it gets popped. void PushDeclContext(Scope S, DeclContext DC); void PopDeclContext(); /// EnterDeclaratorContext - Used when we must lookup names in the context /// of a declarator's nested name specifier. void EnterDeclaratorContext(Scope S, DeclContext DC); void ExitDeclaratorContext(Scope S); /// Enter a template parameter scope, after it's been associated with a particular /// DeclContext. Causes lookup within the scope to chain through enclosing contexts /// in the correct order. void EnterTemplatedContext(Scope S, DeclContext DC); /// Push the parameters of D, which must be a function, into scope. void ActOnReenterFunctionContext(Scope S, Decl* D); void ActOnExitFunctionContext(); DeclContext getFunctionLevelDeclContext(); /// getCurFunctionDecl - If inside of a function body, this returns a pointer /// to the function decl for the function being parsed. If we're currently /// in a 'block', this returns the containing context. FunctionDecl getCurFunctionDecl(); /// getCurMethodDecl - If inside of a method body, this returns a pointer to /// the method decl for the method being parsed. If we're currently /// in a 'block', this returns the containing context. ObjCMethodDecl getCurMethodDecl(); /// getCurFunctionOrMethodDecl - Return the Decl for the current ObjC method /// or C function we're in, otherwise return null. If we're currently /// in a 'block', this returns the containing context. NamedDecl getCurFunctionOrMethodDecl(); /// Add this decl to the scope shadowed decl chains. void PushOnScopeChains(NamedDecl D, Scope S, bool AddToContext = true); /// isDeclInScope - If 'Ctx' is a function/method, isDeclInScope returns true /// if 'D' is in Scope 'S', otherwise 'S' is ignored and isDeclInScope returns /// true if 'D' belongs to the given declaration context. /// /// \param AllowInlineNamespace If \c true, allow the declaration to be in the /// enclosing namespace set of the context, rather than contained /// directly within it. bool isDeclInScope(NamedDecl D, DeclContext Ctx, Scope S = nullptr, bool AllowInlineNamespace = false); /// Finds the scope corresponding to the given decl context, if it /// happens to be an enclosing scope. Otherwise return NULL. static Scope getScopeForDeclContext(Scope S, DeclContext DC); /// Subroutines of ActOnDeclarator(). TypedefDecl ParseTypedefDecl(Scope S, Declarator &D, QualType T, TypeSourceInfo TInfo); bool isIncompatibleTypedef(TypeDecl Old, TypedefNameDecl New); /// Describes the kind of merge to perform for availability /// attributes (including "deprecated", "unavailable", and "availability"). enum AvailabilityMergeKind { /// Don't merge availability attributes at all. AMK_None, /// Merge availability attributes for a redeclaration, which requires /// an exact match. AMK_Redeclaration, /// Merge availability attributes for an override, which requires /// an exact match or a weakening of constraints. AMK_Override, /// Merge availability attributes for an implementation of /// a protocol requirement. AMK_ProtocolImplementation, /// Merge availability attributes for an implementation of /// an optional protocol requirement. AMK_OptionalProtocolImplementation }; /// Describes the kind of priority given to an availability attribute. /// /// The sum of priorities deteremines the final priority of the attribute. /// The final priority determines how the attribute will be merged. /// An attribute with a lower priority will always remove higher priority /// attributes for the specified platform when it is being applied. An /// attribute with a higher priority will not be applied if the declaration /// already has an availability attribute with a lower priority for the /// specified platform. The final prirority values are not expected to match /// the values in this enumeration, but instead should be treated as a plain /// integer value. This enumeration just names the priority weights that are /// used to calculate that final vaue. enum AvailabilityPriority : int { /// The availability attribute was specified explicitly next to the /// declaration. AP_Explicit = 0, /// The availability attribute was applied using '#pragma clang attribute'. AP_PragmaClangAttribute = 1, /// The availability attribute for a specific platform was inferred from /// an availability attribute for another platform. AP_InferredFromOtherPlatform = 2 }; /// Attribute merging methods. Return true if a new attribute was added. AvailabilityAttr mergeAvailabilityAttr(NamedDecl D, const AttributeCommonInfo &CI, IdentifierInfo Platform, bool Implicit, VersionTuple Introduced, VersionTuple Deprecated, VersionTuple Obsoleted, bool IsUnavailable, StringRef Message, bool IsStrict, StringRef Replacement, AvailabilityMergeKind AMK, int Priority); TypeVisibilityAttr * mergeTypeVisibilityAttr(Decl D, const AttributeCommonInfo &CI, TypeVisibilityAttr::VisibilityType Vis); VisibilityAttr mergeVisibilityAttr(Decl D, const AttributeCommonInfo &CI, VisibilityAttr::VisibilityType Vis); UuidAttr mergeUuidAttr(Decl D, const AttributeCommonInfo &CI, StringRef UuidAsWritten, MSGuidDecl GuidDecl); DLLImportAttr mergeDLLImportAttr(Decl D, const AttributeCommonInfo &CI); DLLExportAttr mergeDLLExportAttr(Decl D, const AttributeCommonInfo &CI); MSInheritanceAttr mergeMSInheritanceAttr(Decl D, const AttributeCommonInfo &CI, bool BestCase, MSInheritanceModel Model); ErrorAttr mergeErrorAttr(Decl D, const AttributeCommonInfo &CI, StringRef NewUserDiagnostic); FormatAttr mergeFormatAttr(Decl D, const AttributeCommonInfo &CI, IdentifierInfo Format, int FormatIdx, int FirstArg); SectionAttr mergeSectionAttr(Decl D, const AttributeCommonInfo &CI, StringRef Name); CodeSegAttr mergeCodeSegAttr(Decl D, const AttributeCommonInfo &CI, StringRef Name); AlwaysInlineAttr mergeAlwaysInlineAttr(Decl D, const AttributeCommonInfo &CI, const IdentifierInfo Ident); MinSizeAttr mergeMinSizeAttr(Decl D, const AttributeCommonInfo &CI); SwiftNameAttr mergeSwiftNameAttr(Decl D, const SwiftNameAttr &SNA, StringRef Name); OptimizeNoneAttr mergeOptimizeNoneAttr(Decl D, const AttributeCommonInfo &CI); InternalLinkageAttr mergeInternalLinkageAttr(Decl D, const ParsedAttr &AL); InternalLinkageAttr mergeInternalLinkageAttr(Decl D, const InternalLinkageAttr &AL); WebAssemblyImportNameAttr mergeImportNameAttr( Decl D, const WebAssemblyImportNameAttr &AL); WebAssemblyImportModuleAttr mergeImportModuleAttr( Decl D, const WebAssemblyImportModuleAttr &AL); EnforceTCBAttr mergeEnforceTCBAttr(Decl D, const EnforceTCBAttr &AL); EnforceTCBLeafAttr mergeEnforceTCBLeafAttr(Decl D, const EnforceTCBLeafAttr &AL); BTFDeclTagAttr mergeBTFDeclTagAttr(Decl D, const BTFDeclTagAttr &AL); void mergeDeclAttributes(NamedDecl New, Decl Old, AvailabilityMergeKind AMK = AMK_Redeclaration); void MergeTypedefNameDecl(Scope S, TypedefNameDecl New, LookupResult &OldDecls); bool MergeFunctionDecl(FunctionDecl New, NamedDecl &Old, Scope S, bool MergeTypeWithOld); bool MergeCompatibleFunctionDecls(FunctionDecl New, FunctionDecl Old, Scope S, bool MergeTypeWithOld); void mergeObjCMethodDecls(ObjCMethodDecl New, ObjCMethodDecl Old); void MergeVarDecl(VarDecl New, LookupResult &Previous); void MergeVarDeclTypes(VarDecl New, VarDecl Old, bool MergeTypeWithOld); void MergeVarDeclExceptionSpecs(VarDecl New, VarDecl Old); bool checkVarDeclRedefinition(VarDecl OldDefn, VarDecl NewDefn); void notePreviousDefinition(const NamedDecl Old, SourceLocation New); bool MergeCXXFunctionDecl(FunctionDecl New, FunctionDecl Old, Scope S); // AssignmentAction - This is used by all the assignment diagnostic functions // to represent what is actually causing the operation enum AssignmentAction { AA_Assigning, AA_Passing, AA_Returning, AA_Converting, AA_Initializing, AA_Sending, AA_Casting, AA_Passing_CFAudited }; /// C++ Overloading. enum OverloadKind { /// This is a legitimate overload: the existing declarations are /// functions or function templates with different signatures. Ovl_Overload, /// This is not an overload because the signature exactly matches /// an existing declaration. Ovl_Match, /// This is not an overload because the lookup results contain a /// non-function. Ovl_NonFunction }; OverloadKind CheckOverload(Scope S, FunctionDecl New, const LookupResult &OldDecls, NamedDecl &OldDecl, bool IsForUsingDecl); bool IsOverload(FunctionDecl New, FunctionDecl Old, bool IsForUsingDecl, bool ConsiderCudaAttrs = true, bool ConsiderRequiresClauses = true); enum class AllowedExplicit { /// Allow no explicit functions to be used. None, /// Allow explicit conversion functions but not explicit constructors. Conversions, /// Allow both explicit conversion functions and explicit constructors. All }; ImplicitConversionSequence TryImplicitConversion(Expr From, QualType ToType, bool SuppressUserConversions, AllowedExplicit AllowExplicit, bool InOverloadResolution, bool CStyle, bool AllowObjCWritebackConversion); bool IsIntegralPromotion(Expr From, QualType FromType, QualType ToType); bool IsFloatingPointPromotion(QualType FromType, QualType ToType); bool IsComplexPromotion(QualType FromType, QualType ToType); bool IsPointerConversion(Expr From, QualType FromType, QualType ToType, bool InOverloadResolution, QualType& ConvertedType, bool &IncompatibleObjC); bool isObjCPointerConversion(QualType FromType, QualType ToType, QualType& ConvertedType, bool &IncompatibleObjC); bool isObjCWritebackConversion(QualType FromType, QualType ToType, QualType &ConvertedType); bool IsBlockPointerConversion(QualType FromType, QualType ToType, QualType& ConvertedType); bool FunctionParamTypesAreEqual(const FunctionProtoType OldType, const FunctionProtoType NewType, unsigned ArgPos = nullptr); void HandleFunctionTypeMismatch(PartialDiagnostic &PDiag, QualType FromType, QualType ToType); void maybeExtendBlockObject(ExprResult &E); CastKind PrepareCastToObjCObjectPointer(ExprResult &E); bool CheckPointerConversion(Expr From, QualType ToType, CastKind &Kind, CXXCastPath& BasePath, bool IgnoreBaseAccess, bool Diagnose = true); bool IsMemberPointerConversion(Expr From, QualType FromType, QualType ToType, bool InOverloadResolution, QualType &ConvertedType); bool CheckMemberPointerConversion(Expr From, QualType ToType, CastKind &Kind, CXXCastPath &BasePath, bool IgnoreBaseAccess); bool IsQualificationConversion(QualType FromType, QualType ToType, bool CStyle, bool &ObjCLifetimeConversion); bool IsFunctionConversion(QualType FromType, QualType ToType, QualType &ResultTy); bool DiagnoseMultipleUserDefinedConversion(Expr From, QualType ToType); bool isSameOrCompatibleFunctionType(CanQualType Param, CanQualType Arg); bool CanPerformAggregateInitializationForOverloadResolution( const InitializedEntity &Entity, InitListExpr From); bool IsStringInit(Expr Init, const ArrayType AT); bool CanPerformCopyInitialization(const InitializedEntity &Entity, ExprResult Init); ExprResult PerformCopyInitialization(const InitializedEntity &Entity, SourceLocation EqualLoc, ExprResult Init, bool TopLevelOfInitList = false, bool AllowExplicit = false); ExprResult PerformObjectArgumentInitialization(Expr From, NestedNameSpecifier Qualifier, NamedDecl FoundDecl, CXXMethodDecl Method); /// Check that the lifetime of the initializer (and its subobjects) is /// sufficient for initializing the entity, and perform lifetime extension /// (when permitted) if not. void checkInitializerLifetime(const InitializedEntity &Entity, Expr Init); ExprResult PerformContextuallyConvertToBool(Expr From); ExprResult PerformContextuallyConvertToObjCPointer(Expr From); /// Contexts in which a converted constant expression is required. enum CCEKind { CCEK_CaseValue, ///< Expression in a case label. CCEK_Enumerator, ///< Enumerator value with fixed underlying type. CCEK_TemplateArg, ///< Value of a non-type template parameter. CCEK_ArrayBound, ///< Array bound in array declarator or new-expression. CCEK_ExplicitBool, ///< Condition in an explicit(bool) specifier. CCEK_Noexcept ///< Condition in a noexcept(bool) specifier. }; ExprResult CheckConvertedConstantExpression(Expr From, QualType T, llvm::APSInt &Value, CCEKind CCE); ExprResult CheckConvertedConstantExpression(Expr From, QualType T, APValue &Value, CCEKind CCE, NamedDecl Dest = nullptr); /// Abstract base class used to perform a contextual implicit /// conversion from an expression to any type passing a filter. class ContextualImplicitConverter { public: bool Suppress; bool SuppressConversion; ContextualImplicitConverter(bool Suppress = false, bool SuppressConversion = false) : Suppress(Suppress), SuppressConversion(SuppressConversion) {} /// Determine whether the specified type is a valid destination type /// for this conversion. virtual bool match(QualType T) = 0; /// Emits a diagnostic complaining that the expression does not have /// integral or enumeration type. virtual SemaDiagnosticBuilder diagnoseNoMatch(Sema &S, SourceLocation Loc, QualType T) = 0; /// Emits a diagnostic when the expression has incomplete class type. virtual SemaDiagnosticBuilder diagnoseIncomplete(Sema &S, SourceLocation Loc, QualType T) = 0; /// Emits a diagnostic when the only matching conversion function /// is explicit. virtual SemaDiagnosticBuilder diagnoseExplicitConv( Sema &S, SourceLocation Loc, QualType T, QualType ConvTy) = 0; /// Emits a note for the explicit conversion function. virtual SemaDiagnosticBuilder noteExplicitConv(Sema &S, CXXConversionDecl Conv, QualType ConvTy) = 0; /// Emits a diagnostic when there are multiple possible conversion /// functions. virtual SemaDiagnosticBuilder diagnoseAmbiguous(Sema &S, SourceLocation Loc, QualType T) = 0; /// Emits a note for one of the candidate conversions. virtual SemaDiagnosticBuilder noteAmbiguous(Sema &S, CXXConversionDecl Conv, QualType ConvTy) = 0; /// Emits a diagnostic when we picked a conversion function /// (for cases when we are not allowed to pick a conversion function). virtual SemaDiagnosticBuilder diagnoseConversion( Sema &S, SourceLocation Loc, QualType T, QualType ConvTy) = 0; virtual ~ContextualImplicitConverter() {} }; class ICEConvertDiagnoser : public ContextualImplicitConverter { bool AllowScopedEnumerations; public: ICEConvertDiagnoser(bool AllowScopedEnumerations, bool Suppress, bool SuppressConversion) : ContextualImplicitConverter(Suppress, SuppressConversion), AllowScopedEnumerations(AllowScopedEnumerations) {} /// Match an integral or (possibly scoped) enumeration type. bool match(QualType T) override; SemaDiagnosticBuilder diagnoseNoMatch(Sema &S, SourceLocation Loc, QualType T) override { return diagnoseNotInt(S, Loc, T); } /// Emits a diagnostic complaining that the expression does not have /// integral or enumeration type. virtual SemaDiagnosticBuilder diagnoseNotInt(Sema &S, SourceLocation Loc, QualType T) = 0; }; /// Perform a contextual implicit conversion. ExprResult PerformContextualImplicitConversion( SourceLocation Loc, Expr FromE, ContextualImplicitConverter &Converter); enum ObjCSubscriptKind { OS_Array, OS_Dictionary, OS_Error }; ObjCSubscriptKind CheckSubscriptingKind(Expr FromE); // Note that LK_String is intentionally after the other literals, as // this is used for diagnostics logic. enum ObjCLiteralKind { LK_Array, LK_Dictionary, LK_Numeric, LK_Boxed, LK_String, LK_Block, LK_None }; ObjCLiteralKind CheckLiteralKind(Expr FromE); ExprResult PerformObjectMemberConversion(Expr From, NestedNameSpecifier Qualifier, NamedDecl FoundDecl, NamedDecl Member); // Members have to be NamespaceDecl* or TranslationUnitDecl. // TODO: make this is a typesafe union. typedef llvm::SmallSetVector<DeclContext , 16> AssociatedNamespaceSet; typedef llvm::SmallSetVector<CXXRecordDecl , 16> AssociatedClassSet; using ADLCallKind = CallExpr::ADLCallKind; void AddOverloadCandidate(FunctionDecl Function, DeclAccessPair FoundDecl, ArrayRef<Expr > Args, OverloadCandidateSet &CandidateSet, bool SuppressUserConversions = false, bool PartialOverloading = false, bool AllowExplicit = true, bool AllowExplicitConversion = false, ADLCallKind IsADLCandidate = ADLCallKind::NotADL, ConversionSequenceList EarlyConversions = None, OverloadCandidateParamOrder PO = {}); void AddFunctionCandidates(const UnresolvedSetImpl &Functions, ArrayRef<Expr > Args, OverloadCandidateSet &CandidateSet, TemplateArgumentListInfo ExplicitTemplateArgs = nullptr, bool SuppressUserConversions = false, bool PartialOverloading = false, bool FirstArgumentIsBase = false); void AddMethodCandidate(DeclAccessPair FoundDecl, QualType ObjectType, Expr::Classification ObjectClassification, ArrayRef<Expr > Args, OverloadCandidateSet& CandidateSet, bool SuppressUserConversion = false, OverloadCandidateParamOrder PO = {}); void AddMethodCandidate(CXXMethodDecl Method, DeclAccessPair FoundDecl, CXXRecordDecl ActingContext, QualType ObjectType, Expr::Classification ObjectClassification, ArrayRef<Expr > Args, OverloadCandidateSet& CandidateSet, bool SuppressUserConversions = false, bool PartialOverloading = false, ConversionSequenceList EarlyConversions = None, OverloadCandidateParamOrder PO = {}); void AddMethodTemplateCandidate(FunctionTemplateDecl MethodTmpl, DeclAccessPair FoundDecl, CXXRecordDecl ActingContext, TemplateArgumentListInfo ExplicitTemplateArgs, QualType ObjectType, Expr::Classification ObjectClassification, ArrayRef<Expr > Args, OverloadCandidateSet& CandidateSet, bool SuppressUserConversions = false, bool PartialOverloading = false, OverloadCandidateParamOrder PO = {}); void AddTemplateOverloadCandidate( FunctionTemplateDecl FunctionTemplate, DeclAccessPair FoundDecl, TemplateArgumentListInfo ExplicitTemplateArgs, ArrayRef<Expr > Args, OverloadCandidateSet &CandidateSet, bool SuppressUserConversions = false, bool PartialOverloading = false, bool AllowExplicit = true, ADLCallKind IsADLCandidate = ADLCallKind::NotADL, OverloadCandidateParamOrder PO = {}); bool CheckNonDependentConversions( FunctionTemplateDecl FunctionTemplate, ArrayRef<QualType> ParamTypes, ArrayRef<Expr > Args, OverloadCandidateSet &CandidateSet, ConversionSequenceList &Conversions, bool SuppressUserConversions, CXXRecordDecl ActingContext = nullptr, QualType ObjectType = QualType(), Expr::Classification ObjectClassification = {}, OverloadCandidateParamOrder PO = {}); void AddConversionCandidate( CXXConversionDecl Conversion, DeclAccessPair FoundDecl, CXXRecordDecl ActingContext, Expr From, QualType ToType, OverloadCandidateSet &CandidateSet, bool AllowObjCConversionOnExplicit, bool AllowExplicit, bool AllowResultConversion = true); void AddTemplateConversionCandidate( FunctionTemplateDecl FunctionTemplate, DeclAccessPair FoundDecl, CXXRecordDecl ActingContext, Expr From, QualType ToType, OverloadCandidateSet &CandidateSet, bool AllowObjCConversionOnExplicit, bool AllowExplicit, bool AllowResultConversion = true); void AddSurrogateCandidate(CXXConversionDecl Conversion, DeclAccessPair FoundDecl, CXXRecordDecl ActingContext, const FunctionProtoType Proto, Expr Object, ArrayRef<Expr > Args, OverloadCandidateSet& CandidateSet); void AddNonMemberOperatorCandidates( const UnresolvedSetImpl &Functions, ArrayRef<Expr > Args, OverloadCandidateSet &CandidateSet, TemplateArgumentListInfo ExplicitTemplateArgs = nullptr); void AddMemberOperatorCandidates(OverloadedOperatorKind Op, SourceLocation OpLoc, ArrayRef<Expr > Args, OverloadCandidateSet &CandidateSet, OverloadCandidateParamOrder PO = {}); void AddBuiltinCandidate(QualType ParamTys, ArrayRef<Expr > Args, OverloadCandidateSet& CandidateSet, bool IsAssignmentOperator = false, unsigned NumContextualBoolArguments = 0); void AddBuiltinOperatorCandidates(OverloadedOperatorKind Op, SourceLocation OpLoc, ArrayRef<Expr > Args, OverloadCandidateSet& CandidateSet); void AddArgumentDependentLookupCandidates(DeclarationName Name, SourceLocation Loc, ArrayRef<Expr > Args, TemplateArgumentListInfo ExplicitTemplateArgs, OverloadCandidateSet& CandidateSet, bool PartialOverloading = false); // Emit as a 'note' the specific overload candidate void NoteOverloadCandidate( NamedDecl Found, FunctionDecl Fn, OverloadCandidateRewriteKind RewriteKind = OverloadCandidateRewriteKind(), QualType DestType = QualType(), bool TakingAddress = false); // Emit as a series of 'note's all template and non-templates identified by // the expression Expr void NoteAllOverloadCandidates(Expr E, QualType DestType = QualType(), bool TakingAddress = false); /// Check the enable_if expressions on the given function. Returns the first /// failing attribute, or NULL if they were all successful. EnableIfAttr CheckEnableIf(FunctionDecl Function, SourceLocation CallLoc, ArrayRef<Expr > Args, bool MissingImplicitThis = false); /// Find the failed Boolean condition within a given Boolean /// constant expression, and describe it with a string. std::pair<Expr , std::string> findFailedBooleanCondition(Expr Cond); /// Emit diagnostics for the diagnose_if attributes on Function, ignoring any /// non-ArgDependent DiagnoseIfAttrs. /// /// Argument-dependent diagnose_if attributes should be checked each time a /// function is used as a direct callee of a function call. /// /// Returns true if any errors were emitted. bool diagnoseArgDependentDiagnoseIfAttrs(const FunctionDecl Function, const Expr ThisArg, ArrayRef<const Expr > Args, SourceLocation Loc); /// Emit diagnostics for the diagnose_if attributes on Function, ignoring any /// ArgDependent DiagnoseIfAttrs. /// /// Argument-independent diagnose_if attributes should be checked on every use /// of a function. /// /// Returns true if any errors were emitted. bool diagnoseArgIndependentDiagnoseIfAttrs(const NamedDecl ND, SourceLocation Loc); /// Returns whether the given function's address can be taken or not, /// optionally emitting a diagnostic if the address can't be taken. /// /// Returns false if taking the address of the function is illegal. bool checkAddressOfFunctionIsAvailable(const FunctionDecl Function, bool Complain = false, SourceLocation Loc = SourceLocation()); // [PossiblyAFunctionType] --> [Return] // NonFunctionType --> NonFunctionType // R (A) --> R(A) // R ()(A) --> R (A) // R (&)(A) --> R (A) // R (S::)(A) --> R (A) QualType ExtractUnqualifiedFunctionType(QualType PossiblyAFunctionType); FunctionDecl ResolveAddressOfOverloadedFunction(Expr AddressOfExpr, QualType TargetType, bool Complain, DeclAccessPair &Found, bool pHadMultipleCandidates = nullptr); FunctionDecl * resolveAddressOfSingleOverloadCandidate(Expr E, DeclAccessPair &FoundResult); bool resolveAndFixAddressOfSingleOverloadCandidate( ExprResult &SrcExpr, bool DoFunctionPointerConversion = false); FunctionDecl ResolveSingleFunctionTemplateSpecialization(OverloadExpr ovl, bool Complain = false, DeclAccessPair Found = nullptr); bool ResolveAndFixSingleFunctionTemplateSpecialization( ExprResult &SrcExpr, bool DoFunctionPointerConverion = false, bool Complain = false, SourceRange OpRangeForComplaining = SourceRange(), QualType DestTypeForComplaining = QualType(), unsigned DiagIDForComplaining = 0); Expr FixOverloadedFunctionReference(Expr E, DeclAccessPair FoundDecl, FunctionDecl Fn); ExprResult FixOverloadedFunctionReference(ExprResult, DeclAccessPair FoundDecl, FunctionDecl Fn); void AddOverloadedCallCandidates(UnresolvedLookupExpr ULE, ArrayRef<Expr > Args, OverloadCandidateSet &CandidateSet, bool PartialOverloading = false); void AddOverloadedCallCandidates( LookupResult &R, TemplateArgumentListInfo ExplicitTemplateArgs, ArrayRef<Expr > Args, OverloadCandidateSet &CandidateSet); // An enum used to represent the different possible results of building a // range-based for loop. enum ForRangeStatus { FRS_Success, FRS_NoViableFunction, FRS_DiagnosticIssued }; ForRangeStatus BuildForRangeBeginEndCall(SourceLocation Loc, SourceLocation RangeLoc, const DeclarationNameInfo &NameInfo, LookupResult &MemberLookup, OverloadCandidateSet CandidateSet, Expr Range, ExprResult CallExpr); ExprResult BuildOverloadedCallExpr(Scope S, Expr Fn, UnresolvedLookupExpr ULE, SourceLocation LParenLoc, MultiExprArg Args, SourceLocation RParenLoc, Expr ExecConfig, bool AllowTypoCorrection=true, bool CalleesAddressIsTaken=false); bool buildOverloadedCallSet(Scope S, Expr Fn, UnresolvedLookupExpr ULE, MultiExprArg Args, SourceLocation RParenLoc, OverloadCandidateSet CandidateSet, ExprResult Result); ExprResult CreateUnresolvedLookupExpr(CXXRecordDecl NamingClass, NestedNameSpecifierLoc NNSLoc, DeclarationNameInfo DNI, const UnresolvedSetImpl &Fns, bool PerformADL = true); ExprResult CreateOverloadedUnaryOp(SourceLocation OpLoc, UnaryOperatorKind Opc, const UnresolvedSetImpl &Fns, Expr input, bool RequiresADL = true); void LookupOverloadedBinOp(OverloadCandidateSet &CandidateSet, OverloadedOperatorKind Op, const UnresolvedSetImpl &Fns, ArrayRef<Expr > Args, bool RequiresADL = true); ExprResult CreateOverloadedBinOp(SourceLocation OpLoc, BinaryOperatorKind Opc, const UnresolvedSetImpl &Fns, Expr LHS, Expr RHS, bool RequiresADL = true, bool AllowRewrittenCandidates = true, FunctionDecl DefaultedFn = nullptr); ExprResult BuildSynthesizedThreeWayComparison(SourceLocation OpLoc, const UnresolvedSetImpl &Fns, Expr LHS, Expr RHS, FunctionDecl DefaultedFn); ExprResult CreateOverloadedArraySubscriptExpr(SourceLocation LLoc, SourceLocation RLoc, Expr Base,Expr Idx); ExprResult BuildCallToMemberFunction(Scope S, Expr MemExpr, SourceLocation LParenLoc, MultiExprArg Args, SourceLocation RParenLoc, Expr ExecConfig = nullptr, bool IsExecConfig = false, bool AllowRecovery = false); ExprResult BuildCallToObjectOfClassType(Scope S, Expr Object, SourceLocation LParenLoc, MultiExprArg Args, SourceLocation RParenLoc); ExprResult BuildOverloadedArrowExpr(Scope S, Expr Base, SourceLocation OpLoc, bool NoArrowOperatorFound = nullptr); /// CheckCallReturnType - Checks that a call expression's return type is /// complete. Returns true on failure. The location passed in is the location /// that best represents the call. bool CheckCallReturnType(QualType ReturnType, SourceLocation Loc, CallExpr CE, FunctionDecl FD); /// Helpers for dealing with blocks and functions. bool CheckParmsForFunctionDef(ArrayRef<ParmVarDecl > Parameters, bool CheckParameterNames); void CheckCXXDefaultArguments(FunctionDecl FD); void CheckExtraCXXDefaultArguments(Declarator &D); Scope getNonFieldDeclScope(Scope S); /// \name Name lookup /// /// These routines provide name lookup that is used during semantic /// analysis to resolve the various kinds of names (identifiers, /// overloaded operator names, constructor names, etc.) into zero or /// more declarations within a particular scope. The major entry /// points are LookupName, which performs unqualified name lookup, /// and LookupQualifiedName, which performs qualified name lookup. /// /// All name lookup is performed based on some specific criteria, /// which specify what names will be visible to name lookup and how /// far name lookup should work. These criteria are important both /// for capturing language semantics (certain lookups will ignore /// certain names, for example) and for performance, since name /// lookup is often a bottleneck in the compilation of C++. Name /// lookup criteria is specified via the LookupCriteria enumeration. /// /// The results of name lookup can vary based on the kind of name /// lookup performed, the current language, and the translation /// unit. In C, for example, name lookup will either return nothing /// (no entity found) or a single declaration. In C++, name lookup /// can additionally refer to a set of overloaded functions or /// result in an ambiguity. All of the possible results of name /// lookup are captured by the LookupResult class, which provides /// the ability to distinguish among them. //@{ /// Describes the kind of name lookup to perform. enum LookupNameKind { /// Ordinary name lookup, which finds ordinary names (functions, /// variables, typedefs, etc.) in C and most kinds of names /// (functions, variables, members, types, etc.) in C++. LookupOrdinaryName = 0, /// Tag name lookup, which finds the names of enums, classes, /// structs, and unions. LookupTagName, /// Label name lookup. LookupLabel, /// Member name lookup, which finds the names of /// class/struct/union members. LookupMemberName, /// Look up of an operator name (e.g., operator+) for use with /// operator overloading. This lookup is similar to ordinary name /// lookup, but will ignore any declarations that are class members. LookupOperatorName, /// Look up a name following ~ in a destructor name. This is an ordinary /// lookup, but prefers tags to typedefs. LookupDestructorName, /// Look up of a name that precedes the '::' scope resolution /// operator in C++. This lookup completely ignores operator, object, /// function, and enumerator names (C++ [basic.lookup.qual]p1). LookupNestedNameSpecifierName, /// Look up a namespace name within a C++ using directive or /// namespace alias definition, ignoring non-namespace names (C++ /// [basic.lookup.udir]p1). LookupNamespaceName, /// Look up all declarations in a scope with the given name, /// including resolved using declarations. This is appropriate /// for checking redeclarations for a using declaration. LookupUsingDeclName, /// Look up an ordinary name that is going to be redeclared as a /// name with linkage. This lookup ignores any declarations that /// are outside of the current scope unless they have linkage. See /// C99 6.2.2p4-5 and C++ [basic.link]p6. LookupRedeclarationWithLinkage, /// Look up a friend of a local class. This lookup does not look /// outside the innermost non-class scope. See C++11 [class.friend]p11. LookupLocalFriendName, /// Look up the name of an Objective-C protocol. LookupObjCProtocolName, /// Look up implicit 'self' parameter of an objective-c method. LookupObjCImplicitSelfParam, /// Look up the name of an OpenMP user-defined reduction operation. LookupOMPReductionName, /// Look up the name of an OpenMP user-defined mapper. LookupOMPMapperName, /// Look up any declaration with any name. LookupAnyName }; /// Specifies whether (or how) name lookup is being performed for a /// redeclaration (vs. a reference). enum RedeclarationKind { /// The lookup is a reference to this name that is not for the /// purpose of redeclaring the name. NotForRedeclaration = 0, /// The lookup results will be used for redeclaration of a name, /// if an entity by that name already exists and is visible. ForVisibleRedeclaration, /// The lookup results will be used for redeclaration of a name /// with external linkage; non-visible lookup results with external linkage /// may also be found. ForExternalRedeclaration }; RedeclarationKind forRedeclarationInCurContext() { // A declaration with an owning module for linkage can never link against // anything that is not visible. We don't need to check linkage here; if // the context has internal linkage, redeclaration lookup won't find things // from other TUs, and we can't safely compute linkage yet in general. if (cast<Decl>(CurContext) ->getOwningModuleForLinkage(/IgnoreLinkage/true)) return ForVisibleRedeclaration; return ForExternalRedeclaration; } /// The possible outcomes of name lookup for a literal operator. enum LiteralOperatorLookupResult { /// The lookup resulted in an error. LOLR_Error, /// The lookup found no match but no diagnostic was issued. LOLR_ErrorNoDiagnostic, /// The lookup found a single 'cooked' literal operator, which /// expects a normal literal to be built and passed to it. LOLR_Cooked, /// The lookup found a single 'raw' literal operator, which expects /// a string literal containing the spelling of the literal token. LOLR_Raw, /// The lookup found an overload set of literal operator templates, /// which expect the characters of the spelling of the literal token to be /// passed as a non-type template argument pack. LOLR_Template, /// The lookup found an overload set of literal operator templates, /// which expect the character type and characters of the spelling of the /// string literal token to be passed as template arguments. LOLR_StringTemplatePack, }; SpecialMemberOverloadResult LookupSpecialMember(CXXRecordDecl D, CXXSpecialMember SM, bool ConstArg, bool VolatileArg, bool RValueThis, bool ConstThis, bool VolatileThis); typedef std::function<void(const TypoCorrection &)> TypoDiagnosticGenerator; typedef std::function<ExprResult(Sema &, TypoExpr , TypoCorrection)> TypoRecoveryCallback; private: bool CppLookupName(LookupResult &R, Scope S); struct TypoExprState { std::unique_ptr<TypoCorrectionConsumer> Consumer; TypoDiagnosticGenerator DiagHandler; TypoRecoveryCallback RecoveryHandler; TypoExprState(); TypoExprState(TypoExprState &&other) noexcept; TypoExprState &operator=(TypoExprState &&other) noexcept; }; /// The set of unhandled TypoExprs and their associated state. llvm::MapVector<TypoExpr , TypoExprState> DelayedTypos; /// Creates a new TypoExpr AST node. TypoExpr createDelayedTypo(std::unique_ptr<TypoCorrectionConsumer> TCC, TypoDiagnosticGenerator TDG, TypoRecoveryCallback TRC, SourceLocation TypoLoc); // The set of known/encountered (unique, canonicalized) NamespaceDecls. // // The boolean value will be true to indicate that the namespace was loaded // from an AST/PCH file, or false otherwise. llvm::MapVector<NamespaceDecl, bool> KnownNamespaces; /// Whether we have already loaded known namespaces from an extenal /// source. bool LoadedExternalKnownNamespaces; /// Helper for CorrectTypo and CorrectTypoDelayed used to create and /// populate a new TypoCorrectionConsumer. Returns nullptr if typo correction /// should be skipped entirely. std::unique_ptr<TypoCorrectionConsumer> makeTypoCorrectionConsumer(const DeclarationNameInfo &Typo, Sema::LookupNameKind LookupKind, Scope S, CXXScopeSpec SS, CorrectionCandidateCallback &CCC, DeclContext MemberContext, bool EnteringContext, const ObjCObjectPointerType OPT, bool ErrorRecovery); public: const TypoExprState &getTypoExprState(TypoExpr TE) const; /// Clears the state of the given TypoExpr. void clearDelayedTypo(TypoExpr TE); /// Look up a name, looking for a single declaration. Return /// null if the results were absent, ambiguous, or overloaded. /// /// It is preferable to use the elaborated form and explicitly handle /// ambiguity and overloaded. NamedDecl LookupSingleName(Scope S, DeclarationName Name, SourceLocation Loc, LookupNameKind NameKind, RedeclarationKind Redecl = NotForRedeclaration); bool LookupBuiltin(LookupResult &R); void LookupNecessaryTypesForBuiltin(Scope S, unsigned ID); bool LookupName(LookupResult &R, Scope S, bool AllowBuiltinCreation = false); bool LookupQualifiedName(LookupResult &R, DeclContext LookupCtx, bool InUnqualifiedLookup = false); bool LookupQualifiedName(LookupResult &R, DeclContext LookupCtx, CXXScopeSpec &SS); bool LookupParsedName(LookupResult &R, Scope S, CXXScopeSpec SS, bool AllowBuiltinCreation = false, bool EnteringContext = false); ObjCProtocolDecl LookupProtocol(IdentifierInfo II, SourceLocation IdLoc, RedeclarationKind Redecl = NotForRedeclaration); bool LookupInSuper(LookupResult &R, CXXRecordDecl Class); void LookupOverloadedOperatorName(OverloadedOperatorKind Op, Scope S, UnresolvedSetImpl &Functions); LabelDecl LookupOrCreateLabel(IdentifierInfo II, SourceLocation IdentLoc, SourceLocation GnuLabelLoc = SourceLocation()); DeclContextLookupResult LookupConstructors(CXXRecordDecl Class); CXXConstructorDecl LookupDefaultConstructor(CXXRecordDecl Class); CXXConstructorDecl LookupCopyingConstructor(CXXRecordDecl Class, unsigned Quals); CXXMethodDecl LookupCopyingAssignment(CXXRecordDecl Class, unsigned Quals, bool RValueThis, unsigned ThisQuals); CXXConstructorDecl LookupMovingConstructor(CXXRecordDecl Class, unsigned Quals); CXXMethodDecl LookupMovingAssignment(CXXRecordDecl Class, unsigned Quals, bool RValueThis, unsigned ThisQuals); CXXDestructorDecl LookupDestructor(CXXRecordDecl Class); bool checkLiteralOperatorId(const CXXScopeSpec &SS, const UnqualifiedId &Id, bool IsUDSuffix); LiteralOperatorLookupResult LookupLiteralOperator(Scope S, LookupResult &R, ArrayRef<QualType> ArgTys, bool AllowRaw, bool AllowTemplate, bool AllowStringTemplate, bool DiagnoseMissing, StringLiteral StringLit = nullptr); bool isKnownName(StringRef name); /// Status of the function emission on the CUDA/HIP/OpenMP host/device attrs. enum class FunctionEmissionStatus { Emitted, CUDADiscarded, // Discarded due to CUDA/HIP hostness OMPDiscarded, // Discarded due to OpenMP hostness TemplateDiscarded, // Discarded due to uninstantiated templates Unknown, }; FunctionEmissionStatus getEmissionStatus(FunctionDecl Decl, bool Final = false); DeviceDiagnosticReason getEmissionReason(const FunctionDecl Decl); // Whether the callee should be ignored in CUDA/HIP/OpenMP host/device check. bool shouldIgnoreInHostDeviceCheck(FunctionDecl Callee); void ArgumentDependentLookup(DeclarationName Name, SourceLocation Loc, ArrayRef<Expr > Args, ADLResult &Functions); void LookupVisibleDecls(Scope S, LookupNameKind Kind, VisibleDeclConsumer &Consumer, bool IncludeGlobalScope = true, bool LoadExternal = true); void LookupVisibleDecls(DeclContext Ctx, LookupNameKind Kind, VisibleDeclConsumer &Consumer, bool IncludeGlobalScope = true, bool IncludeDependentBases = false, bool LoadExternal = true); enum CorrectTypoKind { CTK_NonError, // CorrectTypo used in a non error recovery situation. CTK_ErrorRecovery // CorrectTypo used in normal error recovery. }; TypoCorrection CorrectTypo(const DeclarationNameInfo &Typo, Sema::LookupNameKind LookupKind, Scope S, CXXScopeSpec SS, CorrectionCandidateCallback &CCC, CorrectTypoKind Mode, DeclContext MemberContext = nullptr, bool EnteringContext = false, const ObjCObjectPointerType OPT = nullptr, bool RecordFailure = true); TypoExpr CorrectTypoDelayed(const DeclarationNameInfo &Typo, Sema::LookupNameKind LookupKind, Scope S, CXXScopeSpec SS, CorrectionCandidateCallback &CCC, TypoDiagnosticGenerator TDG, TypoRecoveryCallback TRC, CorrectTypoKind Mode, DeclContext MemberContext = nullptr, bool EnteringContext = false, const ObjCObjectPointerType OPT = nullptr); /// Process any TypoExprs in the given Expr and its children, /// generating diagnostics as appropriate and returning a new Expr if there /// were typos that were all successfully corrected and ExprError if one or /// more typos could not be corrected. /// /// \param E The Expr to check for TypoExprs. /// /// \param InitDecl A VarDecl to avoid because the Expr being corrected is its /// initializer. /// /// \param RecoverUncorrectedTypos If true, when typo correction fails, it /// will rebuild the given Expr with all TypoExprs degraded to RecoveryExprs. /// /// \param Filter A function applied to a newly rebuilt Expr to determine if /// it is an acceptable/usable result from a single combination of typo /// corrections. As long as the filter returns ExprError, different /// combinations of corrections will be tried until all are exhausted. ExprResult CorrectDelayedTyposInExpr( Expr E, VarDecl InitDecl = nullptr, bool RecoverUncorrectedTypos = false, llvm::function_ref<ExprResult(Expr )> Filter = [](Expr E) -> ExprResult { return E; }); ExprResult CorrectDelayedTyposInExpr( ExprResult ER, VarDecl InitDecl = nullptr, bool RecoverUncorrectedTypos = false, llvm::function_ref<ExprResult(Expr )> Filter = [](Expr E) -> ExprResult { return E; }) { return ER.isInvalid() ? ER : CorrectDelayedTyposInExpr(ER.get(), InitDecl, RecoverUncorrectedTypos, Filter); } void diagnoseTypo(const TypoCorrection &Correction, const PartialDiagnostic &TypoDiag, bool ErrorRecovery = true); void diagnoseTypo(const TypoCorrection &Correction, const PartialDiagnostic &TypoDiag, const PartialDiagnostic &PrevNote, bool ErrorRecovery = true); void MarkTypoCorrectedFunctionDefinition(const NamedDecl F); void FindAssociatedClassesAndNamespaces(SourceLocation InstantiationLoc, ArrayRef<Expr > Args, AssociatedNamespaceSet &AssociatedNamespaces, AssociatedClassSet &AssociatedClasses); void FilterLookupForScope(LookupResult &R, DeclContext Ctx, Scope S, bool ConsiderLinkage, bool AllowInlineNamespace); bool CheckRedeclarationModuleOwnership(NamedDecl New, NamedDecl Old); void DiagnoseAmbiguousLookup(LookupResult &Result); //@} /// Attempts to produce a RecoveryExpr after some AST node cannot be created. ExprResult CreateRecoveryExpr(SourceLocation Begin, SourceLocation End, ArrayRef<Expr > SubExprs, QualType T = QualType()); ObjCInterfaceDecl getObjCInterfaceDecl(IdentifierInfo &Id, SourceLocation IdLoc, bool TypoCorrection = false); FunctionDecl CreateBuiltin(IdentifierInfo II, QualType Type, unsigned ID, SourceLocation Loc); NamedDecl LazilyCreateBuiltin(IdentifierInfo II, unsigned ID, Scope S, bool ForRedeclaration, SourceLocation Loc); NamedDecl ImplicitlyDefineFunction(SourceLocation Loc, IdentifierInfo &II, Scope S); void AddKnownFunctionAttributesForReplaceableGlobalAllocationFunction( FunctionDecl FD); void AddKnownFunctionAttributes(FunctionDecl FD); // More parsing and symbol table subroutines. void ProcessPragmaWeak(Scope S, Decl D); // Decl attributes - this routine is the top level dispatcher. void ProcessDeclAttributes(Scope S, Decl D, const Declarator &PD); // Helper for delayed processing of attributes. void ProcessDeclAttributeDelayed(Decl D, const ParsedAttributesView &AttrList); void ProcessDeclAttributeList(Scope S, Decl D, const ParsedAttributesView &AL, bool IncludeCXX11Attributes = true); bool ProcessAccessDeclAttributeList(AccessSpecDecl ASDecl, const ParsedAttributesView &AttrList); void checkUnusedDeclAttributes(Declarator &D); /// Handles semantic checking for features that are common to all attributes, /// such as checking whether a parameter was properly specified, or the /// correct number of arguments were passed, etc. Returns true if the /// attribute has been diagnosed. bool checkCommonAttributeFeatures(const Decl D, const ParsedAttr &A); bool checkCommonAttributeFeatures(const Stmt S, const ParsedAttr &A); /// Determine if type T is a valid subject for a nonnull and similar /// attributes. By default, we look through references (the behavior used by /// nonnull), but if the second parameter is true, then we treat a reference /// type as valid. bool isValidPointerAttrType(QualType T, bool RefOkay = false); bool CheckRegparmAttr(const ParsedAttr &attr, unsigned &value); bool CheckCallingConvAttr(const ParsedAttr &attr, CallingConv &CC, const FunctionDecl FD = nullptr); bool CheckAttrTarget(const ParsedAttr &CurrAttr); bool CheckAttrNoArgs(const ParsedAttr &CurrAttr); bool checkStringLiteralArgumentAttr(const ParsedAttr &Attr, unsigned ArgNum, StringRef &Str, SourceLocation ArgLocation = nullptr); llvm::Error isValidSectionSpecifier(StringRef Str); bool checkSectionName(SourceLocation LiteralLoc, StringRef Str); bool checkTargetAttr(SourceLocation LiteralLoc, StringRef Str); bool checkMSInheritanceAttrOnDefinition( CXXRecordDecl RD, SourceRange Range, bool BestCase, MSInheritanceModel SemanticSpelling); void CheckAlignasUnderalignment(Decl D); /// Adjust the calling convention of a method to be the ABI default if it /// wasn't specified explicitly. This handles method types formed from /// function type typedefs and typename template arguments. void adjustMemberFunctionCC(QualType &T, bool IsStatic, bool IsCtorOrDtor, SourceLocation Loc); // Check if there is an explicit attribute, but only look through parens. // The intent is to look for an attribute on the current declarator, but not // one that came from a typedef. bool hasExplicitCallingConv(QualType T); /// Get the outermost AttributedType node that sets a calling convention. /// Valid types should not have multiple attributes with different CCs. const AttributedType getCallingConvAttributedType(QualType T) const; /// Process the attributes before creating an attributed statement. Returns /// the semantic attributes that have been processed. void ProcessStmtAttributes(Stmt Stmt, const ParsedAttributesWithRange &InAttrs, SmallVectorImpl<const Attr > &OutAttrs); void WarnConflictingTypedMethods(ObjCMethodDecl Method, ObjCMethodDecl MethodDecl, bool IsProtocolMethodDecl); void CheckConflictingOverridingMethod(ObjCMethodDecl Method, ObjCMethodDecl Overridden, bool IsProtocolMethodDecl); /// WarnExactTypedMethods - This routine issues a warning if method /// implementation declaration matches exactly that of its declaration. void WarnExactTypedMethods(ObjCMethodDecl Method, ObjCMethodDecl MethodDecl, bool IsProtocolMethodDecl); typedef llvm::SmallPtrSet<Selector, 8> SelectorSet; /// CheckImplementationIvars - This routine checks if the instance variables /// listed in the implelementation match those listed in the interface. void CheckImplementationIvars(ObjCImplementationDecl ImpDecl, ObjCIvarDecl *Fields, unsigned nIvars, SourceLocation Loc); /// ImplMethodsVsClassMethods - This is main routine to warn if any method /// remains unimplemented in the class or category \@implementation. void ImplMethodsVsClassMethods(Scope S, ObjCImplDecl* IMPDecl, ObjCContainerDecl* IDecl, bool IncompleteImpl = false); /// DiagnoseUnimplementedProperties - This routine warns on those properties /// which must be implemented by this implementation. void DiagnoseUnimplementedProperties(Scope S, ObjCImplDecl IMPDecl, ObjCContainerDecl CDecl, bool SynthesizeProperties); /// Diagnose any null-resettable synthesized setters. void diagnoseNullResettableSynthesizedSetters(const ObjCImplDecl impDecl); /// DefaultSynthesizeProperties - This routine default synthesizes all /// properties which must be synthesized in the class's \@implementation. void DefaultSynthesizeProperties(Scope S, ObjCImplDecl IMPDecl, ObjCInterfaceDecl IDecl, SourceLocation AtEnd); void DefaultSynthesizeProperties(Scope S, Decl D, SourceLocation AtEnd); /// IvarBacksCurrentMethodAccessor - This routine returns 'true' if 'IV' is /// an ivar synthesized for 'Method' and 'Method' is a property accessor /// declared in class 'IFace'. bool IvarBacksCurrentMethodAccessor(ObjCInterfaceDecl IFace, ObjCMethodDecl Method, ObjCIvarDecl IV); /// DiagnoseUnusedBackingIvarInAccessor - Issue an 'unused' warning if ivar which /// backs the property is not used in the property's accessor. void DiagnoseUnusedBackingIvarInAccessor(Scope S, const ObjCImplementationDecl ImplD); /// GetIvarBackingPropertyAccessor - If method is a property setter/getter and /// it property has a backing ivar, returns this ivar; otherwise, returns NULL. /// It also returns ivar's property on success. ObjCIvarDecl GetIvarBackingPropertyAccessor(const ObjCMethodDecl Method, const ObjCPropertyDecl &PDecl) const; /// Called by ActOnProperty to handle \@property declarations in /// class extensions. ObjCPropertyDecl HandlePropertyInClassExtension(Scope S, SourceLocation AtLoc, SourceLocation LParenLoc, FieldDeclarator &FD, Selector GetterSel, SourceLocation GetterNameLoc, Selector SetterSel, SourceLocation SetterNameLoc, const bool isReadWrite, unsigned &Attributes, const unsigned AttributesAsWritten, QualType T, TypeSourceInfo TSI, tok::ObjCKeywordKind MethodImplKind); /// Called by ActOnProperty and HandlePropertyInClassExtension to /// handle creating the ObjcPropertyDecl for a category or \@interface. ObjCPropertyDecl CreatePropertyDecl(Scope S, ObjCContainerDecl CDecl, SourceLocation AtLoc, SourceLocation LParenLoc, FieldDeclarator &FD, Selector GetterSel, SourceLocation GetterNameLoc, Selector SetterSel, SourceLocation SetterNameLoc, const bool isReadWrite, const unsigned Attributes, const unsigned AttributesAsWritten, QualType T, TypeSourceInfo TSI, tok::ObjCKeywordKind MethodImplKind, DeclContext lexicalDC = nullptr); /// AtomicPropertySetterGetterRules - This routine enforces the rule (via /// warning) when atomic property has one but not the other user-declared /// setter or getter. void AtomicPropertySetterGetterRules(ObjCImplDecl IMPDecl, ObjCInterfaceDecl* IDecl); void DiagnoseOwningPropertyGetterSynthesis(const ObjCImplementationDecl D); void DiagnoseMissingDesignatedInitOverrides( const ObjCImplementationDecl ImplD, const ObjCInterfaceDecl IFD); void DiagnoseDuplicateIvars(ObjCInterfaceDecl ID, ObjCInterfaceDecl SID); enum MethodMatchStrategy { MMS_loose, MMS_strict }; /// MatchTwoMethodDeclarations - Checks if two methods' type match and returns /// true, or false, accordingly. bool MatchTwoMethodDeclarations(const ObjCMethodDecl Method, const ObjCMethodDecl PrevMethod, MethodMatchStrategy strategy = MMS_strict); /// MatchAllMethodDeclarations - Check methods declaraed in interface or /// or protocol against those declared in their implementations. void MatchAllMethodDeclarations(const SelectorSet &InsMap, const SelectorSet &ClsMap, SelectorSet &InsMapSeen, SelectorSet &ClsMapSeen, ObjCImplDecl IMPDecl, ObjCContainerDecl* IDecl, bool &IncompleteImpl, bool ImmediateClass, bool WarnCategoryMethodImpl=false); /// CheckCategoryVsClassMethodMatches - Checks that methods implemented in /// category matches with those implemented in its primary class and /// warns each time an exact match is found. void CheckCategoryVsClassMethodMatches(ObjCCategoryImplDecl CatIMP); /// Add the given method to the list of globally-known methods. void addMethodToGlobalList(ObjCMethodList List, ObjCMethodDecl Method); /// Returns default addr space for method qualifiers. LangAS getDefaultCXXMethodAddrSpace() const; private: /// AddMethodToGlobalPool - Add an instance or factory method to the global /// pool. See descriptoin of AddInstanceMethodToGlobalPool. void AddMethodToGlobalPool(ObjCMethodDecl Method, bool impl, bool instance); /// LookupMethodInGlobalPool - Returns the instance or factory method and /// optionally warns if there are multiple signatures. ObjCMethodDecl LookupMethodInGlobalPool(Selector Sel, SourceRange R, bool receiverIdOrClass, bool instance); public: /// - Returns instance or factory methods in global method pool for /// given selector. It checks the desired kind first, if none is found, and /// parameter checkTheOther is set, it then checks the other kind. If no such /// method or only one method is found, function returns false; otherwise, it /// returns true. bool CollectMultipleMethodsInGlobalPool(Selector Sel, SmallVectorImpl<ObjCMethodDecl>& Methods, bool InstanceFirst, bool CheckTheOther, const ObjCObjectType TypeBound = nullptr); bool AreMultipleMethodsInGlobalPool(Selector Sel, ObjCMethodDecl BestMethod, SourceRange R, bool receiverIdOrClass, SmallVectorImpl<ObjCMethodDecl>& Methods); void DiagnoseMultipleMethodInGlobalPool(SmallVectorImpl<ObjCMethodDecl> &Methods, Selector Sel, SourceRange R, bool receiverIdOrClass); private: /// - Returns a selector which best matches given argument list or /// nullptr if none could be found ObjCMethodDecl SelectBestMethod(Selector Sel, MultiExprArg Args, bool IsInstance, SmallVectorImpl<ObjCMethodDecl>& Methods); /// Record the typo correction failure and return an empty correction. TypoCorrection FailedCorrection(IdentifierInfo Typo, SourceLocation TypoLoc, bool RecordFailure = true) { if (RecordFailure) TypoCorrectionFailures[Typo].insert(TypoLoc); return TypoCorrection(); } public: /// AddInstanceMethodToGlobalPool - All instance methods in a translation /// unit are added to a global pool. This allows us to efficiently associate /// a selector with a method declaraation for purposes of typechecking /// messages sent to "id" (where the class of the object is unknown). void AddInstanceMethodToGlobalPool(ObjCMethodDecl Method, bool impl=false) { AddMethodToGlobalPool(Method, impl, /instance/true); } /// AddFactoryMethodToGlobalPool - Same as above, but for factory methods. void AddFactoryMethodToGlobalPool(ObjCMethodDecl Method, bool impl=false) { AddMethodToGlobalPool(Method, impl, /instance/false); } /// AddAnyMethodToGlobalPool - Add any method, instance or factory to global /// pool. void AddAnyMethodToGlobalPool(Decl D); /// LookupInstanceMethodInGlobalPool - Returns the method and warns if /// there are multiple signatures. ObjCMethodDecl LookupInstanceMethodInGlobalPool(Selector Sel, SourceRange R, bool receiverIdOrClass=false) { return LookupMethodInGlobalPool(Sel, R, receiverIdOrClass, /instance/true); } /// LookupFactoryMethodInGlobalPool - Returns the method and warns if /// there are multiple signatures. ObjCMethodDecl LookupFactoryMethodInGlobalPool(Selector Sel, SourceRange R, bool receiverIdOrClass=false) { return LookupMethodInGlobalPool(Sel, R, receiverIdOrClass, /instance/false); } const ObjCMethodDecl SelectorsForTypoCorrection(Selector Sel, QualType ObjectType=QualType()); /// LookupImplementedMethodInGlobalPool - Returns the method which has an /// implementation. ObjCMethodDecl LookupImplementedMethodInGlobalPool(Selector Sel); /// CollectIvarsToConstructOrDestruct - Collect those ivars which require /// initialization. void CollectIvarsToConstructOrDestruct(ObjCInterfaceDecl OI, SmallVectorImpl<ObjCIvarDecl> &Ivars); //===--------------------------------------------------------------------===// // Statement Parsing Callbacks: SemaStmt.cpp. public: class FullExprArg { public: FullExprArg() : E(nullptr) { } FullExprArg(Sema &actions) : E(nullptr) { } ExprResult release() { return E; } Expr get() const { return E; } Expr operator->() { return E; } private: // FIXME: No need to make the entire Sema class a friend when it's just // Sema::MakeFullExpr that needs access to the constructor below. friend class Sema; explicit FullExprArg(Expr expr) : E(expr) {} Expr E; }; FullExprArg MakeFullExpr(Expr Arg) { return MakeFullExpr(Arg, Arg ? Arg->getExprLoc() : SourceLocation()); } FullExprArg MakeFullExpr(Expr Arg, SourceLocation CC) { return FullExprArg( ActOnFinishFullExpr(Arg, CC, /DiscardedValue/ false).get()); } FullExprArg MakeFullDiscardedValueExpr(Expr Arg) { ExprResult FE = ActOnFinishFullExpr(Arg, Arg ? Arg->getExprLoc() : SourceLocation(), /DiscardedValue/ true); return FullExprArg(FE.get()); } StmtResult ActOnExprStmt(ExprResult Arg, bool DiscardedValue = true); StmtResult ActOnExprStmtError(); StmtResult ActOnNullStmt(SourceLocation SemiLoc, bool HasLeadingEmptyMacro = false); void ActOnStartOfCompoundStmt(bool IsStmtExpr); void ActOnAfterCompoundStatementLeadingPragmas(); void ActOnFinishOfCompoundStmt(); StmtResult ActOnCompoundStmt(SourceLocation L, SourceLocation R, ArrayRef<Stmt > Elts, bool isStmtExpr); /// A RAII object to enter scope of a compound statement. class CompoundScopeRAII { public: CompoundScopeRAII(Sema &S, bool IsStmtExpr = false) : S(S) { S.ActOnStartOfCompoundStmt(IsStmtExpr); } ~CompoundScopeRAII() { S.ActOnFinishOfCompoundStmt(); } private: Sema &S; }; /// An RAII helper that pops function a function scope on exit. struct FunctionScopeRAII { Sema &S; bool Active; FunctionScopeRAII(Sema &S) : S(S), Active(true) {} ~FunctionScopeRAII() { if (Active) S.PopFunctionScopeInfo(); } void disable() { Active = false; } }; StmtResult ActOnDeclStmt(DeclGroupPtrTy Decl, SourceLocation StartLoc, SourceLocation EndLoc); void ActOnForEachDeclStmt(DeclGroupPtrTy Decl); StmtResult ActOnForEachLValueExpr(Expr E); ExprResult ActOnCaseExpr(SourceLocation CaseLoc, ExprResult Val); StmtResult ActOnCaseStmt(SourceLocation CaseLoc, ExprResult LHS, SourceLocation DotDotDotLoc, ExprResult RHS, SourceLocation ColonLoc); void ActOnCaseStmtBody(Stmt CaseStmt, Stmt SubStmt); StmtResult ActOnDefaultStmt(SourceLocation DefaultLoc, SourceLocation ColonLoc, Stmt SubStmt, Scope CurScope); StmtResult ActOnLabelStmt(SourceLocation IdentLoc, LabelDecl TheDecl, SourceLocation ColonLoc, Stmt SubStmt); StmtResult BuildAttributedStmt(SourceLocation AttrsLoc, ArrayRef<const Attr > Attrs, Stmt SubStmt); StmtResult ActOnAttributedStmt(const ParsedAttributesWithRange &AttrList, Stmt SubStmt); bool CheckRebuiltAttributedStmtAttributes(ArrayRef<const Attr > Attrs); class ConditionResult; StmtResult ActOnIfStmt(SourceLocation IfLoc, IfStatementKind StatementKind, SourceLocation LParenLoc, Stmt InitStmt, ConditionResult Cond, SourceLocation RParenLoc, Stmt ThenVal, SourceLocation ElseLoc, Stmt ElseVal); StmtResult BuildIfStmt(SourceLocation IfLoc, IfStatementKind StatementKind, SourceLocation LParenLoc, Stmt InitStmt, ConditionResult Cond, SourceLocation RParenLoc, Stmt ThenVal, SourceLocation ElseLoc, Stmt ElseVal); StmtResult ActOnStartOfSwitchStmt(SourceLocation SwitchLoc, SourceLocation LParenLoc, Stmt InitStmt, ConditionResult Cond, SourceLocation RParenLoc); StmtResult ActOnFinishSwitchStmt(SourceLocation SwitchLoc, Stmt Switch, Stmt Body); StmtResult ActOnWhileStmt(SourceLocation WhileLoc, SourceLocation LParenLoc, ConditionResult Cond, SourceLocation RParenLoc, Stmt Body); StmtResult ActOnDoStmt(SourceLocation DoLoc, Stmt Body, SourceLocation WhileLoc, SourceLocation CondLParen, Expr Cond, SourceLocation CondRParen); StmtResult ActOnForStmt(SourceLocation ForLoc, SourceLocation LParenLoc, Stmt First, ConditionResult Second, FullExprArg Third, SourceLocation RParenLoc, Stmt Body); ExprResult CheckObjCForCollectionOperand(SourceLocation forLoc, Expr collection); StmtResult ActOnObjCForCollectionStmt(SourceLocation ForColLoc, Stmt First, Expr collection, SourceLocation RParenLoc); StmtResult FinishObjCForCollectionStmt(Stmt ForCollection, Stmt Body); enum BuildForRangeKind { /// Initial building of a for-range statement. BFRK_Build, /// Instantiation or recovery rebuild of a for-range statement. Don't /// attempt any typo-correction. BFRK_Rebuild, /// Determining whether a for-range statement could be built. Avoid any /// unnecessary or irreversible actions. BFRK_Check }; StmtResult ActOnCXXForRangeStmt(Scope S, SourceLocation ForLoc, SourceLocation CoawaitLoc, Stmt InitStmt, Stmt LoopVar, SourceLocation ColonLoc, Expr Collection, SourceLocation RParenLoc, BuildForRangeKind Kind); StmtResult BuildCXXForRangeStmt(SourceLocation ForLoc, SourceLocation CoawaitLoc, Stmt InitStmt, SourceLocation ColonLoc, Stmt RangeDecl, Stmt Begin, Stmt End, Expr Cond, Expr Inc, Stmt LoopVarDecl, SourceLocation RParenLoc, BuildForRangeKind Kind); StmtResult FinishCXXForRangeStmt(Stmt ForRange, Stmt Body); StmtResult ActOnGotoStmt(SourceLocation GotoLoc, SourceLocation LabelLoc, LabelDecl TheDecl); StmtResult ActOnIndirectGotoStmt(SourceLocation GotoLoc, SourceLocation StarLoc, Expr DestExp); StmtResult ActOnContinueStmt(SourceLocation ContinueLoc, Scope CurScope); StmtResult ActOnBreakStmt(SourceLocation BreakLoc, Scope CurScope); void ActOnCapturedRegionStart(SourceLocation Loc, Scope CurScope, CapturedRegionKind Kind, unsigned NumParams); typedef std::pair<StringRef, QualType> CapturedParamNameType; void ActOnCapturedRegionStart(SourceLocation Loc, Scope CurScope, CapturedRegionKind Kind, ArrayRef<CapturedParamNameType> Params, unsigned OpenMPCaptureLevel = 0); StmtResult ActOnCapturedRegionEnd(Stmt S); void ActOnCapturedRegionError(); RecordDecl CreateCapturedStmtRecordDecl(CapturedDecl &CD, SourceLocation Loc, unsigned NumParams); struct NamedReturnInfo { const VarDecl Candidate; enum Status : uint8_t { None, MoveEligible, MoveEligibleAndCopyElidable }; Status S; bool isMoveEligible() const { return S != None; }; bool isCopyElidable() const { return S == MoveEligibleAndCopyElidable; } }; enum class SimplerImplicitMoveMode { ForceOff, Normal, ForceOn }; NamedReturnInfo getNamedReturnInfo( Expr &E, SimplerImplicitMoveMode Mode = SimplerImplicitMoveMode::Normal); NamedReturnInfo getNamedReturnInfo(const VarDecl VD); const VarDecl getCopyElisionCandidate(NamedReturnInfo &Info, QualType ReturnType); ExprResult PerformMoveOrCopyInitialization(const InitializedEntity &Entity, const NamedReturnInfo &NRInfo, Expr Value, bool SupressSimplerImplicitMoves = false); StmtResult ActOnReturnStmt(SourceLocation ReturnLoc, Expr RetValExp, Scope CurScope); StmtResult BuildReturnStmt(SourceLocation ReturnLoc, Expr RetValExp); StmtResult ActOnCapScopeReturnStmt(SourceLocation ReturnLoc, Expr RetValExp, NamedReturnInfo &NRInfo, bool SupressSimplerImplicitMoves); StmtResult ActOnGCCAsmStmt(SourceLocation AsmLoc, bool IsSimple, bool IsVolatile, unsigned NumOutputs, unsigned NumInputs, IdentifierInfo Names, MultiExprArg Constraints, MultiExprArg Exprs, Expr AsmString, MultiExprArg Clobbers, unsigned NumLabels, SourceLocation RParenLoc); void FillInlineAsmIdentifierInfo(Expr Res, llvm::InlineAsmIdentifierInfo &Info); ExprResult LookupInlineAsmIdentifier(CXXScopeSpec &SS, SourceLocation TemplateKWLoc, UnqualifiedId &Id, bool IsUnevaluatedContext); bool LookupInlineAsmField(StringRef Base, StringRef Member, unsigned &Offset, SourceLocation AsmLoc); ExprResult LookupInlineAsmVarDeclField(Expr RefExpr, StringRef Member, SourceLocation AsmLoc); StmtResult ActOnMSAsmStmt(SourceLocation AsmLoc, SourceLocation LBraceLoc, ArrayRef<Token> AsmToks, StringRef AsmString, unsigned NumOutputs, unsigned NumInputs, ArrayRef<StringRef> Constraints, ArrayRef<StringRef> Clobbers, ArrayRef<Expr> Exprs, SourceLocation EndLoc); LabelDecl GetOrCreateMSAsmLabel(StringRef ExternalLabelName, SourceLocation Location, bool AlwaysCreate); VarDecl BuildObjCExceptionDecl(TypeSourceInfo TInfo, QualType ExceptionType, SourceLocation StartLoc, SourceLocation IdLoc, IdentifierInfo Id, bool Invalid = false); Decl ActOnObjCExceptionDecl(Scope S, Declarator &D); StmtResult ActOnObjCAtCatchStmt(SourceLocation AtLoc, SourceLocation RParen, Decl Parm, Stmt Body); StmtResult ActOnObjCAtFinallyStmt(SourceLocation AtLoc, Stmt Body); StmtResult ActOnObjCAtTryStmt(SourceLocation AtLoc, Stmt Try, MultiStmtArg Catch, Stmt Finally); StmtResult BuildObjCAtThrowStmt(SourceLocation AtLoc, Expr Throw); StmtResult ActOnObjCAtThrowStmt(SourceLocation AtLoc, Expr Throw, Scope CurScope); ExprResult ActOnObjCAtSynchronizedOperand(SourceLocation atLoc, Expr operand); StmtResult ActOnObjCAtSynchronizedStmt(SourceLocation AtLoc, Expr SynchExpr, Stmt SynchBody); StmtResult ActOnObjCAutoreleasePoolStmt(SourceLocation AtLoc, Stmt Body); VarDecl BuildExceptionDeclaration(Scope S, TypeSourceInfo TInfo, SourceLocation StartLoc, SourceLocation IdLoc, IdentifierInfo Id); Decl ActOnExceptionDeclarator(Scope S, Declarator &D); StmtResult ActOnCXXCatchBlock(SourceLocation CatchLoc, Decl ExDecl, Stmt HandlerBlock); StmtResult ActOnCXXTryBlock(SourceLocation TryLoc, Stmt TryBlock, ArrayRef<Stmt > Handlers); StmtResult ActOnSEHTryBlock(bool IsCXXTry, // try (true) or __try (false) ? SourceLocation TryLoc, Stmt TryBlock, Stmt Handler); StmtResult ActOnSEHExceptBlock(SourceLocation Loc, Expr FilterExpr, Stmt Block); void ActOnStartSEHFinallyBlock(); void ActOnAbortSEHFinallyBlock(); StmtResult ActOnFinishSEHFinallyBlock(SourceLocation Loc, Stmt Block); StmtResult ActOnSEHLeaveStmt(SourceLocation Loc, Scope CurScope); void DiagnoseReturnInConstructorExceptionHandler(CXXTryStmt TryBlock); bool ShouldWarnIfUnusedFileScopedDecl(const DeclaratorDecl D) const; /// If it's a file scoped decl that must warn if not used, keep track /// of it. void MarkUnusedFileScopedDecl(const DeclaratorDecl D); /// DiagnoseUnusedExprResult - If the statement passed in is an expression /// whose result is unused, warn. void DiagnoseUnusedExprResult(const Stmt S, unsigned DiagID); void DiagnoseUnusedNestedTypedefs(const RecordDecl D); void DiagnoseUnusedDecl(const NamedDecl ND); /// If VD is set but not otherwise used, diagnose, for a parameter or a /// variable. void DiagnoseUnusedButSetDecl(const VarDecl VD); /// Emit \p DiagID if statement located on \p StmtLoc has a suspicious null /// statement as a \p Body, and it is located on the same line. /// /// This helps prevent bugs due to typos, such as: /// if (condition); /// do_stuff(); void DiagnoseEmptyStmtBody(SourceLocation StmtLoc, const Stmt Body, unsigned DiagID); /// Warn if a for/while loop statement \p S, which is followed by /// \p PossibleBody, has a suspicious null statement as a body. void DiagnoseEmptyLoopBody(const Stmt S, const Stmt PossibleBody); /// Warn if a value is moved to itself. void DiagnoseSelfMove(const Expr LHSExpr, const Expr RHSExpr, SourceLocation OpLoc); /// Warn if we're implicitly casting from a _Nullable pointer type to a /// _Nonnull one. void diagnoseNullableToNonnullConversion(QualType DstType, QualType SrcType, SourceLocation Loc); /// Warn when implicitly casting 0 to nullptr. void diagnoseZeroToNullptrConversion(CastKind Kind, const Expr E); ParsingDeclState PushParsingDeclaration(sema::DelayedDiagnosticPool &pool) { return DelayedDiagnostics.push(pool); } void PopParsingDeclaration(ParsingDeclState state, Decl decl); typedef ProcessingContextState ParsingClassState; ParsingClassState PushParsingClass() { ParsingClassDepth++; return DelayedDiagnostics.pushUndelayed(); } void PopParsingClass(ParsingClassState state) { ParsingClassDepth--; DelayedDiagnostics.popUndelayed(state); } void redelayDiagnostics(sema::DelayedDiagnosticPool &pool); void DiagnoseAvailabilityOfDecl(NamedDecl D, ArrayRef<SourceLocation> Locs, const ObjCInterfaceDecl UnknownObjCClass, bool ObjCPropertyAccess, bool AvoidPartialAvailabilityChecks = false, ObjCInterfaceDecl ClassReceiver = nullptr); bool makeUnavailableInSystemHeader(SourceLocation loc, UnavailableAttr::ImplicitReason reason); /// Issue any -Wunguarded-availability warnings in \c FD void DiagnoseUnguardedAvailabilityViolations(Decl FD); void handleDelayedAvailabilityCheck(sema::DelayedDiagnostic &DD, Decl Ctx); //===--------------------------------------------------------------------===// // Expression Parsing Callbacks: SemaExpr.cpp. bool CanUseDecl(NamedDecl D, bool TreatUnavailableAsInvalid); bool DiagnoseUseOfDecl(NamedDecl D, ArrayRef<SourceLocation> Locs, const ObjCInterfaceDecl UnknownObjCClass = nullptr, bool ObjCPropertyAccess = false, bool AvoidPartialAvailabilityChecks = false, ObjCInterfaceDecl ClassReciever = nullptr); void NoteDeletedFunction(FunctionDecl FD); void NoteDeletedInheritingConstructor(CXXConstructorDecl CD); bool DiagnosePropertyAccessorMismatch(ObjCPropertyDecl PD, ObjCMethodDecl Getter, SourceLocation Loc); void DiagnoseSentinelCalls(NamedDecl D, SourceLocation Loc, ArrayRef<Expr > Args); void PushExpressionEvaluationContext( ExpressionEvaluationContext NewContext, Decl LambdaContextDecl = nullptr, ExpressionEvaluationContextRecord::ExpressionKind Type = ExpressionEvaluationContextRecord::EK_Other); enum ReuseLambdaContextDecl_t { ReuseLambdaContextDecl }; void PushExpressionEvaluationContext( ExpressionEvaluationContext NewContext, ReuseLambdaContextDecl_t, ExpressionEvaluationContextRecord::ExpressionKind Type = ExpressionEvaluationContextRecord::EK_Other); void PopExpressionEvaluationContext(); void DiscardCleanupsInEvaluationContext(); ExprResult TransformToPotentiallyEvaluated(Expr E); ExprResult HandleExprEvaluationContextForTypeof(Expr E); ExprResult CheckUnevaluatedOperand(Expr E); void CheckUnusedVolatileAssignment(Expr E); ExprResult ActOnConstantExpression(ExprResult Res); // Functions for marking a declaration referenced. These functions also // contain the relevant logic for marking if a reference to a function or // variable is an odr-use (in the C++11 sense). There are separate variants // for expressions referring to a decl; these exist because odr-use marking // needs to be delayed for some constant variables when we build one of the // named expressions. // // MightBeOdrUse indicates whether the use could possibly be an odr-use, and // should usually be true. This only needs to be set to false if the lack of // odr-use cannot be determined from the current context (for instance, // because the name denotes a virtual function and was written without an // explicit nested-name-specifier). void MarkAnyDeclReferenced(SourceLocation Loc, Decl D, bool MightBeOdrUse); void MarkFunctionReferenced(SourceLocation Loc, FunctionDecl Func, bool MightBeOdrUse = true); void MarkVariableReferenced(SourceLocation Loc, VarDecl Var); void MarkDeclRefReferenced(DeclRefExpr E, const Expr Base = nullptr); void MarkMemberReferenced(MemberExpr E); void MarkFunctionParmPackReferenced(FunctionParmPackExpr E); void MarkCaptureUsedInEnclosingContext(VarDecl Capture, SourceLocation Loc, unsigned CapturingScopeIndex); ExprResult CheckLValueToRValueConversionOperand(Expr E); void CleanupVarDeclMarking(); enum TryCaptureKind { TryCapture_Implicit, TryCapture_ExplicitByVal, TryCapture_ExplicitByRef }; /// Try to capture the given variable. /// /// \param Var The variable to capture. /// /// \param Loc The location at which the capture occurs. /// /// \param Kind The kind of capture, which may be implicit (for either a /// block or a lambda), or explicit by-value or by-reference (for a lambda). /// /// \param EllipsisLoc The location of the ellipsis, if one is provided in /// an explicit lambda capture. /// /// \param BuildAndDiagnose Whether we are actually supposed to add the /// captures or diagnose errors. If false, this routine merely check whether /// the capture can occur without performing the capture itself or complaining /// if the variable cannot be captured. /// /// \param CaptureType Will be set to the type of the field used to capture /// this variable in the innermost block or lambda. Only valid when the /// variable can be captured. /// /// \param DeclRefType Will be set to the type of a reference to the capture /// from within the current scope. Only valid when the variable can be /// captured. /// /// \param FunctionScopeIndexToStopAt If non-null, it points to the index /// of the FunctionScopeInfo stack beyond which we do not attempt to capture. /// This is useful when enclosing lambdas must speculatively capture /// variables that may or may not be used in certain specializations of /// a nested generic lambda. /// /// \returns true if an error occurred (i.e., the variable cannot be /// captured) and false if the capture succeeded. bool tryCaptureVariable(VarDecl Var, SourceLocation Loc, TryCaptureKind Kind, SourceLocation EllipsisLoc, bool BuildAndDiagnose, QualType &CaptureType, QualType &DeclRefType, const unsigned const FunctionScopeIndexToStopAt); /// Try to capture the given variable. bool tryCaptureVariable(VarDecl Var, SourceLocation Loc, TryCaptureKind Kind = TryCapture_Implicit, SourceLocation EllipsisLoc = SourceLocation()); /// Checks if the variable must be captured. bool NeedToCaptureVariable(VarDecl Var, SourceLocation Loc); /// Given a variable, determine the type that a reference to that /// variable will have in the given scope. QualType getCapturedDeclRefType(VarDecl Var, SourceLocation Loc); /// Mark all of the declarations referenced within a particular AST node as /// referenced. Used when template instantiation instantiates a non-dependent /// type -- entities referenced by the type are now referenced. void MarkDeclarationsReferencedInType(SourceLocation Loc, QualType T); void MarkDeclarationsReferencedInExpr(Expr E, bool SkipLocalVariables = false); /// Try to recover by turning the given expression into a /// call. Returns true if recovery was attempted or an error was /// emitted; this may also leave the ExprResult invalid. bool tryToRecoverWithCall(ExprResult &E, const PartialDiagnostic &PD, bool ForceComplain = false, bool (IsPlausibleResult)(QualType) = nullptr); /// Figure out if an expression could be turned into a call. bool tryExprAsCall(Expr &E, QualType &ZeroArgCallReturnTy, UnresolvedSetImpl &NonTemplateOverloads); /// Try to convert an expression \p E to type \p Ty. Returns the result of the /// conversion. ExprResult tryConvertExprToType(Expr E, QualType Ty); /// Conditionally issue a diagnostic based on the statements's reachability /// analysis. /// /// \param Stmts If Stmts is non-empty, delay reporting the diagnostic until /// the function body is parsed, and then do a basic reachability analysis to /// determine if the statement is reachable. If it is unreachable, the /// diagnostic will not be emitted. bool DiagIfReachable(SourceLocation Loc, ArrayRef<const Stmt > Stmts, const PartialDiagnostic &PD); /// Conditionally issue a diagnostic based on the current /// evaluation context. /// /// \param Statement If Statement is non-null, delay reporting the /// diagnostic until the function body is parsed, and then do a basic /// reachability analysis to determine if the statement is reachable. /// If it is unreachable, the diagnostic will not be emitted. bool DiagRuntimeBehavior(SourceLocation Loc, const Stmt Statement, const PartialDiagnostic &PD); /// Similar, but diagnostic is only produced if all the specified statements /// are reachable. bool DiagRuntimeBehavior(SourceLocation Loc, ArrayRef<const Stmt> Stmts, const PartialDiagnostic &PD); // Primary Expressions. SourceRange getExprRange(Expr E) const; ExprResult ActOnIdExpression( Scope S, CXXScopeSpec &SS, SourceLocation TemplateKWLoc, UnqualifiedId &Id, bool HasTrailingLParen, bool IsAddressOfOperand, CorrectionCandidateCallback CCC = nullptr, bool IsInlineAsmIdentifier = false, Token KeywordReplacement = nullptr); void DecomposeUnqualifiedId(const UnqualifiedId &Id, TemplateArgumentListInfo &Buffer, DeclarationNameInfo &NameInfo, const TemplateArgumentListInfo &TemplateArgs); bool DiagnoseDependentMemberLookup(LookupResult &R); bool DiagnoseEmptyLookup(Scope S, CXXScopeSpec &SS, LookupResult &R, CorrectionCandidateCallback &CCC, TemplateArgumentListInfo ExplicitTemplateArgs = nullptr, ArrayRef<Expr > Args = None, TypoExpr Out = nullptr); DeclResult LookupIvarInObjCMethod(LookupResult &Lookup, Scope S, IdentifierInfo II); ExprResult BuildIvarRefExpr(Scope S, SourceLocation Loc, ObjCIvarDecl IV); ExprResult LookupInObjCMethod(LookupResult &LookUp, Scope S, IdentifierInfo II, bool AllowBuiltinCreation=false); ExprResult ActOnDependentIdExpression(const CXXScopeSpec &SS, SourceLocation TemplateKWLoc, const DeclarationNameInfo &NameInfo, bool isAddressOfOperand, const TemplateArgumentListInfo TemplateArgs); /// If \p D cannot be odr-used in the current expression evaluation context, /// return a reason explaining why. Otherwise, return NOUR_None. NonOdrUseReason getNonOdrUseReasonInCurrentContext(ValueDecl D); DeclRefExpr BuildDeclRefExpr(ValueDecl D, QualType Ty, ExprValueKind VK, SourceLocation Loc, const CXXScopeSpec SS = nullptr); DeclRefExpr * BuildDeclRefExpr(ValueDecl D, QualType Ty, ExprValueKind VK, const DeclarationNameInfo &NameInfo, const CXXScopeSpec SS = nullptr, NamedDecl FoundD = nullptr, SourceLocation TemplateKWLoc = SourceLocation(), const TemplateArgumentListInfo TemplateArgs = nullptr); DeclRefExpr * BuildDeclRefExpr(ValueDecl D, QualType Ty, ExprValueKind VK, const DeclarationNameInfo &NameInfo, NestedNameSpecifierLoc NNS, NamedDecl FoundD = nullptr, SourceLocation TemplateKWLoc = SourceLocation(), const TemplateArgumentListInfo TemplateArgs = nullptr); ExprResult BuildAnonymousStructUnionMemberReference( const CXXScopeSpec &SS, SourceLocation nameLoc, IndirectFieldDecl indirectField, DeclAccessPair FoundDecl = DeclAccessPair::make(nullptr, AS_none), Expr baseObjectExpr = nullptr, SourceLocation opLoc = SourceLocation()); ExprResult BuildPossibleImplicitMemberExpr( const CXXScopeSpec &SS, SourceLocation TemplateKWLoc, LookupResult &R, const TemplateArgumentListInfo TemplateArgs, const Scope S, UnresolvedLookupExpr AsULE = nullptr); ExprResult BuildImplicitMemberExpr(const CXXScopeSpec &SS, SourceLocation TemplateKWLoc, LookupResult &R, const TemplateArgumentListInfo TemplateArgs, bool IsDefiniteInstance, const Scope S); bool UseArgumentDependentLookup(const CXXScopeSpec &SS, const LookupResult &R, bool HasTrailingLParen); ExprResult BuildQualifiedDeclarationNameExpr(CXXScopeSpec &SS, const DeclarationNameInfo &NameInfo, bool IsAddressOfOperand, const Scope S, TypeSourceInfo RecoveryTSI = nullptr); ExprResult BuildDependentDeclRefExpr(const CXXScopeSpec &SS, SourceLocation TemplateKWLoc, const DeclarationNameInfo &NameInfo, const TemplateArgumentListInfo TemplateArgs); ExprResult BuildDeclarationNameExpr(const CXXScopeSpec &SS, LookupResult &R, bool NeedsADL, bool AcceptInvalidDecl = false); ExprResult BuildDeclarationNameExpr( const CXXScopeSpec &SS, const DeclarationNameInfo &NameInfo, NamedDecl D, NamedDecl FoundD = nullptr, const TemplateArgumentListInfo TemplateArgs = nullptr, bool AcceptInvalidDecl = false); ExprResult BuildLiteralOperatorCall(LookupResult &R, DeclarationNameInfo &SuffixInfo, ArrayRef<Expr > Args, SourceLocation LitEndLoc, TemplateArgumentListInfo ExplicitTemplateArgs = nullptr); ExprResult BuildPredefinedExpr(SourceLocation Loc, PredefinedExpr::IdentKind IK); ExprResult ActOnPredefinedExpr(SourceLocation Loc, tok::TokenKind Kind); ExprResult ActOnIntegerConstant(SourceLocation Loc, uint64_t Val); ExprResult BuildSYCLUniqueStableNameExpr(SourceLocation OpLoc, SourceLocation LParen, SourceLocation RParen, TypeSourceInfo TSI); ExprResult ActOnSYCLUniqueStableNameExpr(SourceLocation OpLoc, SourceLocation LParen, SourceLocation RParen, ParsedType ParsedTy); ExprResult BuildSYCLUniqueStableIdExpr(SourceLocation OpLoc, SourceLocation LParen, SourceLocation RParen, Expr E); ExprResult ActOnSYCLUniqueStableIdExpr(SourceLocation OpLoc, SourceLocation LParen, SourceLocation RParen, Expr E); bool CheckLoopHintExpr(Expr E, SourceLocation Loc); ExprResult ActOnNumericConstant(const Token &Tok, Scope UDLScope = nullptr); ExprResult ActOnCharacterConstant(const Token &Tok, Scope UDLScope = nullptr); ExprResult ActOnParenExpr(SourceLocation L, SourceLocation R, Expr E); ExprResult ActOnParenListExpr(SourceLocation L, SourceLocation R, MultiExprArg Val); /// ActOnStringLiteral - The specified tokens were lexed as pasted string /// fragments (e.g. "foo" "bar" L"baz"). ExprResult ActOnStringLiteral(ArrayRef<Token> StringToks, Scope UDLScope = nullptr); ExprResult ActOnGenericSelectionExpr(SourceLocation KeyLoc, SourceLocation DefaultLoc, SourceLocation RParenLoc, Expr ControllingExpr, ArrayRef<ParsedType> ArgTypes, ArrayRef<Expr > ArgExprs); ExprResult CreateGenericSelectionExpr(SourceLocation KeyLoc, SourceLocation DefaultLoc, SourceLocation RParenLoc, Expr ControllingExpr, ArrayRef<TypeSourceInfo > Types, ArrayRef<Expr > Exprs); // Binary/Unary Operators. 'Tok' is the token for the operator. ExprResult CreateBuiltinUnaryOp(SourceLocation OpLoc, UnaryOperatorKind Opc, Expr InputExpr); ExprResult BuildUnaryOp(Scope S, SourceLocation OpLoc, UnaryOperatorKind Opc, Expr Input); ExprResult ActOnUnaryOp(Scope S, SourceLocation OpLoc, tok::TokenKind Op, Expr Input); bool isQualifiedMemberAccess(Expr E); QualType CheckAddressOfOperand(ExprResult &Operand, SourceLocation OpLoc); ExprResult CreateUnaryExprOrTypeTraitExpr(TypeSourceInfo TInfo, SourceLocation OpLoc, UnaryExprOrTypeTrait ExprKind, SourceRange R); ExprResult CreateUnaryExprOrTypeTraitExpr(Expr E, SourceLocation OpLoc, UnaryExprOrTypeTrait ExprKind); ExprResult ActOnUnaryExprOrTypeTraitExpr(SourceLocation OpLoc, UnaryExprOrTypeTrait ExprKind, bool IsType, void TyOrEx, SourceRange ArgRange); ExprResult CheckPlaceholderExpr(Expr E); bool CheckVecStepExpr(Expr E); bool CheckUnaryExprOrTypeTraitOperand(Expr E, UnaryExprOrTypeTrait ExprKind); bool CheckUnaryExprOrTypeTraitOperand(QualType ExprType, SourceLocation OpLoc, SourceRange ExprRange, UnaryExprOrTypeTrait ExprKind); ExprResult ActOnSizeofParameterPackExpr(Scope S, SourceLocation OpLoc, IdentifierInfo &Name, SourceLocation NameLoc, SourceLocation RParenLoc); ExprResult ActOnPostfixUnaryOp(Scope S, SourceLocation OpLoc, tok::TokenKind Kind, Expr Input); ExprResult ActOnArraySubscriptExpr(Scope S, Expr Base, SourceLocation LLoc, Expr Idx, SourceLocation RLoc); ExprResult CreateBuiltinArraySubscriptExpr(Expr Base, SourceLocation LLoc, Expr Idx, SourceLocation RLoc); ExprResult CreateBuiltinMatrixSubscriptExpr(Expr Base, Expr RowIdx, Expr ColumnIdx, SourceLocation RBLoc); ExprResult ActOnOMPArraySectionExpr(Expr Base, SourceLocation LBLoc, Expr LowerBound, SourceLocation ColonLocFirst, SourceLocation ColonLocSecond, Expr Length, Expr Stride, SourceLocation RBLoc); ExprResult ActOnOMPArrayShapingExpr(Expr Base, SourceLocation LParenLoc, SourceLocation RParenLoc, ArrayRef<Expr > Dims, ArrayRef<SourceRange> Brackets); /// Data structure for iterator expression. struct OMPIteratorData { IdentifierInfo DeclIdent = nullptr; SourceLocation DeclIdentLoc; ParsedType Type; OMPIteratorExpr::IteratorRange Range; SourceLocation AssignLoc; SourceLocation ColonLoc; SourceLocation SecColonLoc; }; ExprResult ActOnOMPIteratorExpr(Scope S, SourceLocation IteratorKwLoc, SourceLocation LLoc, SourceLocation RLoc, ArrayRef<OMPIteratorData> Data); // This struct is for use by ActOnMemberAccess to allow // BuildMemberReferenceExpr to be able to reinvoke ActOnMemberAccess after // changing the access operator from a '.' to a '->' (to see if that is the // change needed to fix an error about an unknown member, e.g. when the class // defines a custom operator->). struct ActOnMemberAccessExtraArgs { Scope S; UnqualifiedId &Id; Decl ObjCImpDecl; }; ExprResult BuildMemberReferenceExpr( Expr Base, QualType BaseType, SourceLocation OpLoc, bool IsArrow, CXXScopeSpec &SS, SourceLocation TemplateKWLoc, NamedDecl FirstQualifierInScope, const DeclarationNameInfo &NameInfo, const TemplateArgumentListInfo TemplateArgs, const Scope S, ActOnMemberAccessExtraArgs ExtraArgs = nullptr); ExprResult BuildMemberReferenceExpr(Expr Base, QualType BaseType, SourceLocation OpLoc, bool IsArrow, const CXXScopeSpec &SS, SourceLocation TemplateKWLoc, NamedDecl FirstQualifierInScope, LookupResult &R, const TemplateArgumentListInfo TemplateArgs, const Scope S, bool SuppressQualifierCheck = false, ActOnMemberAccessExtraArgs ExtraArgs = nullptr); ExprResult BuildFieldReferenceExpr(Expr BaseExpr, bool IsArrow, SourceLocation OpLoc, const CXXScopeSpec &SS, FieldDecl Field, DeclAccessPair FoundDecl, const DeclarationNameInfo &MemberNameInfo); ExprResult PerformMemberExprBaseConversion(Expr Base, bool IsArrow); bool CheckQualifiedMemberReference(Expr BaseExpr, QualType BaseType, const CXXScopeSpec &SS, const LookupResult &R); ExprResult ActOnDependentMemberExpr(Expr Base, QualType BaseType, bool IsArrow, SourceLocation OpLoc, const CXXScopeSpec &SS, SourceLocation TemplateKWLoc, NamedDecl FirstQualifierInScope, const DeclarationNameInfo &NameInfo, const TemplateArgumentListInfo TemplateArgs); ExprResult ActOnMemberAccessExpr(Scope S, Expr Base, SourceLocation OpLoc, tok::TokenKind OpKind, CXXScopeSpec &SS, SourceLocation TemplateKWLoc, UnqualifiedId &Member, Decl ObjCImpDecl); MemberExpr BuildMemberExpr(Expr Base, bool IsArrow, SourceLocation OpLoc, const CXXScopeSpec SS, SourceLocation TemplateKWLoc, ValueDecl Member, DeclAccessPair FoundDecl, bool HadMultipleCandidates, const DeclarationNameInfo &MemberNameInfo, QualType Ty, ExprValueKind VK, ExprObjectKind OK, const TemplateArgumentListInfo TemplateArgs = nullptr); MemberExpr * BuildMemberExpr(Expr Base, bool IsArrow, SourceLocation OpLoc, NestedNameSpecifierLoc NNS, SourceLocation TemplateKWLoc, ValueDecl Member, DeclAccessPair FoundDecl, bool HadMultipleCandidates, const DeclarationNameInfo &MemberNameInfo, QualType Ty, ExprValueKind VK, ExprObjectKind OK, const TemplateArgumentListInfo TemplateArgs = nullptr); void ActOnDefaultCtorInitializers(Decl CDtorDecl); bool ConvertArgumentsForCall(CallExpr Call, Expr Fn, FunctionDecl FDecl, const FunctionProtoType Proto, ArrayRef<Expr > Args, SourceLocation RParenLoc, bool ExecConfig = false); void CheckStaticArrayArgument(SourceLocation CallLoc, ParmVarDecl Param, const Expr ArgExpr); /// ActOnCallExpr - Handle a call to Fn with the specified array of arguments. /// This provides the location of the left/right parens and a list of comma /// locations. ExprResult ActOnCallExpr(Scope S, Expr Fn, SourceLocation LParenLoc, MultiExprArg ArgExprs, SourceLocation RParenLoc, Expr ExecConfig = nullptr); ExprResult BuildCallExpr(Scope S, Expr Fn, SourceLocation LParenLoc, MultiExprArg ArgExprs, SourceLocation RParenLoc, Expr ExecConfig = nullptr, bool IsExecConfig = false, bool AllowRecovery = false); Expr BuildBuiltinCallExpr(SourceLocation Loc, Builtin::ID Id, MultiExprArg CallArgs); enum class AtomicArgumentOrder { API, AST }; ExprResult BuildAtomicExpr(SourceRange CallRange, SourceRange ExprRange, SourceLocation RParenLoc, MultiExprArg Args, AtomicExpr::AtomicOp Op, AtomicArgumentOrder ArgOrder = AtomicArgumentOrder::API); ExprResult BuildResolvedCallExpr(Expr Fn, NamedDecl NDecl, SourceLocation LParenLoc, ArrayRef<Expr > Arg, SourceLocation RParenLoc, Expr Config = nullptr, bool IsExecConfig = false, ADLCallKind UsesADL = ADLCallKind::NotADL); ExprResult ActOnCUDAExecConfigExpr(Scope S, SourceLocation LLLLoc, MultiExprArg ExecConfig, SourceLocation GGGLoc); ExprResult ActOnCastExpr(Scope S, SourceLocation LParenLoc, Declarator &D, ParsedType &Ty, SourceLocation RParenLoc, Expr CastExpr); ExprResult BuildCStyleCastExpr(SourceLocation LParenLoc, TypeSourceInfo Ty, SourceLocation RParenLoc, Expr Op); CastKind PrepareScalarCast(ExprResult &src, QualType destType); /// Build an altivec or OpenCL literal. ExprResult BuildVectorLiteral(SourceLocation LParenLoc, SourceLocation RParenLoc, Expr E, TypeSourceInfo TInfo); ExprResult MaybeConvertParenListExprToParenExpr(Scope S, Expr ME); ExprResult ActOnCompoundLiteral(SourceLocation LParenLoc, ParsedType Ty, SourceLocation RParenLoc, Expr InitExpr); ExprResult BuildCompoundLiteralExpr(SourceLocation LParenLoc, TypeSourceInfo TInfo, SourceLocation RParenLoc, Expr LiteralExpr); ExprResult ActOnInitList(SourceLocation LBraceLoc, MultiExprArg InitArgList, SourceLocation RBraceLoc); ExprResult BuildInitList(SourceLocation LBraceLoc, MultiExprArg InitArgList, SourceLocation RBraceLoc); ExprResult ActOnDesignatedInitializer(Designation &Desig, SourceLocation EqualOrColonLoc, bool GNUSyntax, ExprResult Init); private: static BinaryOperatorKind ConvertTokenKindToBinaryOpcode(tok::TokenKind Kind); public: ExprResult ActOnBinOp(Scope S, SourceLocation TokLoc, tok::TokenKind Kind, Expr LHSExpr, Expr RHSExpr); ExprResult BuildBinOp(Scope S, SourceLocation OpLoc, BinaryOperatorKind Opc, Expr LHSExpr, Expr RHSExpr); ExprResult CreateBuiltinBinOp(SourceLocation OpLoc, BinaryOperatorKind Opc, Expr LHSExpr, Expr RHSExpr); void LookupBinOp(Scope S, SourceLocation OpLoc, BinaryOperatorKind Opc, UnresolvedSetImpl &Functions); void DiagnoseCommaOperator(const Expr LHS, SourceLocation Loc); /// ActOnConditionalOp - Parse a ?: operation. Note that 'LHS' may be null /// in the case of a the GNU conditional expr extension. ExprResult ActOnConditionalOp(SourceLocation QuestionLoc, SourceLocation ColonLoc, Expr CondExpr, Expr LHSExpr, Expr RHSExpr); /// ActOnAddrLabel - Parse the GNU address of label extension: "&&foo". ExprResult ActOnAddrLabel(SourceLocation OpLoc, SourceLocation LabLoc, LabelDecl TheDecl); void ActOnStartStmtExpr(); ExprResult ActOnStmtExpr(Scope S, SourceLocation LPLoc, Stmt SubStmt, SourceLocation RPLoc); ExprResult BuildStmtExpr(SourceLocation LPLoc, Stmt SubStmt, SourceLocation RPLoc, unsigned TemplateDepth); // Handle the final expression in a statement expression. ExprResult ActOnStmtExprResult(ExprResult E); void ActOnStmtExprError(); // __builtin_offsetof(type, identifier(.identifier\|[expr])) struct OffsetOfComponent { SourceLocation LocStart, LocEnd; bool isBrackets; // true if [expr], false if .ident union { IdentifierInfo IdentInfo; Expr E; } U; }; /// __builtin_offsetof(type, a.b[123][456].c) ExprResult BuildBuiltinOffsetOf(SourceLocation BuiltinLoc, TypeSourceInfo TInfo, ArrayRef<OffsetOfComponent> Components, SourceLocation RParenLoc); ExprResult ActOnBuiltinOffsetOf(Scope S, SourceLocation BuiltinLoc, SourceLocation TypeLoc, ParsedType ParsedArgTy, ArrayRef<OffsetOfComponent> Components, SourceLocation RParenLoc); // __builtin_choose_expr(constExpr, expr1, expr2) ExprResult ActOnChooseExpr(SourceLocation BuiltinLoc, Expr CondExpr, Expr LHSExpr, Expr RHSExpr, SourceLocation RPLoc); // __builtin_va_arg(expr, type) ExprResult ActOnVAArg(SourceLocation BuiltinLoc, Expr E, ParsedType Ty, SourceLocation RPLoc); ExprResult BuildVAArgExpr(SourceLocation BuiltinLoc, Expr E, TypeSourceInfo TInfo, SourceLocation RPLoc); // __builtin_LINE(), __builtin_FUNCTION(), __builtin_FILE(), // __builtin_COLUMN() ExprResult ActOnSourceLocExpr(SourceLocExpr::IdentKind Kind, SourceLocation BuiltinLoc, SourceLocation RPLoc); // Build a potentially resolved SourceLocExpr. ExprResult BuildSourceLocExpr(SourceLocExpr::IdentKind Kind, SourceLocation BuiltinLoc, SourceLocation RPLoc, DeclContext ParentContext); // __null ExprResult ActOnGNUNullExpr(SourceLocation TokenLoc); bool CheckCaseExpression(Expr E); /// Describes the result of an "if-exists" condition check. enum IfExistsResult { /// The symbol exists. IER_Exists, /// The symbol does not exist. IER_DoesNotExist, /// The name is a dependent name, so the results will differ /// from one instantiation to the next. IER_Dependent, /// An error occurred. IER_Error }; IfExistsResult CheckMicrosoftIfExistsSymbol(Scope S, CXXScopeSpec &SS, const DeclarationNameInfo &TargetNameInfo); IfExistsResult CheckMicrosoftIfExistsSymbol(Scope S, SourceLocation KeywordLoc, bool IsIfExists, CXXScopeSpec &SS, UnqualifiedId &Name); StmtResult BuildMSDependentExistsStmt(SourceLocation KeywordLoc, bool IsIfExists, NestedNameSpecifierLoc QualifierLoc, DeclarationNameInfo NameInfo, Stmt Nested); StmtResult ActOnMSDependentExistsStmt(SourceLocation KeywordLoc, bool IsIfExists, CXXScopeSpec &SS, UnqualifiedId &Name, Stmt Nested); //===------------------------- "Block" Extension ------------------------===// /// ActOnBlockStart - This callback is invoked when a block literal is /// started. void ActOnBlockStart(SourceLocation CaretLoc, Scope CurScope); /// ActOnBlockArguments - This callback allows processing of block arguments. /// If there are no arguments, this is still invoked. void ActOnBlockArguments(SourceLocation CaretLoc, Declarator &ParamInfo, Scope CurScope); /// ActOnBlockError - If there is an error parsing a block, this callback /// is invoked to pop the information about the block from the action impl. void ActOnBlockError(SourceLocation CaretLoc, Scope CurScope); /// ActOnBlockStmtExpr - This is called when the body of a block statement /// literal was successfully completed. ^(int x){...} ExprResult ActOnBlockStmtExpr(SourceLocation CaretLoc, Stmt Body, Scope CurScope); //===---------------------------- Clang Extensions ----------------------===// /// __builtin_convertvector(...) ExprResult ActOnConvertVectorExpr(Expr E, ParsedType ParsedDestTy, SourceLocation BuiltinLoc, SourceLocation RParenLoc); //===---------------------------- OpenCL Features -----------------------===// /// __builtin_astype(...) ExprResult ActOnAsTypeExpr(Expr E, ParsedType ParsedDestTy, SourceLocation BuiltinLoc, SourceLocation RParenLoc); ExprResult BuildAsTypeExpr(Expr E, QualType DestTy, SourceLocation BuiltinLoc, SourceLocation RParenLoc); //===---------------------------- C++ Features --------------------------===// // Act on C++ namespaces Decl ActOnStartNamespaceDef(Scope S, SourceLocation InlineLoc, SourceLocation NamespaceLoc, SourceLocation IdentLoc, IdentifierInfo Ident, SourceLocation LBrace, const ParsedAttributesView &AttrList, UsingDirectiveDecl &UsingDecl); void ActOnFinishNamespaceDef(Decl Dcl, SourceLocation RBrace); NamespaceDecl getStdNamespace() const; NamespaceDecl getOrCreateStdNamespace(); NamespaceDecl lookupStdExperimentalNamespace(); CXXRecordDecl getStdBadAlloc() const; EnumDecl getStdAlignValT() const; private: // A cache representing if we've fully checked the various comparison category // types stored in ASTContext. The bit-index corresponds to the integer value // of a ComparisonCategoryType enumerator. llvm::SmallBitVector FullyCheckedComparisonCategories; ValueDecl tryLookupCtorInitMemberDecl(CXXRecordDecl ClassDecl, CXXScopeSpec &SS, ParsedType TemplateTypeTy, IdentifierInfo MemberOrBase); public: enum class ComparisonCategoryUsage { /// The '<=>' operator was used in an expression and a builtin operator /// was selected. OperatorInExpression, /// A defaulted 'operator<=>' needed the comparison category. This /// typically only applies to 'std::strong_ordering', due to the implicit /// fallback return value. DefaultedOperator, }; /// Lookup the specified comparison category types in the standard /// library, an check the VarDecls possibly returned by the operator<=> /// builtins for that type. /// /// \return The type of the comparison category type corresponding to the /// specified Kind, or a null type if an error occurs QualType CheckComparisonCategoryType(ComparisonCategoryType Kind, SourceLocation Loc, ComparisonCategoryUsage Usage); /// Tests whether Ty is an instance of std::initializer_list and, if /// it is and Element is not NULL, assigns the element type to Element. bool isStdInitializerList(QualType Ty, QualType Element); /// Looks for the std::initializer_list template and instantiates it /// with Element, or emits an error if it's not found. /// /// \returns The instantiated template, or null on error. QualType BuildStdInitializerList(QualType Element, SourceLocation Loc); /// Determine whether Ctor is an initializer-list constructor, as /// defined in [dcl.init.list]p2. bool isInitListConstructor(const FunctionDecl Ctor); Decl ActOnUsingDirective(Scope CurScope, SourceLocation UsingLoc, SourceLocation NamespcLoc, CXXScopeSpec &SS, SourceLocation IdentLoc, IdentifierInfo NamespcName, const ParsedAttributesView &AttrList); void PushUsingDirective(Scope S, UsingDirectiveDecl UDir); Decl ActOnNamespaceAliasDef(Scope CurScope, SourceLocation NamespaceLoc, SourceLocation AliasLoc, IdentifierInfo Alias, CXXScopeSpec &SS, SourceLocation IdentLoc, IdentifierInfo Ident); void FilterUsingLookup(Scope S, LookupResult &lookup); void HideUsingShadowDecl(Scope S, UsingShadowDecl Shadow); bool CheckUsingShadowDecl(BaseUsingDecl BUD, NamedDecl Target, const LookupResult &PreviousDecls, UsingShadowDecl &PrevShadow); UsingShadowDecl BuildUsingShadowDecl(Scope S, BaseUsingDecl BUD, NamedDecl Target, UsingShadowDecl PrevDecl); bool CheckUsingDeclRedeclaration(SourceLocation UsingLoc, bool HasTypenameKeyword, const CXXScopeSpec &SS, SourceLocation NameLoc, const LookupResult &Previous); bool CheckUsingDeclQualifier(SourceLocation UsingLoc, bool HasTypename, const CXXScopeSpec &SS, const DeclarationNameInfo &NameInfo, SourceLocation NameLoc, const LookupResult R = nullptr, const UsingDecl UD = nullptr); NamedDecl BuildUsingDeclaration( Scope S, AccessSpecifier AS, SourceLocation UsingLoc, bool HasTypenameKeyword, SourceLocation TypenameLoc, CXXScopeSpec &SS, DeclarationNameInfo NameInfo, SourceLocation EllipsisLoc, const ParsedAttributesView &AttrList, bool IsInstantiation, bool IsUsingIfExists); NamedDecl BuildUsingEnumDeclaration(Scope S, AccessSpecifier AS, SourceLocation UsingLoc, SourceLocation EnumLoc, SourceLocation NameLoc, EnumDecl ED); NamedDecl BuildUsingPackDecl(NamedDecl InstantiatedFrom, ArrayRef<NamedDecl > Expansions); bool CheckInheritingConstructorUsingDecl(UsingDecl UD); /// Given a derived-class using shadow declaration for a constructor and the /// correspnding base class constructor, find or create the implicit /// synthesized derived class constructor to use for this initialization. CXXConstructorDecl * findInheritingConstructor(SourceLocation Loc, CXXConstructorDecl BaseCtor, ConstructorUsingShadowDecl DerivedShadow); Decl ActOnUsingDeclaration(Scope CurScope, AccessSpecifier AS, SourceLocation UsingLoc, SourceLocation TypenameLoc, CXXScopeSpec &SS, UnqualifiedId &Name, SourceLocation EllipsisLoc, const ParsedAttributesView &AttrList); Decl ActOnUsingEnumDeclaration(Scope CurScope, AccessSpecifier AS, SourceLocation UsingLoc, SourceLocation EnumLoc, const DeclSpec &); Decl ActOnAliasDeclaration(Scope CurScope, AccessSpecifier AS, MultiTemplateParamsArg TemplateParams, SourceLocation UsingLoc, UnqualifiedId &Name, const ParsedAttributesView &AttrList, TypeResult Type, Decl DeclFromDeclSpec); /// BuildCXXConstructExpr - Creates a complete call to a constructor, /// including handling of its default argument expressions. /// /// \param ConstructKind - a CXXConstructExpr::ConstructionKind ExprResult BuildCXXConstructExpr(SourceLocation ConstructLoc, QualType DeclInitType, NamedDecl FoundDecl, CXXConstructorDecl Constructor, MultiExprArg Exprs, bool HadMultipleCandidates, bool IsListInitialization, bool IsStdInitListInitialization, bool RequiresZeroInit, unsigned ConstructKind, SourceRange ParenRange); /// Build a CXXConstructExpr whose constructor has already been resolved if /// it denotes an inherited constructor. ExprResult BuildCXXConstructExpr(SourceLocation ConstructLoc, QualType DeclInitType, CXXConstructorDecl Constructor, bool Elidable, MultiExprArg Exprs, bool HadMultipleCandidates, bool IsListInitialization, bool IsStdInitListInitialization, bool RequiresZeroInit, unsigned ConstructKind, SourceRange ParenRange); // FIXME: Can we remove this and have the above BuildCXXConstructExpr check if // the constructor can be elidable? ExprResult BuildCXXConstructExpr(SourceLocation ConstructLoc, QualType DeclInitType, NamedDecl FoundDecl, CXXConstructorDecl Constructor, bool Elidable, MultiExprArg Exprs, bool HadMultipleCandidates, bool IsListInitialization, bool IsStdInitListInitialization, bool RequiresZeroInit, unsigned ConstructKind, SourceRange ParenRange); ExprResult BuildCXXDefaultInitExpr(SourceLocation Loc, FieldDecl Field); /// Instantiate or parse a C++ default argument expression as necessary. /// Return true on error. bool CheckCXXDefaultArgExpr(SourceLocation CallLoc, FunctionDecl FD, ParmVarDecl Param); /// BuildCXXDefaultArgExpr - Creates a CXXDefaultArgExpr, instantiating /// the default expr if needed. ExprResult BuildCXXDefaultArgExpr(SourceLocation CallLoc, FunctionDecl FD, ParmVarDecl Param); /// FinalizeVarWithDestructor - Prepare for calling destructor on the /// constructed variable. void FinalizeVarWithDestructor(VarDecl VD, const RecordType DeclInitType); /// Helper class that collects exception specifications for /// implicitly-declared special member functions. class ImplicitExceptionSpecification { // Pointer to allow copying Sema Self; // We order exception specifications thus: // noexcept is the most restrictive, but is only used in C++11. // throw() comes next. // Then a throw(collected exceptions) // Finally no specification, which is expressed as noexcept(false). // throw(...) is used instead if any called function uses it. ExceptionSpecificationType ComputedEST; llvm::SmallPtrSet<CanQualType, 4> ExceptionsSeen; SmallVector<QualType, 4> Exceptions; void ClearExceptions() { ExceptionsSeen.clear(); Exceptions.clear(); } public: explicit ImplicitExceptionSpecification(Sema &Self) : Self(&Self), ComputedEST(EST_BasicNoexcept) { if (!Self.getLangOpts().CPlusPlus11) ComputedEST = EST_DynamicNone; } /// Get the computed exception specification type. ExceptionSpecificationType getExceptionSpecType() const { assert(!isComputedNoexcept(ComputedEST) && "noexcept(expr) should not be a possible result"); return ComputedEST; } /// The number of exceptions in the exception specification. unsigned size() const { return Exceptions.size(); } /// The set of exceptions in the exception specification. const QualType data() const { return Exceptions.data(); } /// Integrate another called method into the collected data. void CalledDecl(SourceLocation CallLoc, const CXXMethodDecl Method); /// Integrate an invoked expression into the collected data. void CalledExpr(Expr E) { CalledStmt(E); } /// Integrate an invoked statement into the collected data. void CalledStmt(Stmt S); /// Overwrite an EPI's exception specification with this /// computed exception specification. FunctionProtoType::ExceptionSpecInfo getExceptionSpec() const { FunctionProtoType::ExceptionSpecInfo ESI; ESI.Type = getExceptionSpecType(); if (ESI.Type == EST_Dynamic) { ESI.Exceptions = Exceptions; } else if (ESI.Type == EST_None) { /// C++11 [except.spec]p14: /// The exception-specification is noexcept(false) if the set of /// potential exceptions of the special member function contains "any" ESI.Type = EST_NoexceptFalse; ESI.NoexceptExpr = Self->ActOnCXXBoolLiteral(SourceLocation(), tok::kw_false).get(); } return ESI; } }; /// Evaluate the implicit exception specification for a defaulted /// special member function. void EvaluateImplicitExceptionSpec(SourceLocation Loc, FunctionDecl FD); /// Check the given noexcept-specifier, convert its expression, and compute /// the appropriate ExceptionSpecificationType. ExprResult ActOnNoexceptSpec(Expr NoexceptExpr, ExceptionSpecificationType &EST); /// Check the given exception-specification and update the /// exception specification information with the results. void checkExceptionSpecification(bool IsTopLevel, ExceptionSpecificationType EST, ArrayRef<ParsedType> DynamicExceptions, ArrayRef<SourceRange> DynamicExceptionRanges, Expr NoexceptExpr, SmallVectorImpl<QualType> &Exceptions, FunctionProtoType::ExceptionSpecInfo &ESI); /// Determine if we're in a case where we need to (incorrectly) eagerly /// parse an exception specification to work around a libstdc++ bug. bool isLibstdcxxEagerExceptionSpecHack(const Declarator &D); /// Add an exception-specification to the given member function /// (or member function template). The exception-specification was parsed /// after the method itself was declared. void actOnDelayedExceptionSpecification(Decl Method, ExceptionSpecificationType EST, SourceRange SpecificationRange, ArrayRef<ParsedType> DynamicExceptions, ArrayRef<SourceRange> DynamicExceptionRanges, Expr NoexceptExpr); class InheritedConstructorInfo; /// Determine if a special member function should have a deleted /// definition when it is defaulted. bool ShouldDeleteSpecialMember(CXXMethodDecl MD, CXXSpecialMember CSM, InheritedConstructorInfo ICI = nullptr, bool Diagnose = false); /// Produce notes explaining why a defaulted function was defined as deleted. void DiagnoseDeletedDefaultedFunction(FunctionDecl FD); /// Declare the implicit default constructor for the given class. /// /// \param ClassDecl The class declaration into which the implicit /// default constructor will be added. /// /// \returns The implicitly-declared default constructor. CXXConstructorDecl DeclareImplicitDefaultConstructor( CXXRecordDecl ClassDecl); /// DefineImplicitDefaultConstructor - Checks for feasibility of /// defining this constructor as the default constructor. void DefineImplicitDefaultConstructor(SourceLocation CurrentLocation, CXXConstructorDecl Constructor); /// Declare the implicit destructor for the given class. /// /// \param ClassDecl The class declaration into which the implicit /// destructor will be added. /// /// \returns The implicitly-declared destructor. CXXDestructorDecl DeclareImplicitDestructor(CXXRecordDecl ClassDecl); /// DefineImplicitDestructor - Checks for feasibility of /// defining this destructor as the default destructor. void DefineImplicitDestructor(SourceLocation CurrentLocation, CXXDestructorDecl Destructor); /// Build an exception spec for destructors that don't have one. /// /// C++11 says that user-defined destructors with no exception spec get one /// that looks as if the destructor was implicitly declared. void AdjustDestructorExceptionSpec(CXXDestructorDecl Destructor); /// Define the specified inheriting constructor. void DefineInheritingConstructor(SourceLocation UseLoc, CXXConstructorDecl Constructor); /// Declare the implicit copy constructor for the given class. /// /// \param ClassDecl The class declaration into which the implicit /// copy constructor will be added. /// /// \returns The implicitly-declared copy constructor. CXXConstructorDecl DeclareImplicitCopyConstructor(CXXRecordDecl ClassDecl); /// DefineImplicitCopyConstructor - Checks for feasibility of /// defining this constructor as the copy constructor. void DefineImplicitCopyConstructor(SourceLocation CurrentLocation, CXXConstructorDecl Constructor); /// Declare the implicit move constructor for the given class. /// /// \param ClassDecl The Class declaration into which the implicit /// move constructor will be added. /// /// \returns The implicitly-declared move constructor, or NULL if it wasn't /// declared. CXXConstructorDecl DeclareImplicitMoveConstructor(CXXRecordDecl ClassDecl); /// DefineImplicitMoveConstructor - Checks for feasibility of /// defining this constructor as the move constructor. void DefineImplicitMoveConstructor(SourceLocation CurrentLocation, CXXConstructorDecl Constructor); /// Declare the implicit copy assignment operator for the given class. /// /// \param ClassDecl The class declaration into which the implicit /// copy assignment operator will be added. /// /// \returns The implicitly-declared copy assignment operator. CXXMethodDecl DeclareImplicitCopyAssignment(CXXRecordDecl ClassDecl); /// Defines an implicitly-declared copy assignment operator. void DefineImplicitCopyAssignment(SourceLocation CurrentLocation, CXXMethodDecl MethodDecl); /// Declare the implicit move assignment operator for the given class. /// /// \param ClassDecl The Class declaration into which the implicit /// move assignment operator will be added. /// /// \returns The implicitly-declared move assignment operator, or NULL if it /// wasn't declared. CXXMethodDecl DeclareImplicitMoveAssignment(CXXRecordDecl ClassDecl); /// Defines an implicitly-declared move assignment operator. void DefineImplicitMoveAssignment(SourceLocation CurrentLocation, CXXMethodDecl MethodDecl); /// Force the declaration of any implicitly-declared members of this /// class. void ForceDeclarationOfImplicitMembers(CXXRecordDecl Class); /// Check a completed declaration of an implicit special member. void CheckImplicitSpecialMemberDeclaration(Scope S, FunctionDecl FD); /// Determine whether the given function is an implicitly-deleted /// special member function. bool isImplicitlyDeleted(FunctionDecl FD); /// Check whether 'this' shows up in the type of a static member /// function after the (naturally empty) cv-qualifier-seq would be. /// /// \returns true if an error occurred. bool checkThisInStaticMemberFunctionType(CXXMethodDecl Method); /// Whether this' shows up in the exception specification of a static /// member function. bool checkThisInStaticMemberFunctionExceptionSpec(CXXMethodDecl Method); /// Check whether 'this' shows up in the attributes of the given /// static member function. /// /// \returns true if an error occurred. bool checkThisInStaticMemberFunctionAttributes(CXXMethodDecl Method); /// MaybeBindToTemporary - If the passed in expression has a record type with /// a non-trivial destructor, this will return CXXBindTemporaryExpr. Otherwise /// it simply returns the passed in expression. ExprResult MaybeBindToTemporary(Expr E); /// Wrap the expression in a ConstantExpr if it is a potential immediate /// invocation. ExprResult CheckForImmediateInvocation(ExprResult E, FunctionDecl Decl); bool CompleteConstructorCall(CXXConstructorDecl Constructor, QualType DeclInitType, MultiExprArg ArgsPtr, SourceLocation Loc, SmallVectorImpl<Expr > &ConvertedArgs, bool AllowExplicit = false, bool IsListInitialization = false); ParsedType getInheritingConstructorName(CXXScopeSpec &SS, SourceLocation NameLoc, IdentifierInfo &Name); ParsedType getConstructorName(IdentifierInfo &II, SourceLocation NameLoc, Scope S, CXXScopeSpec &SS, bool EnteringContext); ParsedType getDestructorName(SourceLocation TildeLoc, IdentifierInfo &II, SourceLocation NameLoc, Scope S, CXXScopeSpec &SS, ParsedType ObjectType, bool EnteringContext); ParsedType getDestructorTypeForDecltype(const DeclSpec &DS, ParsedType ObjectType); // Checks that reinterpret casts don't have undefined behavior. void CheckCompatibleReinterpretCast(QualType SrcType, QualType DestType, bool IsDereference, SourceRange Range); // Checks that the vector type should be initialized from a scalar // by splatting the value rather than populating a single element. // This is the case for AltiVecVector types as well as with // AltiVecPixel and AltiVecBool when -faltivec-src-compat=xl is specified. bool ShouldSplatAltivecScalarInCast(const VectorType VecTy); // Checks if the -faltivec-src-compat=gcc option is specified. // If so, AltiVecVector, AltiVecBool and AltiVecPixel types are // treated the same way as they are when trying to initialize // these vectors on gcc (an error is emitted). bool CheckAltivecInitFromScalar(SourceRange R, QualType VecTy, QualType SrcTy); /// ActOnCXXNamedCast - Parse /// {dynamic,static,reinterpret,const,addrspace}_cast's. ExprResult ActOnCXXNamedCast(SourceLocation OpLoc, tok::TokenKind Kind, SourceLocation LAngleBracketLoc, Declarator &D, SourceLocation RAngleBracketLoc, SourceLocation LParenLoc, Expr E, SourceLocation RParenLoc); ExprResult BuildCXXNamedCast(SourceLocation OpLoc, tok::TokenKind Kind, TypeSourceInfo Ty, Expr E, SourceRange AngleBrackets, SourceRange Parens); ExprResult ActOnBuiltinBitCastExpr(SourceLocation KWLoc, Declarator &Dcl, ExprResult Operand, SourceLocation RParenLoc); ExprResult BuildBuiltinBitCastExpr(SourceLocation KWLoc, TypeSourceInfo TSI, Expr Operand, SourceLocation RParenLoc); ExprResult BuildCXXTypeId(QualType TypeInfoType, SourceLocation TypeidLoc, TypeSourceInfo Operand, SourceLocation RParenLoc); ExprResult BuildCXXTypeId(QualType TypeInfoType, SourceLocation TypeidLoc, Expr Operand, SourceLocation RParenLoc); /// ActOnCXXTypeid - Parse typeid( something ). ExprResult ActOnCXXTypeid(SourceLocation OpLoc, SourceLocation LParenLoc, bool isType, void TyOrExpr, SourceLocation RParenLoc); ExprResult BuildCXXUuidof(QualType TypeInfoType, SourceLocation TypeidLoc, TypeSourceInfo Operand, SourceLocation RParenLoc); ExprResult BuildCXXUuidof(QualType TypeInfoType, SourceLocation TypeidLoc, Expr Operand, SourceLocation RParenLoc); /// ActOnCXXUuidof - Parse __uuidof( something ). ExprResult ActOnCXXUuidof(SourceLocation OpLoc, SourceLocation LParenLoc, bool isType, void TyOrExpr, SourceLocation RParenLoc); /// Handle a C++1z fold-expression: ( expr op ... op expr ). ExprResult ActOnCXXFoldExpr(Scope S, SourceLocation LParenLoc, Expr LHS, tok::TokenKind Operator, SourceLocation EllipsisLoc, Expr RHS, SourceLocation RParenLoc); ExprResult BuildCXXFoldExpr(UnresolvedLookupExpr Callee, SourceLocation LParenLoc, Expr LHS, BinaryOperatorKind Operator, SourceLocation EllipsisLoc, Expr RHS, SourceLocation RParenLoc, Optional<unsigned> NumExpansions); ExprResult BuildEmptyCXXFoldExpr(SourceLocation EllipsisLoc, BinaryOperatorKind Operator); //// ActOnCXXThis - Parse 'this' pointer. ExprResult ActOnCXXThis(SourceLocation loc); /// Build a CXXThisExpr and mark it referenced in the current context. Expr BuildCXXThisExpr(SourceLocation Loc, QualType Type, bool IsImplicit); void MarkThisReferenced(CXXThisExpr This); /// Try to retrieve the type of the 'this' pointer. /// /// \returns The type of 'this', if possible. Otherwise, returns a NULL type. QualType getCurrentThisType(); /// When non-NULL, the C++ 'this' expression is allowed despite the /// current context not being a non-static member function. In such cases, /// this provides the type used for 'this'. QualType CXXThisTypeOverride; /// RAII object used to temporarily allow the C++ 'this' expression /// to be used, with the given qualifiers on the current class type. class CXXThisScopeRAII { Sema &S; QualType OldCXXThisTypeOverride; bool Enabled; public: /// Introduce a new scope where 'this' may be allowed (when enabled), /// using the given declaration (which is either a class template or a /// class) along with the given qualifiers. /// along with the qualifiers placed on 'this'. CXXThisScopeRAII(Sema &S, Decl ContextDecl, Qualifiers CXXThisTypeQuals, bool Enabled = true); ~CXXThisScopeRAII(); }; /// Make sure the value of 'this' is actually available in the current /// context, if it is a potentially evaluated context. /// /// \param Loc The location at which the capture of 'this' occurs. /// /// \param Explicit Whether 'this' is explicitly captured in a lambda /// capture list. /// /// \param FunctionScopeIndexToStopAt If non-null, it points to the index /// of the FunctionScopeInfo stack beyond which we do not attempt to capture. /// This is useful when enclosing lambdas must speculatively capture /// 'this' that may or may not be used in certain specializations of /// a nested generic lambda (depending on whether the name resolves to /// a non-static member function or a static function). /// \return returns 'true' if failed, 'false' if success. bool CheckCXXThisCapture(SourceLocation Loc, bool Explicit = false, bool BuildAndDiagnose = true, const unsigned const FunctionScopeIndexToStopAt = nullptr, bool ByCopy = false); /// Determine whether the given type is the type of this that is used /// outside of the body of a member function for a type that is currently /// being defined. bool isThisOutsideMemberFunctionBody(QualType BaseType); /// ActOnCXXBoolLiteral - Parse {true,false} literals. ExprResult ActOnCXXBoolLiteral(SourceLocation OpLoc, tok::TokenKind Kind); /// ActOnObjCBoolLiteral - Parse {__objc_yes,__objc_no} literals. ExprResult ActOnObjCBoolLiteral(SourceLocation OpLoc, tok::TokenKind Kind); ExprResult ActOnObjCAvailabilityCheckExpr(llvm::ArrayRef<AvailabilitySpec> AvailSpecs, SourceLocation AtLoc, SourceLocation RParen); /// ActOnCXXNullPtrLiteral - Parse 'nullptr'. ExprResult ActOnCXXNullPtrLiteral(SourceLocation Loc); //// ActOnCXXThrow - Parse throw expressions. ExprResult ActOnCXXThrow(Scope S, SourceLocation OpLoc, Expr expr); ExprResult BuildCXXThrow(SourceLocation OpLoc, Expr Ex, bool IsThrownVarInScope); bool CheckCXXThrowOperand(SourceLocation ThrowLoc, QualType ThrowTy, Expr E); /// ActOnCXXTypeConstructExpr - Parse construction of a specified type. /// Can be interpreted either as function-style casting ("int(x)") /// or class type construction ("ClassType(x,y,z)") /// or creation of a value-initialized type ("int()"). ExprResult ActOnCXXTypeConstructExpr(ParsedType TypeRep, SourceLocation LParenOrBraceLoc, MultiExprArg Exprs, SourceLocation RParenOrBraceLoc, bool ListInitialization); ExprResult BuildCXXTypeConstructExpr(TypeSourceInfo Type, SourceLocation LParenLoc, MultiExprArg Exprs, SourceLocation RParenLoc, bool ListInitialization); /// ActOnCXXNew - Parsed a C++ 'new' expression. ExprResult ActOnCXXNew(SourceLocation StartLoc, bool UseGlobal, SourceLocation PlacementLParen, MultiExprArg PlacementArgs, SourceLocation PlacementRParen, SourceRange TypeIdParens, Declarator &D, Expr Initializer); ExprResult BuildCXXNew(SourceRange Range, bool UseGlobal, SourceLocation PlacementLParen, MultiExprArg PlacementArgs, SourceLocation PlacementRParen, SourceRange TypeIdParens, QualType AllocType, TypeSourceInfo AllocTypeInfo, Optional<Expr > ArraySize, SourceRange DirectInitRange, Expr Initializer); /// Determine whether \p FD is an aligned allocation or deallocation /// function that is unavailable. bool isUnavailableAlignedAllocationFunction(const FunctionDecl &FD) const; /// Produce diagnostics if \p FD is an aligned allocation or deallocation /// function that is unavailable. void diagnoseUnavailableAlignedAllocation(const FunctionDecl &FD, SourceLocation Loc); bool CheckAllocatedType(QualType AllocType, SourceLocation Loc, SourceRange R); /// The scope in which to find allocation functions. enum AllocationFunctionScope { /// Only look for allocation functions in the global scope. AFS_Global, /// Only look for allocation functions in the scope of the /// allocated class. AFS_Class, /// Look for allocation functions in both the global scope /// and in the scope of the allocated class. AFS_Both }; /// Finds the overloads of operator new and delete that are appropriate /// for the allocation. bool FindAllocationFunctions(SourceLocation StartLoc, SourceRange Range, AllocationFunctionScope NewScope, AllocationFunctionScope DeleteScope, QualType AllocType, bool IsArray, bool &PassAlignment, MultiExprArg PlaceArgs, FunctionDecl &OperatorNew, FunctionDecl &OperatorDelete, bool Diagnose = true); void DeclareGlobalNewDelete(); void DeclareGlobalAllocationFunction(DeclarationName Name, QualType Return, ArrayRef<QualType> Params); bool FindDeallocationFunction(SourceLocation StartLoc, CXXRecordDecl RD, DeclarationName Name, FunctionDecl &Operator, bool Diagnose = true); FunctionDecl FindUsualDeallocationFunction(SourceLocation StartLoc, bool CanProvideSize, bool Overaligned, DeclarationName Name); FunctionDecl FindDeallocationFunctionForDestructor(SourceLocation StartLoc, CXXRecordDecl RD); /// ActOnCXXDelete - Parsed a C++ 'delete' expression ExprResult ActOnCXXDelete(SourceLocation StartLoc, bool UseGlobal, bool ArrayForm, Expr Operand); void CheckVirtualDtorCall(CXXDestructorDecl dtor, SourceLocation Loc, bool IsDelete, bool CallCanBeVirtual, bool WarnOnNonAbstractTypes, SourceLocation DtorLoc); ExprResult ActOnNoexceptExpr(SourceLocation KeyLoc, SourceLocation LParen, Expr Operand, SourceLocation RParen); ExprResult BuildCXXNoexceptExpr(SourceLocation KeyLoc, Expr Operand, SourceLocation RParen); /// Parsed one of the type trait support pseudo-functions. ExprResult ActOnTypeTrait(TypeTrait Kind, SourceLocation KWLoc, ArrayRef<ParsedType> Args, SourceLocation RParenLoc); ExprResult BuildTypeTrait(TypeTrait Kind, SourceLocation KWLoc, ArrayRef<TypeSourceInfo > Args, SourceLocation RParenLoc); /// ActOnArrayTypeTrait - Parsed one of the binary type trait support /// pseudo-functions. ExprResult ActOnArrayTypeTrait(ArrayTypeTrait ATT, SourceLocation KWLoc, ParsedType LhsTy, Expr DimExpr, SourceLocation RParen); ExprResult BuildArrayTypeTrait(ArrayTypeTrait ATT, SourceLocation KWLoc, TypeSourceInfo TSInfo, Expr DimExpr, SourceLocation RParen); /// ActOnExpressionTrait - Parsed one of the unary type trait support /// pseudo-functions. ExprResult ActOnExpressionTrait(ExpressionTrait OET, SourceLocation KWLoc, Expr Queried, SourceLocation RParen); ExprResult BuildExpressionTrait(ExpressionTrait OET, SourceLocation KWLoc, Expr Queried, SourceLocation RParen); ExprResult ActOnStartCXXMemberReference(Scope S, Expr Base, SourceLocation OpLoc, tok::TokenKind OpKind, ParsedType &ObjectType, bool &MayBePseudoDestructor); ExprResult BuildPseudoDestructorExpr(Expr Base, SourceLocation OpLoc, tok::TokenKind OpKind, const CXXScopeSpec &SS, TypeSourceInfo ScopeType, SourceLocation CCLoc, SourceLocation TildeLoc, PseudoDestructorTypeStorage DestroyedType); ExprResult ActOnPseudoDestructorExpr(Scope S, Expr Base, SourceLocation OpLoc, tok::TokenKind OpKind, CXXScopeSpec &SS, UnqualifiedId &FirstTypeName, SourceLocation CCLoc, SourceLocation TildeLoc, UnqualifiedId &SecondTypeName); ExprResult ActOnPseudoDestructorExpr(Scope S, Expr Base, SourceLocation OpLoc, tok::TokenKind OpKind, SourceLocation TildeLoc, const DeclSpec& DS); /// MaybeCreateExprWithCleanups - If the current full-expression /// requires any cleanups, surround it with a ExprWithCleanups node. /// Otherwise, just returns the passed-in expression. Expr MaybeCreateExprWithCleanups(Expr SubExpr); Stmt MaybeCreateStmtWithCleanups(Stmt SubStmt); ExprResult MaybeCreateExprWithCleanups(ExprResult SubExpr); MaterializeTemporaryExpr CreateMaterializeTemporaryExpr(QualType T, Expr Temporary, bool BoundToLvalueReference); ExprResult ActOnFinishFullExpr(Expr Expr, bool DiscardedValue) { return ActOnFinishFullExpr( Expr, Expr ? Expr->getExprLoc() : SourceLocation(), DiscardedValue); } ExprResult ActOnFinishFullExpr(Expr Expr, SourceLocation CC, bool DiscardedValue, bool IsConstexpr = false); StmtResult ActOnFinishFullStmt(Stmt Stmt); // Marks SS invalid if it represents an incomplete type. bool RequireCompleteDeclContext(CXXScopeSpec &SS, DeclContext DC); // Complete an enum decl, maybe without a scope spec. bool RequireCompleteEnumDecl(EnumDecl D, SourceLocation L, CXXScopeSpec SS = nullptr); DeclContext computeDeclContext(QualType T); DeclContext computeDeclContext(const CXXScopeSpec &SS, bool EnteringContext = false); bool isDependentScopeSpecifier(const CXXScopeSpec &SS); CXXRecordDecl getCurrentInstantiationOf(NestedNameSpecifier NNS); /// The parser has parsed a global nested-name-specifier '::'. /// /// \param CCLoc The location of the '::'. /// /// \param SS The nested-name-specifier, which will be updated in-place /// to reflect the parsed nested-name-specifier. /// /// \returns true if an error occurred, false otherwise. bool ActOnCXXGlobalScopeSpecifier(SourceLocation CCLoc, CXXScopeSpec &SS); /// The parser has parsed a '__super' nested-name-specifier. /// /// \param SuperLoc The location of the '__super' keyword. /// /// \param ColonColonLoc The location of the '::'. /// /// \param SS The nested-name-specifier, which will be updated in-place /// to reflect the parsed nested-name-specifier. /// /// \returns true if an error occurred, false otherwise. bool ActOnSuperScopeSpecifier(SourceLocation SuperLoc, SourceLocation ColonColonLoc, CXXScopeSpec &SS); bool isAcceptableNestedNameSpecifier(const NamedDecl SD, bool CanCorrect = nullptr); NamedDecl FindFirstQualifierInScope(Scope S, NestedNameSpecifier NNS); /// Keeps information about an identifier in a nested-name-spec. /// struct NestedNameSpecInfo { /// The type of the object, if we're parsing nested-name-specifier in /// a member access expression. ParsedType ObjectType; /// The identifier preceding the '::'. IdentifierInfo Identifier; /// The location of the identifier. SourceLocation IdentifierLoc; /// The location of the '::'. SourceLocation CCLoc; /// Creates info object for the most typical case. NestedNameSpecInfo(IdentifierInfo II, SourceLocation IdLoc, SourceLocation ColonColonLoc, ParsedType ObjectType = ParsedType()) : ObjectType(ObjectType), Identifier(II), IdentifierLoc(IdLoc), CCLoc(ColonColonLoc) { } NestedNameSpecInfo(IdentifierInfo II, SourceLocation IdLoc, SourceLocation ColonColonLoc, QualType ObjectType) : ObjectType(ParsedType::make(ObjectType)), Identifier(II), IdentifierLoc(IdLoc), CCLoc(ColonColonLoc) { } }; bool isNonTypeNestedNameSpecifier(Scope S, CXXScopeSpec &SS, NestedNameSpecInfo &IdInfo); bool BuildCXXNestedNameSpecifier(Scope S, NestedNameSpecInfo &IdInfo, bool EnteringContext, CXXScopeSpec &SS, NamedDecl ScopeLookupResult, bool ErrorRecoveryLookup, bool IsCorrectedToColon = nullptr, bool OnlyNamespace = false); /// The parser has parsed a nested-name-specifier 'identifier::'. /// /// \param S The scope in which this nested-name-specifier occurs. /// /// \param IdInfo Parser information about an identifier in the /// nested-name-spec. /// /// \param EnteringContext Whether we're entering the context nominated by /// this nested-name-specifier. /// /// \param SS The nested-name-specifier, which is both an input /// parameter (the nested-name-specifier before this type) and an /// output parameter (containing the full nested-name-specifier, /// including this new type). /// /// \param ErrorRecoveryLookup If true, then this method is called to improve /// error recovery. In this case do not emit error message. /// /// \param IsCorrectedToColon If not null, suggestions to replace '::' -> ':' /// are allowed. The bool value pointed by this parameter is set to 'true' /// if the identifier is treated as if it was followed by ':', not '::'. /// /// \param OnlyNamespace If true, only considers namespaces in lookup. /// /// \returns true if an error occurred, false otherwise. bool ActOnCXXNestedNameSpecifier(Scope S, NestedNameSpecInfo &IdInfo, bool EnteringContext, CXXScopeSpec &SS, bool ErrorRecoveryLookup = false, bool IsCorrectedToColon = nullptr, bool OnlyNamespace = false); ExprResult ActOnDecltypeExpression(Expr E); bool ActOnCXXNestedNameSpecifierDecltype(CXXScopeSpec &SS, const DeclSpec &DS, SourceLocation ColonColonLoc); bool IsInvalidUnlessNestedName(Scope S, CXXScopeSpec &SS, NestedNameSpecInfo &IdInfo, bool EnteringContext); /// The parser has parsed a nested-name-specifier /// 'template[opt] template-name < template-args >::'. /// /// \param S The scope in which this nested-name-specifier occurs. /// /// \param SS The nested-name-specifier, which is both an input /// parameter (the nested-name-specifier before this type) and an /// output parameter (containing the full nested-name-specifier, /// including this new type). /// /// \param TemplateKWLoc the location of the 'template' keyword, if any. /// \param TemplateName the template name. /// \param TemplateNameLoc The location of the template name. /// \param LAngleLoc The location of the opening angle bracket ('<'). /// \param TemplateArgs The template arguments. /// \param RAngleLoc The location of the closing angle bracket ('>'). /// \param CCLoc The location of the '::'. /// /// \param EnteringContext Whether we're entering the context of the /// nested-name-specifier. /// /// /// \returns true if an error occurred, false otherwise. bool ActOnCXXNestedNameSpecifier(Scope S, CXXScopeSpec &SS, SourceLocation TemplateKWLoc, TemplateTy TemplateName, SourceLocation TemplateNameLoc, SourceLocation LAngleLoc, ASTTemplateArgsPtr TemplateArgs, SourceLocation RAngleLoc, SourceLocation CCLoc, bool EnteringContext); /// Given a C++ nested-name-specifier, produce an annotation value /// that the parser can use later to reconstruct the given /// nested-name-specifier. /// /// \param SS A nested-name-specifier. /// /// \returns A pointer containing all of the information in the /// nested-name-specifier \p SS. void SaveNestedNameSpecifierAnnotation(CXXScopeSpec &SS); /// Given an annotation pointer for a nested-name-specifier, restore /// the nested-name-specifier structure. /// /// \param Annotation The annotation pointer, produced by /// \c SaveNestedNameSpecifierAnnotation(). /// /// \param AnnotationRange The source range corresponding to the annotation. /// /// \param SS The nested-name-specifier that will be updated with the contents /// of the annotation pointer. void RestoreNestedNameSpecifierAnnotation(void Annotation, SourceRange AnnotationRange, CXXScopeSpec &SS); bool ShouldEnterDeclaratorScope(Scope S, const CXXScopeSpec &SS); /// ActOnCXXEnterDeclaratorScope - Called when a C++ scope specifier (global /// scope or nested-name-specifier) is parsed, part of a declarator-id. /// After this method is called, according to [C++ 3.4.3p3], names should be /// looked up in the declarator-id's scope, until the declarator is parsed and /// ActOnCXXExitDeclaratorScope is called. /// The 'SS' should be a non-empty valid CXXScopeSpec. bool ActOnCXXEnterDeclaratorScope(Scope S, CXXScopeSpec &SS); /// ActOnCXXExitDeclaratorScope - Called when a declarator that previously /// invoked ActOnCXXEnterDeclaratorScope(), is finished. 'SS' is the same /// CXXScopeSpec that was passed to ActOnCXXEnterDeclaratorScope as well. /// Used to indicate that names should revert to being looked up in the /// defining scope. void ActOnCXXExitDeclaratorScope(Scope S, const CXXScopeSpec &SS); /// ActOnCXXEnterDeclInitializer - Invoked when we are about to parse an /// initializer for the declaration 'Dcl'. /// After this method is called, according to [C++ 3.4.1p13], if 'Dcl' is a /// static data member of class X, names should be looked up in the scope of /// class X. void ActOnCXXEnterDeclInitializer(Scope S, Decl Dcl); /// ActOnCXXExitDeclInitializer - Invoked after we are finished parsing an /// initializer for the declaration 'Dcl'. void ActOnCXXExitDeclInitializer(Scope S, Decl Dcl); /// Create a new lambda closure type. CXXRecordDecl createLambdaClosureType(SourceRange IntroducerRange, TypeSourceInfo Info, bool KnownDependent, LambdaCaptureDefault CaptureDefault); /// Start the definition of a lambda expression. CXXMethodDecl startLambdaDefinition(CXXRecordDecl Class, SourceRange IntroducerRange, TypeSourceInfo MethodType, SourceLocation EndLoc, ArrayRef<ParmVarDecl > Params, ConstexprSpecKind ConstexprKind, Expr TrailingRequiresClause); /// Number lambda for linkage purposes if necessary. void handleLambdaNumbering( CXXRecordDecl Class, CXXMethodDecl Method, Optional<std::tuple<bool, unsigned, unsigned, Decl >> Mangling = None); /// Endow the lambda scope info with the relevant properties. void buildLambdaScope(sema::LambdaScopeInfo LSI, CXXMethodDecl CallOperator, SourceRange IntroducerRange, LambdaCaptureDefault CaptureDefault, SourceLocation CaptureDefaultLoc, bool ExplicitParams, bool ExplicitResultType, bool Mutable); /// Perform initialization analysis of the init-capture and perform /// any implicit conversions such as an lvalue-to-rvalue conversion if /// not being used to initialize a reference. ParsedType actOnLambdaInitCaptureInitialization( SourceLocation Loc, bool ByRef, SourceLocation EllipsisLoc, IdentifierInfo Id, LambdaCaptureInitKind InitKind, Expr &Init) { return ParsedType::make(buildLambdaInitCaptureInitialization( Loc, ByRef, EllipsisLoc, None, Id, InitKind != LambdaCaptureInitKind::CopyInit, Init)); } QualType buildLambdaInitCaptureInitialization( SourceLocation Loc, bool ByRef, SourceLocation EllipsisLoc, Optional<unsigned> NumExpansions, IdentifierInfo Id, bool DirectInit, Expr &Init); /// Create a dummy variable within the declcontext of the lambda's /// call operator, for name lookup purposes for a lambda init capture. /// /// CodeGen handles emission of lambda captures, ignoring these dummy /// variables appropriately. VarDecl createLambdaInitCaptureVarDecl(SourceLocation Loc, QualType InitCaptureType, SourceLocation EllipsisLoc, IdentifierInfo Id, unsigned InitStyle, Expr Init); /// Add an init-capture to a lambda scope. void addInitCapture(sema::LambdaScopeInfo LSI, VarDecl Var); /// Note that we have finished the explicit captures for the /// given lambda. void finishLambdaExplicitCaptures(sema::LambdaScopeInfo LSI); /// \brief This is called after parsing the explicit template parameter list /// on a lambda (if it exists) in C++2a. void ActOnLambdaExplicitTemplateParameterList(SourceLocation LAngleLoc, ArrayRef<NamedDecl > TParams, SourceLocation RAngleLoc, ExprResult RequiresClause); /// Introduce the lambda parameters into scope. void addLambdaParameters( ArrayRef<LambdaIntroducer::LambdaCapture> Captures, CXXMethodDecl CallOperator, Scope CurScope); /// Deduce a block or lambda's return type based on the return /// statements present in the body. void deduceClosureReturnType(sema::CapturingScopeInfo &CSI); /// ActOnStartOfLambdaDefinition - This is called just before we start /// parsing the body of a lambda; it analyzes the explicit captures and /// arguments, and sets up various data-structures for the body of the /// lambda. void ActOnStartOfLambdaDefinition(LambdaIntroducer &Intro, Declarator &ParamInfo, Scope CurScope); /// ActOnLambdaError - If there is an error parsing a lambda, this callback /// is invoked to pop the information about the lambda. void ActOnLambdaError(SourceLocation StartLoc, Scope CurScope, bool IsInstantiation = false); /// ActOnLambdaExpr - This is called when the body of a lambda expression /// was successfully completed. ExprResult ActOnLambdaExpr(SourceLocation StartLoc, Stmt Body, Scope CurScope); /// Does copying/destroying the captured variable have side effects? bool CaptureHasSideEffects(const sema::Capture &From); /// Diagnose if an explicit lambda capture is unused. Returns true if a /// diagnostic is emitted. bool DiagnoseUnusedLambdaCapture(SourceRange CaptureRange, const sema::Capture &From); /// Build a FieldDecl suitable to hold the given capture. FieldDecl BuildCaptureField(RecordDecl RD, const sema::Capture &Capture); /// Initialize the given capture with a suitable expression. ExprResult BuildCaptureInit(const sema::Capture &Capture, SourceLocation ImplicitCaptureLoc, bool IsOpenMPMapping = false); /// Complete a lambda-expression having processed and attached the /// lambda body. ExprResult BuildLambdaExpr(SourceLocation StartLoc, SourceLocation EndLoc, sema::LambdaScopeInfo LSI); /// Get the return type to use for a lambda's conversion function(s) to /// function pointer type, given the type of the call operator. QualType getLambdaConversionFunctionResultType(const FunctionProtoType CallOpType, CallingConv CC); /// Define the "body" of the conversion from a lambda object to a /// function pointer. /// /// This routine doesn't actually define a sensible body; rather, it fills /// in the initialization expression needed to copy the lambda object into /// the block, and IR generation actually generates the real body of the /// block pointer conversion. void DefineImplicitLambdaToFunctionPointerConversion( SourceLocation CurrentLoc, CXXConversionDecl Conv); /// Define the "body" of the conversion from a lambda object to a /// block pointer. /// /// This routine doesn't actually define a sensible body; rather, it fills /// in the initialization expression needed to copy the lambda object into /// the block, and IR generation actually generates the real body of the /// block pointer conversion. void DefineImplicitLambdaToBlockPointerConversion(SourceLocation CurrentLoc, CXXConversionDecl Conv); ExprResult BuildBlockForLambdaConversion(SourceLocation CurrentLocation, SourceLocation ConvLocation, CXXConversionDecl Conv, Expr Src); /// Check whether the given expression is a valid constraint expression. /// A diagnostic is emitted if it is not, false is returned, and /// PossibleNonPrimary will be set to true if the failure might be due to a /// non-primary expression being used as an atomic constraint. bool CheckConstraintExpression(const Expr CE, Token NextToken = Token(), bool PossibleNonPrimary = nullptr, bool IsTrailingRequiresClause = false); private: /// Caches pairs of template-like decls whose associated constraints were /// checked for subsumption and whether or not the first's constraints did in /// fact subsume the second's. llvm::DenseMap<std::pair<NamedDecl , NamedDecl >, bool> SubsumptionCache; /// Caches the normalized associated constraints of declarations (concepts or /// constrained declarations). If an error occurred while normalizing the /// associated constraints of the template or concept, nullptr will be cached /// here. llvm::DenseMap<NamedDecl , NormalizedConstraint > NormalizationCache; llvm::ContextualFoldingSet<ConstraintSatisfaction, const ASTContext &> SatisfactionCache; public: const NormalizedConstraint * getNormalizedAssociatedConstraints( NamedDecl ConstrainedDecl, ArrayRef<const Expr > AssociatedConstraints); /// \brief Check whether the given declaration's associated constraints are /// at least as constrained than another declaration's according to the /// partial ordering of constraints. /// /// \param Result If no error occurred, receives the result of true if D1 is /// at least constrained than D2, and false otherwise. /// /// \returns true if an error occurred, false otherwise. bool IsAtLeastAsConstrained(NamedDecl D1, ArrayRef<const Expr > AC1, NamedDecl D2, ArrayRef<const Expr > AC2, bool &Result); /// If D1 was not at least as constrained as D2, but would've been if a pair /// of atomic constraints involved had been declared in a concept and not /// repeated in two separate places in code. /// \returns true if such a diagnostic was emitted, false otherwise. bool MaybeEmitAmbiguousAtomicConstraintsDiagnostic(NamedDecl D1, ArrayRef<const Expr > AC1, NamedDecl D2, ArrayRef<const Expr > AC2); /// \brief Check whether the given list of constraint expressions are /// satisfied (as if in a 'conjunction') given template arguments. /// \param Template the template-like entity that triggered the constraints /// check (either a concept or a constrained entity). /// \param ConstraintExprs a list of constraint expressions, treated as if /// they were 'AND'ed together. /// \param TemplateArgs the list of template arguments to substitute into the /// constraint expression. /// \param TemplateIDRange The source range of the template id that /// caused the constraints check. /// \param Satisfaction if true is returned, will contain details of the /// satisfaction, with enough information to diagnose an unsatisfied /// expression. /// \returns true if an error occurred and satisfaction could not be checked, /// false otherwise. bool CheckConstraintSatisfaction( const NamedDecl Template, ArrayRef<const Expr > ConstraintExprs, ArrayRef<TemplateArgument> TemplateArgs, SourceRange TemplateIDRange, ConstraintSatisfaction &Satisfaction); /// \brief Check whether the given non-dependent constraint expression is /// satisfied. Returns false and updates Satisfaction with the satisfaction /// verdict if successful, emits a diagnostic and returns true if an error /// occured and satisfaction could not be determined. /// /// \returns true if an error occurred, false otherwise. bool CheckConstraintSatisfaction(const Expr ConstraintExpr, ConstraintSatisfaction &Satisfaction); /// Check whether the given function decl's trailing requires clause is /// satisfied, if any. Returns false and updates Satisfaction with the /// satisfaction verdict if successful, emits a diagnostic and returns true if /// an error occured and satisfaction could not be determined. /// /// \returns true if an error occurred, false otherwise. bool CheckFunctionConstraints(const FunctionDecl FD, ConstraintSatisfaction &Satisfaction, SourceLocation UsageLoc = SourceLocation()); /// \brief Ensure that the given template arguments satisfy the constraints /// associated with the given template, emitting a diagnostic if they do not. /// /// \param Template The template to which the template arguments are being /// provided. /// /// \param TemplateArgs The converted, canonicalized template arguments. /// /// \param TemplateIDRange The source range of the template id that /// caused the constraints check. /// /// \returns true if the constrains are not satisfied or could not be checked /// for satisfaction, false if the constraints are satisfied. bool EnsureTemplateArgumentListConstraints(TemplateDecl Template, ArrayRef<TemplateArgument> TemplateArgs, SourceRange TemplateIDRange); /// \brief Emit diagnostics explaining why a constraint expression was deemed /// unsatisfied. /// \param First whether this is the first time an unsatisfied constraint is /// diagnosed for this error. void DiagnoseUnsatisfiedConstraint(const ConstraintSatisfaction &Satisfaction, bool First = true); /// \brief Emit diagnostics explaining why a constraint expression was deemed /// unsatisfied. void DiagnoseUnsatisfiedConstraint(const ASTConstraintSatisfaction &Satisfaction, bool First = true); // ParseObjCStringLiteral - Parse Objective-C string literals. ExprResult ParseObjCStringLiteral(SourceLocation AtLocs, ArrayRef<Expr > Strings); ExprResult BuildObjCStringLiteral(SourceLocation AtLoc, StringLiteral S); /// BuildObjCNumericLiteral - builds an ObjCBoxedExpr AST node for the /// numeric literal expression. Type of the expression will be "NSNumber " /// or "id" if NSNumber is unavailable. ExprResult BuildObjCNumericLiteral(SourceLocation AtLoc, Expr Number); ExprResult ActOnObjCBoolLiteral(SourceLocation AtLoc, SourceLocation ValueLoc, bool Value); ExprResult BuildObjCArrayLiteral(SourceRange SR, MultiExprArg Elements); /// BuildObjCBoxedExpr - builds an ObjCBoxedExpr AST node for the /// '@' prefixed parenthesized expression. The type of the expression will /// either be "NSNumber ", "NSString " or "NSValue " depending on the type /// of ValueType, which is allowed to be a built-in numeric type, "char ", /// "const char " or C structure with attribute 'objc_boxable'. ExprResult BuildObjCBoxedExpr(SourceRange SR, Expr ValueExpr); ExprResult BuildObjCSubscriptExpression(SourceLocation RB, Expr BaseExpr, Expr IndexExpr, ObjCMethodDecl getterMethod, ObjCMethodDecl setterMethod); ExprResult BuildObjCDictionaryLiteral(SourceRange SR, MutableArrayRef<ObjCDictionaryElement> Elements); ExprResult BuildObjCEncodeExpression(SourceLocation AtLoc, TypeSourceInfo EncodedTypeInfo, SourceLocation RParenLoc); ExprResult BuildCXXMemberCallExpr(Expr Exp, NamedDecl FoundDecl, CXXConversionDecl Method, bool HadMultipleCandidates); ExprResult ParseObjCEncodeExpression(SourceLocation AtLoc, SourceLocation EncodeLoc, SourceLocation LParenLoc, ParsedType Ty, SourceLocation RParenLoc); /// ParseObjCSelectorExpression - Build selector expression for \@selector ExprResult ParseObjCSelectorExpression(Selector Sel, SourceLocation AtLoc, SourceLocation SelLoc, SourceLocation LParenLoc, SourceLocation RParenLoc, bool WarnMultipleSelectors); /// ParseObjCProtocolExpression - Build protocol expression for \@protocol ExprResult ParseObjCProtocolExpression(IdentifierInfo * ProtocolName, SourceLocation AtLoc, SourceLocation ProtoLoc, SourceLocation LParenLoc, SourceLocation ProtoIdLoc, SourceLocation RParenLoc); //===--------------------------------------------------------------------===// // C++ Declarations // Decl ActOnStartLinkageSpecification(Scope S, SourceLocation ExternLoc, Expr LangStr, SourceLocation LBraceLoc); Decl ActOnFinishLinkageSpecification(Scope S, Decl LinkageSpec, SourceLocation RBraceLoc); //===--------------------------------------------------------------------===// // C++ Classes // CXXRecordDecl getCurrentClass(Scope S, const CXXScopeSpec SS); bool isCurrentClassName(const IdentifierInfo &II, Scope S, const CXXScopeSpec SS = nullptr); bool isCurrentClassNameTypo(IdentifierInfo &II, const CXXScopeSpec SS); bool ActOnAccessSpecifier(AccessSpecifier Access, SourceLocation ASLoc, SourceLocation ColonLoc, const ParsedAttributesView &Attrs); NamedDecl ActOnCXXMemberDeclarator(Scope S, AccessSpecifier AS, Declarator &D, MultiTemplateParamsArg TemplateParameterLists, Expr BitfieldWidth, const VirtSpecifiers &VS, InClassInitStyle InitStyle); void ActOnStartCXXInClassMemberInitializer(); void ActOnFinishCXXInClassMemberInitializer(Decl VarDecl, SourceLocation EqualLoc, Expr Init); MemInitResult ActOnMemInitializer(Decl ConstructorD, Scope S, CXXScopeSpec &SS, IdentifierInfo MemberOrBase, ParsedType TemplateTypeTy, const DeclSpec &DS, SourceLocation IdLoc, SourceLocation LParenLoc, ArrayRef<Expr > Args, SourceLocation RParenLoc, SourceLocation EllipsisLoc); MemInitResult ActOnMemInitializer(Decl ConstructorD, Scope S, CXXScopeSpec &SS, IdentifierInfo MemberOrBase, ParsedType TemplateTypeTy, const DeclSpec &DS, SourceLocation IdLoc, Expr InitList, SourceLocation EllipsisLoc); MemInitResult BuildMemInitializer(Decl ConstructorD, Scope S, CXXScopeSpec &SS, IdentifierInfo MemberOrBase, ParsedType TemplateTypeTy, const DeclSpec &DS, SourceLocation IdLoc, Expr Init, SourceLocation EllipsisLoc); MemInitResult BuildMemberInitializer(ValueDecl Member, Expr Init, SourceLocation IdLoc); MemInitResult BuildBaseInitializer(QualType BaseType, TypeSourceInfo BaseTInfo, Expr Init, CXXRecordDecl ClassDecl, SourceLocation EllipsisLoc); MemInitResult BuildDelegatingInitializer(TypeSourceInfo TInfo, Expr Init, CXXRecordDecl ClassDecl); bool SetDelegatingInitializer(CXXConstructorDecl Constructor, CXXCtorInitializer Initializer); bool SetCtorInitializers(CXXConstructorDecl Constructor, bool AnyErrors, ArrayRef<CXXCtorInitializer > Initializers = None); void SetIvarInitializers(ObjCImplementationDecl ObjCImplementation); /// MarkBaseAndMemberDestructorsReferenced - Given a record decl, /// mark all the non-trivial destructors of its members and bases as /// referenced. void MarkBaseAndMemberDestructorsReferenced(SourceLocation Loc, CXXRecordDecl Record); /// Mark destructors of virtual bases of this class referenced. In the Itanium /// C++ ABI, this is done when emitting a destructor for any non-abstract /// class. In the Microsoft C++ ABI, this is done any time a class's /// destructor is referenced. void MarkVirtualBaseDestructorsReferenced( SourceLocation Location, CXXRecordDecl ClassDecl, llvm::SmallPtrSetImpl<const RecordType > DirectVirtualBases = nullptr); /// Do semantic checks to allow the complete destructor variant to be emitted /// when the destructor is defined in another translation unit. In the Itanium /// C++ ABI, destructor variants are emitted together. In the MS C++ ABI, they /// can be emitted in separate TUs. To emit the complete variant, run a subset /// of the checks performed when emitting a regular destructor. void CheckCompleteDestructorVariant(SourceLocation CurrentLocation, CXXDestructorDecl Dtor); /// The list of classes whose vtables have been used within /// this translation unit, and the source locations at which the /// first use occurred. typedef std::pair<CXXRecordDecl, SourceLocation> VTableUse; /// The list of vtables that are required but have not yet been /// materialized. SmallVector<VTableUse, 16> VTableUses; /// The set of classes whose vtables have been used within /// this translation unit, and a bit that will be true if the vtable is /// required to be emitted (otherwise, it should be emitted only if needed /// by code generation). llvm::DenseMap<CXXRecordDecl , bool> VTablesUsed; /// Load any externally-stored vtable uses. void LoadExternalVTableUses(); /// Note that the vtable for the given class was used at the /// given location. void MarkVTableUsed(SourceLocation Loc, CXXRecordDecl Class, bool DefinitionRequired = false); /// Mark the exception specifications of all virtual member functions /// in the given class as needed. void MarkVirtualMemberExceptionSpecsNeeded(SourceLocation Loc, const CXXRecordDecl RD); /// MarkVirtualMembersReferenced - Will mark all members of the given /// CXXRecordDecl referenced. void MarkVirtualMembersReferenced(SourceLocation Loc, const CXXRecordDecl RD, bool ConstexprOnly = false); /// Define all of the vtables that have been used in this /// translation unit and reference any virtual members used by those /// vtables. /// /// \returns true if any work was done, false otherwise. bool DefineUsedVTables(); void AddImplicitlyDeclaredMembersToClass(CXXRecordDecl ClassDecl); void ActOnMemInitializers(Decl ConstructorDecl, SourceLocation ColonLoc, ArrayRef<CXXCtorInitializer> MemInits, bool AnyErrors); /// Check class-level dllimport/dllexport attribute. The caller must /// ensure that referenceDLLExportedClassMethods is called some point later /// when all outer classes of Class are complete. void checkClassLevelDLLAttribute(CXXRecordDecl Class); void checkClassLevelCodeSegAttribute(CXXRecordDecl Class); void referenceDLLExportedClassMethods(); void propagateDLLAttrToBaseClassTemplate( CXXRecordDecl Class, Attr ClassAttr, ClassTemplateSpecializationDecl BaseTemplateSpec, SourceLocation BaseLoc); /// Add gsl::Pointer attribute to std::container::iterator /// \param ND The declaration that introduces the name /// std::container::iterator. \param UnderlyingRecord The record named by ND. void inferGslPointerAttribute(NamedDecl ND, CXXRecordDecl UnderlyingRecord); /// Add [[gsl::Owner]] and [[gsl::Pointer]] attributes for std:: types. void inferGslOwnerPointerAttribute(CXXRecordDecl Record); /// Add [[gsl::Pointer]] attributes for std:: types. void inferGslPointerAttribute(TypedefNameDecl TD); void CheckCompletedCXXClass(Scope S, CXXRecordDecl Record); /// Check that the C++ class annoated with "trivial_abi" satisfies all the /// conditions that are needed for the attribute to have an effect. void checkIllFormedTrivialABIStruct(CXXRecordDecl &RD); void ActOnFinishCXXMemberSpecification(Scope S, SourceLocation RLoc, Decl TagDecl, SourceLocation LBrac, SourceLocation RBrac, const ParsedAttributesView &AttrList); void ActOnFinishCXXMemberDecls(); void ActOnFinishCXXNonNestedClass(); void ActOnReenterCXXMethodParameter(Scope S, ParmVarDecl Param); unsigned ActOnReenterTemplateScope(Decl Template, llvm::function_ref<Scope ()> EnterScope); void ActOnStartDelayedMemberDeclarations(Scope S, Decl Record); void ActOnStartDelayedCXXMethodDeclaration(Scope S, Decl Method); void ActOnDelayedCXXMethodParameter(Scope S, Decl Param); void ActOnFinishDelayedMemberDeclarations(Scope S, Decl Record); void ActOnFinishDelayedCXXMethodDeclaration(Scope S, Decl Method); void ActOnFinishDelayedMemberInitializers(Decl Record); void MarkAsLateParsedTemplate(FunctionDecl FD, Decl FnD, CachedTokens &Toks); void UnmarkAsLateParsedTemplate(FunctionDecl FD); bool IsInsideALocalClassWithinATemplateFunction(); Decl ActOnStaticAssertDeclaration(SourceLocation StaticAssertLoc, Expr AssertExpr, Expr AssertMessageExpr, SourceLocation RParenLoc); Decl BuildStaticAssertDeclaration(SourceLocation StaticAssertLoc, Expr AssertExpr, StringLiteral AssertMessageExpr, SourceLocation RParenLoc, bool Failed); FriendDecl CheckFriendTypeDecl(SourceLocation LocStart, SourceLocation FriendLoc, TypeSourceInfo TSInfo); Decl ActOnFriendTypeDecl(Scope S, const DeclSpec &DS, MultiTemplateParamsArg TemplateParams); NamedDecl ActOnFriendFunctionDecl(Scope S, Declarator &D, MultiTemplateParamsArg TemplateParams); QualType CheckConstructorDeclarator(Declarator &D, QualType R, StorageClass& SC); void CheckConstructor(CXXConstructorDecl Constructor); QualType CheckDestructorDeclarator(Declarator &D, QualType R, StorageClass& SC); bool CheckDestructor(CXXDestructorDecl Destructor); void CheckConversionDeclarator(Declarator &D, QualType &R, StorageClass& SC); Decl ActOnConversionDeclarator(CXXConversionDecl Conversion); void CheckDeductionGuideDeclarator(Declarator &D, QualType &R, StorageClass &SC); void CheckDeductionGuideTemplate(FunctionTemplateDecl TD); void CheckExplicitlyDefaultedFunction(Scope S, FunctionDecl MD); bool CheckExplicitlyDefaultedSpecialMember(CXXMethodDecl MD, CXXSpecialMember CSM); void CheckDelayedMemberExceptionSpecs(); bool CheckExplicitlyDefaultedComparison(Scope S, FunctionDecl MD, DefaultedComparisonKind DCK); void DeclareImplicitEqualityComparison(CXXRecordDecl RD, FunctionDecl Spaceship); void DefineDefaultedComparison(SourceLocation Loc, FunctionDecl FD, DefaultedComparisonKind DCK); //===--------------------------------------------------------------------===// // C++ Derived Classes // /// ActOnBaseSpecifier - Parsed a base specifier CXXBaseSpecifier CheckBaseSpecifier(CXXRecordDecl Class, SourceRange SpecifierRange, bool Virtual, AccessSpecifier Access, TypeSourceInfo TInfo, SourceLocation EllipsisLoc); BaseResult ActOnBaseSpecifier(Decl classdecl, SourceRange SpecifierRange, ParsedAttributes &Attrs, bool Virtual, AccessSpecifier Access, ParsedType basetype, SourceLocation BaseLoc, SourceLocation EllipsisLoc); bool AttachBaseSpecifiers(CXXRecordDecl Class, MutableArrayRef<CXXBaseSpecifier > Bases); void ActOnBaseSpecifiers(Decl ClassDecl, MutableArrayRef<CXXBaseSpecifier > Bases); bool IsDerivedFrom(SourceLocation Loc, QualType Derived, QualType Base); bool IsDerivedFrom(SourceLocation Loc, QualType Derived, QualType Base, CXXBasePaths &Paths); // FIXME: I don't like this name. void BuildBasePathArray(const CXXBasePaths &Paths, CXXCastPath &BasePath); bool CheckDerivedToBaseConversion(QualType Derived, QualType Base, SourceLocation Loc, SourceRange Range, CXXCastPath BasePath = nullptr, bool IgnoreAccess = false); bool CheckDerivedToBaseConversion(QualType Derived, QualType Base, unsigned InaccessibleBaseID, unsigned AmbiguousBaseConvID, SourceLocation Loc, SourceRange Range, DeclarationName Name, CXXCastPath BasePath, bool IgnoreAccess = false); std::string getAmbiguousPathsDisplayString(CXXBasePaths &Paths); bool CheckOverridingFunctionAttributes(const CXXMethodDecl New, const CXXMethodDecl Old); /// CheckOverridingFunctionReturnType - Checks whether the return types are /// covariant, according to C++ [class.virtual]p5. bool CheckOverridingFunctionReturnType(const CXXMethodDecl New, const CXXMethodDecl Old); /// CheckOverridingFunctionExceptionSpec - Checks whether the exception /// spec is a subset of base spec. bool CheckOverridingFunctionExceptionSpec(const CXXMethodDecl New, const CXXMethodDecl Old); bool CheckPureMethod(CXXMethodDecl Method, SourceRange InitRange); /// CheckOverrideControl - Check C++11 override control semantics. void CheckOverrideControl(NamedDecl D); /// DiagnoseAbsenceOfOverrideControl - Diagnose if 'override' keyword was /// not used in the declaration of an overriding method. void DiagnoseAbsenceOfOverrideControl(NamedDecl D, bool Inconsistent); /// CheckForFunctionMarkedFinal - Checks whether a virtual member function /// overrides a virtual member function marked 'final', according to /// C++11 [class.virtual]p4. bool CheckIfOverriddenFunctionIsMarkedFinal(const CXXMethodDecl New, const CXXMethodDecl Old); //===--------------------------------------------------------------------===// // C++ Access Control // enum AccessResult { AR_accessible, AR_inaccessible, AR_dependent, AR_delayed }; bool SetMemberAccessSpecifier(NamedDecl MemberDecl, NamedDecl PrevMemberDecl, AccessSpecifier LexicalAS); AccessResult CheckUnresolvedMemberAccess(UnresolvedMemberExpr E, DeclAccessPair FoundDecl); AccessResult CheckUnresolvedLookupAccess(UnresolvedLookupExpr E, DeclAccessPair FoundDecl); AccessResult CheckAllocationAccess(SourceLocation OperatorLoc, SourceRange PlacementRange, CXXRecordDecl NamingClass, DeclAccessPair FoundDecl, bool Diagnose = true); AccessResult CheckConstructorAccess(SourceLocation Loc, CXXConstructorDecl D, DeclAccessPair FoundDecl, const InitializedEntity &Entity, bool IsCopyBindingRefToTemp = false); AccessResult CheckConstructorAccess(SourceLocation Loc, CXXConstructorDecl D, DeclAccessPair FoundDecl, const InitializedEntity &Entity, const PartialDiagnostic &PDiag); AccessResult CheckDestructorAccess(SourceLocation Loc, CXXDestructorDecl Dtor, const PartialDiagnostic &PDiag, QualType objectType = QualType()); AccessResult CheckFriendAccess(NamedDecl D); AccessResult CheckMemberAccess(SourceLocation UseLoc, CXXRecordDecl NamingClass, DeclAccessPair Found); AccessResult CheckStructuredBindingMemberAccess(SourceLocation UseLoc, CXXRecordDecl DecomposedClass, DeclAccessPair Field); AccessResult CheckMemberOperatorAccess(SourceLocation Loc, Expr ObjectExpr, Expr ArgExpr, DeclAccessPair FoundDecl); AccessResult CheckAddressOfMemberAccess(Expr OvlExpr, DeclAccessPair FoundDecl); AccessResult CheckBaseClassAccess(SourceLocation AccessLoc, QualType Base, QualType Derived, const CXXBasePath &Path, unsigned DiagID, bool ForceCheck = false, bool ForceUnprivileged = false); void CheckLookupAccess(const LookupResult &R); bool IsSimplyAccessible(NamedDecl Decl, CXXRecordDecl NamingClass, QualType BaseType); bool isMemberAccessibleForDeletion(CXXRecordDecl NamingClass, DeclAccessPair Found, QualType ObjectType, SourceLocation Loc, const PartialDiagnostic &Diag); bool isMemberAccessibleForDeletion(CXXRecordDecl NamingClass, DeclAccessPair Found, QualType ObjectType) { return isMemberAccessibleForDeletion(NamingClass, Found, ObjectType, SourceLocation(), PDiag()); } void HandleDependentAccessCheck(const DependentDiagnostic &DD, const MultiLevelTemplateArgumentList &TemplateArgs); void PerformDependentDiagnostics(const DeclContext Pattern, const MultiLevelTemplateArgumentList &TemplateArgs); void HandleDelayedAccessCheck(sema::DelayedDiagnostic &DD, Decl Ctx); /// When true, access checking violations are treated as SFINAE /// failures rather than hard errors. bool AccessCheckingSFINAE; enum AbstractDiagSelID { AbstractNone = -1, AbstractReturnType, AbstractParamType, AbstractVariableType, AbstractFieldType, AbstractIvarType, AbstractSynthesizedIvarType, AbstractArrayType }; bool isAbstractType(SourceLocation Loc, QualType T); bool RequireNonAbstractType(SourceLocation Loc, QualType T, TypeDiagnoser &Diagnoser); template <typename... Ts> bool RequireNonAbstractType(SourceLocation Loc, QualType T, unsigned DiagID, const Ts &...Args) { BoundTypeDiagnoser<Ts...> Diagnoser(DiagID, Args...); return RequireNonAbstractType(Loc, T, Diagnoser); } void DiagnoseAbstractType(const CXXRecordDecl RD); //===--------------------------------------------------------------------===// // C++ Overloaded Operators [C++ 13.5] // bool CheckOverloadedOperatorDeclaration(FunctionDecl FnDecl); bool CheckLiteralOperatorDeclaration(FunctionDecl FnDecl); //===--------------------------------------------------------------------===// // C++ Templates [C++ 14] // void FilterAcceptableTemplateNames(LookupResult &R, bool AllowFunctionTemplates = true, bool AllowDependent = true); bool hasAnyAcceptableTemplateNames(LookupResult &R, bool AllowFunctionTemplates = true, bool AllowDependent = true, bool AllowNonTemplateFunctions = false); /// Try to interpret the lookup result D as a template-name. /// /// \param D A declaration found by name lookup. /// \param AllowFunctionTemplates Whether function templates should be /// considered valid results. /// \param AllowDependent Whether unresolved using declarations (that might /// name templates) should be considered valid results. static NamedDecl getAsTemplateNameDecl(NamedDecl D, bool AllowFunctionTemplates = true, bool AllowDependent = true); enum TemplateNameIsRequiredTag { TemplateNameIsRequired }; /// Whether and why a template name is required in this lookup. class RequiredTemplateKind { public: /// Template name is required if TemplateKWLoc is valid. RequiredTemplateKind(SourceLocation TemplateKWLoc = SourceLocation()) : TemplateKW(TemplateKWLoc) {} /// Template name is unconditionally required. RequiredTemplateKind(TemplateNameIsRequiredTag) : TemplateKW() {} SourceLocation getTemplateKeywordLoc() const { return TemplateKW.getValueOr(SourceLocation()); } bool hasTemplateKeyword() const { return getTemplateKeywordLoc().isValid(); } bool isRequired() const { return TemplateKW != SourceLocation(); } explicit operator bool() const { return isRequired(); } private: llvm::Optional<SourceLocation> TemplateKW; }; enum class AssumedTemplateKind { /// This is not assumed to be a template name. None, /// This is assumed to be a template name because lookup found nothing. FoundNothing, /// This is assumed to be a template name because lookup found one or more /// functions (but no function templates). FoundFunctions, }; bool LookupTemplateName( LookupResult &R, Scope S, CXXScopeSpec &SS, QualType ObjectType, bool EnteringContext, bool &MemberOfUnknownSpecialization, RequiredTemplateKind RequiredTemplate = SourceLocation(), AssumedTemplateKind ATK = nullptr, bool AllowTypoCorrection = true); TemplateNameKind isTemplateName(Scope S, CXXScopeSpec &SS, bool hasTemplateKeyword, const UnqualifiedId &Name, ParsedType ObjectType, bool EnteringContext, TemplateTy &Template, bool &MemberOfUnknownSpecialization, bool Disambiguation = false); /// Try to resolve an undeclared template name as a type template. /// /// Sets II to the identifier corresponding to the template name, and updates /// Name to a corresponding (typo-corrected) type template name and TNK to /// the corresponding kind, if possible. void ActOnUndeclaredTypeTemplateName(Scope S, TemplateTy &Name, TemplateNameKind &TNK, SourceLocation NameLoc, IdentifierInfo &II); bool resolveAssumedTemplateNameAsType(Scope S, TemplateName &Name, SourceLocation NameLoc, bool Diagnose = true); /// Determine whether a particular identifier might be the name in a C++1z /// deduction-guide declaration. bool isDeductionGuideName(Scope S, const IdentifierInfo &Name, SourceLocation NameLoc, ParsedTemplateTy Template = nullptr); bool DiagnoseUnknownTemplateName(const IdentifierInfo &II, SourceLocation IILoc, Scope S, const CXXScopeSpec SS, TemplateTy &SuggestedTemplate, TemplateNameKind &SuggestedKind); bool DiagnoseUninstantiableTemplate(SourceLocation PointOfInstantiation, NamedDecl Instantiation, bool InstantiatedFromMember, const NamedDecl Pattern, const NamedDecl PatternDef, TemplateSpecializationKind TSK, bool Complain = true); void DiagnoseTemplateParameterShadow(SourceLocation Loc, Decl PrevDecl); TemplateDecl AdjustDeclIfTemplate(Decl &Decl); NamedDecl ActOnTypeParameter(Scope S, bool Typename, SourceLocation EllipsisLoc, SourceLocation KeyLoc, IdentifierInfo ParamName, SourceLocation ParamNameLoc, unsigned Depth, unsigned Position, SourceLocation EqualLoc, ParsedType DefaultArg, bool HasTypeConstraint); bool ActOnTypeConstraint(const CXXScopeSpec &SS, TemplateIdAnnotation TypeConstraint, TemplateTypeParmDecl ConstrainedParameter, SourceLocation EllipsisLoc); bool BuildTypeConstraint(const CXXScopeSpec &SS, TemplateIdAnnotation TypeConstraint, TemplateTypeParmDecl ConstrainedParameter, SourceLocation EllipsisLoc, bool AllowUnexpandedPack); bool AttachTypeConstraint(NestedNameSpecifierLoc NS, DeclarationNameInfo NameInfo, ConceptDecl NamedConcept, const TemplateArgumentListInfo TemplateArgs, TemplateTypeParmDecl ConstrainedParameter, SourceLocation EllipsisLoc); bool AttachTypeConstraint(AutoTypeLoc TL, NonTypeTemplateParmDecl ConstrainedParameter, SourceLocation EllipsisLoc); bool RequireStructuralType(QualType T, SourceLocation Loc); QualType CheckNonTypeTemplateParameterType(TypeSourceInfo &TSI, SourceLocation Loc); QualType CheckNonTypeTemplateParameterType(QualType T, SourceLocation Loc); NamedDecl ActOnNonTypeTemplateParameter(Scope S, Declarator &D, unsigned Depth, unsigned Position, SourceLocation EqualLoc, Expr DefaultArg); NamedDecl ActOnTemplateTemplateParameter(Scope S, SourceLocation TmpLoc, TemplateParameterList Params, SourceLocation EllipsisLoc, IdentifierInfo ParamName, SourceLocation ParamNameLoc, unsigned Depth, unsigned Position, SourceLocation EqualLoc, ParsedTemplateArgument DefaultArg); TemplateParameterList ActOnTemplateParameterList(unsigned Depth, SourceLocation ExportLoc, SourceLocation TemplateLoc, SourceLocation LAngleLoc, ArrayRef<NamedDecl > Params, SourceLocation RAngleLoc, Expr RequiresClause); /// The context in which we are checking a template parameter list. enum TemplateParamListContext { TPC_ClassTemplate, TPC_VarTemplate, TPC_FunctionTemplate, TPC_ClassTemplateMember, TPC_FriendClassTemplate, TPC_FriendFunctionTemplate, TPC_FriendFunctionTemplateDefinition, TPC_TypeAliasTemplate }; bool CheckTemplateParameterList(TemplateParameterList NewParams, TemplateParameterList OldParams, TemplateParamListContext TPC, SkipBodyInfo SkipBody = nullptr); TemplateParameterList MatchTemplateParametersToScopeSpecifier( SourceLocation DeclStartLoc, SourceLocation DeclLoc, const CXXScopeSpec &SS, TemplateIdAnnotation TemplateId, ArrayRef<TemplateParameterList > ParamLists, bool IsFriend, bool &IsMemberSpecialization, bool &Invalid, bool SuppressDiagnostic = false); DeclResult CheckClassTemplate( Scope S, unsigned TagSpec, TagUseKind TUK, SourceLocation KWLoc, CXXScopeSpec &SS, IdentifierInfo Name, SourceLocation NameLoc, const ParsedAttributesView &Attr, TemplateParameterList TemplateParams, AccessSpecifier AS, SourceLocation ModulePrivateLoc, SourceLocation FriendLoc, unsigned NumOuterTemplateParamLists, TemplateParameterList OuterTemplateParamLists, SkipBodyInfo SkipBody = nullptr); TemplateArgumentLoc getTrivialTemplateArgumentLoc(const TemplateArgument &Arg, QualType NTTPType, SourceLocation Loc); /// Get a template argument mapping the given template parameter to itself, /// e.g. for X in \c template<int X>, this would return an expression template /// argument referencing X. TemplateArgumentLoc getIdentityTemplateArgumentLoc(NamedDecl Param, SourceLocation Location); void translateTemplateArguments(const ASTTemplateArgsPtr &In, TemplateArgumentListInfo &Out); ParsedTemplateArgument ActOnTemplateTypeArgument(TypeResult ParsedType); void NoteAllFoundTemplates(TemplateName Name); QualType CheckTemplateIdType(TemplateName Template, SourceLocation TemplateLoc, TemplateArgumentListInfo &TemplateArgs); TypeResult ActOnTemplateIdType(Scope S, CXXScopeSpec &SS, SourceLocation TemplateKWLoc, TemplateTy Template, IdentifierInfo TemplateII, SourceLocation TemplateIILoc, SourceLocation LAngleLoc, ASTTemplateArgsPtr TemplateArgs, SourceLocation RAngleLoc, bool IsCtorOrDtorName = false, bool IsClassName = false); /// Parsed an elaborated-type-specifier that refers to a template-id, /// such as \c class T::template apply<U>. TypeResult ActOnTagTemplateIdType(TagUseKind TUK, TypeSpecifierType TagSpec, SourceLocation TagLoc, CXXScopeSpec &SS, SourceLocation TemplateKWLoc, TemplateTy TemplateD, SourceLocation TemplateLoc, SourceLocation LAngleLoc, ASTTemplateArgsPtr TemplateArgsIn, SourceLocation RAngleLoc); DeclResult ActOnVarTemplateSpecialization( Scope S, Declarator &D, TypeSourceInfo DI, SourceLocation TemplateKWLoc, TemplateParameterList TemplateParams, StorageClass SC, bool IsPartialSpecialization); /// Get the specialization of the given variable template corresponding to /// the specified argument list, or a null-but-valid result if the arguments /// are dependent. DeclResult CheckVarTemplateId(VarTemplateDecl Template, SourceLocation TemplateLoc, SourceLocation TemplateNameLoc, const TemplateArgumentListInfo &TemplateArgs); /// Form a reference to the specialization of the given variable template /// corresponding to the specified argument list, or a null-but-valid result /// if the arguments are dependent. ExprResult CheckVarTemplateId(const CXXScopeSpec &SS, const DeclarationNameInfo &NameInfo, VarTemplateDecl Template, SourceLocation TemplateLoc, const TemplateArgumentListInfo TemplateArgs); ExprResult CheckConceptTemplateId(const CXXScopeSpec &SS, SourceLocation TemplateKWLoc, const DeclarationNameInfo &ConceptNameInfo, NamedDecl FoundDecl, ConceptDecl NamedConcept, const TemplateArgumentListInfo TemplateArgs); void diagnoseMissingTemplateArguments(TemplateName Name, SourceLocation Loc); ExprResult BuildTemplateIdExpr(const CXXScopeSpec &SS, SourceLocation TemplateKWLoc, LookupResult &R, bool RequiresADL, const TemplateArgumentListInfo TemplateArgs); ExprResult BuildQualifiedTemplateIdExpr(CXXScopeSpec &SS, SourceLocation TemplateKWLoc, const DeclarationNameInfo &NameInfo, const TemplateArgumentListInfo TemplateArgs); TemplateNameKind ActOnTemplateName( Scope S, CXXScopeSpec &SS, SourceLocation TemplateKWLoc, const UnqualifiedId &Name, ParsedType ObjectType, bool EnteringContext, TemplateTy &Template, bool AllowInjectedClassName = false); DeclResult ActOnClassTemplateSpecialization( Scope S, unsigned TagSpec, TagUseKind TUK, SourceLocation KWLoc, SourceLocation ModulePrivateLoc, CXXScopeSpec &SS, TemplateIdAnnotation &TemplateId, const ParsedAttributesView &Attr, MultiTemplateParamsArg TemplateParameterLists, SkipBodyInfo SkipBody = nullptr); bool CheckTemplatePartialSpecializationArgs(SourceLocation Loc, TemplateDecl PrimaryTemplate, unsigned NumExplicitArgs, ArrayRef<TemplateArgument> Args); void CheckTemplatePartialSpecialization( ClassTemplatePartialSpecializationDecl Partial); void CheckTemplatePartialSpecialization( VarTemplatePartialSpecializationDecl Partial); Decl ActOnTemplateDeclarator(Scope S, MultiTemplateParamsArg TemplateParameterLists, Declarator &D); bool CheckSpecializationInstantiationRedecl(SourceLocation NewLoc, TemplateSpecializationKind NewTSK, NamedDecl PrevDecl, TemplateSpecializationKind PrevTSK, SourceLocation PrevPtOfInstantiation, bool &SuppressNew); bool CheckDependentFunctionTemplateSpecialization(FunctionDecl FD, const TemplateArgumentListInfo &ExplicitTemplateArgs, LookupResult &Previous); bool CheckFunctionTemplateSpecialization( FunctionDecl FD, TemplateArgumentListInfo ExplicitTemplateArgs, LookupResult &Previous, bool QualifiedFriend = false); bool CheckMemberSpecialization(NamedDecl Member, LookupResult &Previous); void CompleteMemberSpecialization(NamedDecl Member, LookupResult &Previous); DeclResult ActOnExplicitInstantiation( Scope S, SourceLocation ExternLoc, SourceLocation TemplateLoc, unsigned TagSpec, SourceLocation KWLoc, const CXXScopeSpec &SS, TemplateTy Template, SourceLocation TemplateNameLoc, SourceLocation LAngleLoc, ASTTemplateArgsPtr TemplateArgs, SourceLocation RAngleLoc, const ParsedAttributesView &Attr); DeclResult ActOnExplicitInstantiation(Scope S, SourceLocation ExternLoc, SourceLocation TemplateLoc, unsigned TagSpec, SourceLocation KWLoc, CXXScopeSpec &SS, IdentifierInfo Name, SourceLocation NameLoc, const ParsedAttributesView &Attr); DeclResult ActOnExplicitInstantiation(Scope S, SourceLocation ExternLoc, SourceLocation TemplateLoc, Declarator &D); TemplateArgumentLoc SubstDefaultTemplateArgumentIfAvailable(TemplateDecl Template, SourceLocation TemplateLoc, SourceLocation RAngleLoc, Decl Param, SmallVectorImpl<TemplateArgument> &Converted, bool &HasDefaultArg); /// Specifies the context in which a particular template /// argument is being checked. enum CheckTemplateArgumentKind { /// The template argument was specified in the code or was /// instantiated with some deduced template arguments. CTAK_Specified, /// The template argument was deduced via template argument /// deduction. CTAK_Deduced, /// The template argument was deduced from an array bound /// via template argument deduction. CTAK_DeducedFromArrayBound }; bool CheckTemplateArgument(NamedDecl Param, TemplateArgumentLoc &Arg, NamedDecl Template, SourceLocation TemplateLoc, SourceLocation RAngleLoc, unsigned ArgumentPackIndex, SmallVectorImpl<TemplateArgument> &Converted, CheckTemplateArgumentKind CTAK = CTAK_Specified); /// Check that the given template arguments can be be provided to /// the given template, converting the arguments along the way. /// /// \param Template The template to which the template arguments are being /// provided. /// /// \param TemplateLoc The location of the template name in the source. /// /// \param TemplateArgs The list of template arguments. If the template is /// a template template parameter, this function may extend the set of /// template arguments to also include substituted, defaulted template /// arguments. /// /// \param PartialTemplateArgs True if the list of template arguments is /// intentionally partial, e.g., because we're checking just the initial /// set of template arguments. /// /// \param Converted Will receive the converted, canonicalized template /// arguments. /// /// \param UpdateArgsWithConversions If \c true, update \p TemplateArgs to /// contain the converted forms of the template arguments as written. /// Otherwise, \p TemplateArgs will not be modified. /// /// \param ConstraintsNotSatisfied If provided, and an error occured, will /// receive true if the cause for the error is the associated constraints of /// the template not being satisfied by the template arguments. /// /// \returns true if an error occurred, false otherwise. bool CheckTemplateArgumentList(TemplateDecl Template, SourceLocation TemplateLoc, TemplateArgumentListInfo &TemplateArgs, bool PartialTemplateArgs, SmallVectorImpl<TemplateArgument> &Converted, bool UpdateArgsWithConversions = true, bool ConstraintsNotSatisfied = nullptr); bool CheckTemplateTypeArgument(TemplateTypeParmDecl Param, TemplateArgumentLoc &Arg, SmallVectorImpl<TemplateArgument> &Converted); bool CheckTemplateArgument(TypeSourceInfo Arg); ExprResult CheckTemplateArgument(NonTypeTemplateParmDecl Param, QualType InstantiatedParamType, Expr Arg, TemplateArgument &Converted, CheckTemplateArgumentKind CTAK = CTAK_Specified); bool CheckTemplateTemplateArgument(TemplateTemplateParmDecl Param, TemplateParameterList Params, TemplateArgumentLoc &Arg); ExprResult BuildExpressionFromDeclTemplateArgument(const TemplateArgument &Arg, QualType ParamType, SourceLocation Loc); ExprResult BuildExpressionFromIntegralTemplateArgument(const TemplateArgument &Arg, SourceLocation Loc); /// Enumeration describing how template parameter lists are compared /// for equality. enum TemplateParameterListEqualKind { /// We are matching the template parameter lists of two templates /// that might be redeclarations. /// /// \code /// template<typename T> struct X; /// template<typename T> struct X; /// \endcode TPL_TemplateMatch, /// We are matching the template parameter lists of two template /// template parameters as part of matching the template parameter lists /// of two templates that might be redeclarations. /// /// \code /// template<template<int I> class TT> struct X; /// template<template<int Value> class Other> struct X; /// \endcode TPL_TemplateTemplateParmMatch, /// We are matching the template parameter lists of a template /// template argument against the template parameter lists of a template /// template parameter. /// /// \code /// template<template<int Value> class Metafun> struct X; /// template<int Value> struct integer_c; /// X<integer_c> xic; /// \endcode TPL_TemplateTemplateArgumentMatch }; bool TemplateParameterListsAreEqual(TemplateParameterList New, TemplateParameterList Old, bool Complain, TemplateParameterListEqualKind Kind, SourceLocation TemplateArgLoc = SourceLocation()); bool CheckTemplateDeclScope(Scope S, TemplateParameterList TemplateParams); /// Called when the parser has parsed a C++ typename /// specifier, e.g., "typename T::type". /// /// \param S The scope in which this typename type occurs. /// \param TypenameLoc the location of the 'typename' keyword /// \param SS the nested-name-specifier following the typename (e.g., 'T::'). /// \param II the identifier we're retrieving (e.g., 'type' in the example). /// \param IdLoc the location of the identifier. TypeResult ActOnTypenameType(Scope S, SourceLocation TypenameLoc, const CXXScopeSpec &SS, const IdentifierInfo &II, SourceLocation IdLoc); /// Called when the parser has parsed a C++ typename /// specifier that ends in a template-id, e.g., /// "typename MetaFun::template apply<T1, T2>". /// /// \param S The scope in which this typename type occurs. /// \param TypenameLoc the location of the 'typename' keyword /// \param SS the nested-name-specifier following the typename (e.g., 'T::'). /// \param TemplateLoc the location of the 'template' keyword, if any. /// \param TemplateName The template name. /// \param TemplateII The identifier used to name the template. /// \param TemplateIILoc The location of the template name. /// \param LAngleLoc The location of the opening angle bracket ('<'). /// \param TemplateArgs The template arguments. /// \param RAngleLoc The location of the closing angle bracket ('>'). TypeResult ActOnTypenameType(Scope S, SourceLocation TypenameLoc, const CXXScopeSpec &SS, SourceLocation TemplateLoc, TemplateTy TemplateName, IdentifierInfo TemplateII, SourceLocation TemplateIILoc, SourceLocation LAngleLoc, ASTTemplateArgsPtr TemplateArgs, SourceLocation RAngleLoc); QualType CheckTypenameType(ElaboratedTypeKeyword Keyword, SourceLocation KeywordLoc, NestedNameSpecifierLoc QualifierLoc, const IdentifierInfo &II, SourceLocation IILoc, TypeSourceInfo TSI, bool DeducedTSTContext); QualType CheckTypenameType(ElaboratedTypeKeyword Keyword, SourceLocation KeywordLoc, NestedNameSpecifierLoc QualifierLoc, const IdentifierInfo &II, SourceLocation IILoc, bool DeducedTSTContext = true); TypeSourceInfo RebuildTypeInCurrentInstantiation(TypeSourceInfo T, SourceLocation Loc, DeclarationName Name); bool RebuildNestedNameSpecifierInCurrentInstantiation(CXXScopeSpec &SS); ExprResult RebuildExprInCurrentInstantiation(Expr E); bool RebuildTemplateParamsInCurrentInstantiation( TemplateParameterList Params); std::string getTemplateArgumentBindingsText(const TemplateParameterList Params, const TemplateArgumentList &Args); std::string getTemplateArgumentBindingsText(const TemplateParameterList Params, const TemplateArgument Args, unsigned NumArgs); //===--------------------------------------------------------------------===// // C++ Concepts //===--------------------------------------------------------------------===// Decl ActOnConceptDefinition( Scope S, MultiTemplateParamsArg TemplateParameterLists, IdentifierInfo Name, SourceLocation NameLoc, Expr ConstraintExpr); RequiresExprBodyDecl * ActOnStartRequiresExpr(SourceLocation RequiresKWLoc, ArrayRef<ParmVarDecl > LocalParameters, Scope BodyScope); void ActOnFinishRequiresExpr(); concepts::Requirement ActOnSimpleRequirement(Expr E); concepts::Requirement ActOnTypeRequirement( SourceLocation TypenameKWLoc, CXXScopeSpec &SS, SourceLocation NameLoc, IdentifierInfo TypeName, TemplateIdAnnotation TemplateId); concepts::Requirement ActOnCompoundRequirement(Expr E, SourceLocation NoexceptLoc); concepts::Requirement ActOnCompoundRequirement( Expr E, SourceLocation NoexceptLoc, CXXScopeSpec &SS, TemplateIdAnnotation TypeConstraint, unsigned Depth); concepts::Requirement ActOnNestedRequirement(Expr Constraint); concepts::ExprRequirement * BuildExprRequirement( Expr E, bool IsSatisfied, SourceLocation NoexceptLoc, concepts::ExprRequirement::ReturnTypeRequirement ReturnTypeRequirement); concepts::ExprRequirement BuildExprRequirement( concepts::Requirement::SubstitutionDiagnostic ExprSubstDiag, bool IsSatisfied, SourceLocation NoexceptLoc, concepts::ExprRequirement::ReturnTypeRequirement ReturnTypeRequirement); concepts::TypeRequirement BuildTypeRequirement(TypeSourceInfo Type); concepts::TypeRequirement BuildTypeRequirement( concepts::Requirement::SubstitutionDiagnostic SubstDiag); concepts::NestedRequirement BuildNestedRequirement(Expr E); concepts::NestedRequirement BuildNestedRequirement( concepts::Requirement::SubstitutionDiagnostic SubstDiag); ExprResult ActOnRequiresExpr(SourceLocation RequiresKWLoc, RequiresExprBodyDecl Body, ArrayRef<ParmVarDecl > LocalParameters, ArrayRef<concepts::Requirement > Requirements, SourceLocation ClosingBraceLoc); //===--------------------------------------------------------------------===// // C++ Variadic Templates (C++0x [temp.variadic]) //===--------------------------------------------------------------------===// /// Determine whether an unexpanded parameter pack might be permitted in this /// location. Useful for error recovery. bool isUnexpandedParameterPackPermitted(); /// The context in which an unexpanded parameter pack is /// being diagnosed. /// /// Note that the values of this enumeration line up with the first /// argument to the \c err_unexpanded_parameter_pack diagnostic. enum UnexpandedParameterPackContext { /// An arbitrary expression. UPPC_Expression = 0, /// The base type of a class type. UPPC_BaseType, /// The type of an arbitrary declaration. UPPC_DeclarationType, /// The type of a data member. UPPC_DataMemberType, /// The size of a bit-field. UPPC_BitFieldWidth, /// The expression in a static assertion. UPPC_StaticAssertExpression, /// The fixed underlying type of an enumeration. UPPC_FixedUnderlyingType, /// The enumerator value. UPPC_EnumeratorValue, /// A using declaration. UPPC_UsingDeclaration, /// A friend declaration. UPPC_FriendDeclaration, /// A declaration qualifier. UPPC_DeclarationQualifier, /// An initializer. UPPC_Initializer, /// A default argument. UPPC_DefaultArgument, /// The type of a non-type template parameter. UPPC_NonTypeTemplateParameterType, /// The type of an exception. UPPC_ExceptionType, /// Partial specialization. UPPC_PartialSpecialization, /// Microsoft __if_exists. UPPC_IfExists, /// Microsoft __if_not_exists. UPPC_IfNotExists, /// Lambda expression. UPPC_Lambda, /// Block expression. UPPC_Block, /// A type constraint. UPPC_TypeConstraint, // A requirement in a requires-expression. UPPC_Requirement, // A requires-clause. UPPC_RequiresClause, }; /// Diagnose unexpanded parameter packs. /// /// \param Loc The location at which we should emit the diagnostic. /// /// \param UPPC The context in which we are diagnosing unexpanded /// parameter packs. /// /// \param Unexpanded the set of unexpanded parameter packs. /// /// \returns true if an error occurred, false otherwise. bool DiagnoseUnexpandedParameterPacks(SourceLocation Loc, UnexpandedParameterPackContext UPPC, ArrayRef<UnexpandedParameterPack> Unexpanded); /// If the given type contains an unexpanded parameter pack, /// diagnose the error. /// /// \param Loc The source location where a diagnostc should be emitted. /// /// \param T The type that is being checked for unexpanded parameter /// packs. /// /// \returns true if an error occurred, false otherwise. bool DiagnoseUnexpandedParameterPack(SourceLocation Loc, TypeSourceInfo T, UnexpandedParameterPackContext UPPC); /// If the given expression contains an unexpanded parameter /// pack, diagnose the error. /// /// \param E The expression that is being checked for unexpanded /// parameter packs. /// /// \returns true if an error occurred, false otherwise. bool DiagnoseUnexpandedParameterPack(Expr E, UnexpandedParameterPackContext UPPC = UPPC_Expression); /// If the given requirees-expression contains an unexpanded reference to one /// of its own parameter packs, diagnose the error. /// /// \param RE The requiress-expression that is being checked for unexpanded /// parameter packs. /// /// \returns true if an error occurred, false otherwise. bool DiagnoseUnexpandedParameterPackInRequiresExpr(RequiresExpr RE); /// If the given nested-name-specifier contains an unexpanded /// parameter pack, diagnose the error. /// /// \param SS The nested-name-specifier that is being checked for /// unexpanded parameter packs. /// /// \returns true if an error occurred, false otherwise. bool DiagnoseUnexpandedParameterPack(const CXXScopeSpec &SS, UnexpandedParameterPackContext UPPC); /// If the given name contains an unexpanded parameter pack, /// diagnose the error. /// /// \param NameInfo The name (with source location information) that /// is being checked for unexpanded parameter packs. /// /// \returns true if an error occurred, false otherwise. bool DiagnoseUnexpandedParameterPack(const DeclarationNameInfo &NameInfo, UnexpandedParameterPackContext UPPC); /// If the given template name contains an unexpanded parameter pack, /// diagnose the error. /// /// \param Loc The location of the template name. /// /// \param Template The template name that is being checked for unexpanded /// parameter packs. /// /// \returns true if an error occurred, false otherwise. bool DiagnoseUnexpandedParameterPack(SourceLocation Loc, TemplateName Template, UnexpandedParameterPackContext UPPC); /// If the given template argument contains an unexpanded parameter /// pack, diagnose the error. /// /// \param Arg The template argument that is being checked for unexpanded /// parameter packs. /// /// \returns true if an error occurred, false otherwise. bool DiagnoseUnexpandedParameterPack(TemplateArgumentLoc Arg, UnexpandedParameterPackContext UPPC); /// Collect the set of unexpanded parameter packs within the given /// template argument. /// /// \param Arg The template argument that will be traversed to find /// unexpanded parameter packs. void collectUnexpandedParameterPacks(TemplateArgument Arg, SmallVectorImpl<UnexpandedParameterPack> &Unexpanded); /// Collect the set of unexpanded parameter packs within the given /// template argument. /// /// \param Arg The template argument that will be traversed to find /// unexpanded parameter packs. void collectUnexpandedParameterPacks(TemplateArgumentLoc Arg, SmallVectorImpl<UnexpandedParameterPack> &Unexpanded); /// Collect the set of unexpanded parameter packs within the given /// type. /// /// \param T The type that will be traversed to find /// unexpanded parameter packs. void collectUnexpandedParameterPacks(QualType T, SmallVectorImpl<UnexpandedParameterPack> &Unexpanded); /// Collect the set of unexpanded parameter packs within the given /// type. /// /// \param TL The type that will be traversed to find /// unexpanded parameter packs. void collectUnexpandedParameterPacks(TypeLoc TL, SmallVectorImpl<UnexpandedParameterPack> &Unexpanded); /// Collect the set of unexpanded parameter packs within the given /// nested-name-specifier. /// /// \param NNS The nested-name-specifier that will be traversed to find /// unexpanded parameter packs. void collectUnexpandedParameterPacks(NestedNameSpecifierLoc NNS, SmallVectorImpl<UnexpandedParameterPack> &Unexpanded); /// Collect the set of unexpanded parameter packs within the given /// name. /// /// \param NameInfo The name that will be traversed to find /// unexpanded parameter packs. void collectUnexpandedParameterPacks(const DeclarationNameInfo &NameInfo, SmallVectorImpl<UnexpandedParameterPack> &Unexpanded); /// Invoked when parsing a template argument followed by an /// ellipsis, which creates a pack expansion. /// /// \param Arg The template argument preceding the ellipsis, which /// may already be invalid. /// /// \param EllipsisLoc The location of the ellipsis. ParsedTemplateArgument ActOnPackExpansion(const ParsedTemplateArgument &Arg, SourceLocation EllipsisLoc); /// Invoked when parsing a type followed by an ellipsis, which /// creates a pack expansion. /// /// \param Type The type preceding the ellipsis, which will become /// the pattern of the pack expansion. /// /// \param EllipsisLoc The location of the ellipsis. TypeResult ActOnPackExpansion(ParsedType Type, SourceLocation EllipsisLoc); /// Construct a pack expansion type from the pattern of the pack /// expansion. TypeSourceInfo CheckPackExpansion(TypeSourceInfo Pattern, SourceLocation EllipsisLoc, Optional<unsigned> NumExpansions); /// Construct a pack expansion type from the pattern of the pack /// expansion. QualType CheckPackExpansion(QualType Pattern, SourceRange PatternRange, SourceLocation EllipsisLoc, Optional<unsigned> NumExpansions); /// Invoked when parsing an expression followed by an ellipsis, which /// creates a pack expansion. /// /// \param Pattern The expression preceding the ellipsis, which will become /// the pattern of the pack expansion. /// /// \param EllipsisLoc The location of the ellipsis. ExprResult ActOnPackExpansion(Expr Pattern, SourceLocation EllipsisLoc); /// Invoked when parsing an expression followed by an ellipsis, which /// creates a pack expansion. /// /// \param Pattern The expression preceding the ellipsis, which will become /// the pattern of the pack expansion. /// /// \param EllipsisLoc The location of the ellipsis. ExprResult CheckPackExpansion(Expr Pattern, SourceLocation EllipsisLoc, Optional<unsigned> NumExpansions); /// Determine whether we could expand a pack expansion with the /// given set of parameter packs into separate arguments by repeatedly /// transforming the pattern. /// /// \param EllipsisLoc The location of the ellipsis that identifies the /// pack expansion. /// /// \param PatternRange The source range that covers the entire pattern of /// the pack expansion. /// /// \param Unexpanded The set of unexpanded parameter packs within the /// pattern. /// /// \param ShouldExpand Will be set to \c true if the transformer should /// expand the corresponding pack expansions into separate arguments. When /// set, \c NumExpansions must also be set. /// /// \param RetainExpansion Whether the caller should add an unexpanded /// pack expansion after all of the expanded arguments. This is used /// when extending explicitly-specified template argument packs per /// C++0x [temp.arg.explicit]p9. /// /// \param NumExpansions The number of separate arguments that will be in /// the expanded form of the corresponding pack expansion. This is both an /// input and an output parameter, which can be set by the caller if the /// number of expansions is known a priori (e.g., due to a prior substitution) /// and will be set by the callee when the number of expansions is known. /// The callee must set this value when \c ShouldExpand is \c true; it may /// set this value in other cases. /// /// \returns true if an error occurred (e.g., because the parameter packs /// are to be instantiated with arguments of different lengths), false /// otherwise. If false, \c ShouldExpand (and possibly \c NumExpansions) /// must be set. bool CheckParameterPacksForExpansion(SourceLocation EllipsisLoc, SourceRange PatternRange, ArrayRef<UnexpandedParameterPack> Unexpanded, const MultiLevelTemplateArgumentList &TemplateArgs, bool &ShouldExpand, bool &RetainExpansion, Optional<unsigned> &NumExpansions); /// Determine the number of arguments in the given pack expansion /// type. /// /// This routine assumes that the number of arguments in the expansion is /// consistent across all of the unexpanded parameter packs in its pattern. /// /// Returns an empty Optional if the type can't be expanded. Optional<unsigned> getNumArgumentsInExpansion(QualType T, const MultiLevelTemplateArgumentList &TemplateArgs); /// Determine whether the given declarator contains any unexpanded /// parameter packs. /// /// This routine is used by the parser to disambiguate function declarators /// with an ellipsis prior to the ')', e.g., /// /// \code /// void f(T...); /// \endcode /// /// To determine whether we have an (unnamed) function parameter pack or /// a variadic function. /// /// \returns true if the declarator contains any unexpanded parameter packs, /// false otherwise. bool containsUnexpandedParameterPacks(Declarator &D); /// Returns the pattern of the pack expansion for a template argument. /// /// \param OrigLoc The template argument to expand. /// /// \param Ellipsis Will be set to the location of the ellipsis. /// /// \param NumExpansions Will be set to the number of expansions that will /// be generated from this pack expansion, if known a priori. TemplateArgumentLoc getTemplateArgumentPackExpansionPattern( TemplateArgumentLoc OrigLoc, SourceLocation &Ellipsis, Optional<unsigned> &NumExpansions) const; /// Given a template argument that contains an unexpanded parameter pack, but /// which has already been substituted, attempt to determine the number of /// elements that will be produced once this argument is fully-expanded. /// /// This is intended for use when transforming 'sizeof...(Arg)' in order to /// avoid actually expanding the pack where possible. Optional<unsigned> getFullyPackExpandedSize(TemplateArgument Arg); //===--------------------------------------------------------------------===// // C++ Template Argument Deduction (C++ [temp.deduct]) //===--------------------------------------------------------------------===// /// Adjust the type \p ArgFunctionType to match the calling convention, /// noreturn, and optionally the exception specification of \p FunctionType. /// Deduction often wants to ignore these properties when matching function /// types. QualType adjustCCAndNoReturn(QualType ArgFunctionType, QualType FunctionType, bool AdjustExceptionSpec = false); /// Describes the result of template argument deduction. /// /// The TemplateDeductionResult enumeration describes the result of /// template argument deduction, as returned from /// DeduceTemplateArguments(). The separate TemplateDeductionInfo /// structure provides additional information about the results of /// template argument deduction, e.g., the deduced template argument /// list (if successful) or the specific template parameters or /// deduced arguments that were involved in the failure. enum TemplateDeductionResult { /// Template argument deduction was successful. TDK_Success = 0, /// The declaration was invalid; do nothing. TDK_Invalid, /// Template argument deduction exceeded the maximum template /// instantiation depth (which has already been diagnosed). TDK_InstantiationDepth, /// Template argument deduction did not deduce a value /// for every template parameter. TDK_Incomplete, /// Template argument deduction did not deduce a value for every /// expansion of an expanded template parameter pack. TDK_IncompletePack, /// Template argument deduction produced inconsistent /// deduced values for the given template parameter. TDK_Inconsistent, /// Template argument deduction failed due to inconsistent /// cv-qualifiers on a template parameter type that would /// otherwise be deduced, e.g., we tried to deduce T in "const T" /// but were given a non-const "X". TDK_Underqualified, /// Substitution of the deduced template argument values /// resulted in an error. TDK_SubstitutionFailure, /// After substituting deduced template arguments, a dependent /// parameter type did not match the corresponding argument. TDK_DeducedMismatch, /// After substituting deduced template arguments, an element of /// a dependent parameter type did not match the corresponding element /// of the corresponding argument (when deducing from an initializer list). TDK_DeducedMismatchNested, /// A non-depnedent component of the parameter did not match the /// corresponding component of the argument. TDK_NonDeducedMismatch, /// When performing template argument deduction for a function /// template, there were too many call arguments. TDK_TooManyArguments, /// When performing template argument deduction for a function /// template, there were too few call arguments. TDK_TooFewArguments, /// The explicitly-specified template arguments were not valid /// template arguments for the given template. TDK_InvalidExplicitArguments, /// Checking non-dependent argument conversions failed. TDK_NonDependentConversionFailure, /// The deduced arguments did not satisfy the constraints associated /// with the template. TDK_ConstraintsNotSatisfied, /// Deduction failed; that's all we know. TDK_MiscellaneousDeductionFailure, /// CUDA Target attributes do not match. TDK_CUDATargetMismatch }; TemplateDeductionResult DeduceTemplateArguments(ClassTemplatePartialSpecializationDecl Partial, const TemplateArgumentList &TemplateArgs, sema::TemplateDeductionInfo &Info); TemplateDeductionResult DeduceTemplateArguments(VarTemplatePartialSpecializationDecl Partial, const TemplateArgumentList &TemplateArgs, sema::TemplateDeductionInfo &Info); TemplateDeductionResult SubstituteExplicitTemplateArguments( FunctionTemplateDecl FunctionTemplate, TemplateArgumentListInfo &ExplicitTemplateArgs, SmallVectorImpl<DeducedTemplateArgument> &Deduced, SmallVectorImpl<QualType> &ParamTypes, QualType FunctionType, sema::TemplateDeductionInfo &Info); /// brief A function argument from which we performed template argument // deduction for a call. struct OriginalCallArg { OriginalCallArg(QualType OriginalParamType, bool DecomposedParam, unsigned ArgIdx, QualType OriginalArgType) : OriginalParamType(OriginalParamType), DecomposedParam(DecomposedParam), ArgIdx(ArgIdx), OriginalArgType(OriginalArgType) {} QualType OriginalParamType; bool DecomposedParam; unsigned ArgIdx; QualType OriginalArgType; }; TemplateDeductionResult FinishTemplateArgumentDeduction( FunctionTemplateDecl FunctionTemplate, SmallVectorImpl<DeducedTemplateArgument> &Deduced, unsigned NumExplicitlySpecified, FunctionDecl &Specialization, sema::TemplateDeductionInfo &Info, SmallVectorImpl<OriginalCallArg> const OriginalCallArgs = nullptr, bool PartialOverloading = false, llvm::function_ref<bool()> CheckNonDependent = []{ return false; }); TemplateDeductionResult DeduceTemplateArguments( FunctionTemplateDecl FunctionTemplate, TemplateArgumentListInfo ExplicitTemplateArgs, ArrayRef<Expr > Args, FunctionDecl &Specialization, sema::TemplateDeductionInfo &Info, bool PartialOverloading, llvm::function_ref<bool(ArrayRef<QualType>)> CheckNonDependent); TemplateDeductionResult DeduceTemplateArguments(FunctionTemplateDecl FunctionTemplate, TemplateArgumentListInfo ExplicitTemplateArgs, QualType ArgFunctionType, FunctionDecl &Specialization, sema::TemplateDeductionInfo &Info, bool IsAddressOfFunction = false); TemplateDeductionResult DeduceTemplateArguments(FunctionTemplateDecl FunctionTemplate, QualType ToType, CXXConversionDecl &Specialization, sema::TemplateDeductionInfo &Info); TemplateDeductionResult DeduceTemplateArguments(FunctionTemplateDecl FunctionTemplate, TemplateArgumentListInfo ExplicitTemplateArgs, FunctionDecl &Specialization, sema::TemplateDeductionInfo &Info, bool IsAddressOfFunction = false); /// Substitute Replacement for \p auto in \p TypeWithAuto QualType SubstAutoType(QualType TypeWithAuto, QualType Replacement); /// Substitute Replacement for auto in TypeWithAuto TypeSourceInfo* SubstAutoTypeSourceInfo(TypeSourceInfo TypeWithAuto, QualType Replacement); /// Completely replace the \c auto in \p TypeWithAuto by /// \p Replacement. This does not retain any \c auto type sugar. QualType ReplaceAutoType(QualType TypeWithAuto, QualType Replacement); TypeSourceInfo ReplaceAutoTypeSourceInfo(TypeSourceInfo TypeWithAuto, QualType Replacement); /// Result type of DeduceAutoType. enum DeduceAutoResult { DAR_Succeeded, DAR_Failed, DAR_FailedAlreadyDiagnosed }; DeduceAutoResult DeduceAutoType(TypeSourceInfo AutoType, Expr &Initializer, QualType &Result, Optional<unsigned> DependentDeductionDepth = None, bool IgnoreConstraints = false); DeduceAutoResult DeduceAutoType(TypeLoc AutoTypeLoc, Expr &Initializer, QualType &Result, Optional<unsigned> DependentDeductionDepth = None, bool IgnoreConstraints = false); void DiagnoseAutoDeductionFailure(VarDecl VDecl, Expr Init); bool DeduceReturnType(FunctionDecl FD, SourceLocation Loc, bool Diagnose = true); /// Declare implicit deduction guides for a class template if we've /// not already done so. void DeclareImplicitDeductionGuides(TemplateDecl Template, SourceLocation Loc); QualType DeduceTemplateSpecializationFromInitializer( TypeSourceInfo TInfo, const InitializedEntity &Entity, const InitializationKind &Kind, MultiExprArg Init); QualType deduceVarTypeFromInitializer(VarDecl VDecl, DeclarationName Name, QualType Type, TypeSourceInfo TSI, SourceRange Range, bool DirectInit, Expr Init); TypeLoc getReturnTypeLoc(FunctionDecl FD) const; bool DeduceFunctionTypeFromReturnExpr(FunctionDecl FD, SourceLocation ReturnLoc, Expr &RetExpr, AutoType AT); FunctionTemplateDecl getMoreSpecializedTemplate( FunctionTemplateDecl FT1, FunctionTemplateDecl FT2, SourceLocation Loc, TemplatePartialOrderingContext TPOC, unsigned NumCallArguments1, unsigned NumCallArguments2, bool Reversed = false); UnresolvedSetIterator getMostSpecialized(UnresolvedSetIterator SBegin, UnresolvedSetIterator SEnd, TemplateSpecCandidateSet &FailedCandidates, SourceLocation Loc, const PartialDiagnostic &NoneDiag, const PartialDiagnostic &AmbigDiag, const PartialDiagnostic &CandidateDiag, bool Complain = true, QualType TargetType = QualType()); ClassTemplatePartialSpecializationDecl getMoreSpecializedPartialSpecialization( ClassTemplatePartialSpecializationDecl PS1, ClassTemplatePartialSpecializationDecl PS2, SourceLocation Loc); bool isMoreSpecializedThanPrimary(ClassTemplatePartialSpecializationDecl T, sema::TemplateDeductionInfo &Info); VarTemplatePartialSpecializationDecl getMoreSpecializedPartialSpecialization( VarTemplatePartialSpecializationDecl PS1, VarTemplatePartialSpecializationDecl PS2, SourceLocation Loc); bool isMoreSpecializedThanPrimary(VarTemplatePartialSpecializationDecl T, sema::TemplateDeductionInfo &Info); bool isTemplateTemplateParameterAtLeastAsSpecializedAs( TemplateParameterList PParam, TemplateDecl AArg, SourceLocation Loc); void MarkUsedTemplateParameters(const Expr E, bool OnlyDeduced, unsigned Depth, llvm::SmallBitVector &Used); void MarkUsedTemplateParameters(const TemplateArgumentList &TemplateArgs, bool OnlyDeduced, unsigned Depth, llvm::SmallBitVector &Used); void MarkDeducedTemplateParameters( const FunctionTemplateDecl FunctionTemplate, llvm::SmallBitVector &Deduced) { return MarkDeducedTemplateParameters(Context, FunctionTemplate, Deduced); } static void MarkDeducedTemplateParameters(ASTContext &Ctx, const FunctionTemplateDecl FunctionTemplate, llvm::SmallBitVector &Deduced); //===--------------------------------------------------------------------===// // C++ Template Instantiation // MultiLevelTemplateArgumentList getTemplateInstantiationArgs(NamedDecl D, const TemplateArgumentList Innermost = nullptr, bool RelativeToPrimary = false, const FunctionDecl Pattern = nullptr); /// A context in which code is being synthesized (where a source location /// alone is not sufficient to identify the context). This covers template /// instantiation and various forms of implicitly-generated functions. struct CodeSynthesisContext { /// The kind of template instantiation we are performing enum SynthesisKind { /// We are instantiating a template declaration. The entity is /// the declaration we're instantiating (e.g., a CXXRecordDecl). TemplateInstantiation, /// We are instantiating a default argument for a template /// parameter. The Entity is the template parameter whose argument is /// being instantiated, the Template is the template, and the /// TemplateArgs/NumTemplateArguments provide the template arguments as /// specified. DefaultTemplateArgumentInstantiation, /// We are instantiating a default argument for a function. /// The Entity is the ParmVarDecl, and TemplateArgs/NumTemplateArgs /// provides the template arguments as specified. DefaultFunctionArgumentInstantiation, /// We are substituting explicit template arguments provided for /// a function template. The entity is a FunctionTemplateDecl. ExplicitTemplateArgumentSubstitution, /// We are substituting template argument determined as part of /// template argument deduction for either a class template /// partial specialization or a function template. The /// Entity is either a {Class\|Var}TemplatePartialSpecializationDecl or /// a TemplateDecl. DeducedTemplateArgumentSubstitution, /// We are substituting prior template arguments into a new /// template parameter. The template parameter itself is either a /// NonTypeTemplateParmDecl or a TemplateTemplateParmDecl. PriorTemplateArgumentSubstitution, /// We are checking the validity of a default template argument that /// has been used when naming a template-id. DefaultTemplateArgumentChecking, /// We are computing the exception specification for a defaulted special /// member function. ExceptionSpecEvaluation, /// We are instantiating the exception specification for a function /// template which was deferred until it was needed. ExceptionSpecInstantiation, /// We are instantiating a requirement of a requires expression. RequirementInstantiation, /// We are checking the satisfaction of a nested requirement of a requires /// expression. NestedRequirementConstraintsCheck, /// We are declaring an implicit special member function. DeclaringSpecialMember, /// We are declaring an implicit 'operator==' for a defaulted /// 'operator<=>'. DeclaringImplicitEqualityComparison, /// We are defining a synthesized function (such as a defaulted special /// member). DefiningSynthesizedFunction, // We are checking the constraints associated with a constrained entity or // the constraint expression of a concept. This includes the checks that // atomic constraints have the type 'bool' and that they can be constant // evaluated. ConstraintsCheck, // We are substituting template arguments into a constraint expression. ConstraintSubstitution, // We are normalizing a constraint expression. ConstraintNormalization, // We are substituting into the parameter mapping of an atomic constraint // during normalization. ParameterMappingSubstitution, /// We are rewriting a comparison operator in terms of an operator<=>. RewritingOperatorAsSpaceship, /// We are initializing a structured binding. InitializingStructuredBinding, /// We are marking a class as __dllexport. MarkingClassDllexported, /// Added for Template instantiation observation. /// Memoization means we are _not_ instantiating a template because /// it is already instantiated (but we entered a context where we /// would have had to if it was not already instantiated). Memoization } Kind; /// Was the enclosing context a non-instantiation SFINAE context? bool SavedInNonInstantiationSFINAEContext; /// The point of instantiation or synthesis within the source code. SourceLocation PointOfInstantiation; /// The entity that is being synthesized. Decl Entity; /// The template (or partial specialization) in which we are /// performing the instantiation, for substitutions of prior template /// arguments. NamedDecl Template; /// The list of template arguments we are substituting, if they /// are not part of the entity. const TemplateArgument TemplateArgs; // FIXME: Wrap this union around more members, or perhaps store the // kind-specific members in the RAII object owning the context. union { /// The number of template arguments in TemplateArgs. unsigned NumTemplateArgs; /// The special member being declared or defined. CXXSpecialMember SpecialMember; }; ArrayRef<TemplateArgument> template_arguments() const { assert(Kind != DeclaringSpecialMember); return {TemplateArgs, NumTemplateArgs}; } /// The template deduction info object associated with the /// substitution or checking of explicit or deduced template arguments. sema::TemplateDeductionInfo DeductionInfo; /// The source range that covers the construct that cause /// the instantiation, e.g., the template-id that causes a class /// template instantiation. SourceRange InstantiationRange; CodeSynthesisContext() : Kind(TemplateInstantiation), SavedInNonInstantiationSFINAEContext(false), Entity(nullptr), Template(nullptr), TemplateArgs(nullptr), NumTemplateArgs(0), DeductionInfo(nullptr) {} /// Determines whether this template is an actual instantiation /// that should be counted toward the maximum instantiation depth. bool isInstantiationRecord() const; }; /// List of active code synthesis contexts. /// /// This vector is treated as a stack. As synthesis of one entity requires /// synthesis of another, additional contexts are pushed onto the stack. SmallVector<CodeSynthesisContext, 16> CodeSynthesisContexts; /// Specializations whose definitions are currently being instantiated. llvm::DenseSet<std::pair<Decl , unsigned>> InstantiatingSpecializations; /// Non-dependent types used in templates that have already been instantiated /// by some template instantiation. llvm::DenseSet<QualType> InstantiatedNonDependentTypes; /// Extra modules inspected when performing a lookup during a template /// instantiation. Computed lazily. SmallVector<Module, 16> CodeSynthesisContextLookupModules; /// Cache of additional modules that should be used for name lookup /// within the current template instantiation. Computed lazily; use /// getLookupModules() to get a complete set. llvm::DenseSet<Module> LookupModulesCache; /// Get the set of additional modules that should be checked during /// name lookup. A module and its imports become visible when instanting a /// template defined within it. llvm::DenseSet<Module> &getLookupModules(); /// Map from the most recent declaration of a namespace to the most /// recent visible declaration of that namespace. llvm::DenseMap<NamedDecl, NamedDecl> VisibleNamespaceCache; /// Whether we are in a SFINAE context that is not associated with /// template instantiation. /// /// This is used when setting up a SFINAE trap (\c see SFINAETrap) outside /// of a template instantiation or template argument deduction. bool InNonInstantiationSFINAEContext; /// The number of \p CodeSynthesisContexts that are not template /// instantiations and, therefore, should not be counted as part of the /// instantiation depth. /// /// When the instantiation depth reaches the user-configurable limit /// \p LangOptions::InstantiationDepth we will abort instantiation. // FIXME: Should we have a similar limit for other forms of synthesis? unsigned NonInstantiationEntries; /// The depth of the context stack at the point when the most recent /// error or warning was produced. /// /// This value is used to suppress printing of redundant context stacks /// when there are multiple errors or warnings in the same instantiation. // FIXME: Does this belong in Sema? It's tough to implement it anywhere else. unsigned LastEmittedCodeSynthesisContextDepth = 0; /// The template instantiation callbacks to trace or track /// instantiations (objects can be chained). /// /// This callbacks is used to print, trace or track template /// instantiations as they are being constructed. std::vector<std::unique_ptr<TemplateInstantiationCallback>> TemplateInstCallbacks; /// The current index into pack expansion arguments that will be /// used for substitution of parameter packs. /// /// The pack expansion index will be -1 to indicate that parameter packs /// should be instantiated as themselves. Otherwise, the index specifies /// which argument within the parameter pack will be used for substitution. int ArgumentPackSubstitutionIndex; /// RAII object used to change the argument pack substitution index /// within a \c Sema object. /// /// See \c ArgumentPackSubstitutionIndex for more information. class ArgumentPackSubstitutionIndexRAII { Sema &Self; int OldSubstitutionIndex; public: ArgumentPackSubstitutionIndexRAII(Sema &Self, int NewSubstitutionIndex) : Self(Self), OldSubstitutionIndex(Self.ArgumentPackSubstitutionIndex) { Self.ArgumentPackSubstitutionIndex = NewSubstitutionIndex; } ~ArgumentPackSubstitutionIndexRAII() { Self.ArgumentPackSubstitutionIndex = OldSubstitutionIndex; } }; friend class ArgumentPackSubstitutionRAII; /// For each declaration that involved template argument deduction, the /// set of diagnostics that were suppressed during that template argument /// deduction. /// /// FIXME: Serialize this structure to the AST file. typedef llvm::DenseMap<Decl , SmallVector<PartialDiagnosticAt, 1> > SuppressedDiagnosticsMap; SuppressedDiagnosticsMap SuppressedDiagnostics; /// A stack object to be created when performing template /// instantiation. /// /// Construction of an object of type \c InstantiatingTemplate /// pushes the current instantiation onto the stack of active /// instantiations. If the size of this stack exceeds the maximum /// number of recursive template instantiations, construction /// produces an error and evaluates true. /// /// Destruction of this object will pop the named instantiation off /// the stack. struct InstantiatingTemplate { /// Note that we are instantiating a class template, /// function template, variable template, alias template, /// or a member thereof. InstantiatingTemplate(Sema &SemaRef, SourceLocation PointOfInstantiation, Decl Entity, SourceRange InstantiationRange = SourceRange()); struct ExceptionSpecification {}; /// Note that we are instantiating an exception specification /// of a function template. InstantiatingTemplate(Sema &SemaRef, SourceLocation PointOfInstantiation, FunctionDecl Entity, ExceptionSpecification, SourceRange InstantiationRange = SourceRange()); /// Note that we are instantiating a default argument in a /// template-id. InstantiatingTemplate(Sema &SemaRef, SourceLocation PointOfInstantiation, TemplateParameter Param, TemplateDecl Template, ArrayRef<TemplateArgument> TemplateArgs, SourceRange InstantiationRange = SourceRange()); /// Note that we are substituting either explicitly-specified or /// deduced template arguments during function template argument deduction. InstantiatingTemplate(Sema &SemaRef, SourceLocation PointOfInstantiation, FunctionTemplateDecl FunctionTemplate, ArrayRef<TemplateArgument> TemplateArgs, CodeSynthesisContext::SynthesisKind Kind, sema::TemplateDeductionInfo &DeductionInfo, SourceRange InstantiationRange = SourceRange()); /// Note that we are instantiating as part of template /// argument deduction for a class template declaration. InstantiatingTemplate(Sema &SemaRef, SourceLocation PointOfInstantiation, TemplateDecl Template, ArrayRef<TemplateArgument> TemplateArgs, sema::TemplateDeductionInfo &DeductionInfo, SourceRange InstantiationRange = SourceRange()); /// Note that we are instantiating as part of template /// argument deduction for a class template partial /// specialization. InstantiatingTemplate(Sema &SemaRef, SourceLocation PointOfInstantiation, ClassTemplatePartialSpecializationDecl PartialSpec, ArrayRef<TemplateArgument> TemplateArgs, sema::TemplateDeductionInfo &DeductionInfo, SourceRange InstantiationRange = SourceRange()); /// Note that we are instantiating as part of template /// argument deduction for a variable template partial /// specialization. InstantiatingTemplate(Sema &SemaRef, SourceLocation PointOfInstantiation, VarTemplatePartialSpecializationDecl PartialSpec, ArrayRef<TemplateArgument> TemplateArgs, sema::TemplateDeductionInfo &DeductionInfo, SourceRange InstantiationRange = SourceRange()); /// Note that we are instantiating a default argument for a function /// parameter. InstantiatingTemplate(Sema &SemaRef, SourceLocation PointOfInstantiation, ParmVarDecl Param, ArrayRef<TemplateArgument> TemplateArgs, SourceRange InstantiationRange = SourceRange()); /// Note that we are substituting prior template arguments into a /// non-type parameter. InstantiatingTemplate(Sema &SemaRef, SourceLocation PointOfInstantiation, NamedDecl Template, NonTypeTemplateParmDecl Param, ArrayRef<TemplateArgument> TemplateArgs, SourceRange InstantiationRange); /// Note that we are substituting prior template arguments into a /// template template parameter. InstantiatingTemplate(Sema &SemaRef, SourceLocation PointOfInstantiation, NamedDecl Template, TemplateTemplateParmDecl Param, ArrayRef<TemplateArgument> TemplateArgs, SourceRange InstantiationRange); /// Note that we are checking the default template argument /// against the template parameter for a given template-id. InstantiatingTemplate(Sema &SemaRef, SourceLocation PointOfInstantiation, TemplateDecl Template, NamedDecl Param, ArrayRef<TemplateArgument> TemplateArgs, SourceRange InstantiationRange); struct ConstraintsCheck {}; /// \brief Note that we are checking the constraints associated with some /// constrained entity (a concept declaration or a template with associated /// constraints). InstantiatingTemplate(Sema &SemaRef, SourceLocation PointOfInstantiation, ConstraintsCheck, NamedDecl Template, ArrayRef<TemplateArgument> TemplateArgs, SourceRange InstantiationRange); struct ConstraintSubstitution {}; /// \brief Note that we are checking a constraint expression associated /// with a template declaration or as part of the satisfaction check of a /// concept. InstantiatingTemplate(Sema &SemaRef, SourceLocation PointOfInstantiation, ConstraintSubstitution, NamedDecl Template, sema::TemplateDeductionInfo &DeductionInfo, SourceRange InstantiationRange); struct ConstraintNormalization {}; /// \brief Note that we are normalizing a constraint expression. InstantiatingTemplate(Sema &SemaRef, SourceLocation PointOfInstantiation, ConstraintNormalization, NamedDecl Template, SourceRange InstantiationRange); struct ParameterMappingSubstitution {}; /// \brief Note that we are subtituting into the parameter mapping of an /// atomic constraint during constraint normalization. InstantiatingTemplate(Sema &SemaRef, SourceLocation PointOfInstantiation, ParameterMappingSubstitution, NamedDecl Template, SourceRange InstantiationRange); /// \brief Note that we are substituting template arguments into a part of /// a requirement of a requires expression. InstantiatingTemplate(Sema &SemaRef, SourceLocation PointOfInstantiation, concepts::Requirement Req, sema::TemplateDeductionInfo &DeductionInfo, SourceRange InstantiationRange = SourceRange()); /// \brief Note that we are checking the satisfaction of the constraint /// expression inside of a nested requirement. InstantiatingTemplate(Sema &SemaRef, SourceLocation PointOfInstantiation, concepts::NestedRequirement Req, ConstraintsCheck, SourceRange InstantiationRange = SourceRange()); /// Note that we have finished instantiating this template. void Clear(); ~InstantiatingTemplate() { Clear(); } /// Determines whether we have exceeded the maximum /// recursive template instantiations. bool isInvalid() const { return Invalid; } /// Determine whether we are already instantiating this /// specialization in some surrounding active instantiation. bool isAlreadyInstantiating() const { return AlreadyInstantiating; } private: Sema &SemaRef; bool Invalid; bool AlreadyInstantiating; bool CheckInstantiationDepth(SourceLocation PointOfInstantiation, SourceRange InstantiationRange); InstantiatingTemplate( Sema &SemaRef, CodeSynthesisContext::SynthesisKind Kind, SourceLocation PointOfInstantiation, SourceRange InstantiationRange, Decl Entity, NamedDecl Template = nullptr, ArrayRef<TemplateArgument> TemplateArgs = None, sema::TemplateDeductionInfo DeductionInfo = nullptr); InstantiatingTemplate(const InstantiatingTemplate&) = delete; InstantiatingTemplate& operator=(const InstantiatingTemplate&) = delete; }; void pushCodeSynthesisContext(CodeSynthesisContext Ctx); void popCodeSynthesisContext(); /// Determine whether we are currently performing template instantiation. bool inTemplateInstantiation() const { return CodeSynthesisContexts.size() > NonInstantiationEntries; } void PrintContextStack() { if (!CodeSynthesisContexts.empty() && CodeSynthesisContexts.size() != LastEmittedCodeSynthesisContextDepth) { PrintInstantiationStack(); LastEmittedCodeSynthesisContextDepth = CodeSynthesisContexts.size(); } if (PragmaAttributeCurrentTargetDecl) PrintPragmaAttributeInstantiationPoint(); } void PrintInstantiationStack(); void PrintPragmaAttributeInstantiationPoint(); /// Determines whether we are currently in a context where /// template argument substitution failures are not considered /// errors. /// /// \returns An empty \c Optional if we're not in a SFINAE context. /// Otherwise, contains a pointer that, if non-NULL, contains the nearest /// template-deduction context object, which can be used to capture /// diagnostics that will be suppressed. Optional<sema::TemplateDeductionInfo > isSFINAEContext() const; /// Determines whether we are currently in a context that /// is not evaluated as per C++ [expr] p5. bool isUnevaluatedContext() const { assert(!ExprEvalContexts.empty() && "Must be in an expression evaluation context"); return ExprEvalContexts.back().isUnevaluated(); } bool isImmediateFunctionContext() const { assert(!ExprEvalContexts.empty() && "Must be in an expression evaluation context"); for (const ExpressionEvaluationContextRecord &context : llvm::reverse(ExprEvalContexts)) { if (context.isImmediateFunctionContext()) return true; if (context.isUnevaluated()) return false; } return false; } /// RAII class used to determine whether SFINAE has /// trapped any errors that occur during template argument /// deduction. class SFINAETrap { Sema &SemaRef; unsigned PrevSFINAEErrors; bool PrevInNonInstantiationSFINAEContext; bool PrevAccessCheckingSFINAE; bool PrevLastDiagnosticIgnored; public: explicit SFINAETrap(Sema &SemaRef, bool AccessCheckingSFINAE = false) : SemaRef(SemaRef), PrevSFINAEErrors(SemaRef.NumSFINAEErrors), PrevInNonInstantiationSFINAEContext( SemaRef.InNonInstantiationSFINAEContext), PrevAccessCheckingSFINAE(SemaRef.AccessCheckingSFINAE), PrevLastDiagnosticIgnored( SemaRef.getDiagnostics().isLastDiagnosticIgnored()) { if (!SemaRef.isSFINAEContext()) SemaRef.InNonInstantiationSFINAEContext = true; SemaRef.AccessCheckingSFINAE = AccessCheckingSFINAE; } ~SFINAETrap() { SemaRef.NumSFINAEErrors = PrevSFINAEErrors; SemaRef.InNonInstantiationSFINAEContext = PrevInNonInstantiationSFINAEContext; SemaRef.AccessCheckingSFINAE = PrevAccessCheckingSFINAE; SemaRef.getDiagnostics().setLastDiagnosticIgnored( PrevLastDiagnosticIgnored); } /// Determine whether any SFINAE errors have been trapped. bool hasErrorOccurred() const { return SemaRef.NumSFINAEErrors > PrevSFINAEErrors; } }; /// RAII class used to indicate that we are performing provisional /// semantic analysis to determine the validity of a construct, so /// typo-correction and diagnostics in the immediate context (not within /// implicitly-instantiated templates) should be suppressed. class TentativeAnalysisScope { Sema &SemaRef; // FIXME: Using a SFINAETrap for this is a hack. SFINAETrap Trap; bool PrevDisableTypoCorrection; public: explicit TentativeAnalysisScope(Sema &SemaRef) : SemaRef(SemaRef), Trap(SemaRef, true), PrevDisableTypoCorrection(SemaRef.DisableTypoCorrection) { SemaRef.DisableTypoCorrection = true; } ~TentativeAnalysisScope() { SemaRef.DisableTypoCorrection = PrevDisableTypoCorrection; } }; /// The current instantiation scope used to store local /// variables. LocalInstantiationScope CurrentInstantiationScope; /// Tracks whether we are in a context where typo correction is /// disabled. bool DisableTypoCorrection; /// The number of typos corrected by CorrectTypo. unsigned TyposCorrected; typedef llvm::SmallSet<SourceLocation, 2> SrcLocSet; typedef llvm::DenseMap<IdentifierInfo , SrcLocSet> IdentifierSourceLocations; /// A cache containing identifiers for which typo correction failed and /// their locations, so that repeated attempts to correct an identifier in a /// given location are ignored if typo correction already failed for it. IdentifierSourceLocations TypoCorrectionFailures; /// Worker object for performing CFG-based warnings. sema::AnalysisBasedWarnings AnalysisWarnings; threadSafety::BeforeSet ThreadSafetyDeclCache; /// An entity for which implicit template instantiation is required. /// /// The source location associated with the declaration is the first place in /// the source code where the declaration was "used". It is not necessarily /// the point of instantiation (which will be either before or after the /// namespace-scope declaration that triggered this implicit instantiation), /// However, it is the location that diagnostics should generally refer to, /// because users will need to know what code triggered the instantiation. typedef std::pair<ValueDecl , SourceLocation> PendingImplicitInstantiation; /// The queue of implicit template instantiations that are required /// but have not yet been performed. std::deque<PendingImplicitInstantiation> PendingInstantiations; /// Queue of implicit template instantiations that cannot be performed /// eagerly. SmallVector<PendingImplicitInstantiation, 1> LateParsedInstantiations; class GlobalEagerInstantiationScope { public: GlobalEagerInstantiationScope(Sema &S, bool Enabled) : S(S), Enabled(Enabled) { if (!Enabled) return; SavedPendingInstantiations.swap(S.PendingInstantiations); SavedVTableUses.swap(S.VTableUses); } void perform() { if (Enabled) { S.DefineUsedVTables(); S.PerformPendingInstantiations(); } } ~GlobalEagerInstantiationScope() { if (!Enabled) return; // Restore the set of pending vtables. assert(S.VTableUses.empty() && "VTableUses should be empty before it is discarded."); S.VTableUses.swap(SavedVTableUses); // Restore the set of pending implicit instantiations. if (S.TUKind != TU_Prefix \|\| !S.LangOpts.PCHInstantiateTemplates) { assert(S.PendingInstantiations.empty() && "PendingInstantiations should be empty before it is discarded."); S.PendingInstantiations.swap(SavedPendingInstantiations); } else { // Template instantiations in the PCH may be delayed until the TU. S.PendingInstantiations.swap(SavedPendingInstantiations); S.PendingInstantiations.insert(S.PendingInstantiations.end(), SavedPendingInstantiations.begin(), SavedPendingInstantiations.end()); } } private: Sema &S; SmallVector<VTableUse, 16> SavedVTableUses; std::deque<PendingImplicitInstantiation> SavedPendingInstantiations; bool Enabled; }; /// The queue of implicit template instantiations that are required /// and must be performed within the current local scope. /// /// This queue is only used for member functions of local classes in /// templates, which must be instantiated in the same scope as their /// enclosing function, so that they can reference function-local /// types, static variables, enumerators, etc. std::deque<PendingImplicitInstantiation> PendingLocalImplicitInstantiations; class LocalEagerInstantiationScope { public: LocalEagerInstantiationScope(Sema &S) : S(S) { SavedPendingLocalImplicitInstantiations.swap( S.PendingLocalImplicitInstantiations); } void perform() { S.PerformPendingInstantiations(/LocalOnly=/true); } ~LocalEagerInstantiationScope() { assert(S.PendingLocalImplicitInstantiations.empty() && "there shouldn't be any pending local implicit instantiations"); SavedPendingLocalImplicitInstantiations.swap( S.PendingLocalImplicitInstantiations); } private: Sema &S; std::deque<PendingImplicitInstantiation> SavedPendingLocalImplicitInstantiations; }; /// A helper class for building up ExtParameterInfos. class ExtParameterInfoBuilder { SmallVector<FunctionProtoType::ExtParameterInfo, 16> Infos; bool HasInteresting = false; public: /// Set the ExtParameterInfo for the parameter at the given index, /// void set(unsigned index, FunctionProtoType::ExtParameterInfo info) { assert(Infos.size() <= index); Infos.resize(index); Infos.push_back(info); if (!HasInteresting) HasInteresting = (info != FunctionProtoType::ExtParameterInfo()); } /// Return a pointer (suitable for setting in an ExtProtoInfo) to the /// ExtParameterInfo array we've built up. const FunctionProtoType::ExtParameterInfo * getPointerOrNull(unsigned numParams) { if (!HasInteresting) return nullptr; Infos.resize(numParams); return Infos.data(); } }; void PerformPendingInstantiations(bool LocalOnly = false); TypeSourceInfo SubstType(TypeSourceInfo T, const MultiLevelTemplateArgumentList &TemplateArgs, SourceLocation Loc, DeclarationName Entity, bool AllowDeducedTST = false); QualType SubstType(QualType T, const MultiLevelTemplateArgumentList &TemplateArgs, SourceLocation Loc, DeclarationName Entity); TypeSourceInfo SubstType(TypeLoc TL, const MultiLevelTemplateArgumentList &TemplateArgs, SourceLocation Loc, DeclarationName Entity); TypeSourceInfo SubstFunctionDeclType(TypeSourceInfo T, const MultiLevelTemplateArgumentList &TemplateArgs, SourceLocation Loc, DeclarationName Entity, CXXRecordDecl ThisContext, Qualifiers ThisTypeQuals); void SubstExceptionSpec(FunctionDecl New, const FunctionProtoType Proto, const MultiLevelTemplateArgumentList &Args); bool SubstExceptionSpec(SourceLocation Loc, FunctionProtoType::ExceptionSpecInfo &ESI, SmallVectorImpl<QualType> &ExceptionStorage, const MultiLevelTemplateArgumentList &Args); ParmVarDecl SubstParmVarDecl(ParmVarDecl D, const MultiLevelTemplateArgumentList &TemplateArgs, int indexAdjustment, Optional<unsigned> NumExpansions, bool ExpectParameterPack); bool SubstParmTypes(SourceLocation Loc, ArrayRef<ParmVarDecl > Params, const FunctionProtoType::ExtParameterInfo ExtParamInfos, const MultiLevelTemplateArgumentList &TemplateArgs, SmallVectorImpl<QualType> &ParamTypes, SmallVectorImpl<ParmVarDecl > OutParams, ExtParameterInfoBuilder &ParamInfos); ExprResult SubstExpr(Expr E, const MultiLevelTemplateArgumentList &TemplateArgs); /// Substitute the given template arguments into a list of /// expressions, expanding pack expansions if required. /// /// \param Exprs The list of expressions to substitute into. /// /// \param IsCall Whether this is some form of call, in which case /// default arguments will be dropped. /// /// \param TemplateArgs The set of template arguments to substitute. /// /// \param Outputs Will receive all of the substituted arguments. /// /// \returns true if an error occurred, false otherwise. bool SubstExprs(ArrayRef<Expr > Exprs, bool IsCall, const MultiLevelTemplateArgumentList &TemplateArgs, SmallVectorImpl<Expr > &Outputs); StmtResult SubstStmt(Stmt S, const MultiLevelTemplateArgumentList &TemplateArgs); TemplateParameterList * SubstTemplateParams(TemplateParameterList Params, DeclContext Owner, const MultiLevelTemplateArgumentList &TemplateArgs); bool SubstTemplateArguments(ArrayRef<TemplateArgumentLoc> Args, const MultiLevelTemplateArgumentList &TemplateArgs, TemplateArgumentListInfo &Outputs); Decl SubstDecl(Decl D, DeclContext Owner, const MultiLevelTemplateArgumentList &TemplateArgs); /// Substitute the name and return type of a defaulted 'operator<=>' to form /// an implicit 'operator=='. FunctionDecl SubstSpaceshipAsEqualEqual(CXXRecordDecl RD, FunctionDecl Spaceship); ExprResult SubstInitializer(Expr E, const MultiLevelTemplateArgumentList &TemplateArgs, bool CXXDirectInit); bool SubstBaseSpecifiers(CXXRecordDecl Instantiation, CXXRecordDecl Pattern, const MultiLevelTemplateArgumentList &TemplateArgs); bool InstantiateClass(SourceLocation PointOfInstantiation, CXXRecordDecl Instantiation, CXXRecordDecl Pattern, const MultiLevelTemplateArgumentList &TemplateArgs, TemplateSpecializationKind TSK, bool Complain = true); bool InstantiateEnum(SourceLocation PointOfInstantiation, EnumDecl Instantiation, EnumDecl Pattern, const MultiLevelTemplateArgumentList &TemplateArgs, TemplateSpecializationKind TSK); bool InstantiateInClassInitializer( SourceLocation PointOfInstantiation, FieldDecl Instantiation, FieldDecl Pattern, const MultiLevelTemplateArgumentList &TemplateArgs); struct LateInstantiatedAttribute { const Attr TmplAttr; LocalInstantiationScope Scope; Decl NewDecl; LateInstantiatedAttribute(const Attr A, LocalInstantiationScope S, Decl D) : TmplAttr(A), Scope(S), NewDecl(D) { } }; typedef SmallVector<LateInstantiatedAttribute, 16> LateInstantiatedAttrVec; void InstantiateAttrs(const MultiLevelTemplateArgumentList &TemplateArgs, const Decl Pattern, Decl Inst, LateInstantiatedAttrVec LateAttrs = nullptr, LocalInstantiationScope OuterMostScope = nullptr); void InstantiateAttrsForDecl(const MultiLevelTemplateArgumentList &TemplateArgs, const Decl Pattern, Decl Inst, LateInstantiatedAttrVec LateAttrs = nullptr, LocalInstantiationScope OuterMostScope = nullptr); void InstantiateDefaultCtorDefaultArgs(CXXConstructorDecl Ctor); bool usesPartialOrExplicitSpecialization( SourceLocation Loc, ClassTemplateSpecializationDecl ClassTemplateSpec); bool InstantiateClassTemplateSpecialization(SourceLocation PointOfInstantiation, ClassTemplateSpecializationDecl ClassTemplateSpec, TemplateSpecializationKind TSK, bool Complain = true); void InstantiateClassMembers(SourceLocation PointOfInstantiation, CXXRecordDecl Instantiation, const MultiLevelTemplateArgumentList &TemplateArgs, TemplateSpecializationKind TSK); void InstantiateClassTemplateSpecializationMembers( SourceLocation PointOfInstantiation, ClassTemplateSpecializationDecl ClassTemplateSpec, TemplateSpecializationKind TSK); NestedNameSpecifierLoc SubstNestedNameSpecifierLoc(NestedNameSpecifierLoc NNS, const MultiLevelTemplateArgumentList &TemplateArgs); DeclarationNameInfo SubstDeclarationNameInfo(const DeclarationNameInfo &NameInfo, const MultiLevelTemplateArgumentList &TemplateArgs); TemplateName SubstTemplateName(NestedNameSpecifierLoc QualifierLoc, TemplateName Name, SourceLocation Loc, const MultiLevelTemplateArgumentList &TemplateArgs); bool SubstTypeConstraint(TemplateTypeParmDecl Inst, const TypeConstraint TC, const MultiLevelTemplateArgumentList &TemplateArgs); bool InstantiateDefaultArgument(SourceLocation CallLoc, FunctionDecl FD, ParmVarDecl Param); void InstantiateExceptionSpec(SourceLocation PointOfInstantiation, FunctionDecl Function); bool CheckInstantiatedFunctionTemplateConstraints( SourceLocation PointOfInstantiation, FunctionDecl Decl, ArrayRef<TemplateArgument> TemplateArgs, ConstraintSatisfaction &Satisfaction); FunctionDecl InstantiateFunctionDeclaration(FunctionTemplateDecl FTD, const TemplateArgumentList Args, SourceLocation Loc); void InstantiateFunctionDefinition(SourceLocation PointOfInstantiation, FunctionDecl Function, bool Recursive = false, bool DefinitionRequired = false, bool AtEndOfTU = false); VarTemplateSpecializationDecl BuildVarTemplateInstantiation( VarTemplateDecl VarTemplate, VarDecl FromVar, const TemplateArgumentList &TemplateArgList, const TemplateArgumentListInfo &TemplateArgsInfo, SmallVectorImpl<TemplateArgument> &Converted, SourceLocation PointOfInstantiation, LateInstantiatedAttrVec LateAttrs = nullptr, LocalInstantiationScope StartingScope = nullptr); VarTemplateSpecializationDecl CompleteVarTemplateSpecializationDecl( VarTemplateSpecializationDecl VarSpec, VarDecl PatternDecl, const MultiLevelTemplateArgumentList &TemplateArgs); void BuildVariableInstantiation(VarDecl NewVar, VarDecl OldVar, const MultiLevelTemplateArgumentList &TemplateArgs, LateInstantiatedAttrVec LateAttrs, DeclContext Owner, LocalInstantiationScope StartingScope, bool InstantiatingVarTemplate = false, VarTemplateSpecializationDecl PrevVTSD = nullptr); void InstantiateVariableInitializer( VarDecl Var, VarDecl OldVar, const MultiLevelTemplateArgumentList &TemplateArgs); void InstantiateVariableDefinition(SourceLocation PointOfInstantiation, VarDecl Var, bool Recursive = false, bool DefinitionRequired = false, bool AtEndOfTU = false); void InstantiateMemInitializers(CXXConstructorDecl New, const CXXConstructorDecl Tmpl, const MultiLevelTemplateArgumentList &TemplateArgs); NamedDecl FindInstantiatedDecl(SourceLocation Loc, NamedDecl D, const MultiLevelTemplateArgumentList &TemplateArgs, bool FindingInstantiatedContext = false); DeclContext FindInstantiatedContext(SourceLocation Loc, DeclContext DC, const MultiLevelTemplateArgumentList &TemplateArgs); // Objective-C declarations. enum ObjCContainerKind { OCK_None = -1, OCK_Interface = 0, OCK_Protocol, OCK_Category, OCK_ClassExtension, OCK_Implementation, OCK_CategoryImplementation }; ObjCContainerKind getObjCContainerKind() const; DeclResult actOnObjCTypeParam(Scope S, ObjCTypeParamVariance variance, SourceLocation varianceLoc, unsigned index, IdentifierInfo paramName, SourceLocation paramLoc, SourceLocation colonLoc, ParsedType typeBound); ObjCTypeParamList actOnObjCTypeParamList(Scope S, SourceLocation lAngleLoc, ArrayRef<Decl > typeParams, SourceLocation rAngleLoc); void popObjCTypeParamList(Scope S, ObjCTypeParamList typeParamList); Decl ActOnStartClassInterface( Scope S, SourceLocation AtInterfaceLoc, IdentifierInfo ClassName, SourceLocation ClassLoc, ObjCTypeParamList typeParamList, IdentifierInfo SuperName, SourceLocation SuperLoc, ArrayRef<ParsedType> SuperTypeArgs, SourceRange SuperTypeArgsRange, Decl const ProtoRefs, unsigned NumProtoRefs, const SourceLocation ProtoLocs, SourceLocation EndProtoLoc, const ParsedAttributesView &AttrList); void ActOnSuperClassOfClassInterface(Scope S, SourceLocation AtInterfaceLoc, ObjCInterfaceDecl IDecl, IdentifierInfo ClassName, SourceLocation ClassLoc, IdentifierInfo SuperName, SourceLocation SuperLoc, ArrayRef<ParsedType> SuperTypeArgs, SourceRange SuperTypeArgsRange); void ActOnTypedefedProtocols(SmallVectorImpl<Decl > &ProtocolRefs, SmallVectorImpl<SourceLocation> &ProtocolLocs, IdentifierInfo SuperName, SourceLocation SuperLoc); Decl ActOnCompatibilityAlias( SourceLocation AtCompatibilityAliasLoc, IdentifierInfo AliasName, SourceLocation AliasLocation, IdentifierInfo ClassName, SourceLocation ClassLocation); bool CheckForwardProtocolDeclarationForCircularDependency( IdentifierInfo PName, SourceLocation &PLoc, SourceLocation PrevLoc, const ObjCList<ObjCProtocolDecl> &PList); Decl ActOnStartProtocolInterface( SourceLocation AtProtoInterfaceLoc, IdentifierInfo ProtocolName, SourceLocation ProtocolLoc, Decl const ProtoRefNames, unsigned NumProtoRefs, const SourceLocation ProtoLocs, SourceLocation EndProtoLoc, const ParsedAttributesView &AttrList); Decl ActOnStartCategoryInterface( SourceLocation AtInterfaceLoc, IdentifierInfo ClassName, SourceLocation ClassLoc, ObjCTypeParamList typeParamList, IdentifierInfo CategoryName, SourceLocation CategoryLoc, Decl const ProtoRefs, unsigned NumProtoRefs, const SourceLocation ProtoLocs, SourceLocation EndProtoLoc, const ParsedAttributesView &AttrList); Decl ActOnStartClassImplementation(SourceLocation AtClassImplLoc, IdentifierInfo ClassName, SourceLocation ClassLoc, IdentifierInfo SuperClassname, SourceLocation SuperClassLoc, const ParsedAttributesView &AttrList); Decl ActOnStartCategoryImplementation(SourceLocation AtCatImplLoc, IdentifierInfo ClassName, SourceLocation ClassLoc, IdentifierInfo CatName, SourceLocation CatLoc, const ParsedAttributesView &AttrList); DeclGroupPtrTy ActOnFinishObjCImplementation(Decl ObjCImpDecl, ArrayRef<Decl > Decls); DeclGroupPtrTy ActOnForwardClassDeclaration(SourceLocation Loc, IdentifierInfo *IdentList, SourceLocation IdentLocs, ArrayRef<ObjCTypeParamList > TypeParamLists, unsigned NumElts); DeclGroupPtrTy ActOnForwardProtocolDeclaration(SourceLocation AtProtoclLoc, ArrayRef<IdentifierLocPair> IdentList, const ParsedAttributesView &attrList); void FindProtocolDeclaration(bool WarnOnDeclarations, bool ForObjCContainer, ArrayRef<IdentifierLocPair> ProtocolId, SmallVectorImpl<Decl > &Protocols); void DiagnoseTypeArgsAndProtocols(IdentifierInfo ProtocolId, SourceLocation ProtocolLoc, IdentifierInfo TypeArgId, SourceLocation TypeArgLoc, bool SelectProtocolFirst = false); /// Given a list of identifiers (and their locations), resolve the /// names to either Objective-C protocol qualifiers or type /// arguments, as appropriate. void actOnObjCTypeArgsOrProtocolQualifiers( Scope S, ParsedType baseType, SourceLocation lAngleLoc, ArrayRef<IdentifierInfo > identifiers, ArrayRef<SourceLocation> identifierLocs, SourceLocation rAngleLoc, SourceLocation &typeArgsLAngleLoc, SmallVectorImpl<ParsedType> &typeArgs, SourceLocation &typeArgsRAngleLoc, SourceLocation &protocolLAngleLoc, SmallVectorImpl<Decl > &protocols, SourceLocation &protocolRAngleLoc, bool warnOnIncompleteProtocols); /// Build a an Objective-C protocol-qualified 'id' type where no /// base type was specified. TypeResult actOnObjCProtocolQualifierType( SourceLocation lAngleLoc, ArrayRef<Decl > protocols, ArrayRef<SourceLocation> protocolLocs, SourceLocation rAngleLoc); /// Build a specialized and/or protocol-qualified Objective-C type. TypeResult actOnObjCTypeArgsAndProtocolQualifiers( Scope S, SourceLocation Loc, ParsedType BaseType, SourceLocation TypeArgsLAngleLoc, ArrayRef<ParsedType> TypeArgs, SourceLocation TypeArgsRAngleLoc, SourceLocation ProtocolLAngleLoc, ArrayRef<Decl > Protocols, ArrayRef<SourceLocation> ProtocolLocs, SourceLocation ProtocolRAngleLoc); /// Build an Objective-C type parameter type. QualType BuildObjCTypeParamType(const ObjCTypeParamDecl Decl, SourceLocation ProtocolLAngleLoc, ArrayRef<ObjCProtocolDecl > Protocols, ArrayRef<SourceLocation> ProtocolLocs, SourceLocation ProtocolRAngleLoc, bool FailOnError = false); /// Build an Objective-C object pointer type. QualType BuildObjCObjectType(QualType BaseType, SourceLocation Loc, SourceLocation TypeArgsLAngleLoc, ArrayRef<TypeSourceInfo > TypeArgs, SourceLocation TypeArgsRAngleLoc, SourceLocation ProtocolLAngleLoc, ArrayRef<ObjCProtocolDecl > Protocols, ArrayRef<SourceLocation> ProtocolLocs, SourceLocation ProtocolRAngleLoc, bool FailOnError = false); /// Ensure attributes are consistent with type. /// \param [in, out] Attributes The attributes to check; they will /// be modified to be consistent with \p PropertyTy. void CheckObjCPropertyAttributes(Decl PropertyPtrTy, SourceLocation Loc, unsigned &Attributes, bool propertyInPrimaryClass); /// Process the specified property declaration and create decls for the /// setters and getters as needed. /// \param property The property declaration being processed void ProcessPropertyDecl(ObjCPropertyDecl property); void DiagnosePropertyMismatch(ObjCPropertyDecl Property, ObjCPropertyDecl SuperProperty, const IdentifierInfo Name, bool OverridingProtocolProperty); void DiagnoseClassExtensionDupMethods(ObjCCategoryDecl CAT, ObjCInterfaceDecl ID); Decl ActOnAtEnd(Scope S, SourceRange AtEnd, ArrayRef<Decl > allMethods = None, ArrayRef<DeclGroupPtrTy> allTUVars = None); Decl ActOnProperty(Scope S, SourceLocation AtLoc, SourceLocation LParenLoc, FieldDeclarator &FD, ObjCDeclSpec &ODS, Selector GetterSel, Selector SetterSel, tok::ObjCKeywordKind MethodImplKind, DeclContext lexicalDC = nullptr); Decl ActOnPropertyImplDecl(Scope S, SourceLocation AtLoc, SourceLocation PropertyLoc, bool ImplKind, IdentifierInfo PropertyId, IdentifierInfo PropertyIvar, SourceLocation PropertyIvarLoc, ObjCPropertyQueryKind QueryKind); enum ObjCSpecialMethodKind { OSMK_None, OSMK_Alloc, OSMK_New, OSMK_Copy, OSMK_RetainingInit, OSMK_NonRetainingInit }; struct ObjCArgInfo { IdentifierInfo Name; SourceLocation NameLoc; // The Type is null if no type was specified, and the DeclSpec is invalid // in this case. ParsedType Type; ObjCDeclSpec DeclSpec; /// ArgAttrs - Attribute list for this argument. ParsedAttributesView ArgAttrs; }; Decl ActOnMethodDeclaration( Scope S, SourceLocation BeginLoc, // location of the + or -. SourceLocation EndLoc, // location of the ; or {. tok::TokenKind MethodType, ObjCDeclSpec &ReturnQT, ParsedType ReturnType, ArrayRef<SourceLocation> SelectorLocs, Selector Sel, // optional arguments. The number of types/arguments is obtained // from the Sel.getNumArgs(). ObjCArgInfo ArgInfo, DeclaratorChunk::ParamInfo CParamInfo, unsigned CNumArgs, // c-style args const ParsedAttributesView &AttrList, tok::ObjCKeywordKind MethodImplKind, bool isVariadic, bool MethodDefinition); ObjCMethodDecl LookupMethodInQualifiedType(Selector Sel, const ObjCObjectPointerType OPT, bool IsInstance); ObjCMethodDecl LookupMethodInObjectType(Selector Sel, QualType Ty, bool IsInstance); bool CheckARCMethodDecl(ObjCMethodDecl method); bool inferObjCARCLifetime(ValueDecl decl); void deduceOpenCLAddressSpace(ValueDecl decl); ExprResult HandleExprPropertyRefExpr(const ObjCObjectPointerType OPT, Expr BaseExpr, SourceLocation OpLoc, DeclarationName MemberName, SourceLocation MemberLoc, SourceLocation SuperLoc, QualType SuperType, bool Super); ExprResult ActOnClassPropertyRefExpr(IdentifierInfo &receiverName, IdentifierInfo &propertyName, SourceLocation receiverNameLoc, SourceLocation propertyNameLoc); ObjCMethodDecl tryCaptureObjCSelf(SourceLocation Loc); /// Describes the kind of message expression indicated by a message /// send that starts with an identifier. enum ObjCMessageKind { /// The message is sent to 'super'. ObjCSuperMessage, /// The message is an instance message. ObjCInstanceMessage, /// The message is a class message, and the identifier is a type /// name. ObjCClassMessage }; ObjCMessageKind getObjCMessageKind(Scope S, IdentifierInfo Name, SourceLocation NameLoc, bool IsSuper, bool HasTrailingDot, ParsedType &ReceiverType); ExprResult ActOnSuperMessage(Scope S, SourceLocation SuperLoc, Selector Sel, SourceLocation LBracLoc, ArrayRef<SourceLocation> SelectorLocs, SourceLocation RBracLoc, MultiExprArg Args); ExprResult BuildClassMessage(TypeSourceInfo ReceiverTypeInfo, QualType ReceiverType, SourceLocation SuperLoc, Selector Sel, ObjCMethodDecl Method, SourceLocation LBracLoc, ArrayRef<SourceLocation> SelectorLocs, SourceLocation RBracLoc, MultiExprArg Args, bool isImplicit = false); ExprResult BuildClassMessageImplicit(QualType ReceiverType, bool isSuperReceiver, SourceLocation Loc, Selector Sel, ObjCMethodDecl Method, MultiExprArg Args); ExprResult ActOnClassMessage(Scope S, ParsedType Receiver, Selector Sel, SourceLocation LBracLoc, ArrayRef<SourceLocation> SelectorLocs, SourceLocation RBracLoc, MultiExprArg Args); ExprResult BuildInstanceMessage(Expr Receiver, QualType ReceiverType, SourceLocation SuperLoc, Selector Sel, ObjCMethodDecl Method, SourceLocation LBracLoc, ArrayRef<SourceLocation> SelectorLocs, SourceLocation RBracLoc, MultiExprArg Args, bool isImplicit = false); ExprResult BuildInstanceMessageImplicit(Expr Receiver, QualType ReceiverType, SourceLocation Loc, Selector Sel, ObjCMethodDecl Method, MultiExprArg Args); ExprResult ActOnInstanceMessage(Scope S, Expr Receiver, Selector Sel, SourceLocation LBracLoc, ArrayRef<SourceLocation> SelectorLocs, SourceLocation RBracLoc, MultiExprArg Args); ExprResult BuildObjCBridgedCast(SourceLocation LParenLoc, ObjCBridgeCastKind Kind, SourceLocation BridgeKeywordLoc, TypeSourceInfo TSInfo, Expr SubExpr); ExprResult ActOnObjCBridgedCast(Scope S, SourceLocation LParenLoc, ObjCBridgeCastKind Kind, SourceLocation BridgeKeywordLoc, ParsedType Type, SourceLocation RParenLoc, Expr SubExpr); void CheckTollFreeBridgeCast(QualType castType, Expr castExpr); void CheckObjCBridgeRelatedCast(QualType castType, Expr castExpr); bool CheckTollFreeBridgeStaticCast(QualType castType, Expr castExpr, CastKind &Kind); bool checkObjCBridgeRelatedComponents(SourceLocation Loc, QualType DestType, QualType SrcType, ObjCInterfaceDecl &RelatedClass, ObjCMethodDecl &ClassMethod, ObjCMethodDecl &InstanceMethod, TypedefNameDecl &TDNDecl, bool CfToNs, bool Diagnose = true); bool CheckObjCBridgeRelatedConversions(SourceLocation Loc, QualType DestType, QualType SrcType, Expr &SrcExpr, bool Diagnose = true); bool CheckConversionToObjCLiteral(QualType DstType, Expr &SrcExpr, bool Diagnose = true); bool checkInitMethod(ObjCMethodDecl method, QualType receiverTypeIfCall); /// Check whether the given new method is a valid override of the /// given overridden method, and set any properties that should be inherited. void CheckObjCMethodOverride(ObjCMethodDecl NewMethod, const ObjCMethodDecl Overridden); /// Describes the compatibility of a result type with its method. enum ResultTypeCompatibilityKind { RTC_Compatible, RTC_Incompatible, RTC_Unknown }; void CheckObjCMethodDirectOverrides(ObjCMethodDecl method, ObjCMethodDecl overridden); void CheckObjCMethodOverrides(ObjCMethodDecl ObjCMethod, ObjCInterfaceDecl CurrentClass, ResultTypeCompatibilityKind RTC); enum PragmaOptionsAlignKind { POAK_Native, // #pragma options align=native POAK_Natural, // #pragma options align=natural POAK_Packed, // #pragma options align=packed POAK_Power, // #pragma options align=power POAK_Mac68k, // #pragma options align=mac68k POAK_Reset // #pragma options align=reset }; /// ActOnPragmaClangSection - Called on well formed \#pragma clang section void ActOnPragmaClangSection(SourceLocation PragmaLoc, PragmaClangSectionAction Action, PragmaClangSectionKind SecKind, StringRef SecName); /// ActOnPragmaOptionsAlign - Called on well formed \#pragma options align. void ActOnPragmaOptionsAlign(PragmaOptionsAlignKind Kind, SourceLocation PragmaLoc); /// ActOnPragmaPack - Called on well formed \#pragma pack(...). void ActOnPragmaPack(SourceLocation PragmaLoc, PragmaMsStackAction Action, StringRef SlotLabel, Expr Alignment); enum class PragmaAlignPackDiagnoseKind { NonDefaultStateAtInclude, ChangedStateAtExit }; void DiagnoseNonDefaultPragmaAlignPack(PragmaAlignPackDiagnoseKind Kind, SourceLocation IncludeLoc); void DiagnoseUnterminatedPragmaAlignPack(); /// ActOnPragmaMSStruct - Called on well formed \#pragma ms_struct [on\|off]. void ActOnPragmaMSStruct(PragmaMSStructKind Kind); /// ActOnPragmaMSComment - Called on well formed /// \#pragma comment(kind, "arg"). void ActOnPragmaMSComment(SourceLocation CommentLoc, PragmaMSCommentKind Kind, StringRef Arg); /// ActOnPragmaMSPointersToMembers - called on well formed \#pragma /// pointers_to_members(representation method[, general purpose /// representation]). void ActOnPragmaMSPointersToMembers( LangOptions::PragmaMSPointersToMembersKind Kind, SourceLocation PragmaLoc); /// Called on well formed \#pragma vtordisp(). void ActOnPragmaMSVtorDisp(PragmaMsStackAction Action, SourceLocation PragmaLoc, MSVtorDispMode Value); enum PragmaSectionKind { PSK_DataSeg, PSK_BSSSeg, PSK_ConstSeg, PSK_CodeSeg, }; bool UnifySection(StringRef SectionName, int SectionFlags, NamedDecl TheDecl); bool UnifySection(StringRef SectionName, int SectionFlags, SourceLocation PragmaSectionLocation); /// Called on well formed \#pragma bss_seg/data_seg/const_seg/code_seg. void ActOnPragmaMSSeg(SourceLocation PragmaLocation, PragmaMsStackAction Action, llvm::StringRef StackSlotLabel, StringLiteral SegmentName, llvm::StringRef PragmaName); /// Called on well formed \#pragma section(). void ActOnPragmaMSSection(SourceLocation PragmaLocation, int SectionFlags, StringLiteral SegmentName); /// Called on well-formed \#pragma init_seg(). void ActOnPragmaMSInitSeg(SourceLocation PragmaLocation, StringLiteral SegmentName); /// Called on #pragma clang __debug dump II void ActOnPragmaDump(Scope S, SourceLocation Loc, IdentifierInfo II); /// ActOnPragmaDetectMismatch - Call on well-formed \#pragma detect_mismatch void ActOnPragmaDetectMismatch(SourceLocation Loc, StringRef Name, StringRef Value); /// Are precise floating point semantics currently enabled? bool isPreciseFPEnabled() { return !CurFPFeatures.getAllowFPReassociate() && !CurFPFeatures.getNoSignedZero() && !CurFPFeatures.getAllowReciprocal() && !CurFPFeatures.getAllowApproxFunc(); } /// ActOnPragmaFloatControl - Call on well-formed \#pragma float_control void ActOnPragmaFloatControl(SourceLocation Loc, PragmaMsStackAction Action, PragmaFloatControlKind Value); /// ActOnPragmaUnused - Called on well-formed '\#pragma unused'. void ActOnPragmaUnused(const Token &Identifier, Scope curScope, SourceLocation PragmaLoc); /// ActOnPragmaVisibility - Called on well formed \#pragma GCC visibility... . void ActOnPragmaVisibility(const IdentifierInfo* VisType, SourceLocation PragmaLoc); NamedDecl DeclClonePragmaWeak(NamedDecl ND, IdentifierInfo II, SourceLocation Loc); void DeclApplyPragmaWeak(Scope S, NamedDecl ND, WeakInfo &W); /// ActOnPragmaWeakID - Called on well formed \#pragma weak ident. void ActOnPragmaWeakID(IdentifierInfo WeakName, SourceLocation PragmaLoc, SourceLocation WeakNameLoc); /// ActOnPragmaRedefineExtname - Called on well formed /// \#pragma redefine_extname oldname newname. void ActOnPragmaRedefineExtname(IdentifierInfo* WeakName, IdentifierInfo* AliasName, SourceLocation PragmaLoc, SourceLocation WeakNameLoc, SourceLocation AliasNameLoc); /// ActOnPragmaWeakAlias - Called on well formed \#pragma weak ident = ident. void ActOnPragmaWeakAlias(IdentifierInfo* WeakName, IdentifierInfo* AliasName, SourceLocation PragmaLoc, SourceLocation WeakNameLoc, SourceLocation AliasNameLoc); /// ActOnPragmaFPContract - Called on well formed /// \#pragma {STDC,OPENCL} FP_CONTRACT and /// \#pragma clang fp contract void ActOnPragmaFPContract(SourceLocation Loc, LangOptions::FPModeKind FPC); /// Called on well formed /// \#pragma clang fp reassociate void ActOnPragmaFPReassociate(SourceLocation Loc, bool IsEnabled); /// ActOnPragmaFenvAccess - Called on well formed /// \#pragma STDC FENV_ACCESS void ActOnPragmaFEnvAccess(SourceLocation Loc, bool IsEnabled); /// Called on well formed '\#pragma clang fp' that has option 'exceptions'. void ActOnPragmaFPExceptions(SourceLocation Loc, LangOptions::FPExceptionModeKind); /// Called to set constant rounding mode for floating point operations. void setRoundingMode(SourceLocation Loc, llvm::RoundingMode); /// Called to set exception behavior for floating point operations. void setExceptionMode(SourceLocation Loc, LangOptions::FPExceptionModeKind); /// AddAlignmentAttributesForRecord - Adds any needed alignment attributes to /// a the record decl, to handle '\#pragma pack' and '\#pragma options align'. void AddAlignmentAttributesForRecord(RecordDecl RD); /// AddMsStructLayoutForRecord - Adds ms_struct layout attribute to record. void AddMsStructLayoutForRecord(RecordDecl RD); /// PushNamespaceVisibilityAttr - Note that we've entered a /// namespace with a visibility attribute. void PushNamespaceVisibilityAttr(const VisibilityAttr Attr, SourceLocation Loc); /// AddPushedVisibilityAttribute - If '\#pragma GCC visibility' was used, /// add an appropriate visibility attribute. void AddPushedVisibilityAttribute(Decl RD); /// PopPragmaVisibility - Pop the top element of the visibility stack; used /// for '\#pragma GCC visibility' and visibility attributes on namespaces. void PopPragmaVisibility(bool IsNamespaceEnd, SourceLocation EndLoc); /// FreeVisContext - Deallocate and null out VisContext. void FreeVisContext(); /// AddCFAuditedAttribute - Check whether we're currently within /// '\#pragma clang arc_cf_code_audited' and, if so, consider adding /// the appropriate attribute. void AddCFAuditedAttribute(Decl D); void ActOnPragmaAttributeAttribute(ParsedAttr &Attribute, SourceLocation PragmaLoc, attr::ParsedSubjectMatchRuleSet Rules); void ActOnPragmaAttributeEmptyPush(SourceLocation PragmaLoc, const IdentifierInfo Namespace); /// Called on well-formed '\#pragma clang attribute pop'. void ActOnPragmaAttributePop(SourceLocation PragmaLoc, const IdentifierInfo Namespace); /// Adds the attributes that have been specified using the /// '\#pragma clang attribute push' directives to the given declaration. void AddPragmaAttributes(Scope S, Decl D); void DiagnoseUnterminatedPragmaAttribute(); /// Called on well formed \#pragma clang optimize. void ActOnPragmaOptimize(bool On, SourceLocation PragmaLoc); /// Get the location for the currently active "\#pragma clang optimize /// off". If this location is invalid, then the state of the pragma is "on". SourceLocation getOptimizeOffPragmaLocation() const { return OptimizeOffPragmaLocation; } /// Only called on function definitions; if there is a pragma in scope /// with the effect of a range-based optnone, consider marking the function /// with attribute optnone. void AddRangeBasedOptnone(FunctionDecl FD); /// Adds the 'optnone' attribute to the function declaration if there /// are no conflicts; Loc represents the location causing the 'optnone' /// attribute to be added (usually because of a pragma). void AddOptnoneAttributeIfNoConflicts(FunctionDecl FD, SourceLocation Loc); void AddIntelFPGABankBitsAttr(Decl D, const AttributeCommonInfo &CI, Expr *Exprs, unsigned Size); template <typename AttrType> void addIntelTripleArgAttr(Decl D, const AttributeCommonInfo &CI, Expr XDimExpr, Expr YDimExpr, Expr ZDimExpr); void AddWorkGroupSizeHintAttr(Decl D, const AttributeCommonInfo &CI, Expr XDim, Expr YDim, Expr ZDim); WorkGroupSizeHintAttr MergeWorkGroupSizeHintAttr(Decl D, const WorkGroupSizeHintAttr &A); void AddIntelReqdSubGroupSize(Decl D, const AttributeCommonInfo &CI, Expr E); IntelReqdSubGroupSizeAttr MergeIntelReqdSubGroupSizeAttr(Decl D, const IntelReqdSubGroupSizeAttr &A); IntelNamedSubGroupSizeAttr MergeIntelNamedSubGroupSizeAttr(Decl D, const IntelNamedSubGroupSizeAttr &A); void AddSYCLIntelNumSimdWorkItemsAttr(Decl D, const AttributeCommonInfo &CI, Expr E); SYCLIntelNumSimdWorkItemsAttr MergeSYCLIntelNumSimdWorkItemsAttr(Decl D, const SYCLIntelNumSimdWorkItemsAttr &A); void AddSYCLIntelESimdVectorizeAttr(Decl D, const AttributeCommonInfo &CI, Expr E); SYCLIntelESimdVectorizeAttr MergeSYCLIntelESimdVectorizeAttr(Decl D, const SYCLIntelESimdVectorizeAttr &A); void AddSYCLIntelSchedulerTargetFmaxMhzAttr(Decl D, const AttributeCommonInfo &CI, Expr E); SYCLIntelSchedulerTargetFmaxMhzAttr MergeSYCLIntelSchedulerTargetFmaxMhzAttr( Decl D, const SYCLIntelSchedulerTargetFmaxMhzAttr &A); void AddSYCLIntelNoGlobalWorkOffsetAttr(Decl D, const AttributeCommonInfo &CI, Expr E); SYCLIntelNoGlobalWorkOffsetAttr MergeSYCLIntelNoGlobalWorkOffsetAttr( Decl D, const SYCLIntelNoGlobalWorkOffsetAttr &A); void AddSYCLIntelLoopFuseAttr(Decl D, const AttributeCommonInfo &CI, Expr E); SYCLIntelLoopFuseAttr MergeSYCLIntelLoopFuseAttr(Decl D, const SYCLIntelLoopFuseAttr &A); void AddIntelFPGAPrivateCopiesAttr(Decl D, const AttributeCommonInfo &CI, Expr E); void AddIntelFPGAMaxReplicatesAttr(Decl D, const AttributeCommonInfo &CI, Expr E); IntelFPGAMaxReplicatesAttr MergeIntelFPGAMaxReplicatesAttr(Decl D, const IntelFPGAMaxReplicatesAttr &A); void AddIntelFPGAForcePow2DepthAttr(Decl D, const AttributeCommonInfo &CI, Expr E); IntelFPGAForcePow2DepthAttr MergeIntelFPGAForcePow2DepthAttr(Decl D, const IntelFPGAForcePow2DepthAttr &A); void AddSYCLIntelFPGAInitiationIntervalAttr(Decl D, const AttributeCommonInfo &CI, Expr E); SYCLIntelFPGAInitiationIntervalAttr MergeSYCLIntelFPGAInitiationIntervalAttr( Decl D, const SYCLIntelFPGAInitiationIntervalAttr &A); SYCLIntelFPGAMaxConcurrencyAttr MergeSYCLIntelFPGAMaxConcurrencyAttr( Decl D, const SYCLIntelFPGAMaxConcurrencyAttr &A); void AddSYCLIntelMaxGlobalWorkDimAttr(Decl D, const AttributeCommonInfo &CI, Expr E); SYCLIntelMaxGlobalWorkDimAttr MergeSYCLIntelMaxGlobalWorkDimAttr(Decl D, const SYCLIntelMaxGlobalWorkDimAttr &A); void AddIntelFPGABankWidthAttr(Decl D, const AttributeCommonInfo &CI, Expr E); IntelFPGABankWidthAttr MergeIntelFPGABankWidthAttr(Decl D, const IntelFPGABankWidthAttr &A); void AddIntelFPGANumBanksAttr(Decl D, const AttributeCommonInfo &CI, Expr E); IntelFPGANumBanksAttr MergeIntelFPGANumBanksAttr(Decl D, const IntelFPGANumBanksAttr &A); /// AddAlignedAttr - Adds an aligned attribute to a particular declaration. void AddAlignedAttr(Decl D, const AttributeCommonInfo &CI, Expr E, bool IsPackExpansion); void AddAlignedAttr(Decl D, const AttributeCommonInfo &CI, TypeSourceInfo T, bool IsPackExpansion); /// AddAssumeAlignedAttr - Adds an assume_aligned attribute to a particular /// declaration. void AddAssumeAlignedAttr(Decl D, const AttributeCommonInfo &CI, Expr E, Expr OE); /// AddAllocAlignAttr - Adds an alloc_align attribute to a particular /// declaration. void AddAllocAlignAttr(Decl D, const AttributeCommonInfo &CI, Expr ParamExpr); /// AddAlignValueAttr - Adds an align_value attribute to a particular /// declaration. void AddAlignValueAttr(Decl D, const AttributeCommonInfo &CI, Expr E); /// AddAnnotationAttr - Adds an annotation Annot with Args arguments to D. void AddAnnotationAttr(Decl D, const AttributeCommonInfo &CI, StringRef Annot, MutableArrayRef<Expr > Args); /// AddLaunchBoundsAttr - Adds a launch_bounds attribute to a particular /// declaration. void AddLaunchBoundsAttr(Decl D, const AttributeCommonInfo &CI, Expr MaxThreads, Expr MinBlocks); /// AddModeAttr - Adds a mode attribute to a particular declaration. void AddModeAttr(Decl D, const AttributeCommonInfo &CI, IdentifierInfo Name, bool InInstantiation = false); void AddParameterABIAttr(Decl D, const AttributeCommonInfo &CI, ParameterABI ABI); enum class RetainOwnershipKind {NS, CF, OS}; void AddXConsumedAttr(Decl D, const AttributeCommonInfo &CI, RetainOwnershipKind K, bool IsTemplateInstantiation); /// addAMDGPUFlatWorkGroupSizeAttr - Adds an amdgpu_flat_work_group_size /// attribute to a particular declaration. void addAMDGPUFlatWorkGroupSizeAttr(Decl D, const AttributeCommonInfo &CI, Expr Min, Expr Max); /// addAMDGPUWavePersEUAttr - Adds an amdgpu_waves_per_eu attribute to a /// particular declaration. void addAMDGPUWavesPerEUAttr(Decl D, const AttributeCommonInfo &CI, Expr Min, Expr Max); /// addSYCLIntelPipeIOAttr - Adds a pipe I/O attribute to a particular /// declaration. void addSYCLIntelPipeIOAttr(Decl D, const AttributeCommonInfo &CI, Expr ID); /// AddSYCLIntelFPGAMaxConcurrencyAttr - Adds a max_concurrency attribute to a /// particular declaration. void AddSYCLIntelFPGAMaxConcurrencyAttr(Decl D, const AttributeCommonInfo &CI, Expr E); bool checkNSReturnsRetainedReturnType(SourceLocation loc, QualType type); bool checkAllowedSYCLInitializer(VarDecl VD, bool CheckValueDependent = false); //===--------------------------------------------------------------------===// // C++ Coroutines TS // bool ActOnCoroutineBodyStart(Scope S, SourceLocation KwLoc, StringRef Keyword); ExprResult ActOnCoawaitExpr(Scope S, SourceLocation KwLoc, Expr E); ExprResult ActOnCoyieldExpr(Scope S, SourceLocation KwLoc, Expr E); StmtResult ActOnCoreturnStmt(Scope S, SourceLocation KwLoc, Expr E); ExprResult BuildResolvedCoawaitExpr(SourceLocation KwLoc, Expr E, bool IsImplicit = false); ExprResult BuildUnresolvedCoawaitExpr(SourceLocation KwLoc, Expr E, UnresolvedLookupExpr Lookup); ExprResult BuildCoyieldExpr(SourceLocation KwLoc, Expr E); StmtResult BuildCoreturnStmt(SourceLocation KwLoc, Expr E, bool IsImplicit = false); StmtResult BuildCoroutineBodyStmt(CoroutineBodyStmt::CtorArgs); bool buildCoroutineParameterMoves(SourceLocation Loc); VarDecl buildCoroutinePromise(SourceLocation Loc); void CheckCompletedCoroutineBody(FunctionDecl FD, Stmt &Body); ClassTemplateDecl lookupCoroutineTraits(SourceLocation KwLoc, SourceLocation FuncLoc); /// Check that the expression co_await promise.final_suspend() shall not be /// potentially-throwing. bool checkFinalSuspendNoThrow(const Stmt FinalSuspend); //===--------------------------------------------------------------------===// // OpenMP directives and clauses. // private: void VarDataSharingAttributesStack; struct DeclareTargetContextInfo { struct MapInfo { OMPDeclareTargetDeclAttr::MapTypeTy MT; SourceLocation Loc; }; /// Explicitly listed variables and functions in a 'to' or 'link' clause. llvm::DenseMap<NamedDecl , MapInfo> ExplicitlyMapped; /// The 'device_type' as parsed from the clause. OMPDeclareTargetDeclAttr::DevTypeTy DT = OMPDeclareTargetDeclAttr::DT_Any; /// The directive kind, `begin declare target` or `declare target`. OpenMPDirectiveKind Kind; /// The directive location. SourceLocation Loc; DeclareTargetContextInfo(OpenMPDirectiveKind Kind, SourceLocation Loc) : Kind(Kind), Loc(Loc) {} }; /// Number of nested '#pragma omp declare target' directives. SmallVector<DeclareTargetContextInfo, 4> DeclareTargetNesting; /// Initialization of data-sharing attributes stack. void InitDataSharingAttributesStack(); void DestroyDataSharingAttributesStack(); ExprResult VerifyPositiveIntegerConstantInClause(Expr Op, OpenMPClauseKind CKind, bool StrictlyPositive = true, bool SuppressExprDiags = false); /// Returns OpenMP nesting level for current directive. unsigned getOpenMPNestingLevel() const; /// Adjusts the function scopes index for the target-based regions. void adjustOpenMPTargetScopeIndex(unsigned &FunctionScopesIndex, unsigned Level) const; /// Returns the number of scopes associated with the construct on the given /// OpenMP level. int getNumberOfConstructScopes(unsigned Level) const; /// Push new OpenMP function region for non-capturing function. void pushOpenMPFunctionRegion(); /// Pop OpenMP function region for non-capturing function. void popOpenMPFunctionRegion(const sema::FunctionScopeInfo OldFSI); /// Analyzes and checks a loop nest for use by a loop transformation. /// /// \param Kind The loop transformation directive kind. /// \param NumLoops How many nested loops the directive is expecting. /// \param AStmt Associated statement of the transformation directive. /// \param LoopHelpers [out] The loop analysis result. /// \param Body [out] The body code nested in \p NumLoops loop. /// \param OriginalInits [out] Collection of statements and declarations that /// must have been executed/declared before entering the /// loop. /// /// \return Whether there was any error. bool checkTransformableLoopNest( OpenMPDirectiveKind Kind, Stmt AStmt, int NumLoops, SmallVectorImpl<OMPLoopBasedDirective::HelperExprs> &LoopHelpers, Stmt &Body, SmallVectorImpl<SmallVector<llvm::PointerUnion<Stmt , Decl >, 0>> &OriginalInits); /// Helper to keep information about the current `omp begin/end declare /// variant` nesting. struct OMPDeclareVariantScope { /// The associated OpenMP context selector. OMPTraitInfo TI; /// The associated OpenMP context selector mangling. std::string NameSuffix; OMPDeclareVariantScope(OMPTraitInfo &TI); }; /// Return the OMPTraitInfo for the surrounding scope, if any. OMPTraitInfo getOMPTraitInfoForSurroundingScope() { return OMPDeclareVariantScopes.empty() ? nullptr : OMPDeclareVariantScopes.back().TI; } /// The current `omp begin/end declare variant` scopes. SmallVector<OMPDeclareVariantScope, 4> OMPDeclareVariantScopes; /// The current `omp begin/end assumes` scopes. SmallVector<AssumptionAttr , 4> OMPAssumeScoped; /// All `omp assumes` we encountered so far. SmallVector<AssumptionAttr , 4> OMPAssumeGlobal; public: /// The declarator \p D defines a function in the scope \p S which is nested /// in an `omp begin/end declare variant` scope. In this method we create a /// declaration for \p D and rename \p D according to the OpenMP context /// selector of the surrounding scope. Return all base functions in \p Bases. void ActOnStartOfFunctionDefinitionInOpenMPDeclareVariantScope( Scope S, Declarator &D, MultiTemplateParamsArg TemplateParameterLists, SmallVectorImpl<FunctionDecl > &Bases); /// Register \p D as specialization of all base functions in \p Bases in the /// current `omp begin/end declare variant` scope. void ActOnFinishedFunctionDefinitionInOpenMPDeclareVariantScope( Decl D, SmallVectorImpl<FunctionDecl > &Bases); /// Act on \p D, a function definition inside of an `omp [begin/end] assumes`. void ActOnFinishedFunctionDefinitionInOpenMPAssumeScope(Decl D); /// Can we exit an OpenMP declare variant scope at the moment. bool isInOpenMPDeclareVariantScope() const { return !OMPDeclareVariantScopes.empty(); } /// Given the potential call expression \p Call, determine if there is a /// specialization via the OpenMP declare variant mechanism available. If /// there is, return the specialized call expression, otherwise return the /// original \p Call. ExprResult ActOnOpenMPCall(ExprResult Call, Scope Scope, SourceLocation LParenLoc, MultiExprArg ArgExprs, SourceLocation RParenLoc, Expr ExecConfig); /// Handle a `omp begin declare variant`. void ActOnOpenMPBeginDeclareVariant(SourceLocation Loc, OMPTraitInfo &TI); /// Handle a `omp end declare variant`. void ActOnOpenMPEndDeclareVariant(); /// Checks if the variant/multiversion functions are compatible. bool areMultiversionVariantFunctionsCompatible( const FunctionDecl OldFD, const FunctionDecl NewFD, const PartialDiagnostic &NoProtoDiagID, const PartialDiagnosticAt &NoteCausedDiagIDAt, const PartialDiagnosticAt &NoSupportDiagIDAt, const PartialDiagnosticAt &DiffDiagIDAt, bool TemplatesSupported, bool ConstexprSupported, bool CLinkageMayDiffer); /// Function tries to capture lambda's captured variables in the OpenMP region /// before the original lambda is captured. void tryCaptureOpenMPLambdas(ValueDecl V); /// Return true if the provided declaration \a VD should be captured by /// reference. /// \param Level Relative level of nested OpenMP construct for that the check /// is performed. /// \param OpenMPCaptureLevel Capture level within an OpenMP construct. bool isOpenMPCapturedByRef(const ValueDecl D, unsigned Level, unsigned OpenMPCaptureLevel) const; /// Check if the specified variable is used in one of the private /// clauses (private, firstprivate, lastprivate, reduction etc.) in OpenMP /// constructs. VarDecl isOpenMPCapturedDecl(ValueDecl D, bool CheckScopeInfo = false, unsigned StopAt = 0); ExprResult getOpenMPCapturedExpr(VarDecl Capture, ExprValueKind VK, ExprObjectKind OK, SourceLocation Loc); /// If the current region is a loop-based region, mark the start of the loop /// construct. void startOpenMPLoop(); /// If the current region is a range loop-based region, mark the start of the /// loop construct. void startOpenMPCXXRangeFor(); /// Check if the specified variable is used in 'private' clause. /// \param Level Relative level of nested OpenMP construct for that the check /// is performed. OpenMPClauseKind isOpenMPPrivateDecl(ValueDecl D, unsigned Level, unsigned CapLevel) const; /// Sets OpenMP capture kind (OMPC_private, OMPC_firstprivate, OMPC_map etc.) /// for \p FD based on DSA for the provided corresponding captured declaration /// \p D. void setOpenMPCaptureKind(FieldDecl FD, const ValueDecl D, unsigned Level); /// Check if the specified variable is captured by 'target' directive. /// \param Level Relative level of nested OpenMP construct for that the check /// is performed. bool isOpenMPTargetCapturedDecl(const ValueDecl D, unsigned Level, unsigned CaptureLevel) const; /// Check if the specified global variable must be captured by outer capture /// regions. /// \param Level Relative level of nested OpenMP construct for that /// the check is performed. bool isOpenMPGlobalCapturedDecl(ValueDecl D, unsigned Level, unsigned CaptureLevel) const; ExprResult PerformOpenMPImplicitIntegerConversion(SourceLocation OpLoc, Expr Op); /// Called on start of new data sharing attribute block. void StartOpenMPDSABlock(OpenMPDirectiveKind K, const DeclarationNameInfo &DirName, Scope CurScope, SourceLocation Loc); /// Start analysis of clauses. void StartOpenMPClause(OpenMPClauseKind K); /// End analysis of clauses. void EndOpenMPClause(); /// Called on end of data sharing attribute block. void EndOpenMPDSABlock(Stmt CurDirective); /// Check if the current region is an OpenMP loop region and if it is, /// mark loop control variable, used in \p Init for loop initialization, as /// private by default. /// \param Init First part of the for loop. void ActOnOpenMPLoopInitialization(SourceLocation ForLoc, Stmt Init); /// Called on well-formed '\#pragma omp metadirective' after parsing /// of the associated statement. StmtResult ActOnOpenMPMetaDirective(ArrayRef<OMPClause > Clauses, Stmt AStmt, SourceLocation StartLoc, SourceLocation EndLoc); // OpenMP directives and clauses. /// Called on correct id-expression from the '#pragma omp /// threadprivate'. ExprResult ActOnOpenMPIdExpression(Scope CurScope, CXXScopeSpec &ScopeSpec, const DeclarationNameInfo &Id, OpenMPDirectiveKind Kind); /// Called on well-formed '#pragma omp threadprivate'. DeclGroupPtrTy ActOnOpenMPThreadprivateDirective( SourceLocation Loc, ArrayRef<Expr > VarList); /// Builds a new OpenMPThreadPrivateDecl and checks its correctness. OMPThreadPrivateDecl CheckOMPThreadPrivateDecl(SourceLocation Loc, ArrayRef<Expr > VarList); /// Called on well-formed '#pragma omp allocate'. DeclGroupPtrTy ActOnOpenMPAllocateDirective(SourceLocation Loc, ArrayRef<Expr > VarList, ArrayRef<OMPClause > Clauses, DeclContext Owner = nullptr); /// Called on well-formed '#pragma omp [begin] assume[s]'. void ActOnOpenMPAssumesDirective(SourceLocation Loc, OpenMPDirectiveKind DKind, ArrayRef<std::string> Assumptions, bool SkippedClauses); /// Check if there is an active global `omp begin assumes` directive. bool isInOpenMPAssumeScope() const { return !OMPAssumeScoped.empty(); } /// Check if there is an active global `omp assumes` directive. bool hasGlobalOpenMPAssumes() const { return !OMPAssumeGlobal.empty(); } /// Called on well-formed '#pragma omp end assumes'. void ActOnOpenMPEndAssumesDirective(); /// Called on well-formed '#pragma omp requires'. DeclGroupPtrTy ActOnOpenMPRequiresDirective(SourceLocation Loc, ArrayRef<OMPClause > ClauseList); /// Check restrictions on Requires directive OMPRequiresDecl CheckOMPRequiresDecl(SourceLocation Loc, ArrayRef<OMPClause > Clauses); /// Check if the specified type is allowed to be used in 'omp declare /// reduction' construct. QualType ActOnOpenMPDeclareReductionType(SourceLocation TyLoc, TypeResult ParsedType); /// Called on start of '#pragma omp declare reduction'. DeclGroupPtrTy ActOnOpenMPDeclareReductionDirectiveStart( Scope S, DeclContext DC, DeclarationName Name, ArrayRef<std::pair<QualType, SourceLocation>> ReductionTypes, AccessSpecifier AS, Decl PrevDeclInScope = nullptr); /// Initialize declare reduction construct initializer. void ActOnOpenMPDeclareReductionCombinerStart(Scope S, Decl D); /// Finish current declare reduction construct initializer. void ActOnOpenMPDeclareReductionCombinerEnd(Decl D, Expr Combiner); /// Initialize declare reduction construct initializer. /// \return omp_priv variable. VarDecl ActOnOpenMPDeclareReductionInitializerStart(Scope S, Decl D); /// Finish current declare reduction construct initializer. void ActOnOpenMPDeclareReductionInitializerEnd(Decl D, Expr Initializer, VarDecl OmpPrivParm); /// Called at the end of '#pragma omp declare reduction'. DeclGroupPtrTy ActOnOpenMPDeclareReductionDirectiveEnd( Scope S, DeclGroupPtrTy DeclReductions, bool IsValid); /// Check variable declaration in 'omp declare mapper' construct. TypeResult ActOnOpenMPDeclareMapperVarDecl(Scope S, Declarator &D); /// Check if the specified type is allowed to be used in 'omp declare /// mapper' construct. QualType ActOnOpenMPDeclareMapperType(SourceLocation TyLoc, TypeResult ParsedType); /// Called on start of '#pragma omp declare mapper'. DeclGroupPtrTy ActOnOpenMPDeclareMapperDirective( Scope S, DeclContext DC, DeclarationName Name, QualType MapperType, SourceLocation StartLoc, DeclarationName VN, AccessSpecifier AS, Expr MapperVarRef, ArrayRef<OMPClause > Clauses, Decl PrevDeclInScope = nullptr); /// Build the mapper variable of '#pragma omp declare mapper'. ExprResult ActOnOpenMPDeclareMapperDirectiveVarDecl(Scope S, QualType MapperType, SourceLocation StartLoc, DeclarationName VN); bool isOpenMPDeclareMapperVarDeclAllowed(const VarDecl VD) const; const ValueDecl getOpenMPDeclareMapperVarName() const; /// Called on the start of target region i.e. '#pragma omp declare target'. bool ActOnStartOpenMPDeclareTargetContext(DeclareTargetContextInfo &DTCI); /// Called at the end of target region i.e. '#pragma omp end declare target'. const DeclareTargetContextInfo ActOnOpenMPEndDeclareTargetDirective(); /// Called once a target context is completed, that can be when a /// '#pragma omp end declare target' was encountered or when a /// '#pragma omp declare target' without declaration-definition-seq was /// encountered. void ActOnFinishedOpenMPDeclareTargetContext(DeclareTargetContextInfo &DTCI); /// Searches for the provided declaration name for OpenMP declare target /// directive. NamedDecl lookupOpenMPDeclareTargetName(Scope CurScope, CXXScopeSpec &ScopeSpec, const DeclarationNameInfo &Id); /// Called on correct id-expression from the '#pragma omp declare target'. void ActOnOpenMPDeclareTargetName(NamedDecl ND, SourceLocation Loc, OMPDeclareTargetDeclAttr::MapTypeTy MT, OMPDeclareTargetDeclAttr::DevTypeTy DT); /// Check declaration inside target region. void checkDeclIsAllowedInOpenMPTarget(Expr E, Decl D, SourceLocation IdLoc = SourceLocation()); /// Finishes analysis of the deferred functions calls that may be declared as /// host/nohost during device/host compilation. void finalizeOpenMPDelayedAnalysis(const FunctionDecl Caller, const FunctionDecl Callee, SourceLocation Loc); /// Return true inside OpenMP declare target region. bool isInOpenMPDeclareTargetContext() const { return !DeclareTargetNesting.empty(); } /// Return true inside OpenMP target region. bool isInOpenMPTargetExecutionDirective() const; /// Return the number of captured regions created for an OpenMP directive. static int getOpenMPCaptureLevels(OpenMPDirectiveKind Kind); /// Initialization of captured region for OpenMP region. void ActOnOpenMPRegionStart(OpenMPDirectiveKind DKind, Scope CurScope); /// Called for syntactical loops (ForStmt or CXXForRangeStmt) associated to /// an OpenMP loop directive. StmtResult ActOnOpenMPCanonicalLoop(Stmt AStmt); /// Process a canonical OpenMP loop nest that can either be a canonical /// literal loop (ForStmt or CXXForRangeStmt), or the generated loop of an /// OpenMP loop transformation construct. StmtResult ActOnOpenMPLoopnest(Stmt AStmt); /// End of OpenMP region. /// /// \param S Statement associated with the current OpenMP region. /// \param Clauses List of clauses for the current OpenMP region. /// /// \returns Statement for finished OpenMP region. StmtResult ActOnOpenMPRegionEnd(StmtResult S, ArrayRef<OMPClause > Clauses); StmtResult ActOnOpenMPExecutableDirective( OpenMPDirectiveKind Kind, const DeclarationNameInfo &DirName, OpenMPDirectiveKind CancelRegion, ArrayRef<OMPClause > Clauses, Stmt AStmt, SourceLocation StartLoc, SourceLocation EndLoc); /// Called on well-formed '\#pragma omp parallel' after parsing /// of the associated statement. StmtResult ActOnOpenMPParallelDirective(ArrayRef<OMPClause > Clauses, Stmt AStmt, SourceLocation StartLoc, SourceLocation EndLoc); using VarsWithInheritedDSAType = llvm::SmallDenseMap<const ValueDecl , const Expr , 4>; /// Called on well-formed '\#pragma omp simd' after parsing /// of the associated statement. StmtResult ActOnOpenMPSimdDirective(ArrayRef<OMPClause > Clauses, Stmt AStmt, SourceLocation StartLoc, SourceLocation EndLoc, VarsWithInheritedDSAType &VarsWithImplicitDSA); /// Called on well-formed '#pragma omp tile' after parsing of its clauses and /// the associated statement. StmtResult ActOnOpenMPTileDirective(ArrayRef<OMPClause > Clauses, Stmt AStmt, SourceLocation StartLoc, SourceLocation EndLoc); /// Called on well-formed '#pragma omp unroll' after parsing of its clauses /// and the associated statement. StmtResult ActOnOpenMPUnrollDirective(ArrayRef<OMPClause > Clauses, Stmt AStmt, SourceLocation StartLoc, SourceLocation EndLoc); /// Called on well-formed '\#pragma omp for' after parsing /// of the associated statement. StmtResult ActOnOpenMPForDirective(ArrayRef<OMPClause > Clauses, Stmt AStmt, SourceLocation StartLoc, SourceLocation EndLoc, VarsWithInheritedDSAType &VarsWithImplicitDSA); /// Called on well-formed '\#pragma omp for simd' after parsing /// of the associated statement. StmtResult ActOnOpenMPForSimdDirective(ArrayRef<OMPClause > Clauses, Stmt AStmt, SourceLocation StartLoc, SourceLocation EndLoc, VarsWithInheritedDSAType &VarsWithImplicitDSA); /// Called on well-formed '\#pragma omp sections' after parsing /// of the associated statement. StmtResult ActOnOpenMPSectionsDirective(ArrayRef<OMPClause > Clauses, Stmt AStmt, SourceLocation StartLoc, SourceLocation EndLoc); /// Called on well-formed '\#pragma omp section' after parsing of the /// associated statement. StmtResult ActOnOpenMPSectionDirective(Stmt AStmt, SourceLocation StartLoc, SourceLocation EndLoc); /// Called on well-formed '\#pragma omp single' after parsing of the /// associated statement. StmtResult ActOnOpenMPSingleDirective(ArrayRef<OMPClause > Clauses, Stmt AStmt, SourceLocation StartLoc, SourceLocation EndLoc); /// Called on well-formed '\#pragma omp master' after parsing of the /// associated statement. StmtResult ActOnOpenMPMasterDirective(Stmt AStmt, SourceLocation StartLoc, SourceLocation EndLoc); /// Called on well-formed '\#pragma omp critical' after parsing of the /// associated statement. StmtResult ActOnOpenMPCriticalDirective(const DeclarationNameInfo &DirName, ArrayRef<OMPClause > Clauses, Stmt AStmt, SourceLocation StartLoc, SourceLocation EndLoc); /// Called on well-formed '\#pragma omp parallel for' after parsing /// of the associated statement. StmtResult ActOnOpenMPParallelForDirective( ArrayRef<OMPClause > Clauses, Stmt AStmt, SourceLocation StartLoc, SourceLocation EndLoc, VarsWithInheritedDSAType &VarsWithImplicitDSA); /// Called on well-formed '\#pragma omp parallel for simd' after /// parsing of the associated statement. StmtResult ActOnOpenMPParallelForSimdDirective( ArrayRef<OMPClause > Clauses, Stmt AStmt, SourceLocation StartLoc, SourceLocation EndLoc, VarsWithInheritedDSAType &VarsWithImplicitDSA); /// Called on well-formed '\#pragma omp parallel master' after /// parsing of the associated statement. StmtResult ActOnOpenMPParallelMasterDirective(ArrayRef<OMPClause > Clauses, Stmt AStmt, SourceLocation StartLoc, SourceLocation EndLoc); /// Called on well-formed '\#pragma omp parallel sections' after /// parsing of the associated statement. StmtResult ActOnOpenMPParallelSectionsDirective(ArrayRef<OMPClause > Clauses, Stmt AStmt, SourceLocation StartLoc, SourceLocation EndLoc); /// Called on well-formed '\#pragma omp task' after parsing of the /// associated statement. StmtResult ActOnOpenMPTaskDirective(ArrayRef<OMPClause > Clauses, Stmt AStmt, SourceLocation StartLoc, SourceLocation EndLoc); /// Called on well-formed '\#pragma omp taskyield'. StmtResult ActOnOpenMPTaskyieldDirective(SourceLocation StartLoc, SourceLocation EndLoc); /// Called on well-formed '\#pragma omp barrier'. StmtResult ActOnOpenMPBarrierDirective(SourceLocation StartLoc, SourceLocation EndLoc); /// Called on well-formed '\#pragma omp taskwait'. StmtResult ActOnOpenMPTaskwaitDirective(SourceLocation StartLoc, SourceLocation EndLoc); /// Called on well-formed '\#pragma omp taskgroup'. StmtResult ActOnOpenMPTaskgroupDirective(ArrayRef<OMPClause > Clauses, Stmt AStmt, SourceLocation StartLoc, SourceLocation EndLoc); /// Called on well-formed '\#pragma omp flush'. StmtResult ActOnOpenMPFlushDirective(ArrayRef<OMPClause > Clauses, SourceLocation StartLoc, SourceLocation EndLoc); /// Called on well-formed '\#pragma omp depobj'. StmtResult ActOnOpenMPDepobjDirective(ArrayRef<OMPClause > Clauses, SourceLocation StartLoc, SourceLocation EndLoc); /// Called on well-formed '\#pragma omp scan'. StmtResult ActOnOpenMPScanDirective(ArrayRef<OMPClause > Clauses, SourceLocation StartLoc, SourceLocation EndLoc); /// Called on well-formed '\#pragma omp ordered' after parsing of the /// associated statement. StmtResult ActOnOpenMPOrderedDirective(ArrayRef<OMPClause > Clauses, Stmt AStmt, SourceLocation StartLoc, SourceLocation EndLoc); /// Called on well-formed '\#pragma omp atomic' after parsing of the /// associated statement. StmtResult ActOnOpenMPAtomicDirective(ArrayRef<OMPClause > Clauses, Stmt AStmt, SourceLocation StartLoc, SourceLocation EndLoc); /// Called on well-formed '\#pragma omp target' after parsing of the /// associated statement. StmtResult ActOnOpenMPTargetDirective(ArrayRef<OMPClause > Clauses, Stmt AStmt, SourceLocation StartLoc, SourceLocation EndLoc); /// Called on well-formed '\#pragma omp target data' after parsing of /// the associated statement. StmtResult ActOnOpenMPTargetDataDirective(ArrayRef<OMPClause > Clauses, Stmt AStmt, SourceLocation StartLoc, SourceLocation EndLoc); /// Called on well-formed '\#pragma omp target enter data' after /// parsing of the associated statement. StmtResult ActOnOpenMPTargetEnterDataDirective(ArrayRef<OMPClause > Clauses, SourceLocation StartLoc, SourceLocation EndLoc, Stmt AStmt); /// Called on well-formed '\#pragma omp target exit data' after /// parsing of the associated statement. StmtResult ActOnOpenMPTargetExitDataDirective(ArrayRef<OMPClause > Clauses, SourceLocation StartLoc, SourceLocation EndLoc, Stmt AStmt); /// Called on well-formed '\#pragma omp target parallel' after /// parsing of the associated statement. StmtResult ActOnOpenMPTargetParallelDirective(ArrayRef<OMPClause > Clauses, Stmt AStmt, SourceLocation StartLoc, SourceLocation EndLoc); /// Called on well-formed '\#pragma omp target parallel for' after /// parsing of the associated statement. StmtResult ActOnOpenMPTargetParallelForDirective( ArrayRef<OMPClause > Clauses, Stmt AStmt, SourceLocation StartLoc, SourceLocation EndLoc, VarsWithInheritedDSAType &VarsWithImplicitDSA); /// Called on well-formed '\#pragma omp teams' after parsing of the /// associated statement. StmtResult ActOnOpenMPTeamsDirective(ArrayRef<OMPClause > Clauses, Stmt AStmt, SourceLocation StartLoc, SourceLocation EndLoc); /// Called on well-formed '\#pragma omp cancellation point'. StmtResult ActOnOpenMPCancellationPointDirective(SourceLocation StartLoc, SourceLocation EndLoc, OpenMPDirectiveKind CancelRegion); /// Called on well-formed '\#pragma omp cancel'. StmtResult ActOnOpenMPCancelDirective(ArrayRef<OMPClause > Clauses, SourceLocation StartLoc, SourceLocation EndLoc, OpenMPDirectiveKind CancelRegion); /// Called on well-formed '\#pragma omp taskloop' after parsing of the /// associated statement. StmtResult ActOnOpenMPTaskLoopDirective(ArrayRef<OMPClause > Clauses, Stmt AStmt, SourceLocation StartLoc, SourceLocation EndLoc, VarsWithInheritedDSAType &VarsWithImplicitDSA); /// Called on well-formed '\#pragma omp taskloop simd' after parsing of /// the associated statement. StmtResult ActOnOpenMPTaskLoopSimdDirective( ArrayRef<OMPClause > Clauses, Stmt AStmt, SourceLocation StartLoc, SourceLocation EndLoc, VarsWithInheritedDSAType &VarsWithImplicitDSA); /// Called on well-formed '\#pragma omp master taskloop' after parsing of the /// associated statement. StmtResult ActOnOpenMPMasterTaskLoopDirective( ArrayRef<OMPClause > Clauses, Stmt AStmt, SourceLocation StartLoc, SourceLocation EndLoc, VarsWithInheritedDSAType &VarsWithImplicitDSA); /// Called on well-formed '\#pragma omp master taskloop simd' after parsing of /// the associated statement. StmtResult ActOnOpenMPMasterTaskLoopSimdDirective( ArrayRef<OMPClause > Clauses, Stmt AStmt, SourceLocation StartLoc, SourceLocation EndLoc, VarsWithInheritedDSAType &VarsWithImplicitDSA); /// Called on well-formed '\#pragma omp parallel master taskloop' after /// parsing of the associated statement. StmtResult ActOnOpenMPParallelMasterTaskLoopDirective( ArrayRef<OMPClause > Clauses, Stmt AStmt, SourceLocation StartLoc, SourceLocation EndLoc, VarsWithInheritedDSAType &VarsWithImplicitDSA); /// Called on well-formed '\#pragma omp parallel master taskloop simd' after /// parsing of the associated statement. StmtResult ActOnOpenMPParallelMasterTaskLoopSimdDirective( ArrayRef<OMPClause > Clauses, Stmt AStmt, SourceLocation StartLoc, SourceLocation EndLoc, VarsWithInheritedDSAType &VarsWithImplicitDSA); /// Called on well-formed '\#pragma omp distribute' after parsing /// of the associated statement. StmtResult ActOnOpenMPDistributeDirective(ArrayRef<OMPClause > Clauses, Stmt AStmt, SourceLocation StartLoc, SourceLocation EndLoc, VarsWithInheritedDSAType &VarsWithImplicitDSA); /// Called on well-formed '\#pragma omp target update'. StmtResult ActOnOpenMPTargetUpdateDirective(ArrayRef<OMPClause > Clauses, SourceLocation StartLoc, SourceLocation EndLoc, Stmt AStmt); /// Called on well-formed '\#pragma omp distribute parallel for' after /// parsing of the associated statement. StmtResult ActOnOpenMPDistributeParallelForDirective( ArrayRef<OMPClause > Clauses, Stmt AStmt, SourceLocation StartLoc, SourceLocation EndLoc, VarsWithInheritedDSAType &VarsWithImplicitDSA); /// Called on well-formed '\#pragma omp distribute parallel for simd' /// after parsing of the associated statement. StmtResult ActOnOpenMPDistributeParallelForSimdDirective( ArrayRef<OMPClause > Clauses, Stmt AStmt, SourceLocation StartLoc, SourceLocation EndLoc, VarsWithInheritedDSAType &VarsWithImplicitDSA); /// Called on well-formed '\#pragma omp distribute simd' after /// parsing of the associated statement. StmtResult ActOnOpenMPDistributeSimdDirective( ArrayRef<OMPClause > Clauses, Stmt AStmt, SourceLocation StartLoc, SourceLocation EndLoc, VarsWithInheritedDSAType &VarsWithImplicitDSA); /// Called on well-formed '\#pragma omp target parallel for simd' after /// parsing of the associated statement. StmtResult ActOnOpenMPTargetParallelForSimdDirective( ArrayRef<OMPClause > Clauses, Stmt AStmt, SourceLocation StartLoc, SourceLocation EndLoc, VarsWithInheritedDSAType &VarsWithImplicitDSA); /// Called on well-formed '\#pragma omp target simd' after parsing of /// the associated statement. StmtResult ActOnOpenMPTargetSimdDirective(ArrayRef<OMPClause > Clauses, Stmt AStmt, SourceLocation StartLoc, SourceLocation EndLoc, VarsWithInheritedDSAType &VarsWithImplicitDSA); /// Called on well-formed '\#pragma omp teams distribute' after parsing of /// the associated statement. StmtResult ActOnOpenMPTeamsDistributeDirective( ArrayRef<OMPClause > Clauses, Stmt AStmt, SourceLocation StartLoc, SourceLocation EndLoc, VarsWithInheritedDSAType &VarsWithImplicitDSA); /// Called on well-formed '\#pragma omp teams distribute simd' after parsing /// of the associated statement. StmtResult ActOnOpenMPTeamsDistributeSimdDirective( ArrayRef<OMPClause > Clauses, Stmt AStmt, SourceLocation StartLoc, SourceLocation EndLoc, VarsWithInheritedDSAType &VarsWithImplicitDSA); /// Called on well-formed '\#pragma omp teams distribute parallel for simd' /// after parsing of the associated statement. StmtResult ActOnOpenMPTeamsDistributeParallelForSimdDirective( ArrayRef<OMPClause > Clauses, Stmt AStmt, SourceLocation StartLoc, SourceLocation EndLoc, VarsWithInheritedDSAType &VarsWithImplicitDSA); /// Called on well-formed '\#pragma omp teams distribute parallel for' /// after parsing of the associated statement. StmtResult ActOnOpenMPTeamsDistributeParallelForDirective( ArrayRef<OMPClause > Clauses, Stmt AStmt, SourceLocation StartLoc, SourceLocation EndLoc, VarsWithInheritedDSAType &VarsWithImplicitDSA); /// Called on well-formed '\#pragma omp target teams' after parsing of the /// associated statement. StmtResult ActOnOpenMPTargetTeamsDirective(ArrayRef<OMPClause > Clauses, Stmt AStmt, SourceLocation StartLoc, SourceLocation EndLoc); /// Called on well-formed '\#pragma omp target teams distribute' after parsing /// of the associated statement. StmtResult ActOnOpenMPTargetTeamsDistributeDirective( ArrayRef<OMPClause > Clauses, Stmt AStmt, SourceLocation StartLoc, SourceLocation EndLoc, VarsWithInheritedDSAType &VarsWithImplicitDSA); /// Called on well-formed '\#pragma omp target teams distribute parallel for' /// after parsing of the associated statement. StmtResult ActOnOpenMPTargetTeamsDistributeParallelForDirective( ArrayRef<OMPClause > Clauses, Stmt AStmt, SourceLocation StartLoc, SourceLocation EndLoc, VarsWithInheritedDSAType &VarsWithImplicitDSA); /// Called on well-formed '\#pragma omp target teams distribute parallel for /// simd' after parsing of the associated statement. StmtResult ActOnOpenMPTargetTeamsDistributeParallelForSimdDirective( ArrayRef<OMPClause > Clauses, Stmt AStmt, SourceLocation StartLoc, SourceLocation EndLoc, VarsWithInheritedDSAType &VarsWithImplicitDSA); /// Called on well-formed '\#pragma omp target teams distribute simd' after /// parsing of the associated statement. StmtResult ActOnOpenMPTargetTeamsDistributeSimdDirective( ArrayRef<OMPClause > Clauses, Stmt AStmt, SourceLocation StartLoc, SourceLocation EndLoc, VarsWithInheritedDSAType &VarsWithImplicitDSA); /// Called on well-formed '\#pragma omp interop'. StmtResult ActOnOpenMPInteropDirective(ArrayRef<OMPClause > Clauses, SourceLocation StartLoc, SourceLocation EndLoc); /// Called on well-formed '\#pragma omp dispatch' after parsing of the // /associated statement. StmtResult ActOnOpenMPDispatchDirective(ArrayRef<OMPClause > Clauses, Stmt AStmt, SourceLocation StartLoc, SourceLocation EndLoc); /// Called on well-formed '\#pragma omp masked' after parsing of the // /associated statement. StmtResult ActOnOpenMPMaskedDirective(ArrayRef<OMPClause > Clauses, Stmt AStmt, SourceLocation StartLoc, SourceLocation EndLoc); /// Called on well-formed '\#pragma omp loop' after parsing of the /// associated statement. StmtResult ActOnOpenMPGenericLoopDirective( ArrayRef<OMPClause > Clauses, Stmt AStmt, SourceLocation StartLoc, SourceLocation EndLoc, VarsWithInheritedDSAType &VarsWithImplicitDSA); /// Checks correctness of linear modifiers. bool CheckOpenMPLinearModifier(OpenMPLinearClauseKind LinKind, SourceLocation LinLoc); /// Checks that the specified declaration matches requirements for the linear /// decls. bool CheckOpenMPLinearDecl(const ValueDecl D, SourceLocation ELoc, OpenMPLinearClauseKind LinKind, QualType Type, bool IsDeclareSimd = false); /// Called on well-formed '\#pragma omp declare simd' after parsing of /// the associated method/function. DeclGroupPtrTy ActOnOpenMPDeclareSimdDirective( DeclGroupPtrTy DG, OMPDeclareSimdDeclAttr::BranchStateTy BS, Expr Simdlen, ArrayRef<Expr > Uniforms, ArrayRef<Expr > Aligneds, ArrayRef<Expr > Alignments, ArrayRef<Expr > Linears, ArrayRef<unsigned> LinModifiers, ArrayRef<Expr > Steps, SourceRange SR); /// Checks '\#pragma omp declare variant' variant function and original /// functions after parsing of the associated method/function. /// \param DG Function declaration to which declare variant directive is /// applied to. /// \param VariantRef Expression that references the variant function, which /// must be used instead of the original one, specified in \p DG. /// \param TI The trait info object representing the match clause. /// \param NumAppendArgs The number of omp_interop_t arguments to account for /// in checking. /// \returns None, if the function/variant function are not compatible with /// the pragma, pair of original function/variant ref expression otherwise. Optional<std::pair<FunctionDecl , Expr >> checkOpenMPDeclareVariantFunction(DeclGroupPtrTy DG, Expr VariantRef, OMPTraitInfo &TI, unsigned NumAppendArgs, SourceRange SR); /// Called on well-formed '\#pragma omp declare variant' after parsing of /// the associated method/function. /// \param FD Function declaration to which declare variant directive is /// applied to. /// \param VariantRef Expression that references the variant function, which /// must be used instead of the original one, specified in \p DG. /// \param TI The context traits associated with the function variant. /// \param AdjustArgsNothing The list of 'nothing' arguments. /// \param AdjustArgsNeedDevicePtr The list of 'need_device_ptr' arguments. /// \param AppendArgs The list of 'append_args' arguments. /// \param AdjustArgsLoc The Location of an 'adjust_args' clause. /// \param AppendArgsLoc The Location of an 'append_args' clause. /// \param SR The SourceRange of the 'declare variant' directive. void ActOnOpenMPDeclareVariantDirective( FunctionDecl FD, Expr VariantRef, OMPTraitInfo &TI, ArrayRef<Expr > AdjustArgsNothing, ArrayRef<Expr > AdjustArgsNeedDevicePtr, ArrayRef<OMPDeclareVariantAttr::InteropType> AppendArgs, SourceLocation AdjustArgsLoc, SourceLocation AppendArgsLoc, SourceRange SR); OMPClause ActOnOpenMPSingleExprClause(OpenMPClauseKind Kind, Expr Expr, SourceLocation StartLoc, SourceLocation LParenLoc, SourceLocation EndLoc); /// Called on well-formed 'allocator' clause. OMPClause ActOnOpenMPAllocatorClause(Expr Allocator, SourceLocation StartLoc, SourceLocation LParenLoc, SourceLocation EndLoc); /// Called on well-formed 'if' clause. OMPClause ActOnOpenMPIfClause(OpenMPDirectiveKind NameModifier, Expr Condition, SourceLocation StartLoc, SourceLocation LParenLoc, SourceLocation NameModifierLoc, SourceLocation ColonLoc, SourceLocation EndLoc); /// Called on well-formed 'final' clause. OMPClause ActOnOpenMPFinalClause(Expr Condition, SourceLocation StartLoc, SourceLocation LParenLoc, SourceLocation EndLoc); /// Called on well-formed 'num_threads' clause. OMPClause ActOnOpenMPNumThreadsClause(Expr NumThreads, SourceLocation StartLoc, SourceLocation LParenLoc, SourceLocation EndLoc); /// Called on well-formed 'safelen' clause. OMPClause ActOnOpenMPSafelenClause(Expr Length, SourceLocation StartLoc, SourceLocation LParenLoc, SourceLocation EndLoc); /// Called on well-formed 'simdlen' clause. OMPClause ActOnOpenMPSimdlenClause(Expr Length, SourceLocation StartLoc, SourceLocation LParenLoc, SourceLocation EndLoc); /// Called on well-form 'sizes' clause. OMPClause ActOnOpenMPSizesClause(ArrayRef<Expr > SizeExprs, SourceLocation StartLoc, SourceLocation LParenLoc, SourceLocation EndLoc); /// Called on well-form 'full' clauses. OMPClause ActOnOpenMPFullClause(SourceLocation StartLoc, SourceLocation EndLoc); /// Called on well-form 'partial' clauses. OMPClause ActOnOpenMPPartialClause(Expr FactorExpr, SourceLocation StartLoc, SourceLocation LParenLoc, SourceLocation EndLoc); /// Called on well-formed 'collapse' clause. OMPClause ActOnOpenMPCollapseClause(Expr NumForLoops, SourceLocation StartLoc, SourceLocation LParenLoc, SourceLocation EndLoc); /// Called on well-formed 'ordered' clause. OMPClause * ActOnOpenMPOrderedClause(SourceLocation StartLoc, SourceLocation EndLoc, SourceLocation LParenLoc = SourceLocation(), Expr NumForLoops = nullptr); /// Called on well-formed 'grainsize' clause. OMPClause ActOnOpenMPGrainsizeClause(Expr Size, SourceLocation StartLoc, SourceLocation LParenLoc, SourceLocation EndLoc); /// Called on well-formed 'num_tasks' clause. OMPClause ActOnOpenMPNumTasksClause(Expr NumTasks, SourceLocation StartLoc, SourceLocation LParenLoc, SourceLocation EndLoc); /// Called on well-formed 'hint' clause. OMPClause ActOnOpenMPHintClause(Expr Hint, SourceLocation StartLoc, SourceLocation LParenLoc, SourceLocation EndLoc); /// Called on well-formed 'detach' clause. OMPClause ActOnOpenMPDetachClause(Expr Evt, SourceLocation StartLoc, SourceLocation LParenLoc, SourceLocation EndLoc); OMPClause ActOnOpenMPSimpleClause(OpenMPClauseKind Kind, unsigned Argument, SourceLocation ArgumentLoc, SourceLocation StartLoc, SourceLocation LParenLoc, SourceLocation EndLoc); /// Called on well-formed 'when' clause. OMPClause ActOnOpenMPWhenClause(OMPTraitInfo &TI, SourceLocation StartLoc, SourceLocation LParenLoc, SourceLocation EndLoc); /// Called on well-formed 'default' clause. OMPClause ActOnOpenMPDefaultClause(llvm::omp::DefaultKind Kind, SourceLocation KindLoc, SourceLocation StartLoc, SourceLocation LParenLoc, SourceLocation EndLoc); /// Called on well-formed 'proc_bind' clause. OMPClause ActOnOpenMPProcBindClause(llvm::omp::ProcBindKind Kind, SourceLocation KindLoc, SourceLocation StartLoc, SourceLocation LParenLoc, SourceLocation EndLoc); /// Called on well-formed 'order' clause. OMPClause ActOnOpenMPOrderClause(OpenMPOrderClauseKind Kind, SourceLocation KindLoc, SourceLocation StartLoc, SourceLocation LParenLoc, SourceLocation EndLoc); /// Called on well-formed 'update' clause. OMPClause ActOnOpenMPUpdateClause(OpenMPDependClauseKind Kind, SourceLocation KindLoc, SourceLocation StartLoc, SourceLocation LParenLoc, SourceLocation EndLoc); OMPClause ActOnOpenMPSingleExprWithArgClause( OpenMPClauseKind Kind, ArrayRef<unsigned> Arguments, Expr Expr, SourceLocation StartLoc, SourceLocation LParenLoc, ArrayRef<SourceLocation> ArgumentsLoc, SourceLocation DelimLoc, SourceLocation EndLoc); /// Called on well-formed 'schedule' clause. OMPClause ActOnOpenMPScheduleClause( OpenMPScheduleClauseModifier M1, OpenMPScheduleClauseModifier M2, OpenMPScheduleClauseKind Kind, Expr ChunkSize, SourceLocation StartLoc, SourceLocation LParenLoc, SourceLocation M1Loc, SourceLocation M2Loc, SourceLocation KindLoc, SourceLocation CommaLoc, SourceLocation EndLoc); OMPClause ActOnOpenMPClause(OpenMPClauseKind Kind, SourceLocation StartLoc, SourceLocation EndLoc); /// Called on well-formed 'nowait' clause. OMPClause ActOnOpenMPNowaitClause(SourceLocation StartLoc, SourceLocation EndLoc); /// Called on well-formed 'untied' clause. OMPClause ActOnOpenMPUntiedClause(SourceLocation StartLoc, SourceLocation EndLoc); /// Called on well-formed 'mergeable' clause. OMPClause ActOnOpenMPMergeableClause(SourceLocation StartLoc, SourceLocation EndLoc); /// Called on well-formed 'read' clause. OMPClause ActOnOpenMPReadClause(SourceLocation StartLoc, SourceLocation EndLoc); /// Called on well-formed 'write' clause. OMPClause ActOnOpenMPWriteClause(SourceLocation StartLoc, SourceLocation EndLoc); /// Called on well-formed 'update' clause. OMPClause ActOnOpenMPUpdateClause(SourceLocation StartLoc, SourceLocation EndLoc); /// Called on well-formed 'capture' clause. OMPClause ActOnOpenMPCaptureClause(SourceLocation StartLoc, SourceLocation EndLoc); /// Called on well-formed 'seq_cst' clause. OMPClause ActOnOpenMPSeqCstClause(SourceLocation StartLoc, SourceLocation EndLoc); /// Called on well-formed 'acq_rel' clause. OMPClause ActOnOpenMPAcqRelClause(SourceLocation StartLoc, SourceLocation EndLoc); /// Called on well-formed 'acquire' clause. OMPClause ActOnOpenMPAcquireClause(SourceLocation StartLoc, SourceLocation EndLoc); /// Called on well-formed 'release' clause. OMPClause ActOnOpenMPReleaseClause(SourceLocation StartLoc, SourceLocation EndLoc); /// Called on well-formed 'relaxed' clause. OMPClause ActOnOpenMPRelaxedClause(SourceLocation StartLoc, SourceLocation EndLoc); /// Called on well-formed 'init' clause. OMPClause ActOnOpenMPInitClause(Expr InteropVar, ArrayRef<Expr > PrefExprs, bool IsTarget, bool IsTargetSync, SourceLocation StartLoc, SourceLocation LParenLoc, SourceLocation VarLoc, SourceLocation EndLoc); /// Called on well-formed 'use' clause. OMPClause ActOnOpenMPUseClause(Expr InteropVar, SourceLocation StartLoc, SourceLocation LParenLoc, SourceLocation VarLoc, SourceLocation EndLoc); /// Called on well-formed 'destroy' clause. OMPClause ActOnOpenMPDestroyClause(Expr InteropVar, SourceLocation StartLoc, SourceLocation LParenLoc, SourceLocation VarLoc, SourceLocation EndLoc); /// Called on well-formed 'novariants' clause. OMPClause ActOnOpenMPNovariantsClause(Expr Condition, SourceLocation StartLoc, SourceLocation LParenLoc, SourceLocation EndLoc); /// Called on well-formed 'nocontext' clause. OMPClause ActOnOpenMPNocontextClause(Expr Condition, SourceLocation StartLoc, SourceLocation LParenLoc, SourceLocation EndLoc); /// Called on well-formed 'filter' clause. OMPClause ActOnOpenMPFilterClause(Expr ThreadID, SourceLocation StartLoc, SourceLocation LParenLoc, SourceLocation EndLoc); /// Called on well-formed 'threads' clause. OMPClause ActOnOpenMPThreadsClause(SourceLocation StartLoc, SourceLocation EndLoc); /// Called on well-formed 'simd' clause. OMPClause ActOnOpenMPSIMDClause(SourceLocation StartLoc, SourceLocation EndLoc); /// Called on well-formed 'nogroup' clause. OMPClause ActOnOpenMPNogroupClause(SourceLocation StartLoc, SourceLocation EndLoc); /// Called on well-formed 'unified_address' clause. OMPClause ActOnOpenMPUnifiedAddressClause(SourceLocation StartLoc, SourceLocation EndLoc); /// Called on well-formed 'unified_address' clause. OMPClause ActOnOpenMPUnifiedSharedMemoryClause(SourceLocation StartLoc, SourceLocation EndLoc); /// Called on well-formed 'reverse_offload' clause. OMPClause ActOnOpenMPReverseOffloadClause(SourceLocation StartLoc, SourceLocation EndLoc); /// Called on well-formed 'dynamic_allocators' clause. OMPClause ActOnOpenMPDynamicAllocatorsClause(SourceLocation StartLoc, SourceLocation EndLoc); /// Called on well-formed 'atomic_default_mem_order' clause. OMPClause ActOnOpenMPAtomicDefaultMemOrderClause( OpenMPAtomicDefaultMemOrderClauseKind Kind, SourceLocation KindLoc, SourceLocation StartLoc, SourceLocation LParenLoc, SourceLocation EndLoc); OMPClause ActOnOpenMPVarListClause( OpenMPClauseKind Kind, ArrayRef<Expr > Vars, Expr DepModOrTailExpr, const OMPVarListLocTy &Locs, SourceLocation ColonLoc, CXXScopeSpec &ReductionOrMapperIdScopeSpec, DeclarationNameInfo &ReductionOrMapperId, int ExtraModifier, ArrayRef<OpenMPMapModifierKind> MapTypeModifiers, ArrayRef<SourceLocation> MapTypeModifiersLoc, bool IsMapTypeImplicit, SourceLocation ExtraModifierLoc, ArrayRef<OpenMPMotionModifierKind> MotionModifiers, ArrayRef<SourceLocation> MotionModifiersLoc); /// Called on well-formed 'inclusive' clause. OMPClause ActOnOpenMPInclusiveClause(ArrayRef<Expr > VarList, SourceLocation StartLoc, SourceLocation LParenLoc, SourceLocation EndLoc); /// Called on well-formed 'exclusive' clause. OMPClause ActOnOpenMPExclusiveClause(ArrayRef<Expr > VarList, SourceLocation StartLoc, SourceLocation LParenLoc, SourceLocation EndLoc); /// Called on well-formed 'allocate' clause. OMPClause * ActOnOpenMPAllocateClause(Expr Allocator, ArrayRef<Expr > VarList, SourceLocation StartLoc, SourceLocation ColonLoc, SourceLocation LParenLoc, SourceLocation EndLoc); /// Called on well-formed 'private' clause. OMPClause ActOnOpenMPPrivateClause(ArrayRef<Expr > VarList, SourceLocation StartLoc, SourceLocation LParenLoc, SourceLocation EndLoc); /// Called on well-formed 'firstprivate' clause. OMPClause ActOnOpenMPFirstprivateClause(ArrayRef<Expr > VarList, SourceLocation StartLoc, SourceLocation LParenLoc, SourceLocation EndLoc); /// Called on well-formed 'lastprivate' clause. OMPClause ActOnOpenMPLastprivateClause( ArrayRef<Expr > VarList, OpenMPLastprivateModifier LPKind, SourceLocation LPKindLoc, SourceLocation ColonLoc, SourceLocation StartLoc, SourceLocation LParenLoc, SourceLocation EndLoc); /// Called on well-formed 'shared' clause. OMPClause ActOnOpenMPSharedClause(ArrayRef<Expr > VarList, SourceLocation StartLoc, SourceLocation LParenLoc, SourceLocation EndLoc); /// Called on well-formed 'reduction' clause. OMPClause ActOnOpenMPReductionClause( ArrayRef<Expr > VarList, OpenMPReductionClauseModifier Modifier, SourceLocation StartLoc, SourceLocation LParenLoc, SourceLocation ModifierLoc, SourceLocation ColonLoc, SourceLocation EndLoc, CXXScopeSpec &ReductionIdScopeSpec, const DeclarationNameInfo &ReductionId, ArrayRef<Expr > UnresolvedReductions = llvm::None); /// Called on well-formed 'task_reduction' clause. OMPClause ActOnOpenMPTaskReductionClause( ArrayRef<Expr > VarList, SourceLocation StartLoc, SourceLocation LParenLoc, SourceLocation ColonLoc, SourceLocation EndLoc, CXXScopeSpec &ReductionIdScopeSpec, const DeclarationNameInfo &ReductionId, ArrayRef<Expr > UnresolvedReductions = llvm::None); /// Called on well-formed 'in_reduction' clause. OMPClause ActOnOpenMPInReductionClause( ArrayRef<Expr > VarList, SourceLocation StartLoc, SourceLocation LParenLoc, SourceLocation ColonLoc, SourceLocation EndLoc, CXXScopeSpec &ReductionIdScopeSpec, const DeclarationNameInfo &ReductionId, ArrayRef<Expr > UnresolvedReductions = llvm::None); /// Called on well-formed 'linear' clause. OMPClause ActOnOpenMPLinearClause(ArrayRef<Expr > VarList, Expr Step, SourceLocation StartLoc, SourceLocation LParenLoc, OpenMPLinearClauseKind LinKind, SourceLocation LinLoc, SourceLocation ColonLoc, SourceLocation EndLoc); /// Called on well-formed 'aligned' clause. OMPClause ActOnOpenMPAlignedClause(ArrayRef<Expr > VarList, Expr Alignment, SourceLocation StartLoc, SourceLocation LParenLoc, SourceLocation ColonLoc, SourceLocation EndLoc); /// Called on well-formed 'copyin' clause. OMPClause ActOnOpenMPCopyinClause(ArrayRef<Expr > VarList, SourceLocation StartLoc, SourceLocation LParenLoc, SourceLocation EndLoc); /// Called on well-formed 'copyprivate' clause. OMPClause ActOnOpenMPCopyprivateClause(ArrayRef<Expr > VarList, SourceLocation StartLoc, SourceLocation LParenLoc, SourceLocation EndLoc); /// Called on well-formed 'flush' pseudo clause. OMPClause ActOnOpenMPFlushClause(ArrayRef<Expr > VarList, SourceLocation StartLoc, SourceLocation LParenLoc, SourceLocation EndLoc); /// Called on well-formed 'depobj' pseudo clause. OMPClause ActOnOpenMPDepobjClause(Expr Depobj, SourceLocation StartLoc, SourceLocation LParenLoc, SourceLocation EndLoc); /// Called on well-formed 'depend' clause. OMPClause ActOnOpenMPDependClause(Expr DepModifier, OpenMPDependClauseKind DepKind, SourceLocation DepLoc, SourceLocation ColonLoc, ArrayRef<Expr > VarList, SourceLocation StartLoc, SourceLocation LParenLoc, SourceLocation EndLoc); /// Called on well-formed 'device' clause. OMPClause ActOnOpenMPDeviceClause(OpenMPDeviceClauseModifier Modifier, Expr Device, SourceLocation StartLoc, SourceLocation LParenLoc, SourceLocation ModifierLoc, SourceLocation EndLoc); /// Called on well-formed 'map' clause. OMPClause ActOnOpenMPMapClause( ArrayRef<OpenMPMapModifierKind> MapTypeModifiers, ArrayRef<SourceLocation> MapTypeModifiersLoc, CXXScopeSpec &MapperIdScopeSpec, DeclarationNameInfo &MapperId, OpenMPMapClauseKind MapType, bool IsMapTypeImplicit, SourceLocation MapLoc, SourceLocation ColonLoc, ArrayRef<Expr > VarList, const OMPVarListLocTy &Locs, bool NoDiagnose = false, ArrayRef<Expr > UnresolvedMappers = llvm::None); /// Called on well-formed 'num_teams' clause. OMPClause ActOnOpenMPNumTeamsClause(Expr NumTeams, SourceLocation StartLoc, SourceLocation LParenLoc, SourceLocation EndLoc); /// Called on well-formed 'thread_limit' clause. OMPClause ActOnOpenMPThreadLimitClause(Expr ThreadLimit, SourceLocation StartLoc, SourceLocation LParenLoc, SourceLocation EndLoc); /// Called on well-formed 'priority' clause. OMPClause ActOnOpenMPPriorityClause(Expr Priority, SourceLocation StartLoc, SourceLocation LParenLoc, SourceLocation EndLoc); /// Called on well-formed 'dist_schedule' clause. OMPClause ActOnOpenMPDistScheduleClause( OpenMPDistScheduleClauseKind Kind, Expr ChunkSize, SourceLocation StartLoc, SourceLocation LParenLoc, SourceLocation KindLoc, SourceLocation CommaLoc, SourceLocation EndLoc); /// Called on well-formed 'defaultmap' clause. OMPClause ActOnOpenMPDefaultmapClause( OpenMPDefaultmapClauseModifier M, OpenMPDefaultmapClauseKind Kind, SourceLocation StartLoc, SourceLocation LParenLoc, SourceLocation MLoc, SourceLocation KindLoc, SourceLocation EndLoc); /// Called on well-formed 'to' clause. OMPClause * ActOnOpenMPToClause(ArrayRef<OpenMPMotionModifierKind> MotionModifiers, ArrayRef<SourceLocation> MotionModifiersLoc, CXXScopeSpec &MapperIdScopeSpec, DeclarationNameInfo &MapperId, SourceLocation ColonLoc, ArrayRef<Expr > VarList, const OMPVarListLocTy &Locs, ArrayRef<Expr > UnresolvedMappers = llvm::None); /// Called on well-formed 'from' clause. OMPClause * ActOnOpenMPFromClause(ArrayRef<OpenMPMotionModifierKind> MotionModifiers, ArrayRef<SourceLocation> MotionModifiersLoc, CXXScopeSpec &MapperIdScopeSpec, DeclarationNameInfo &MapperId, SourceLocation ColonLoc, ArrayRef<Expr > VarList, const OMPVarListLocTy &Locs, ArrayRef<Expr > UnresolvedMappers = llvm::None); /// Called on well-formed 'use_device_ptr' clause. OMPClause ActOnOpenMPUseDevicePtrClause(ArrayRef<Expr > VarList, const OMPVarListLocTy &Locs); /// Called on well-formed 'use_device_addr' clause. OMPClause ActOnOpenMPUseDeviceAddrClause(ArrayRef<Expr > VarList, const OMPVarListLocTy &Locs); /// Called on well-formed 'is_device_ptr' clause. OMPClause ActOnOpenMPIsDevicePtrClause(ArrayRef<Expr > VarList, const OMPVarListLocTy &Locs); /// Called on well-formed 'nontemporal' clause. OMPClause ActOnOpenMPNontemporalClause(ArrayRef<Expr > VarList, SourceLocation StartLoc, SourceLocation LParenLoc, SourceLocation EndLoc); /// Data for list of allocators. struct UsesAllocatorsData { /// Allocator. Expr Allocator = nullptr; /// Allocator traits. Expr AllocatorTraits = nullptr; /// Locations of '(' and ')' symbols. SourceLocation LParenLoc, RParenLoc; }; /// Called on well-formed 'uses_allocators' clause. OMPClause ActOnOpenMPUsesAllocatorClause(SourceLocation StartLoc, SourceLocation LParenLoc, SourceLocation EndLoc, ArrayRef<UsesAllocatorsData> Data); /// Called on well-formed 'affinity' clause. OMPClause ActOnOpenMPAffinityClause(SourceLocation StartLoc, SourceLocation LParenLoc, SourceLocation ColonLoc, SourceLocation EndLoc, Expr Modifier, ArrayRef<Expr > Locators); /// The kind of conversion being performed. enum CheckedConversionKind { /// An implicit conversion. CCK_ImplicitConversion, /// A C-style cast. CCK_CStyleCast, /// A functional-style cast. CCK_FunctionalCast, /// A cast other than a C-style cast. CCK_OtherCast, /// A conversion for an operand of a builtin overloaded operator. CCK_ForBuiltinOverloadedOp }; static bool isCast(CheckedConversionKind CCK) { return CCK == CCK_CStyleCast \|\| CCK == CCK_FunctionalCast \|\| CCK == CCK_OtherCast; } /// ImpCastExprToType - If Expr is not of type 'Type', insert an implicit /// cast. If there is already an implicit cast, merge into the existing one. /// If isLvalue, the result of the cast is an lvalue. ExprResult ImpCastExprToType(Expr E, QualType Type, CastKind CK, ExprValueKind VK = VK_PRValue, const CXXCastPath BasePath = nullptr, CheckedConversionKind CCK = CCK_ImplicitConversion); /// ScalarTypeToBooleanCastKind - Returns the cast kind corresponding /// to the conversion from scalar type ScalarTy to the Boolean type. static CastKind ScalarTypeToBooleanCastKind(QualType ScalarTy); /// IgnoredValueConversions - Given that an expression's result is /// syntactically ignored, perform any conversions that are /// required. ExprResult IgnoredValueConversions(Expr E); // UsualUnaryConversions - promotes integers (C99 6.3.1.1p2) and converts // functions and arrays to their respective pointers (C99 6.3.2.1). ExprResult UsualUnaryConversions(Expr E); /// CallExprUnaryConversions - a special case of an unary conversion /// performed on a function designator of a call expression. ExprResult CallExprUnaryConversions(Expr E); // DefaultFunctionArrayConversion - converts functions and arrays // to their respective pointers (C99 6.3.2.1). ExprResult DefaultFunctionArrayConversion(Expr E, bool Diagnose = true); // DefaultFunctionArrayLvalueConversion - converts functions and // arrays to their respective pointers and performs the // lvalue-to-rvalue conversion. ExprResult DefaultFunctionArrayLvalueConversion(Expr E, bool Diagnose = true); // DefaultLvalueConversion - performs lvalue-to-rvalue conversion on // the operand. This function is a no-op if the operand has a function type // or an array type. ExprResult DefaultLvalueConversion(Expr E); // DefaultArgumentPromotion (C99 6.5.2.2p6). Used for function calls that // do not have a prototype. Integer promotions are performed on each // argument, and arguments that have type float are promoted to double. ExprResult DefaultArgumentPromotion(Expr E); /// If \p E is a prvalue denoting an unmaterialized temporary, materialize /// it as an xvalue. In C++98, the result will still be a prvalue, because /// we don't have xvalues there. ExprResult TemporaryMaterializationConversion(Expr E); // Used for emitting the right warning by DefaultVariadicArgumentPromotion enum VariadicCallType { VariadicFunction, VariadicBlock, VariadicMethod, VariadicConstructor, VariadicDoesNotApply }; VariadicCallType getVariadicCallType(FunctionDecl FDecl, const FunctionProtoType Proto, Expr Fn); // Used for determining in which context a type is allowed to be passed to a // vararg function. enum VarArgKind { VAK_Valid, VAK_ValidInCXX11, VAK_Undefined, VAK_MSVCUndefined, VAK_Invalid }; // Determines which VarArgKind fits an expression. VarArgKind isValidVarArgType(const QualType &Ty); /// Check to see if the given expression is a valid argument to a variadic /// function, issuing a diagnostic if not. void checkVariadicArgument(const Expr E, VariadicCallType CT); /// Check whether the given statement can have musttail applied to it, /// issuing a diagnostic and returning false if not. In the success case, /// the statement is rewritten to remove implicit nodes from the return /// value. bool checkAndRewriteMustTailAttr(Stmt St, const Attr &MTA); private: /// Check whether the given statement can have musttail applied to it, /// issuing a diagnostic and returning false if not. bool checkMustTailAttr(const Stmt St, const Attr &MTA); public: /// Check to see if a given expression could have '.c_str()' called on it. bool hasCStrMethod(const Expr E); /// GatherArgumentsForCall - Collector argument expressions for various /// form of call prototypes. bool GatherArgumentsForCall(SourceLocation CallLoc, FunctionDecl FDecl, const FunctionProtoType Proto, unsigned FirstParam, ArrayRef<Expr > Args, SmallVectorImpl<Expr > &AllArgs, VariadicCallType CallType = VariadicDoesNotApply, bool AllowExplicit = false, bool IsListInitialization = false); // DefaultVariadicArgumentPromotion - Like DefaultArgumentPromotion, but // will create a runtime trap if the resulting type is not a POD type. ExprResult DefaultVariadicArgumentPromotion(Expr E, VariadicCallType CT, FunctionDecl FDecl); /// Context in which we're performing a usual arithmetic conversion. enum ArithConvKind { /// An arithmetic operation. ACK_Arithmetic, /// A bitwise operation. ACK_BitwiseOp, /// A comparison. ACK_Comparison, /// A conditional (?:) operator. ACK_Conditional, /// A compound assignment expression. ACK_CompAssign, }; // UsualArithmeticConversions - performs the UsualUnaryConversions on it's // operands and then handles various conversions that are common to binary // operators (C99 6.3.1.8). If both operands aren't arithmetic, this // routine returns the first non-arithmetic type found. The client is // responsible for emitting appropriate error diagnostics. QualType UsualArithmeticConversions(ExprResult &LHS, ExprResult &RHS, SourceLocation Loc, ArithConvKind ACK); /// AssignConvertType - All of the 'assignment' semantic checks return this /// enum to indicate whether the assignment was allowed. These checks are /// done for simple assignments, as well as initialization, return from /// function, argument passing, etc. The query is phrased in terms of a /// source and destination type. enum AssignConvertType { /// Compatible - the types are compatible according to the standard. Compatible, /// PointerToInt - The assignment converts a pointer to an int, which we /// accept as an extension. PointerToInt, /// IntToPointer - The assignment converts an int to a pointer, which we /// accept as an extension. IntToPointer, /// FunctionVoidPointer - The assignment is between a function pointer and /// void, which the standard doesn't allow, but we accept as an extension. FunctionVoidPointer, /// IncompatiblePointer - The assignment is between two pointers types that /// are not compatible, but we accept them as an extension. IncompatiblePointer, /// IncompatibleFunctionPointer - The assignment is between two function /// pointers types that are not compatible, but we accept them as an /// extension. IncompatibleFunctionPointer, /// IncompatiblePointerSign - The assignment is between two pointers types /// which point to integers which have a different sign, but are otherwise /// identical. This is a subset of the above, but broken out because it's by /// far the most common case of incompatible pointers. IncompatiblePointerSign, /// CompatiblePointerDiscardsQualifiers - The assignment discards /// c/v/r qualifiers, which we accept as an extension. CompatiblePointerDiscardsQualifiers, /// IncompatiblePointerDiscardsQualifiers - The assignment /// discards qualifiers that we don't permit to be discarded, /// like address spaces. IncompatiblePointerDiscardsQualifiers, /// IncompatibleNestedPointerAddressSpaceMismatch - The assignment /// changes address spaces in nested pointer types which is not allowed. /// For instance, converting __private int to __generic int is /// illegal even though __private could be converted to __generic. IncompatibleNestedPointerAddressSpaceMismatch, /// IncompatibleNestedPointerQualifiers - The assignment is between two /// nested pointer types, and the qualifiers other than the first two /// levels differ e.g. char -> const char , but we accept them as an /// extension. IncompatibleNestedPointerQualifiers, /// IncompatibleVectors - The assignment is between two vector types that /// have the same size, which we accept as an extension. IncompatibleVectors, /// IntToBlockPointer - The assignment converts an int to a block /// pointer. We disallow this. IntToBlockPointer, /// IncompatibleBlockPointer - The assignment is between two block /// pointers types that are not compatible. IncompatibleBlockPointer, /// IncompatibleObjCQualifiedId - The assignment is between a qualified /// id type and something else (that is incompatible with it). For example, /// "id <XXX>" = "Foo ", where "Foo " doesn't implement the XXX protocol. IncompatibleObjCQualifiedId, /// IncompatibleObjCWeakRef - Assigning a weak-unavailable object to an /// object with __weak qualifier. IncompatibleObjCWeakRef, /// Incompatible - We reject this conversion outright, it is invalid to /// represent it in the AST. Incompatible }; /// DiagnoseAssignmentResult - Emit a diagnostic, if required, for the /// assignment conversion type specified by ConvTy. This returns true if the /// conversion was invalid or false if the conversion was accepted. bool DiagnoseAssignmentResult(AssignConvertType ConvTy, SourceLocation Loc, QualType DstType, QualType SrcType, Expr SrcExpr, AssignmentAction Action, bool Complained = nullptr); /// IsValueInFlagEnum - Determine if a value is allowed as part of a flag /// enum. If AllowMask is true, then we also allow the complement of a valid /// value, to be used as a mask. bool IsValueInFlagEnum(const EnumDecl ED, const llvm::APInt &Val, bool AllowMask) const; /// DiagnoseAssignmentEnum - Warn if assignment to enum is a constant /// integer not in the range of enum values. void DiagnoseAssignmentEnum(QualType DstType, QualType SrcType, Expr SrcExpr); /// CheckAssignmentConstraints - Perform type checking for assignment, /// argument passing, variable initialization, and function return values. /// C99 6.5.16. AssignConvertType CheckAssignmentConstraints(SourceLocation Loc, QualType LHSType, QualType RHSType); /// Check assignment constraints and optionally prepare for a conversion of /// the RHS to the LHS type. The conversion is prepared for if ConvertRHS /// is true. AssignConvertType CheckAssignmentConstraints(QualType LHSType, ExprResult &RHS, CastKind &Kind, bool ConvertRHS = true); /// Check assignment constraints for an assignment of RHS to LHSType. /// /// \param LHSType The destination type for the assignment. /// \param RHS The source expression for the assignment. /// \param Diagnose If \c true, diagnostics may be produced when checking /// for assignability. If a diagnostic is produced, \p RHS will be /// set to ExprError(). Note that this function may still return /// without producing a diagnostic, even for an invalid assignment. /// \param DiagnoseCFAudited If \c true, the target is a function parameter /// in an audited Core Foundation API and does not need to be checked /// for ARC retain issues. /// \param ConvertRHS If \c true, \p RHS will be updated to model the /// conversions necessary to perform the assignment. If \c false, /// \p Diagnose must also be \c false. AssignConvertType CheckSingleAssignmentConstraints( QualType LHSType, ExprResult &RHS, bool Diagnose = true, bool DiagnoseCFAudited = false, bool ConvertRHS = true); // If the lhs type is a transparent union, check whether we // can initialize the transparent union with the given expression. AssignConvertType CheckTransparentUnionArgumentConstraints(QualType ArgType, ExprResult &RHS); bool IsStringLiteralToNonConstPointerConversion(Expr From, QualType ToType); bool CheckExceptionSpecCompatibility(Expr From, QualType ToType); ExprResult PerformImplicitConversion(Expr From, QualType ToType, AssignmentAction Action, bool AllowExplicit = false); ExprResult PerformImplicitConversion(Expr From, QualType ToType, const ImplicitConversionSequence& ICS, AssignmentAction Action, CheckedConversionKind CCK = CCK_ImplicitConversion); ExprResult PerformImplicitConversion(Expr From, QualType ToType, const StandardConversionSequence& SCS, AssignmentAction Action, CheckedConversionKind CCK); ExprResult PerformQualificationConversion( Expr E, QualType Ty, ExprValueKind VK = VK_PRValue, CheckedConversionKind CCK = CCK_ImplicitConversion); /// the following "Check" methods will return a valid/converted QualType /// or a null QualType (indicating an error diagnostic was issued). /// type checking binary operators (subroutines of CreateBuiltinBinOp). QualType InvalidOperands(SourceLocation Loc, ExprResult &LHS, ExprResult &RHS); QualType InvalidLogicalVectorOperands(SourceLocation Loc, ExprResult &LHS, ExprResult &RHS); QualType CheckPointerToMemberOperands( // C++ 5.5 ExprResult &LHS, ExprResult &RHS, ExprValueKind &VK, SourceLocation OpLoc, bool isIndirect); QualType CheckMultiplyDivideOperands( // C99 6.5.5 ExprResult &LHS, ExprResult &RHS, SourceLocation Loc, bool IsCompAssign, bool IsDivide); QualType CheckRemainderOperands( // C99 6.5.5 ExprResult &LHS, ExprResult &RHS, SourceLocation Loc, bool IsCompAssign = false); QualType CheckAdditionOperands( // C99 6.5.6 ExprResult &LHS, ExprResult &RHS, SourceLocation Loc, BinaryOperatorKind Opc, QualType* CompLHSTy = nullptr); QualType CheckSubtractionOperands( // C99 6.5.6 ExprResult &LHS, ExprResult &RHS, SourceLocation Loc, QualType* CompLHSTy = nullptr); QualType CheckShiftOperands( // C99 6.5.7 ExprResult &LHS, ExprResult &RHS, SourceLocation Loc, BinaryOperatorKind Opc, bool IsCompAssign = false); void CheckPtrComparisonWithNullChar(ExprResult &E, ExprResult &NullE); QualType CheckCompareOperands( // C99 6.5.8/9 ExprResult &LHS, ExprResult &RHS, SourceLocation Loc, BinaryOperatorKind Opc); QualType CheckBitwiseOperands( // C99 6.5.[10...12] ExprResult &LHS, ExprResult &RHS, SourceLocation Loc, BinaryOperatorKind Opc); QualType CheckLogicalOperands( // C99 6.5.[13,14] ExprResult &LHS, ExprResult &RHS, SourceLocation Loc, BinaryOperatorKind Opc); // CheckAssignmentOperands is used for both simple and compound assignment. // For simple assignment, pass both expressions and a null converted type. // For compound assignment, pass both expressions and the converted type. QualType CheckAssignmentOperands( // C99 6.5.16.[1,2] Expr LHSExpr, ExprResult &RHS, SourceLocation Loc, QualType CompoundType); ExprResult checkPseudoObjectIncDec(Scope S, SourceLocation OpLoc, UnaryOperatorKind Opcode, Expr Op); ExprResult checkPseudoObjectAssignment(Scope S, SourceLocation OpLoc, BinaryOperatorKind Opcode, Expr LHS, Expr RHS); ExprResult checkPseudoObjectRValue(Expr E); Expr recreateSyntacticForm(PseudoObjectExpr E); QualType CheckConditionalOperands( // C99 6.5.15 ExprResult &Cond, ExprResult &LHS, ExprResult &RHS, ExprValueKind &VK, ExprObjectKind &OK, SourceLocation QuestionLoc); QualType CXXCheckConditionalOperands( // C++ 5.16 ExprResult &cond, ExprResult &lhs, ExprResult &rhs, ExprValueKind &VK, ExprObjectKind &OK, SourceLocation questionLoc); QualType CheckVectorConditionalTypes(ExprResult &Cond, ExprResult &LHS, ExprResult &RHS, SourceLocation QuestionLoc); QualType FindCompositePointerType(SourceLocation Loc, Expr &E1, Expr &E2, bool ConvertArgs = true); QualType FindCompositePointerType(SourceLocation Loc, ExprResult &E1, ExprResult &E2, bool ConvertArgs = true) { Expr E1Tmp = E1.get(), E2Tmp = E2.get(); QualType Composite = FindCompositePointerType(Loc, E1Tmp, E2Tmp, ConvertArgs); E1 = E1Tmp; E2 = E2Tmp; return Composite; } QualType FindCompositeObjCPointerType(ExprResult &LHS, ExprResult &RHS, SourceLocation QuestionLoc); bool DiagnoseConditionalForNull(Expr LHSExpr, Expr RHSExpr, SourceLocation QuestionLoc); void DiagnoseAlwaysNonNullPointer(Expr E, Expr::NullPointerConstantKind NullType, bool IsEqual, SourceRange Range); /// type checking for vector binary operators. QualType CheckVectorOperands(ExprResult &LHS, ExprResult &RHS, SourceLocation Loc, bool IsCompAssign, bool AllowBothBool, bool AllowBoolConversion); QualType GetSignedVectorType(QualType V); QualType CheckVectorCompareOperands(ExprResult &LHS, ExprResult &RHS, SourceLocation Loc, BinaryOperatorKind Opc); QualType CheckVectorLogicalOperands(ExprResult &LHS, ExprResult &RHS, SourceLocation Loc); /// Type checking for matrix binary operators. QualType CheckMatrixElementwiseOperands(ExprResult &LHS, ExprResult &RHS, SourceLocation Loc, bool IsCompAssign); QualType CheckMatrixMultiplyOperands(ExprResult &LHS, ExprResult &RHS, SourceLocation Loc, bool IsCompAssign); bool isValidSveBitcast(QualType srcType, QualType destType); bool areMatrixTypesOfTheSameDimension(QualType srcTy, QualType destTy); bool areVectorTypesSameSize(QualType srcType, QualType destType); bool areLaxCompatibleVectorTypes(QualType srcType, QualType destType); bool isLaxVectorConversion(QualType srcType, QualType destType); /// type checking declaration initializers (C99 6.7.8) bool CheckForConstantInitializer(Expr e, QualType t); // type checking C++ declaration initializers (C++ [dcl.init]). /// ReferenceCompareResult - Expresses the result of comparing two /// types (cv1 T1 and cv2 T2) to determine their compatibility for the /// purposes of initialization by reference (C++ [dcl.init.ref]p4). enum ReferenceCompareResult { /// Ref_Incompatible - The two types are incompatible, so direct /// reference binding is not possible. Ref_Incompatible = 0, /// Ref_Related - The two types are reference-related, which means /// that their unqualified forms (T1 and T2) are either the same /// or T1 is a base class of T2. Ref_Related, /// Ref_Compatible - The two types are reference-compatible. Ref_Compatible }; // Fake up a scoped enumeration that still contextually converts to bool. struct ReferenceConversionsScope { /// The conversions that would be performed on an lvalue of type T2 when /// binding a reference of type T1 to it, as determined when evaluating /// whether T1 is reference-compatible with T2. enum ReferenceConversions { Qualification = 0x1, NestedQualification = 0x2, Function = 0x4, DerivedToBase = 0x8, ObjC = 0x10, ObjCLifetime = 0x20, LLVM_MARK_AS_BITMASK_ENUM(/LargestValue=/ObjCLifetime) }; }; using ReferenceConversions = ReferenceConversionsScope::ReferenceConversions; ReferenceCompareResult CompareReferenceRelationship(SourceLocation Loc, QualType T1, QualType T2, ReferenceConversions Conv = nullptr); ExprResult checkUnknownAnyCast(SourceRange TypeRange, QualType CastType, Expr CastExpr, CastKind &CastKind, ExprValueKind &VK, CXXCastPath &Path); /// Force an expression with unknown-type to an expression of the /// given type. ExprResult forceUnknownAnyToType(Expr E, QualType ToType); /// Type-check an expression that's being passed to an /// __unknown_anytype parameter. ExprResult checkUnknownAnyArg(SourceLocation callLoc, Expr result, QualType &paramType); // CheckMatrixCast - Check type constraints for matrix casts. // We allow casting between matrixes of the same dimensions i.e. when they // have the same number of rows and column. Returns true if the cast is // invalid. bool CheckMatrixCast(SourceRange R, QualType DestTy, QualType SrcTy, CastKind &Kind); // CheckVectorCast - check type constraints for vectors. // Since vectors are an extension, there are no C standard reference for this. // We allow casting between vectors and integer datatypes of the same size. // returns true if the cast is invalid bool CheckVectorCast(SourceRange R, QualType VectorTy, QualType Ty, CastKind &Kind); /// Prepare `SplattedExpr` for a vector splat operation, adding /// implicit casts if necessary. ExprResult prepareVectorSplat(QualType VectorTy, Expr SplattedExpr); // CheckExtVectorCast - check type constraints for extended vectors. // Since vectors are an extension, there are no C standard reference for this. // We allow casting between vectors and integer datatypes of the same size, // or vectors and the element type of that vector. // returns the cast expr ExprResult CheckExtVectorCast(SourceRange R, QualType DestTy, Expr CastExpr, CastKind &Kind); ExprResult BuildCXXFunctionalCastExpr(TypeSourceInfo TInfo, QualType Type, SourceLocation LParenLoc, Expr CastExpr, SourceLocation RParenLoc); enum ARCConversionResult { ACR_okay, ACR_unbridged, ACR_error }; /// Checks for invalid conversions and casts between /// retainable pointers and other pointer kinds for ARC and Weak. ARCConversionResult CheckObjCConversion(SourceRange castRange, QualType castType, Expr &op, CheckedConversionKind CCK, bool Diagnose = true, bool DiagnoseCFAudited = false, BinaryOperatorKind Opc = BO_PtrMemD ); Expr stripARCUnbridgedCast(Expr e); void diagnoseARCUnbridgedCast(Expr e); bool CheckObjCARCUnavailableWeakConversion(QualType castType, QualType ExprType); /// checkRetainCycles - Check whether an Objective-C message send /// might create an obvious retain cycle. void checkRetainCycles(ObjCMessageExpr msg); void checkRetainCycles(Expr receiver, Expr argument); void checkRetainCycles(VarDecl Var, Expr Init); /// checkUnsafeAssigns - Check whether +1 expr is being assigned /// to weak/__unsafe_unretained type. bool checkUnsafeAssigns(SourceLocation Loc, QualType LHS, Expr RHS); /// checkUnsafeExprAssigns - Check whether +1 expr is being assigned /// to weak/__unsafe_unretained expression. void checkUnsafeExprAssigns(SourceLocation Loc, Expr LHS, Expr RHS); /// CheckMessageArgumentTypes - Check types in an Obj-C message send. /// \param Method - May be null. /// \param [out] ReturnType - The return type of the send. /// \return true iff there were any incompatible types. bool CheckMessageArgumentTypes(const Expr Receiver, QualType ReceiverType, MultiExprArg Args, Selector Sel, ArrayRef<SourceLocation> SelectorLocs, ObjCMethodDecl Method, bool isClassMessage, bool isSuperMessage, SourceLocation lbrac, SourceLocation rbrac, SourceRange RecRange, QualType &ReturnType, ExprValueKind &VK); /// Determine the result of a message send expression based on /// the type of the receiver, the method expected to receive the message, /// and the form of the message send. QualType getMessageSendResultType(const Expr Receiver, QualType ReceiverType, ObjCMethodDecl Method, bool isClassMessage, bool isSuperMessage); /// If the given expression involves a message send to a method /// with a related result type, emit a note describing what happened. void EmitRelatedResultTypeNote(const Expr E); /// Given that we had incompatible pointer types in a return /// statement, check whether we're in a method with a related result /// type, and if so, emit a note describing what happened. void EmitRelatedResultTypeNoteForReturn(QualType destType); class ConditionResult { Decl ConditionVar; FullExprArg Condition; bool Invalid; bool HasKnownValue; bool KnownValue; friend class Sema; ConditionResult(Sema &S, Decl ConditionVar, FullExprArg Condition, bool IsConstexpr) : ConditionVar(ConditionVar), Condition(Condition), Invalid(false), HasKnownValue(IsConstexpr && Condition.get() && !Condition.get()->isValueDependent()), KnownValue(HasKnownValue && !!Condition.get()->EvaluateKnownConstInt(S.Context)) {} explicit ConditionResult(bool Invalid) : ConditionVar(nullptr), Condition(nullptr), Invalid(Invalid), HasKnownValue(false), KnownValue(false) {} public: ConditionResult() : ConditionResult(false) {} bool isInvalid() const { return Invalid; } std::pair<VarDecl , Expr > get() const { return std::make_pair(cast_or_null<VarDecl>(ConditionVar), Condition.get()); } llvm::Optional<bool> getKnownValue() const { if (!HasKnownValue) return None; return KnownValue; } }; static ConditionResult ConditionError() { return ConditionResult(true); } enum class ConditionKind { Boolean, ///< A boolean condition, from 'if', 'while', 'for', or 'do'. ConstexprIf, ///< A constant boolean condition from 'if constexpr'. Switch ///< An integral condition for a 'switch' statement. }; ConditionResult ActOnCondition(Scope S, SourceLocation Loc, Expr SubExpr, ConditionKind CK); ConditionResult ActOnConditionVariable(Decl ConditionVar, SourceLocation StmtLoc, ConditionKind CK); DeclResult ActOnCXXConditionDeclaration(Scope S, Declarator &D); ExprResult CheckConditionVariable(VarDecl ConditionVar, SourceLocation StmtLoc, ConditionKind CK); ExprResult CheckSwitchCondition(SourceLocation SwitchLoc, Expr Cond); /// CheckBooleanCondition - Diagnose problems involving the use of /// the given expression as a boolean condition (e.g. in an if /// statement). Also performs the standard function and array /// decays, possibly changing the input variable. /// /// \param Loc - A location associated with the condition, e.g. the /// 'if' keyword. /// \return true iff there were any errors ExprResult CheckBooleanCondition(SourceLocation Loc, Expr E, bool IsConstexpr = false); /// ActOnExplicitBoolSpecifier - Build an ExplicitSpecifier from an expression /// found in an explicit(bool) specifier. ExplicitSpecifier ActOnExplicitBoolSpecifier(Expr E); /// tryResolveExplicitSpecifier - Attempt to resolve the explict specifier. /// Returns true if the explicit specifier is now resolved. bool tryResolveExplicitSpecifier(ExplicitSpecifier &ExplicitSpec); /// DiagnoseAssignmentAsCondition - Given that an expression is /// being used as a boolean condition, warn if it's an assignment. void DiagnoseAssignmentAsCondition(Expr E); /// Redundant parentheses over an equality comparison can indicate /// that the user intended an assignment used as condition. void DiagnoseEqualityWithExtraParens(ParenExpr ParenE); /// CheckCXXBooleanCondition - Returns true if conversion to bool is invalid. ExprResult CheckCXXBooleanCondition(Expr CondExpr, bool IsConstexpr = false); /// ConvertIntegerToTypeWarnOnOverflow - Convert the specified APInt to have /// the specified width and sign. If an overflow occurs, detect it and emit /// the specified diagnostic. void ConvertIntegerToTypeWarnOnOverflow(llvm::APSInt &OldVal, unsigned NewWidth, bool NewSign, SourceLocation Loc, unsigned DiagID); /// Checks that the Objective-C declaration is declared in the global scope. /// Emits an error and marks the declaration as invalid if it's not declared /// in the global scope. bool CheckObjCDeclScope(Decl D); /// Abstract base class used for diagnosing integer constant /// expression violations. class VerifyICEDiagnoser { public: bool Suppress; VerifyICEDiagnoser(bool Suppress = false) : Suppress(Suppress) { } virtual SemaDiagnosticBuilder diagnoseNotICEType(Sema &S, SourceLocation Loc, QualType T); virtual SemaDiagnosticBuilder diagnoseNotICE(Sema &S, SourceLocation Loc) = 0; virtual SemaDiagnosticBuilder diagnoseFold(Sema &S, SourceLocation Loc); virtual ~VerifyICEDiagnoser() {} }; enum AllowFoldKind { NoFold, AllowFold, }; /// VerifyIntegerConstantExpression - Verifies that an expression is an ICE, /// and reports the appropriate diagnostics. Returns false on success. /// Can optionally return the value of the expression. ExprResult VerifyIntegerConstantExpression(Expr E, llvm::APSInt Result, VerifyICEDiagnoser &Diagnoser, AllowFoldKind CanFold = NoFold); ExprResult VerifyIntegerConstantExpression(Expr E, llvm::APSInt Result, unsigned DiagID, AllowFoldKind CanFold = NoFold); ExprResult VerifyIntegerConstantExpression(Expr E, llvm::APSInt Result = nullptr, AllowFoldKind CanFold = NoFold); ExprResult VerifyIntegerConstantExpression(Expr E, AllowFoldKind CanFold = NoFold) { return VerifyIntegerConstantExpression(E, nullptr, CanFold); } /// VerifyBitField - verifies that a bit field expression is an ICE and has /// the correct width, and that the field type is valid. /// Returns false on success. /// Can optionally return whether the bit-field is of width 0 ExprResult VerifyBitField(SourceLocation FieldLoc, IdentifierInfo FieldName, QualType FieldTy, bool IsMsStruct, Expr BitWidth, bool ZeroWidth = nullptr); private: unsigned ForceCUDAHostDeviceDepth = 0; public: /// Increments our count of the number of times we've seen a pragma forcing /// functions to be __host__ __device__. So long as this count is greater /// than zero, all functions encountered will be __host__ __device__. void PushForceCUDAHostDevice(); /// Decrements our count of the number of times we've seen a pragma forcing /// functions to be __host__ __device__. Returns false if the count is 0 /// before incrementing, so you can emit an error. bool PopForceCUDAHostDevice(); class DeviceDeferredDiagnostic { public: DeviceDeferredDiagnostic(SourceLocation SL, const PartialDiagnostic &PD, DeviceDiagnosticReason R) : Diagnostic(SL, PD), Reason(R) {} PartialDiagnosticAt &getDiag() { return Diagnostic; } DeviceDiagnosticReason getReason() const { return Reason; } private: PartialDiagnosticAt Diagnostic; DeviceDiagnosticReason Reason; }; /// Diagnostics that are emitted only if we discover that the given function /// must be codegen'ed. Because handling these correctly adds overhead to /// compilation, this is currently only enabled for CUDA compilations. llvm::DenseMap<CanonicalDeclPtr<FunctionDecl>, std::vector<DeviceDeferredDiagnostic>> DeviceDeferredDiags; /// A pair of a canonical FunctionDecl and a SourceLocation. When used as the /// key in a hashtable, both the FD and location are hashed. struct FunctionDeclAndLoc { CanonicalDeclPtr<FunctionDecl> FD; SourceLocation Loc; }; /// FunctionDecls and SourceLocations for which CheckCUDACall has emitted a /// (maybe deferred) "bad call" diagnostic. We use this to avoid emitting the /// same deferred diag twice. llvm::DenseSet<FunctionDeclAndLoc> LocsWithCUDACallDiags; /// An inverse call graph, mapping known-emitted functions to one of their /// known-emitted callers (plus the location of the call). /// /// Functions that we can tell a priori must be emitted aren't added to this /// map. llvm::DenseMap</* Callee = / CanonicalDeclPtr<FunctionDecl>, / Caller = / FunctionDeclAndLoc> DeviceKnownEmittedFns; /// Creates a SemaDiagnosticBuilder that emits the diagnostic if the current /// context is "used as device code". /// /// - If CurContext is a __host__ function, does not emit any diagnostics /// unless \p EmitOnBothSides is true. /// - If CurContext is a __device__ or __global__ function, emits the /// diagnostics immediately. /// - If CurContext is a __host__ __device__ function and we are compiling for /// the device, creates a diagnostic which is emitted if and when we realize /// that the function will be codegen'ed. /// /// Example usage: /// /// // Variable-length arrays are not allowed in CUDA device code. /// if (CUDADiagIfDeviceCode(Loc, diag::err_cuda_vla) << CurrentCUDATarget()) /// return ExprError(); /// // Otherwise, continue parsing as normal. SemaDiagnosticBuilder CUDADiagIfDeviceCode(SourceLocation Loc, unsigned DiagID); /// Creates a SemaDiagnosticBuilder that emits the diagnostic if the current /// context is "used as host code". /// /// Same as CUDADiagIfDeviceCode, with "host" and "device" switched. SemaDiagnosticBuilder CUDADiagIfHostCode(SourceLocation Loc, unsigned DiagID); /// Creates a SemaDiagnosticBuilder that emits the diagnostic if the current /// context is "used as device code". /// /// - If CurContext is a `declare target` function or it is known that the /// function is emitted for the device, emits the diagnostics immediately. /// - If CurContext is a non-`declare target` function and we are compiling /// for the device, creates a diagnostic which is emitted if and when we /// realize that the function will be codegen'ed. /// /// Example usage: /// /// // Variable-length arrays are not allowed in NVPTX device code. /// if (diagIfOpenMPDeviceCode(Loc, diag::err_vla_unsupported)) /// return ExprError(); /// // Otherwise, continue parsing as normal. SemaDiagnosticBuilder diagIfOpenMPDeviceCode(SourceLocation Loc, unsigned DiagID, FunctionDecl FD); /// Creates a SemaDiagnosticBuilder that emits the diagnostic if the current /// context is "used as host code". /// /// - If CurContext is a `declare target` function or it is known that the /// function is emitted for the host, emits the diagnostics immediately. /// - If CurContext is a non-host function, just ignore it. /// /// Example usage: /// /// // Variable-length arrays are not allowed in NVPTX device code. /// if (diagIfOpenMPHostode(Loc, diag::err_vla_unsupported)) /// return ExprError(); /// // Otherwise, continue parsing as normal. SemaDiagnosticBuilder diagIfOpenMPHostCode(SourceLocation Loc, unsigned DiagID, FunctionDecl FD); SemaDiagnosticBuilder targetDiag(SourceLocation Loc, unsigned DiagID, FunctionDecl FD = nullptr); SemaDiagnosticBuilder targetDiag(SourceLocation Loc, const PartialDiagnostic &PD, FunctionDecl FD = nullptr) { return targetDiag(Loc, PD.getDiagID(), FD) << PD; } /// Check if the type is allowed to be used for the current target. void checkTypeSupport(QualType Ty, SourceLocation Loc, ValueDecl D = nullptr); enum CUDAFunctionTarget { CFT_Device, CFT_Global, CFT_Host, CFT_HostDevice, CFT_InvalidTarget }; /// Determines whether the given function is a CUDA device/host/kernel/etc. /// function. /// /// Use this rather than examining the function's attributes yourself -- you /// will get it wrong. Returns CFT_Host if D is null. CUDAFunctionTarget IdentifyCUDATarget(const FunctionDecl D, bool IgnoreImplicitHDAttr = false); CUDAFunctionTarget IdentifyCUDATarget(const ParsedAttributesView &Attrs); enum CUDAVariableTarget { CVT_Device, /// Emitted on device side with a shadow variable on host side CVT_Host, /// Emitted on host side only CVT_Both, /// Emitted on both sides with different addresses CVT_Unified, /// Emitted as a unified address, e.g. managed variables }; /// Determines whether the given variable is emitted on host or device side. CUDAVariableTarget IdentifyCUDATarget(const VarDecl D); /// Gets the CUDA target for the current context. CUDAFunctionTarget CurrentCUDATarget() { return IdentifyCUDATarget(dyn_cast<FunctionDecl>(CurContext)); } static bool isCUDAImplicitHostDeviceFunction(const FunctionDecl D); // CUDA function call preference. Must be ordered numerically from // worst to best. enum CUDAFunctionPreference { CFP_Never, // Invalid caller/callee combination. CFP_WrongSide, // Calls from host-device to host or device // function that do not match current compilation // mode. CFP_HostDevice, // Any calls to host/device functions. CFP_SameSide, // Calls from host-device to host or device // function matching current compilation mode. CFP_Native, // host-to-host or device-to-device calls. }; /// Identifies relative preference of a given Caller/Callee /// combination, based on their host/device attributes. /// \param Caller function which needs address of \p Callee. /// nullptr in case of global context. /// \param Callee target function /// /// \returns preference value for particular Caller/Callee combination. CUDAFunctionPreference IdentifyCUDAPreference(const FunctionDecl Caller, const FunctionDecl Callee); /// Determines whether Caller may invoke Callee, based on their CUDA /// host/device attributes. Returns false if the call is not allowed. /// /// Note: Will return true for CFP_WrongSide calls. These may appear in /// semantically correct CUDA programs, but only if they're never codegen'ed. bool IsAllowedCUDACall(const FunctionDecl Caller, const FunctionDecl Callee) { return IdentifyCUDAPreference(Caller, Callee) != CFP_Never; } /// May add implicit CUDAHostAttr and CUDADeviceAttr attributes to FD, /// depending on FD and the current compilation settings. void maybeAddCUDAHostDeviceAttrs(FunctionDecl FD, const LookupResult &Previous); /// May add implicit CUDAConstantAttr attribute to VD, depending on VD /// and current compilation settings. void MaybeAddCUDAConstantAttr(VarDecl VD); public: /// Check whether we're allowed to call Callee from the current context. /// /// - If the call is never allowed in a semantically-correct program /// (CFP_Never), emits an error and returns false. /// /// - If the call is allowed in semantically-correct programs, but only if /// it's never codegen'ed (CFP_WrongSide), creates a deferred diagnostic to /// be emitted if and when the caller is codegen'ed, and returns true. /// /// Will only create deferred diagnostics for a given SourceLocation once, /// so you can safely call this multiple times without generating duplicate /// deferred errors. /// /// - Otherwise, returns true without emitting any diagnostics. bool CheckCUDACall(SourceLocation Loc, FunctionDecl Callee); void CUDACheckLambdaCapture(CXXMethodDecl D, const sema::Capture &Capture); /// Set __device__ or __host__ __device__ attributes on the given lambda /// operator() method. /// /// CUDA lambdas by default is host device function unless it has explicit /// host or device attribute. void CUDASetLambdaAttrs(CXXMethodDecl Method); /// Finds a function in \p Matches with highest calling priority /// from \p Caller context and erases all functions with lower /// calling priority. void EraseUnwantedCUDAMatches( const FunctionDecl Caller, SmallVectorImpl<std::pair<DeclAccessPair, FunctionDecl >> &Matches); /// Given a implicit special member, infer its CUDA target from the /// calls it needs to make to underlying base/field special members. /// \param ClassDecl the class for which the member is being created. /// \param CSM the kind of special member. /// \param MemberDecl the special member itself. /// \param ConstRHS true if this is a copy operation with a const object on /// its RHS. /// \param Diagnose true if this call should emit diagnostics. /// \return true if there was an error inferring. /// The result of this call is implicit CUDA target attribute(s) attached to /// the member declaration. bool inferCUDATargetForImplicitSpecialMember(CXXRecordDecl ClassDecl, CXXSpecialMember CSM, CXXMethodDecl MemberDecl, bool ConstRHS, bool Diagnose); /// \return true if \p CD can be considered empty according to CUDA /// (E.2.3.1 in CUDA 7.5 Programming guide). bool isEmptyCudaConstructor(SourceLocation Loc, CXXConstructorDecl CD); bool isEmptyCudaDestructor(SourceLocation Loc, CXXDestructorDecl CD); // \brief Checks that initializers of \p Var satisfy CUDA restrictions. In // case of error emits appropriate diagnostic and invalidates \p Var. // // \details CUDA allows only empty constructors as initializers for global // variables (see E.2.3.1, CUDA 7.5). The same restriction also applies to all // __shared__ variables whether they are local or not (they all are implicitly // static in CUDA). One exception is that CUDA allows constant initializers // for __constant__ and __device__ variables. void checkAllowedCUDAInitializer(VarDecl VD); /// Check whether NewFD is a valid overload for CUDA. Emits /// diagnostics and invalidates NewFD if not. void checkCUDATargetOverload(FunctionDecl NewFD, const LookupResult &Previous); /// Copies target attributes from the template TD to the function FD. void inheritCUDATargetAttrs(FunctionDecl FD, const FunctionTemplateDecl &TD); /// Returns the name of the launch configuration function. This is the name /// of the function that will be called to configure kernel call, with the /// parameters specified via <<<>>>. std::string getCudaConfigureFuncName() const; /// \name Code completion //@{ /// Describes the context in which code completion occurs. enum ParserCompletionContext { /// Code completion occurs at top-level or namespace context. PCC_Namespace, /// Code completion occurs within a class, struct, or union. PCC_Class, /// Code completion occurs within an Objective-C interface, protocol, /// or category. PCC_ObjCInterface, /// Code completion occurs within an Objective-C implementation or /// category implementation PCC_ObjCImplementation, /// Code completion occurs within the list of instance variables /// in an Objective-C interface, protocol, category, or implementation. PCC_ObjCInstanceVariableList, /// Code completion occurs following one or more template /// headers. PCC_Template, /// Code completion occurs following one or more template /// headers within a class. PCC_MemberTemplate, /// Code completion occurs within an expression. PCC_Expression, /// Code completion occurs within a statement, which may /// also be an expression or a declaration. PCC_Statement, /// Code completion occurs at the beginning of the /// initialization statement (or expression) in a for loop. PCC_ForInit, /// Code completion occurs within the condition of an if, /// while, switch, or for statement. PCC_Condition, /// Code completion occurs within the body of a function on a /// recovery path, where we do not have a specific handle on our position /// in the grammar. PCC_RecoveryInFunction, /// Code completion occurs where only a type is permitted. PCC_Type, /// Code completion occurs in a parenthesized expression, which /// might also be a type cast. PCC_ParenthesizedExpression, /// Code completion occurs within a sequence of declaration /// specifiers within a function, method, or block. PCC_LocalDeclarationSpecifiers }; void CodeCompleteModuleImport(SourceLocation ImportLoc, ModuleIdPath Path); void CodeCompleteOrdinaryName(Scope S, ParserCompletionContext CompletionContext); void CodeCompleteDeclSpec(Scope S, DeclSpec &DS, bool AllowNonIdentifiers, bool AllowNestedNameSpecifiers); struct CodeCompleteExpressionData; void CodeCompleteExpression(Scope S, const CodeCompleteExpressionData &Data); void CodeCompleteExpression(Scope S, QualType PreferredType, bool IsParenthesized = false); void CodeCompleteMemberReferenceExpr(Scope S, Expr Base, Expr OtherOpBase, SourceLocation OpLoc, bool IsArrow, bool IsBaseExprStatement, QualType PreferredType); void CodeCompletePostfixExpression(Scope S, ExprResult LHS, QualType PreferredType); void CodeCompleteTag(Scope S, unsigned TagSpec); void CodeCompleteTypeQualifiers(DeclSpec &DS); void CodeCompleteFunctionQualifiers(DeclSpec &DS, Declarator &D, const VirtSpecifiers VS = nullptr); void CodeCompleteBracketDeclarator(Scope S); void CodeCompleteCase(Scope S); enum class AttributeCompletion { Attribute, Scope, None, }; void CodeCompleteAttribute( AttributeCommonInfo::Syntax Syntax, AttributeCompletion Completion = AttributeCompletion::Attribute, const IdentifierInfo Scope = nullptr); /// Determines the preferred type of the current function argument, by /// examining the signatures of all possible overloads. /// Returns null if unknown or ambiguous, or if code completion is off. /// /// If the code completion point has been reached, also reports the function /// signatures that were considered. /// /// FIXME: rename to GuessCallArgumentType to reduce confusion. QualType ProduceCallSignatureHelp(Scope S, Expr Fn, ArrayRef<Expr > Args, SourceLocation OpenParLoc); QualType ProduceConstructorSignatureHelp(Scope S, QualType Type, SourceLocation Loc, ArrayRef<Expr > Args, SourceLocation OpenParLoc); QualType ProduceCtorInitMemberSignatureHelp(Scope S, Decl ConstructorDecl, CXXScopeSpec SS, ParsedType TemplateTypeTy, ArrayRef<Expr > ArgExprs, IdentifierInfo II, SourceLocation OpenParLoc); void CodeCompleteInitializer(Scope S, Decl D); /// Trigger code completion for a record of \p BaseType. \p InitExprs are /// expressions in the initializer list seen so far and \p D is the current /// Designation being parsed. void CodeCompleteDesignator(const QualType BaseType, llvm::ArrayRef<Expr > InitExprs, const Designation &D); void CodeCompleteAfterIf(Scope S, bool IsBracedThen); void CodeCompleteQualifiedId(Scope S, CXXScopeSpec &SS, bool EnteringContext, bool IsUsingDeclaration, QualType BaseType, QualType PreferredType); void CodeCompleteUsing(Scope S); void CodeCompleteUsingDirective(Scope S); void CodeCompleteNamespaceDecl(Scope S); void CodeCompleteNamespaceAliasDecl(Scope S); void CodeCompleteOperatorName(Scope S); void CodeCompleteConstructorInitializer( Decl Constructor, ArrayRef<CXXCtorInitializer > Initializers); void CodeCompleteLambdaIntroducer(Scope S, LambdaIntroducer &Intro, bool AfterAmpersand); void CodeCompleteAfterFunctionEquals(Declarator &D); void CodeCompleteObjCAtDirective(Scope S); void CodeCompleteObjCAtVisibility(Scope S); void CodeCompleteObjCAtStatement(Scope S); void CodeCompleteObjCAtExpression(Scope S); void CodeCompleteObjCPropertyFlags(Scope S, ObjCDeclSpec &ODS); void CodeCompleteObjCPropertyGetter(Scope S); void CodeCompleteObjCPropertySetter(Scope S); void CodeCompleteObjCPassingType(Scope S, ObjCDeclSpec &DS, bool IsParameter); void CodeCompleteObjCMessageReceiver(Scope S); void CodeCompleteObjCSuperMessage(Scope S, SourceLocation SuperLoc, ArrayRef<IdentifierInfo > SelIdents, bool AtArgumentExpression); void CodeCompleteObjCClassMessage(Scope S, ParsedType Receiver, ArrayRef<IdentifierInfo > SelIdents, bool AtArgumentExpression, bool IsSuper = false); void CodeCompleteObjCInstanceMessage(Scope S, Expr Receiver, ArrayRef<IdentifierInfo > SelIdents, bool AtArgumentExpression, ObjCInterfaceDecl Super = nullptr); void CodeCompleteObjCForCollection(Scope S, DeclGroupPtrTy IterationVar); void CodeCompleteObjCSelector(Scope S, ArrayRef<IdentifierInfo > SelIdents); void CodeCompleteObjCProtocolReferences( ArrayRef<IdentifierLocPair> Protocols); void CodeCompleteObjCProtocolDecl(Scope S); void CodeCompleteObjCInterfaceDecl(Scope S); void CodeCompleteObjCSuperclass(Scope S, IdentifierInfo ClassName, SourceLocation ClassNameLoc); void CodeCompleteObjCImplementationDecl(Scope S); void CodeCompleteObjCInterfaceCategory(Scope S, IdentifierInfo ClassName, SourceLocation ClassNameLoc); void CodeCompleteObjCImplementationCategory(Scope S, IdentifierInfo ClassName, SourceLocation ClassNameLoc); void CodeCompleteObjCPropertyDefinition(Scope S); void CodeCompleteObjCPropertySynthesizeIvar(Scope S, IdentifierInfo PropertyName); void CodeCompleteObjCMethodDecl(Scope S, Optional<bool> IsInstanceMethod, ParsedType ReturnType); void CodeCompleteObjCMethodDeclSelector(Scope S, bool IsInstanceMethod, bool AtParameterName, ParsedType ReturnType, ArrayRef<IdentifierInfo > SelIdents); void CodeCompleteObjCClassPropertyRefExpr(Scope S, IdentifierInfo &ClassName, SourceLocation ClassNameLoc, bool IsBaseExprStatement); void CodeCompletePreprocessorDirective(bool InConditional); void CodeCompleteInPreprocessorConditionalExclusion(Scope S); void CodeCompletePreprocessorMacroName(bool IsDefinition); void CodeCompletePreprocessorExpression(); void CodeCompletePreprocessorMacroArgument(Scope S, IdentifierInfo Macro, MacroInfo MacroInfo, unsigned Argument); void CodeCompleteIncludedFile(llvm::StringRef Dir, bool IsAngled); void CodeCompleteNaturalLanguage(); void CodeCompleteAvailabilityPlatformName(); void GatherGlobalCodeCompletions(CodeCompletionAllocator &Allocator, CodeCompletionTUInfo &CCTUInfo, SmallVectorImpl<CodeCompletionResult> &Results); //@} //===--------------------------------------------------------------------===// // Extra semantic analysis beyond the C type system public: SourceLocation getLocationOfStringLiteralByte(const StringLiteral SL, unsigned ByteNo) const; private: void CheckArrayAccess(const Expr BaseExpr, const Expr IndexExpr, const ArraySubscriptExpr ASE=nullptr, bool AllowOnePastEnd=true, bool IndexNegated=false); void CheckArrayAccess(const Expr E); // Used to grab the relevant information from a FormatAttr and a // FunctionDeclaration. struct FormatStringInfo { unsigned FormatIdx; unsigned FirstDataArg; bool HasVAListArg; }; static bool getFormatStringInfo(const FormatAttr Format, bool IsCXXMember, FormatStringInfo FSI); bool CheckFunctionCall(FunctionDecl FDecl, CallExpr TheCall, const FunctionProtoType Proto); bool CheckObjCMethodCall(ObjCMethodDecl Method, SourceLocation loc, ArrayRef<const Expr > Args); bool CheckPointerCall(NamedDecl NDecl, CallExpr TheCall, const FunctionProtoType Proto); bool CheckOtherCall(CallExpr TheCall, const FunctionProtoType Proto); void CheckConstructorCall(FunctionDecl FDecl, QualType ThisType, ArrayRef<const Expr > Args, const FunctionProtoType Proto, SourceLocation Loc); void CheckArgAlignment(SourceLocation Loc, NamedDecl FDecl, StringRef ParamName, QualType ArgTy, QualType ParamTy); void checkCall(NamedDecl FDecl, const FunctionProtoType Proto, const Expr ThisArg, ArrayRef<const Expr > Args, bool IsMemberFunction, SourceLocation Loc, SourceRange Range, VariadicCallType CallType); void CheckSYCLKernelCall(FunctionDecl CallerFunc, SourceRange CallLoc, ArrayRef<const Expr > Args); bool CheckObjCString(Expr Arg); ExprResult CheckOSLogFormatStringArg(Expr Arg); ExprResult CheckBuiltinFunctionCall(FunctionDecl FDecl, unsigned BuiltinID, CallExpr TheCall); bool CheckTSBuiltinFunctionCall(const TargetInfo &TI, unsigned BuiltinID, CallExpr TheCall); void checkFortifiedBuiltinMemoryFunction(FunctionDecl FD, CallExpr TheCall); bool CheckARMBuiltinExclusiveCall(unsigned BuiltinID, CallExpr TheCall, unsigned MaxWidth); bool CheckNeonBuiltinFunctionCall(const TargetInfo &TI, unsigned BuiltinID, CallExpr TheCall); bool CheckMVEBuiltinFunctionCall(unsigned BuiltinID, CallExpr TheCall); bool CheckSVEBuiltinFunctionCall(unsigned BuiltinID, CallExpr TheCall); bool CheckCDEBuiltinFunctionCall(const TargetInfo &TI, unsigned BuiltinID, CallExpr TheCall); bool CheckARMCoprocessorImmediate(const TargetInfo &TI, const Expr CoprocArg, bool WantCDE); bool CheckARMBuiltinFunctionCall(const TargetInfo &TI, unsigned BuiltinID, CallExpr TheCall); bool CheckAArch64BuiltinFunctionCall(const TargetInfo &TI, unsigned BuiltinID, CallExpr TheCall); bool CheckBPFBuiltinFunctionCall(unsigned BuiltinID, CallExpr TheCall); bool CheckHexagonBuiltinFunctionCall(unsigned BuiltinID, CallExpr TheCall); bool CheckHexagonBuiltinArgument(unsigned BuiltinID, CallExpr TheCall); bool CheckMipsBuiltinFunctionCall(const TargetInfo &TI, unsigned BuiltinID, CallExpr TheCall); bool CheckMipsBuiltinCpu(const TargetInfo &TI, unsigned BuiltinID, CallExpr TheCall); bool CheckMipsBuiltinArgument(unsigned BuiltinID, CallExpr TheCall); bool CheckSystemZBuiltinFunctionCall(unsigned BuiltinID, CallExpr TheCall); bool CheckX86BuiltinRoundingOrSAE(unsigned BuiltinID, CallExpr TheCall); bool CheckX86BuiltinGatherScatterScale(unsigned BuiltinID, CallExpr TheCall); bool CheckX86BuiltinTileArguments(unsigned BuiltinID, CallExpr TheCall); bool CheckX86BuiltinTileArgumentsRange(CallExpr TheCall, ArrayRef<int> ArgNums); bool CheckX86BuiltinTileDuplicate(CallExpr TheCall, ArrayRef<int> ArgNums); bool CheckX86BuiltinTileRangeAndDuplicate(CallExpr TheCall, ArrayRef<int> ArgNums); bool CheckX86BuiltinFunctionCall(const TargetInfo &TI, unsigned BuiltinID, CallExpr TheCall); bool CheckPPCBuiltinFunctionCall(const TargetInfo &TI, unsigned BuiltinID, CallExpr TheCall); bool CheckAMDGCNBuiltinFunctionCall(unsigned BuiltinID, CallExpr TheCall); bool CheckRISCVLMUL(CallExpr TheCall, unsigned ArgNum); bool CheckRISCVBuiltinFunctionCall(const TargetInfo &TI, unsigned BuiltinID, CallExpr TheCall); bool CheckIntelFPGARegBuiltinFunctionCall(unsigned BuiltinID, CallExpr Call); bool CheckIntelFPGAMemBuiltinFunctionCall(CallExpr Call); bool SemaBuiltinVAStart(unsigned BuiltinID, CallExpr TheCall); bool SemaBuiltinVAStartARMMicrosoft(CallExpr Call); bool SemaBuiltinUnorderedCompare(CallExpr TheCall); bool SemaBuiltinFPClassification(CallExpr TheCall, unsigned NumArgs); bool SemaBuiltinComplex(CallExpr TheCall); bool SemaBuiltinVSX(CallExpr TheCall); bool SemaBuiltinOSLogFormat(CallExpr TheCall); bool SemaValueIsRunOfOnes(CallExpr TheCall, unsigned ArgNum); public: // Used by C++ template instantiation. ExprResult SemaBuiltinShuffleVector(CallExpr TheCall); ExprResult SemaConvertVectorExpr(Expr E, TypeSourceInfo TInfo, SourceLocation BuiltinLoc, SourceLocation RParenLoc); private: bool SemaBuiltinPrefetch(CallExpr TheCall); bool SemaBuiltinAllocaWithAlign(CallExpr TheCall); bool SemaBuiltinArithmeticFence(CallExpr TheCall); bool SemaBuiltinAssume(CallExpr TheCall); bool SemaBuiltinAssumeAligned(CallExpr TheCall); bool SemaBuiltinLongjmp(CallExpr TheCall); bool SemaBuiltinSetjmp(CallExpr TheCall); ExprResult SemaBuiltinAtomicOverloaded(ExprResult TheCallResult); ExprResult SemaBuiltinNontemporalOverloaded(ExprResult TheCallResult); ExprResult SemaAtomicOpsOverloaded(ExprResult TheCallResult, AtomicExpr::AtomicOp Op); ExprResult SemaBuiltinOperatorNewDeleteOverloaded(ExprResult TheCallResult, bool IsDelete); bool SemaBuiltinConstantArg(CallExpr TheCall, int ArgNum, llvm::APSInt &Result); bool SemaBuiltinConstantArgRange(CallExpr TheCall, int ArgNum, int Low, int High, bool RangeIsError = true); bool SemaBuiltinConstantArgMultiple(CallExpr TheCall, int ArgNum, unsigned Multiple); bool SemaBuiltinConstantArgPower2(CallExpr TheCall, int ArgNum); bool SemaBuiltinConstantArgShiftedByte(CallExpr TheCall, int ArgNum, unsigned ArgBits); bool SemaBuiltinConstantArgShiftedByteOrXXFF(CallExpr TheCall, int ArgNum, unsigned ArgBits); bool SemaBuiltinARMSpecialReg(unsigned BuiltinID, CallExpr TheCall, int ArgNum, unsigned ExpectedFieldNum, bool AllowName); bool SemaBuiltinARMMemoryTaggingCall(unsigned BuiltinID, CallExpr TheCall); bool SemaBuiltinPPCMMACall(CallExpr TheCall, unsigned BuiltinID, const char TypeDesc); bool CheckPPCMMAType(QualType Type, SourceLocation TypeLoc); bool SemaBuiltinElementwiseMath(CallExpr TheCall); bool SemaBuiltinElementwiseMathOneArg(CallExpr TheCall); // Matrix builtin handling. ExprResult SemaBuiltinMatrixTranspose(CallExpr TheCall, ExprResult CallResult); ExprResult SemaBuiltinMatrixColumnMajorLoad(CallExpr TheCall, ExprResult CallResult); ExprResult SemaBuiltinMatrixColumnMajorStore(CallExpr TheCall, ExprResult CallResult); public: enum FormatStringType { FST_Scanf, FST_Printf, FST_NSString, FST_Strftime, FST_Strfmon, FST_Kprintf, FST_FreeBSDKPrintf, FST_OSTrace, FST_OSLog, FST_Unknown }; static FormatStringType GetFormatStringType(const FormatAttr Format); bool FormatStringHasSArg(const StringLiteral FExpr); static bool GetFormatNSStringIdx(const FormatAttr Format, unsigned &Idx); private: bool CheckFormatArguments(const FormatAttr Format, ArrayRef<const Expr > Args, bool IsCXXMember, VariadicCallType CallType, SourceLocation Loc, SourceRange Range, llvm::SmallBitVector &CheckedVarArgs); bool CheckFormatArguments(ArrayRef<const Expr > Args, bool HasVAListArg, unsigned format_idx, unsigned firstDataArg, FormatStringType Type, VariadicCallType CallType, SourceLocation Loc, SourceRange range, llvm::SmallBitVector &CheckedVarArgs); void CheckAbsoluteValueFunction(const CallExpr Call, const FunctionDecl FDecl); void CheckMaxUnsignedZero(const CallExpr Call, const FunctionDecl FDecl); void CheckMemaccessArguments(const CallExpr Call, unsigned BId, IdentifierInfo FnName); void CheckStrlcpycatArguments(const CallExpr Call, IdentifierInfo FnName); void CheckStrncatArguments(const CallExpr Call, IdentifierInfo FnName); void CheckFreeArguments(const CallExpr E); void CheckReturnValExpr(Expr RetValExp, QualType lhsType, SourceLocation ReturnLoc, bool isObjCMethod = false, const AttrVec Attrs = nullptr, const FunctionDecl FD = nullptr); public: void CheckFloatComparison(SourceLocation Loc, Expr LHS, Expr RHS); private: void CheckImplicitConversions(Expr E, SourceLocation CC = SourceLocation()); void CheckBoolLikeConversion(Expr E, SourceLocation CC); void CheckForIntOverflow(Expr E); void CheckUnsequencedOperations(const Expr E); /// Perform semantic checks on a completed expression. This will either /// be a full-expression or a default argument expression. void CheckCompletedExpr(Expr E, SourceLocation CheckLoc = SourceLocation(), bool IsConstexpr = false); void CheckBitFieldInitialization(SourceLocation InitLoc, FieldDecl Field, Expr Init); /// Check if there is a field shadowing. void CheckShadowInheritedFields(const SourceLocation &Loc, DeclarationName FieldName, const CXXRecordDecl RD, bool DeclIsField = true); /// Check if the given expression contains 'break' or 'continue' /// statement that produces control flow different from GCC. void CheckBreakContinueBinding(Expr E); /// Check whether receiver is mutable ObjC container which /// attempts to add itself into the container void CheckObjCCircularContainer(ObjCMessageExpr Message); void CheckTCBEnforcement(const CallExpr TheCall, const FunctionDecl Callee); void AnalyzeDeleteExprMismatch(const CXXDeleteExpr DE); void AnalyzeDeleteExprMismatch(FieldDecl Field, SourceLocation DeleteLoc, bool DeleteWasArrayForm); public: /// Register a magic integral constant to be used as a type tag. void RegisterTypeTagForDatatype(const IdentifierInfo ArgumentKind, uint64_t MagicValue, QualType Type, bool LayoutCompatible, bool MustBeNull); struct TypeTagData { TypeTagData() {} TypeTagData(QualType Type, bool LayoutCompatible, bool MustBeNull) : Type(Type), LayoutCompatible(LayoutCompatible), MustBeNull(MustBeNull) {} QualType Type; /// If true, \c Type should be compared with other expression's types for /// layout-compatibility. unsigned LayoutCompatible : 1; unsigned MustBeNull : 1; }; /// A pair of ArgumentKind identifier and magic value. This uniquely /// identifies the magic value. typedef std::pair<const IdentifierInfo , uint64_t> TypeTagMagicValue; private: /// A map from magic value to type information. std::unique_ptr<llvm::DenseMap<TypeTagMagicValue, TypeTagData>> TypeTagForDatatypeMagicValues; /// Peform checks on a call of a function with argument_with_type_tag /// or pointer_with_type_tag attributes. void CheckArgumentWithTypeTag(const ArgumentWithTypeTagAttr Attr, const ArrayRef<const Expr > ExprArgs, SourceLocation CallSiteLoc); /// Check if we are taking the address of a packed field /// as this may be a problem if the pointer value is dereferenced. void CheckAddressOfPackedMember(Expr rhs); /// The parser's current scope. /// /// The parser maintains this state here. Scope CurScope; mutable IdentifierInfo Ident_super; mutable IdentifierInfo Ident___float128; /// Nullability type specifiers. IdentifierInfo Ident__Nonnull = nullptr; IdentifierInfo Ident__Nullable = nullptr; IdentifierInfo Ident__Nullable_result = nullptr; IdentifierInfo Ident__Null_unspecified = nullptr; IdentifierInfo Ident_NSError = nullptr; /// The handler for the FileChanged preprocessor events. /// /// Used for diagnostics that implement custom semantic analysis for #include /// directives, like -Wpragma-pack. sema::SemaPPCallbacks SemaPPCallbackHandler; protected: friend class Parser; friend class InitializationSequence; friend class ASTReader; friend class ASTDeclReader; friend class ASTWriter; public: /// Retrieve the keyword associated IdentifierInfo getNullabilityKeyword(NullabilityKind nullability); /// The struct behind the CFErrorRef pointer. RecordDecl CFError = nullptr; bool isCFError(RecordDecl D); /// Retrieve the identifier "NSError". IdentifierInfo getNSErrorIdent(); /// Retrieve the parser's current scope. /// /// This routine must only be used when it is certain that semantic analysis /// and the parser are in precisely the same context, which is not the case /// when, e.g., we are performing any kind of template instantiation. /// Therefore, the only safe places to use this scope are in the parser /// itself and in routines directly invoked from the parser and never* from /// template substitution or instantiation. Scope getCurScope() const { return CurScope; } void incrementMSManglingNumber() const { return CurScope->incrementMSManglingNumber(); } IdentifierInfo getSuperIdentifier() const; IdentifierInfo getFloat128Identifier() const; Decl getObjCDeclContext() const; DeclContext getCurLexicalContext() const { return OriginalLexicalContext ? OriginalLexicalContext : CurContext; } const DeclContext getCurObjCLexicalContext() const { const DeclContext DC = getCurLexicalContext(); // A category implicitly has the attribute of the interface. if (const ObjCCategoryDecl CatD = dyn_cast<ObjCCategoryDecl>(DC)) DC = CatD->getClassInterface(); return DC; } /// Determine the number of levels of enclosing template parameters. This is /// only usable while parsing. Note that this does not include dependent /// contexts in which no template parameters have yet been declared, such as /// in a terse function template or generic lambda before the first 'auto' is /// encountered. unsigned getTemplateDepth(Scope S) const; /// To be used for checking whether the arguments being passed to /// function exceeds the number of parameters expected for it. static bool TooManyArguments(size_t NumParams, size_t NumArgs, bool PartialOverloading = false) { // We check whether we're just after a comma in code-completion. if (NumArgs > 0 && PartialOverloading) return NumArgs + 1 > NumParams; // If so, we view as an extra argument. return NumArgs > NumParams; } // Emitting members of dllexported classes is delayed until the class // (including field initializers) is fully parsed. SmallVector<CXXRecordDecl, 4> DelayedDllExportClasses; SmallVector<CXXMethodDecl, 4> DelayedDllExportMemberFunctions; private: int ParsingClassDepth = 0; class SavePendingParsedClassStateRAII { public: SavePendingParsedClassStateRAII(Sema &S) : S(S) { swapSavedState(); } ~SavePendingParsedClassStateRAII() { assert(S.DelayedOverridingExceptionSpecChecks.empty() && "there shouldn't be any pending delayed exception spec checks"); assert(S.DelayedEquivalentExceptionSpecChecks.empty() && "there shouldn't be any pending delayed exception spec checks"); swapSavedState(); } private: Sema &S; decltype(DelayedOverridingExceptionSpecChecks) SavedOverridingExceptionSpecChecks; decltype(DelayedEquivalentExceptionSpecChecks) SavedEquivalentExceptionSpecChecks; void swapSavedState() { SavedOverridingExceptionSpecChecks.swap( S.DelayedOverridingExceptionSpecChecks); SavedEquivalentExceptionSpecChecks.swap( S.DelayedEquivalentExceptionSpecChecks); } }; /// Helper class that collects misaligned member designations and /// their location info for delayed diagnostics. struct MisalignedMember { Expr E; RecordDecl RD; ValueDecl MD; CharUnits Alignment; MisalignedMember() : E(), RD(), MD(), Alignment() {} MisalignedMember(Expr E, RecordDecl RD, ValueDecl MD, CharUnits Alignment) : E(E), RD(RD), MD(MD), Alignment(Alignment) {} explicit MisalignedMember(Expr E) : MisalignedMember(E, nullptr, nullptr, CharUnits()) {} bool operator==(const MisalignedMember &m) { return this->E == m.E; } }; /// Small set of gathered accesses to potentially misaligned members /// due to the packed attribute. SmallVector<MisalignedMember, 4> MisalignedMembers; /// Adds an expression to the set of gathered misaligned members. void AddPotentialMisalignedMembers(Expr E, RecordDecl RD, ValueDecl MD, CharUnits Alignment); public: /// Diagnoses the current set of gathered accesses. This typically /// happens at full expression level. The set is cleared after emitting the /// diagnostics. void DiagnoseMisalignedMembers(); /// This function checks if the expression is in the sef of potentially /// misaligned members and it is converted to some pointer type T with lower /// or equal alignment requirements. If so it removes it. This is used when /// we do not want to diagnose such misaligned access (e.g. in conversions to /// void). void DiscardMisalignedMemberAddress(const Type T, Expr E); /// This function calls Action when it determines that E designates a /// misaligned member due to the packed attribute. This is used to emit /// local diagnostics like in reference binding. void RefersToMemberWithReducedAlignment( Expr E, llvm::function_ref<void(Expr , RecordDecl , FieldDecl , CharUnits)> Action); /// Describes the reason a calling convention specification was ignored, used /// for diagnostics. enum class CallingConventionIgnoredReason { ForThisTarget = 0, VariadicFunction, ConstructorDestructor, BuiltinFunction }; private: // We store SYCL Kernels here and handle separately -- which is a hack. // FIXME: It would be best to refactor this. llvm::SetVector<Decl > SyclDeviceDecls; // SYCL integration header instance for current compilation unit this Sema // is associated with. std::unique_ptr<SYCLIntegrationHeader> SyclIntHeader; std::unique_ptr<SYCLIntegrationFooter> SyclIntFooter; // We need to store the list of the sycl_kernel functions and their associated // generated OpenCL Kernels so we can go back and re-name these after the // fact. llvm::SmallVector<std::pair<const FunctionDecl , FunctionDecl >> SyclKernelsToOpenCLKernels; // Used to suppress diagnostics during kernel construction, since these were // already emitted earlier. Diagnosing during Kernel emissions also skips the // useful notes that shows where the kernel was called. bool DiagnosingSYCLKernel = false; public: void addSyclOpenCLKernel(const FunctionDecl SyclKernel, FunctionDecl OpenCLKernel) { SyclKernelsToOpenCLKernels.emplace_back(SyclKernel, OpenCLKernel); } void addSyclDeviceDecl(Decl d) { SyclDeviceDecls.insert(d); } llvm::SetVector<Decl > &syclDeviceDecls() { return SyclDeviceDecls; } /// Lazily creates and returns SYCL integration header instance. SYCLIntegrationHeader &getSyclIntegrationHeader() { if (SyclIntHeader == nullptr) SyclIntHeader = std::make_unique<SYCLIntegrationHeader>(this); return SyclIntHeader.get(); } SYCLIntegrationFooter &getSyclIntegrationFooter() { if (SyclIntFooter == nullptr) SyclIntFooter = std::make_unique<SYCLIntegrationFooter>(this); return SyclIntFooter.get(); } void addSyclVarDecl(VarDecl VD) { if (LangOpts.SYCLIsDevice && !LangOpts.SYCLIntFooter.empty()) getSyclIntegrationFooter().addVarDecl(VD); } enum SYCLRestrictKind { KernelGlobalVariable, KernelRTTI, KernelNonConstStaticDataVariable, KernelCallVirtualFunction, KernelUseExceptions, KernelCallRecursiveFunction, KernelCallFunctionPointer, KernelAllocateStorage, KernelUseAssembly, KernelCallDllimportFunction, KernelCallVariadicFunction, KernelCallUndefinedFunction, KernelConstStaticVariable }; bool isKnownGoodSYCLDecl(const Decl D); void checkSYCLDeviceVarDecl(VarDecl Var); void copySYCLKernelAttrs(const CXXRecordDecl KernelObj); void ConstructOpenCLKernel(FunctionDecl KernelCallerFunc, MangleContext &MC); void SetSYCLKernelNames(); void MarkDevices(); /// Get the number of fields or captures within the parsed type. ExprResult ActOnSYCLBuiltinNumFieldsExpr(ParsedType PT); ExprResult BuildSYCLBuiltinNumFieldsExpr(SourceLocation Loc, QualType SourceTy); /// Get a value based on the type of the given field number so that callers /// can wrap it in a decltype() to get the actual type of the field. ExprResult ActOnSYCLBuiltinFieldTypeExpr(ParsedType PT, Expr Idx); ExprResult BuildSYCLBuiltinFieldTypeExpr(SourceLocation Loc, QualType SourceTy, Expr Idx); /// Get the number of base classes within the parsed type. ExprResult ActOnSYCLBuiltinNumBasesExpr(ParsedType PT); ExprResult BuildSYCLBuiltinNumBasesExpr(SourceLocation Loc, QualType SourceTy); /// Get a value based on the type of the given base number so that callers /// can wrap it in a decltype() to get the actual type of the base class. ExprResult ActOnSYCLBuiltinBaseTypeExpr(ParsedType PT, Expr Idx); ExprResult BuildSYCLBuiltinBaseTypeExpr(SourceLocation Loc, QualType SourceTy, Expr Idx); /// Emit a diagnostic about the given attribute having a deprecated name, and /// also emit a fixit hint to generate the new attribute name. void DiagnoseDeprecatedAttribute(const ParsedAttr &A, StringRef NewScope, StringRef NewName); /// Diagnoses an attribute in the 'intelfpga' namespace and suggests using /// the attribute in the 'intel' namespace instead. void CheckDeprecatedSYCLAttributeSpelling(const ParsedAttr &A, StringRef NewName = ""); /// Creates a SemaDiagnosticBuilder that emits the diagnostic if the current /// context is "used as device code". /// /// - If CurLexicalContext is a kernel function or it is known that the /// function will be emitted for the device, emits the diagnostics /// immediately. /// - If CurLexicalContext is a function and we are compiling /// for the device, but we don't know that this function will be codegen'ed /// for devive yet, creates a diagnostic which is emitted if and when we /// realize that the function will be codegen'ed. /// /// Example usage: /// /// Diagnose __float128 type usage only from SYCL device code if the current /// target doesn't support it /// if (!S.Context.getTargetInfo().hasFloat128Type() && /// S.getLangOpts().SYCLIsDevice) /// SYCLDiagIfDeviceCode(Loc, diag::err_type_unsupported) << "__float128"; SemaDiagnosticBuilder SYCLDiagIfDeviceCode( SourceLocation Loc, unsigned DiagID, DeviceDiagnosticReason Reason = DeviceDiagnosticReason::Sycl \| DeviceDiagnosticReason::Esimd); /// Check whether we're allowed to call Callee from the current context. /// /// - If the call is never allowed in a semantically-correct program /// emits an error and returns false. /// /// - If the call is allowed in semantically-correct programs, but only if /// it's never codegen'ed, creates a deferred diagnostic to be emitted if /// and when the caller is codegen'ed, and returns true. /// /// - Otherwise, returns true without emitting any diagnostics. /// /// Adds Callee to DeviceCallGraph if we don't know if its caller will be /// codegen'ed yet. bool checkSYCLDeviceFunction(SourceLocation Loc, FunctionDecl Callee); /// Finishes analysis of the deferred functions calls that may be not /// properly declared for device compilation. void finalizeSYCLDelayedAnalysis(const FunctionDecl Caller, const FunctionDecl Callee, SourceLocation Loc, DeviceDiagnosticReason Reason); /// Tells whether given variable is a SYCL explicit SIMD extension's "private /// global" variable - global variable in the private address space. bool isSYCLEsimdPrivateGlobal(VarDecl VDecl) { return getLangOpts().SYCLIsDevice && VDecl->hasAttr<SYCLSimdAttr>() && VDecl->hasGlobalStorage() && (VDecl->getType().getAddressSpace() == LangAS::sycl_private); } }; inline Expr checkMaxWorkSizeAttrExpr(Sema &S, const AttributeCommonInfo &CI, Expr E) { assert(E && "Attribute must have an argument."); if (!E->isInstantiationDependent()) { llvm::APSInt ArgVal; ExprResult ICE = S.VerifyIntegerConstantExpression(E, &ArgVal); if (ICE.isInvalid()) return nullptr; E = ICE.get(); if (ArgVal.isNegative()) { S.Diag(E->getExprLoc(), diag::warn_attribute_requires_non_negative_integer_argument) << E->getType() << S.Context.UnsignedLongLongTy << E->getSourceRange(); return E; } unsigned Val = ArgVal.getZExtValue(); if (Val == 0) { S.Diag(E->getExprLoc(), diag::err_attribute_argument_is_zero) << CI << E->getSourceRange(); return nullptr; } } return E; } template <typename WorkGroupAttrType> void Sema::addIntelTripleArgAttr(Decl D, const AttributeCommonInfo &CI, Expr XDimExpr, Expr YDimExpr, Expr ZDimExpr) { assert((XDimExpr && YDimExpr && ZDimExpr) && "argument has unexpected null value"); // Accept template arguments for now as they depend on something else. // We'll get to check them when they eventually get instantiated. if (!XDimExpr->isValueDependent() && !YDimExpr->isValueDependent() && !ZDimExpr->isValueDependent()) { // Save ConstantExpr in semantic attribute XDimExpr = checkMaxWorkSizeAttrExpr(this, CI, XDimExpr); YDimExpr = checkMaxWorkSizeAttrExpr(this, CI, YDimExpr); ZDimExpr = checkMaxWorkSizeAttrExpr(this, CI, ZDimExpr); if (!XDimExpr \|\| !YDimExpr \|\| !ZDimExpr) return; } D->addAttr(::new (Context) WorkGroupAttrType(Context, CI, XDimExpr, YDimExpr, ZDimExpr)); } /// RAII object that enters a new expression evaluation context. class EnterExpressionEvaluationContext { Sema &Actions; bool Entered = true; public: EnterExpressionEvaluationContext( Sema &Actions, Sema::ExpressionEvaluationContext NewContext, Decl LambdaContextDecl = nullptr, Sema::ExpressionEvaluationContextRecord::ExpressionKind ExprContext = Sema::ExpressionEvaluationContextRecord::EK_Other, bool ShouldEnter = true) : Actions(Actions), Entered(ShouldEnter) { if (Entered) Actions.PushExpressionEvaluationContext(NewContext, LambdaContextDecl, ExprContext); } EnterExpressionEvaluationContext( Sema &Actions, Sema::ExpressionEvaluationContext NewContext, Sema::ReuseLambdaContextDecl_t, Sema::ExpressionEvaluationContextRecord::ExpressionKind ExprContext = Sema::ExpressionEvaluationContextRecord::EK_Other) : Actions(Actions) { Actions.PushExpressionEvaluationContext( NewContext, Sema::ReuseLambdaContextDecl, ExprContext); } enum InitListTag { InitList }; EnterExpressionEvaluationContext(Sema &Actions, InitListTag, bool ShouldEnter = true) : Actions(Actions), Entered(false) { // In C++11 onwards, narrowing checks are performed on the contents of // braced-init-lists, even when they occur within unevaluated operands. // Therefore we still need to instantiate constexpr functions used in such // a context. if (ShouldEnter && Actions.isUnevaluatedContext() && Actions.getLangOpts().CPlusPlus11) { Actions.PushExpressionEvaluationContext( Sema::ExpressionEvaluationContext::UnevaluatedList); Entered = true; } } ~EnterExpressionEvaluationContext() { if (Entered) Actions.PopExpressionEvaluationContext(); } }; DeductionFailureInfo MakeDeductionFailureInfo(ASTContext &Context, Sema::TemplateDeductionResult TDK, sema::TemplateDeductionInfo &Info); /// Contains a late templated function. /// Will be parsed at the end of the translation unit, used by Sema & Parser. struct LateParsedTemplate { CachedTokens Toks; /// The template function declaration to be late parsed. Decl *D; }; template <> void Sema::PragmaStack<Sema::AlignPackInfo>::Act(SourceLocation PragmaLocation, PragmaMsStackAction Action, llvm::StringRef StackSlotLabel, AlignPackInfo Value); } // end namespace clang namespace llvm { // Hash a FunctionDeclAndLoc by looking at both its FunctionDecl and its // SourceLocation. template <> struct DenseMapInfo<clang::Sema::FunctionDeclAndLoc> { using FunctionDeclAndLoc = clang::Sema::FunctionDeclAndLoc; using FDBaseInfo = DenseMapInfo<clang::CanonicalDeclPtr<clang::FunctionDecl>>; static FunctionDeclAndLoc getEmptyKey() { return {FDBaseInfo::getEmptyKey(), clang::SourceLocation()}; } static FunctionDeclAndLoc getTombstoneKey() { return {FDBaseInfo::getTombstoneKey(), clang::SourceLocation()}; } static unsigned getHashValue(const FunctionDeclAndLoc &FDL) { return hash_combine(FDBaseInfo::getHashValue(FDL.FD), FDL.Loc.getHashValue()); } static bool isEqual(const FunctionDeclAndLoc &LHS, const FunctionDeclAndLoc &RHS) { return LHS.FD == RHS.FD && LHS.Loc == RHS.Loc; } }; } // namespace llvm #endif
3d25pt.c	/* * Order-2, 3D 25 point stencil * Adapted from PLUTO and Pochoir test bench * * Tareq Malas / #include <stdio.h> #include <stdlib.h> #include <sys/time.h> #ifdef LIKWID_PERFMON #include <likwid.h> #endif #include "print_utils.h" #define TESTS 2 #define MAX(a,b) ((a) > (b) ? a : b) #define MIN(a,b) ((a) < (b) ? a : b) #ifndef min #define min(x,y) ((x) < (y)? (x) : (y)) #endif / Subtract the `struct timeval' values X and Y, * storing the result in RESULT. * * Return 1 if the difference is negative, otherwise 0. / int timeval_subtract(struct timeval result, struct timeval x, struct timeval y) { /* Perform the carry for the later subtraction by updating y. / if (x->tv_usec < y->tv_usec) { int nsec = (y->tv_usec - x->tv_usec) / 1000000 + 1; y->tv_usec -= 1000000 nsec; y->tv_sec += nsec; } if (x->tv_usec - y->tv_usec > 1000000) { int nsec = (x->tv_usec - y->tv_usec) / 1000000; y->tv_usec += 1000000 * nsec; y->tv_sec -= nsec; } /* Compute the time remaining to wait. * tv_usec is certainly positive. / result->tv_sec = x->tv_sec - y->tv_sec; result->tv_usec = x->tv_usec - y->tv_usec; / Return 1 if result is negative. / return x->tv_sec < y->tv_sec; } int main(int argc, char argv[]) { int t, i, j, k, test; int Nx, Ny, Nz, Nt; if (argc > 3) { Nx = atoi(argv[1])+8; Ny = atoi(argv[2])+8; Nz = atoi(argv[3])+8; } if (argc > 4) Nt = atoi(argv[4]); double **A = (double ) malloc(sizeof(double)2); double *roc2 = (double ) malloc(sizeof(double)); A[0] = (double ) malloc(sizeof(double)Nz); A[1] = (double ) malloc(sizeof(double)Nz); roc2 = (double ) malloc(sizeof(double)Nz); for(i=0; i<Nz; i++){ A[0][i] = (double) malloc(sizeof(double)Ny); A[1][i] = (double) malloc(sizeof(double)Ny); roc2[i] = (double) malloc(sizeof(double)Ny); for(j=0;j<Ny;j++){ A[0][i][j] = (double) malloc(sizeof(double)Nx); A[1][i][j] = (double) malloc(sizeof(double)Nx); roc2[i][j] = (double) malloc(sizeof(double)Nx); } } // tile size information, including extra element to decide the list length int tile_size = (int) malloc(sizeof(int)); tile_size[0] = -1; // The list is modified here before source-to-source transformations tile_size = (int) realloc((void )tile_size, sizeof(int)5); tile_size[0] = 4; tile_size[1] = 4; tile_size[2] = 4; tile_size[3] = 256; tile_size[4] = -1; // for timekeeping int ts_return = -1; struct timeval start, end, result; double tdiff = 0.0, min_tdiff=1.e100; const int BASE = 1024; // initialize variables // srand(42); for (i = 1; i < Nz; i++) { for (j = 1; j < Ny; j++) { for (k = 1; k < Nx; k++) { A[0][i][j][k] = 1.0 * (rand() % BASE); roc2[i][j][k] = 2.0 * (rand() % BASE); } } } #ifdef LIKWID_PERFMON LIKWID_MARKER_INIT; #pragma omp parallel { LIKWID_MARKER_THREADINIT; #pragma omp barrier LIKWID_MARKER_START("calc"); } #endif int num_threads = 1; #if defined(_OPENMP) num_threads = omp_get_max_threads(); #endif const double coef0 = -0.28472; const double coef1 = 0.16000; const double coef2 = -0.02000; const double coef3 = 0.00254; const double coef4 = -0.00018; for(test=0; test<TESTS; test++){ gettimeofday(&start, 0); // serial execution - Addition: 6 && Multiplication: 2 #pragma scop for (t = 0; t < Nt; t++) { for (i = 4; i < Nz-4; i++) { for (j = 4; j < Ny-4; j++) { for (k = 4; k < Nx-4; k++) { A[(t+1)%2][i][j][k] = 2.0A[t%2][i][j][k] - A[(t+1)%2][i][j][k] + roc2[i][j][k]( coef0* A[t%2][i ][j ][k ] + coef1(A[t%2][i-1][j ][k ] + A[t%2][i+1][j ][k ] + A[t%2][i ][j-1][k ] + A[t%2][i ][j+1][k ] + A[t%2][i ][j ][k-1] + A[t%2][i ][j ][k+1]) + coef2(A[t%2][i-2][j ][k ] + A[t%2][i+2][j ][k ] + A[t%2][i ][j-2][k ] + A[t%2][i ][j+2][k ] + A[t%2][i ][j ][k-2] + A[t%2][i ][j ][k+2]) + coef3(A[t%2][i-3][j ][k ] + A[t%2][i+3][j ][k ] + A[t%2][i ][j-3][k ] + A[t%2][i ][j+3][k ] + A[t%2][i ][j ][k-3] + A[t%2][i ][j ][k+3]) + coef4(A[t%2][i-4][j ][k ] + A[t%2][i+4][j ][k ] + A[t%2][i ][j-4][k ] + A[t%2][i ][j+4][k ] + A[t%2][i ][j ][k-4] + A[t%2][i ][j ][k+4]) ); } } } } #pragma endscop gettimeofday(&end, 0); ts_return = timeval_subtract(&result, &end, &start); tdiff = (double) (result.tv_sec + result.tv_usec * 1.0e-6); min_tdiff = MIN(min_tdiff, tdiff); printf("Rank 0 TEST# %d time: %f\n", test, tdiff); } PRINT_RESULTS(4, "constant") #ifdef LIKWID_PERFMON #pragma omp parallel { LIKWID_MARKER_STOP("calc"); } LIKWID_MARKER_CLOSE; #endif // Free allocated arrays for(i=0; i<Nz; i++){ for(j=0;j<Ny;j++){ free(A[0][i][j]); free(A[1][i][j]); free(roc2[i][j]); } free(A[0][i]); free(A[1][i]); free(roc2[i]); } free(A[0]); free(A[1]); free(roc2); return 0; }
wave_billiard.c	/********************************************************************************/ / / / Animation of wave equation in a planar domain / / / / N. Berglund, december 2012, may 2021 / / / / UPDATE 24/04: distinction between damping and "elasticity" parameters / / UPDATE 27/04: new billiard shapes, bug in color scheme fixed / / UPDATE 28/04: code made more efficient, with help of Marco Mancini / / / / Feel free to reuse, but if doing so it would be nice to drop a / / line to nils.berglund@univ-orleans.fr - Thanks! / / / / compile with / / gcc -o wave_billiard wave_billiard.c / / -L/usr/X11R6/lib -ltiff -lm -lGL -lGLU -lX11 -lXmu -lglut -O3 -fopenmp / / / / OMP acceleration may be more effective after executing / / export OMP_NUM_THREADS=2 in the shell before running the program / / / / To make a video, set MOVIE to 1 and create subfolder tif_wave / / It may be possible to increase parameter PAUSE / / / / create movie using / / ffmpeg -i wave.%05d.tif -vcodec libx264 wave.mp4 / / / /******************************************************************************/ /******************************************************************************/ / / / NB: The algorithm used to simulate the wave equation is highly paralellizable / / One could make it much faster by using a GPU / / / /*******************************************************************************/ #include <math.h> #include <string.h> #include <GL/glut.h> #include <GL/glu.h> #include <unistd.h> #include <sys/types.h> #include <tiffio.h> / Sam Leffler's libtiff library. / #include <omp.h> #define MOVIE 0 / set to 1 to generate movie / #define DOUBLE_MOVIE 0 / set to 1 to produce movies for wave height and energy simultaneously / / General geometrical parameters / #define WINWIDTH 1280 / window width / #define WINHEIGHT 720 / window height / #define NX 1280 / number of grid points on x axis / #define NY 720 / number of grid points on y axis / #define XMIN -2.0 #define XMAX 2.0 / x interval / #define YMIN -1.125 #define YMAX 1.125 / y interval for 9/16 aspect ratio / #define JULIA_SCALE 1.0 / scaling for Julia sets / / Choice of the billiard table / #define B_DOMAIN 38 / choice of domain shape, see list in global_pdes.c / #define CIRCLE_PATTERN 2 / pattern of circles or polygons, see list in global_pdes.c / #define P_PERCOL 0.25 / probability of having a circle in C_RAND_PERCOL arrangement / #define NPOISSON 300 / number of points for Poisson C_RAND_POISSON arrangement / #define RANDOM_POLY_ANGLE 1 / set to 1 to randomize angle of polygons / #define LAMBDA 0.9 / parameter controlling the dimensions of domain / #define MU 0.03 / parameter controlling the dimensions of domain / #define NPOLY 6 / number of sides of polygon / #define APOLY 2.0 / angle by which to turn polygon, in units of Pi/2 / #define MDEPTH 5 / depth of computation of Menger gasket / #define MRATIO 3 / ratio defining Menger gasket / #define MANDELLEVEL 1000 / iteration level for Mandelbrot set / #define MANDELLIMIT 10.0 / limit value for approximation of Mandelbrot set / #define FOCI 1 / set to 1 to draw focal points of ellipse / #define NGRIDX 10 / number of grid point for grid of disks / #define NGRIDY 12 / number of grid point for grid of disks / // #define NGRIDX 16 / number of grid point for grid of disks / // #define NGRIDY 20 / number of grid point for grid of disks / #define X_SHOOTER -0.2 #define Y_SHOOTER -0.6 #define X_TARGET 0.4 #define Y_TARGET 0.7 / shooter and target positions in laser fight / #define ISO_XSHIFT_LEFT -2.9 #define ISO_XSHIFT_RIGHT 1.4 #define ISO_YSHIFT_LEFT -0.15 #define ISO_YSHIFT_RIGHT -0.15 #define ISO_SCALE 0.5 / coordinates for isospectral billiards / / You can add more billiard tables by adapting the functions / / xy_in_billiard and draw_billiard below / / Physical parameters of wave equation / #define TWOSPEEDS 0 / set to 1 to replace hardcore boundary by medium with different speed / #define OSCILLATE_LEFT 0 / set to 1 to add oscilating boundary condition on the left / #define OSCILLATE_TOPBOT 0 / set to 1 to enforce a planar wave on top and bottom boundary / #define OMEGA 0.002 / frequency of periodic excitation / #define AMPLITUDE 1.0 / amplitude of periodic excitation / #define COURANT 0.02 / Courant number / #define COURANTB 0.01 / Courant number in medium B / #define GAMMA 0.0 / damping factor in wave equation / // #define GAMMAB 5.0e-3 / damping factor in wave equation / // #define GAMMAB 1.0e-2 / damping factor in wave equation / #define GAMMAB 1.0e-6 / damping factor in wave equation / #define GAMMA_SIDES 1.0e-4 / damping factor on boundary / #define GAMMA_TOPBOT 1.0e-7 / damping factor on boundary / #define KAPPA 0.0 / "elasticity" term enforcing oscillations / #define KAPPA_SIDES 5.0e-4 / "elasticity" term on absorbing boundary / #define KAPPA_TOPBOT 0.0 / "elasticity" term on absorbing boundary / / The Courant number is given by cDT/DX, where DT is the time step and DX the lattice spacing / /* The physical damping coefficient is given by GAMMA/(DT)^2 / / Increasing COURANT speeds up the simulation, but decreases accuracy / / For similar wave forms, COURANT^2GAMMA should be kept constant / /* Boundary conditions, see list in global_pdes.c / #define B_COND 3 / Parameters for length and speed of simulation / // #define NSTEPS 500 / number of frames of movie / #define NSTEPS 1500 / number of frames of movie / #define NVID 40 / number of iterations between images displayed on screen / #define NSEG 100 / number of segments of boundary / #define INITIAL_TIME 0 / time after which to start saving frames / #define BOUNDARY_WIDTH 2 / width of billiard boundary / #define PAUSE 1000 / number of frames after which to pause / #define PSLEEP 1 / sleep time during pause / #define SLEEP1 1 / initial sleeping time / #define SLEEP2 1 / final sleeping time / #define MID_FRAMES 20 / number of still frames between parts of two-part movie / #define END_FRAMES 50 / number of still frames at end of movie / / Parameters of initial condition / #define INITIAL_AMP 0.75 / amplitude of initial condition / // #define INITIAL_VARIANCE 0.0003 / variance of initial condition / // #define INITIAL_WAVELENGTH 0.015 / wavelength of initial condition / #define INITIAL_VARIANCE 0.0003 / variance of initial condition / #define INITIAL_WAVELENGTH 0.015 / wavelength of initial condition / / Plot type, see list in global_pdes.c / #define PLOT 1 #define PLOT_B 0 / plot type for second movie / / Color schemes / #define COLOR_PALETTE 14 / Color palette, see list in global_pdes.c / #define BLACK 1 / background / #define COLOR_SCHEME 3 / choice of color scheme, see list in global_pdes.c / #define SCALE 0 / set to 1 to adjust color scheme to variance of field / // #define SLOPE 0.25 / sensitivity of color on wave amplitude / #define SLOPE 1.0 / sensitivity of color on wave amplitude / #define ATTENUATION 0.0 / exponential attenuation coefficient of contrast with time / // #define E_SCALE 150.0 / scaling factor for energy representation / #define E_SCALE 100.0 / scaling factor for energy representation / #define COLORHUE 260 / initial hue of water color for scheme C_LUM / #define COLORDRIFT 0.0 / how much the color hue drifts during the whole simulation / #define LUMMEAN 0.5 / amplitude of luminosity variation for scheme C_LUM / #define LUMAMP 0.3 / amplitude of luminosity variation for scheme C_LUM / #define HUEMEAN 180.0 / mean value of hue for color scheme C_HUE / // #define HUEMEAN 210.0 / mean value of hue for color scheme C_HUE / #define HUEAMP -180.0 / amplitude of variation of hue for color scheme C_HUE / // #define HUEAMP -180.0 / amplitude of variation of hue for color scheme C_HUE / #define DRAW_COLOR_SCHEME 1 / set to 1 to plot the color scheme / #define COLORBAR_RANGE 2.0 / scale of color scheme bar / #define COLORBAR_RANGE_B 12.0 / scale of color scheme bar for 2nd part / #define ROTATE_COLOR_SCHEME 1 / set to 1 to draw color scheme horizontally / #define SAVE_TIME_SERIES 0 / set to 1 to save wave time series at a point / / For debugging purposes only / #define FLOOR 0 / set to 1 to limit wave amplitude to VMAX / #define VMAX 10.0 / max value of wave amplitude / #include "global_pdes.c" / constants and global variables / #include "sub_wave.c" / common functions for wave_billiard, heat and schrodinger / #include "wave_common.c" / common functions for wave_billiard, wave_comparison, etc / FILE time_series_left, time_series_right; double courant2, courantb2; / Courant parameters squared / /*******************/ / animation part / /*******************/ void evolve_wave_half_old(double phi_in[NX], double psi_in[NX], double phi_out[NX], double psi_out[NX], short int xy_in[NX]) /* time step of field evolution / / phi is value of field at time t, psi at time t-1 / { int i, j, iplus, iminus, jplus, jminus; double delta, x, y, c, cc, gamma; static long time = 0; time++; // c = COURANT; // cc = courant2; #pragma omp parallel for private(i,j,iplus,iminus,jplus,jminus,delta,x,y,c,cc,gamma) for (i=0; i<NX; i++){ for (j=0; j<NY; j++){ // if (xy_in[i][j]) // { // c = COURANT; // cc = courant2; // gamma = GAMMA; // } if (xy_in[i][j] != 0) { c = COURANT; cc = courant2; if (xy_in[i][j] == 1) gamma = GAMMA; else gamma = GAMMAB; } else if (TWOSPEEDS) { c = COURANTB; cc = courantb2; gamma = GAMMAB; } if ((TWOSPEEDS)\|\|(xy_in[i][j] != 0)){ / discretized Laplacian for various boundary conditions / if ((B_COND == BC_DIRICHLET)\|\|(B_COND == BC_ABSORBING)) { iplus = (i+1); if (iplus == NX) iplus = NX-1; iminus = (i-1); if (iminus == -1) iminus = 0; jplus = (j+1); if (jplus == NY) jplus = NY-1; jminus = (j-1); if (jminus == -1) jminus = 0; } else if (B_COND == BC_PERIODIC) { iplus = (i+1) % NX; iminus = (i-1) % NX; if (iminus < 0) iminus += NX; jplus = (j+1) % NY; jminus = (j-1) % NY; if (jminus < 0) jminus += NY; } else if (B_COND == BC_VPER_HABS) { iplus = (i+1); if (iplus == NX) iplus = NX-1; iminus = (i-1); if (iminus == -1) iminus = 0; jplus = (j+1) % NY; jminus = (j-1) % NY; if (jminus < 0) jminus += NY; } / imposing linear wave on top and bottom by making Laplacian 1d / if (OSCILLATE_TOPBOT) { if (j == NY-1) jminus = NY-1; else if (j == 0) jplus = 0; } delta = phi_in[iplus][j] + phi_in[iminus][j] + phi_in[i][jplus] + phi_in[i][jminus] - 4.0phi_in[i][j]; x = phi_in[i][j]; y = psi_in[i][j]; /* evolve phi / if ((B_COND == BC_PERIODIC)\|\|(B_COND == BC_DIRICHLET)) phi_out[i][j] = -y + 2x + ccdelta - KAPPAx - gamma(x-y); else if (B_COND == BC_ABSORBING) { if ((i>0)&&(i<NX-1)&&(j>0)&&(j<NY-1)) phi_out[i][j] = -y + 2x + ccdelta - KAPPAx - gamma(x-y); / upper border / else if (j==NY-1) phi_out[i][j] = x - c(x - phi_in[i][NY-2]) - KAPPA_TOPBOTx - GAMMA_TOPBOT(x-y); /* lower border / else if (j==0) phi_out[i][j] = x - c(x - phi_in[i][1]) - KAPPA_TOPBOTx - GAMMA_TOPBOT(x-y); /* right border / if (i==NX-1) phi_out[i][j] = x - c(x - phi_in[NX-2][j]) - KAPPA_SIDESx - GAMMA_SIDES(x-y); /* left border / else if (i==0) phi_out[i][j] = x - c(x - phi_in[1][j]) - KAPPA_SIDESx - GAMMA_SIDES(x-y); } else if (B_COND == BC_VPER_HABS) { if ((i>0)&&(i<NX-1)) phi_out[i][j] = -y + 2x + ccdelta - KAPPAx - gamma(x-y); /* right border / else if (i==NX-1) phi_out[i][j] = x - c(x - phi_in[NX-2][j]) - KAPPA_SIDESx - GAMMA_SIDES(x-y); /* left border / else if (i==0) phi_out[i][j] = x - c(x - phi_in[1][j]) - KAPPA_SIDESx - GAMMA_SIDES(x-y); } psi_out[i][j] = x; /* add oscillating boundary condition on the left / if ((i == 0)&&(OSCILLATE_LEFT)) phi_out[i][j] = AMPLITUDEcos((double)timeOMEGA); // psi_out[i][j] = x; if (FLOOR) { if (phi_out[i][j] > VMAX) phi_out[i][j] = VMAX; if (phi_out[i][j] < -VMAX) phi_out[i][j] = -VMAX; if (psi_out[i][j] > VMAX) psi_out[i][j] = VMAX; if (psi_out[i][j] < -VMAX) psi_out[i][j] = -VMAX; } } } } // printf("phi(0,0) = %.3lg, psi(0,0) = %.3lg\n", phi[NX/2][NY/2], psi[NX/2][NY/2]); } void evolve_wave_half(double phi_in[NX], double psi_in[NX], double phi_out[NX], double psi_out[NX], short int xy_in[NX]) /* time step of field evolution / / phi is value of field at time t, psi at time t-1 / / this version of the function has been rewritten in order to minimize the number of if-branches / { int i, j, iplus, iminus, jplus, jminus; double delta, x, y, c, cc, gamma; static long time = 0; static double tc[NX][NY], tcc[NX][NY], tgamma[NX][NY]; static short int first = 1; time++; / initialize tables with wave speeds and dissipation / if (first) { for (i=0; i<NX; i++){ for (j=0; j<NY; j++){ if (xy_in[i][j] != 0) { tc[i][j] = COURANT; tcc[i][j] = courant2; if (xy_in[i][j] == 1) tgamma[i][j] = GAMMA; else tgamma[i][j] = GAMMAB; } else if (TWOSPEEDS) { tc[i][j] = COURANTB; tcc[i][j] = courantb2; tgamma[i][j] = GAMMAB; } } } first = 0; } #pragma omp parallel for private(i,j,iplus,iminus,jplus,jminus,delta,x,y) / evolution in the bulk / for (i=1; i<NX-1; i++){ for (j=1; j<NY-1; j++){ if ((TWOSPEEDS)\|\|(xy_in[i][j] != 0)){ x = phi_in[i][j]; y = psi_in[i][j]; / discretized Laplacian / delta = phi_in[i+1][j] + phi_in[i-1][j] + phi_in[i][j+1] + phi_in[i][j-1] - 4.0x; /* evolve phi / phi_out[i][j] = -y + 2x + tcc[i][j]delta - KAPPAx - tgamma[i][j](x-y); psi_out[i][j] = x; } } } / left boundary / if (OSCILLATE_LEFT) for (j=1; j<NY-1; j++) phi_out[0][j] = AMPLITUDEcos((double)timeOMEGA); else for (j=1; j<NY-1; j++){ if ((TWOSPEEDS)\|\|(xy_in[0][j] != 0)){ x = phi_in[0][j]; y = psi_in[0][j]; switch (B_COND) { case (BC_DIRICHLET): { delta = phi_in[1][j] + phi_in[0][j+1] + phi_in[0][j-1] - 3.0x; phi_out[0][j] = -y + 2x + tcc[0][j]delta - KAPPAx - tgamma[0][j](x-y); break; } case (BC_PERIODIC): { delta = phi_in[1][j] + phi_in[NX-1][j] + phi_in[0][j+1] + phi_in[0][j-1] - 4.0x; phi_out[0][j] = -y + 2x + tcc[0][j]delta - KAPPAx - tgamma[0][j](x-y); break; } case (BC_ABSORBING): { delta = phi_in[1][j] + phi_in[0][j+1] + phi_in[0][j-1] - 3.0x; phi_out[0][j] = x - tc[0][j](x - phi_in[1][j]) - KAPPA_SIDESx - GAMMA_SIDES(x-y); break; } case (BC_VPER_HABS): { delta = phi_in[1][j] + phi_in[0][j+1] + phi_in[0][j-1] - 3.0x; phi_out[0][j] = x - tc[0][j](x - phi_in[1][j]) - KAPPA_SIDESx - GAMMA_SIDES(x-y); break; } } psi_out[0][j] = x; } } / right boundary / for (j=1; j<NY-1; j++){ if ((TWOSPEEDS)\|\|(xy_in[NX-1][j] != 0)){ x = phi_in[NX-1][j]; y = psi_in[NX-1][j]; switch (B_COND) { case (BC_DIRICHLET): { delta = phi_in[NX-2][j] + phi_in[NX-1][j+1] + phi_in[NX-1][j-1] - 3.0x; phi_out[NX-1][j] = -y + 2x + tcc[NX-1][j]delta - KAPPAx - tgamma[NX-1][j](x-y); break; } case (BC_PERIODIC): { delta = phi_in[NX-2][j] + phi_in[0][j] + phi_in[NX-1][j+1] + phi_in[NX-1][j-1] - 4.0x; phi_out[NX-1][j] = -y + 2x + tcc[NX-1][j]delta - KAPPAx - tgamma[NX-1][j](x-y); break; } case (BC_ABSORBING): { delta = phi_in[NX-2][j] + phi_in[NX-1][j+1] + phi_in[NX-1][j-1] - 3.0x; phi_out[NX-1][j] = x - tc[NX-1][j](x - phi_in[NX-2][j]) - KAPPA_SIDESx - GAMMA_SIDES(x-y); break; } case (BC_VPER_HABS): { delta = phi_in[NX-2][j] + phi_in[NX-1][j+1] + phi_in[NX-1][j-1] - 3.0x; phi_out[NX-1][j] = x - tc[NX-1][j](x - phi_in[NX-2][j]) - KAPPA_SIDESx - GAMMA_SIDES(x-y); break; } } psi_out[NX-1][j] = x; } } / top boundary / for (i=0; i<NX; i++){ if ((TWOSPEEDS)\|\|(xy_in[i][NY-1] != 0)){ x = phi_in[i][NY-1]; y = psi_in[i][NY-1]; switch (B_COND) { case (BC_DIRICHLET): { iplus = i+1; if (iplus == NX) iplus = NX-1; iminus = i-1; if (iminus == -1) iminus = 0; delta = phi_in[iplus][NY-1] + phi_in[iminus][NY-1] + phi_in[i][NY-2] - 3.0x; phi_out[i][NY-1] = -y + 2x + tcc[i][NY-1]delta - KAPPAx - tgamma[i][NY-1](x-y); break; } case (BC_PERIODIC): { iplus = (i+1) % NX; iminus = (i-1) % NX; if (iminus < 0) iminus += NX; delta = phi_in[iplus][NY-1] + phi_in[iminus][NY-1] + phi_in[i][NY-2] + phi_in[i][0] - 4.0x; phi_out[i][NY-1] = -y + 2x + tcc[i][NY-1]delta - KAPPAx - tgamma[i][NY-1](x-y); break; } case (BC_ABSORBING): { iplus = (i+1); if (iplus == NX) iplus = NX-1; iminus = (i-1); if (iminus == -1) iminus = 0; delta = phi_in[iplus][NY-1] + phi_in[iminus][NY-1] + phi_in[i][NY-2] - 3.0x; phi_out[i][NY-1] = x - tc[i][NY-1](x - phi_in[i][NY-2]) - KAPPA_TOPBOTx - GAMMA_TOPBOT(x-y); break; } case (BC_VPER_HABS): { iplus = (i+1); if (iplus == NX) iplus = NX-1; iminus = (i-1); if (iminus == -1) iminus = 0; delta = phi_in[iplus][NY-1] + phi_in[iminus][NY-1] + phi_in[i][NY-2] + phi_in[i][0] - 4.0x; if (i==0) phi_out[0][NY-1] = x - tc[0][NY-1](x - phi_in[1][NY-1]) - KAPPA_SIDESx - GAMMA_SIDES(x-y); else phi_out[i][NY-1] = -y + 2x + tcc[i][NY-1]delta - KAPPAx - tgamma[i][NY-1](x-y); break; } } psi_out[i][NY-1] = x; } } / bottom boundary / for (i=0; i<NX; i++){ if ((TWOSPEEDS)\|\|(xy_in[i][0] != 0)){ x = phi_in[i][0]; y = psi_in[i][0]; switch (B_COND) { case (BC_DIRICHLET): { iplus = i+1; if (iplus == NX) iplus = NX-1; iminus = i-1; if (iminus == -1) iminus = 0; delta = phi_in[iplus][0] + phi_in[iminus][0] + phi_in[i][1] - 3.0x; phi_out[i][0] = -y + 2x + tcc[i][0]delta - KAPPAx - tgamma[i][0](x-y); break; } case (BC_PERIODIC): { iplus = (i+1) % NX; iminus = (i-1) % NX; if (iminus < 0) iminus += NX; delta = phi_in[iplus][0] + phi_in[iminus][0] + phi_in[i][1] + phi_in[i][NY-1] - 4.0x; phi_out[i][0] = -y + 2x + tcc[i][0]delta - KAPPAx - tgamma[i][0](x-y); break; } case (BC_ABSORBING): { iplus = (i+1); if (iplus == NX) iplus = NX-1; iminus = (i-1); if (iminus == -1) iminus = 0; delta = phi_in[iplus][0] + phi_in[iminus][0] + phi_in[i][1] - 3.0x; phi_out[i][0] = x - tc[i][0](x - phi_in[i][1]) - KAPPA_TOPBOTx - GAMMA_TOPBOT(x-y); break; } case (BC_VPER_HABS): { iplus = (i+1); if (iplus == NX) iplus = NX-1; iminus = (i-1); if (iminus == -1) iminus = 0; delta = phi_in[iplus][0] + phi_in[iminus][0] + phi_in[i][1] + phi_in[i][NY-1] - 4.0x; if (i==0) phi_out[0][0] = x - tc[0][0](x - phi_in[1][0]) - KAPPA_SIDESx - GAMMA_SIDES(x-y); else phi_out[i][0] = -y + 2x + tcc[i][0]delta - KAPPAx - tgamma[i][0](x-y); break; } } psi_out[i][0] = x; } } / add oscillating boundary condition on the left corners / if (OSCILLATE_LEFT) { phi_out[0][0] = AMPLITUDEcos((double)timeOMEGA); phi_out[0][NY-1] = AMPLITUDEcos((double)timeOMEGA); } / for debugging purposes/if there is a risk of blow-up / if (FLOOR) for (i=0; i<NX; i++){ for (j=0; j<NY; j++){ if (xy_in[i][j] != 0) { if (phi_out[i][j] > VMAX) phi_out[i][j] = VMAX; if (phi_out[i][j] < -VMAX) phi_out[i][j] = -VMAX; if (psi_out[i][j] > VMAX) psi_out[i][j] = VMAX; if (psi_out[i][j] < -VMAX) psi_out[i][j] = -VMAX; } } } } void evolve_wave(double phi[NX], double psi[NX], double phi_tmp[NX], double psi_tmp[NX], short int xy_in[NX]) /* time step of field evolution / / phi is value of field at time t, psi at time t-1 / { evolve_wave_half(phi, psi, phi_tmp, psi_tmp, xy_in); evolve_wave_half(phi_tmp, psi_tmp, phi, psi, xy_in); // evolve_wave_half_old(phi, psi, phi_tmp, psi_tmp, xy_in); // evolve_wave_half_old(phi_tmp, psi_tmp, phi, psi, xy_in); } void draw_color_bar(int plot, double range) { if (ROTATE_COLOR_SCHEME) draw_color_scheme(-1.0, -0.8, XMAX - 0.1, -1.0, plot, -range, range); else draw_color_scheme(1.7, YMIN + 0.1, 1.9, YMAX - 0.1, plot, -range, range); } void animation() { double time, scale, ratio, startleft[2], startright[2]; double phi[NX], psi[NX], phi_tmp[NX], psi_tmp[NX], total_energy[NX]; short int xy_in[NX]; int i, j, s, sample_left[2], sample_right[2]; static int counter = 0; long int wave_value; if (SAVE_TIME_SERIES) { time_series_left = fopen("wave_left.dat", "w"); time_series_right = fopen("wave_right.dat", "w"); } / Since NX and NY are big, it seemed wiser to use some memory allocation here / for (i=0; i<NX; i++) { phi[i] = (double )malloc(NYsizeof(double)); psi[i] = (double )malloc(NYsizeof(double)); phi_tmp[i] = (double )malloc(NYsizeof(double)); psi_tmp[i] = (double )malloc(NYsizeof(double)); total_energy[i] = (double )malloc(NYsizeof(double)); xy_in[i] = (short int )malloc(NYsizeof(short int)); } / initialise positions and radii of circles / if ((B_DOMAIN == D_CIRCLES)\|\|(B_DOMAIN == D_CIRCLES_IN_RECT)) init_circle_config(circles); else if (B_DOMAIN == D_POLYGONS) init_polygon_config(polygons); printf("Polygons initialized\n"); / initialise polyline for von Koch and simular domains / npolyline = init_polyline(MDEPTH, polyline); for (i=0; i<npolyline; i++) printf("vertex %i: (%.3f, %.3f)\n", i, polyline[i].x, polyline[i].y); courant2 = COURANTCOURANT; courantb2 = COURANTBCOURANTB; / initialize wave with a drop at one point, zero elsewhere / // init_circular_wave(0.0, -LAMBDA, phi, psi, xy_in); / initialize total energy table / if ((PLOT == P_MEAN_ENERGY)\|\|(PLOT_B == P_MEAN_ENERGY)) for (i=0; i<NX; i++) for (j=0; j<NY; j++) total_energy[i][j] = 0.0; ratio = (XMAX - XMIN)/8.4; / for Tokarsky billiard / // isospectral_initial_point(0.2, 0.0, startleft, startright); / for isospectral billiards / homophonic_initial_point(0.5, -0.25, 1.5, -0.25, startleft, startright); // homophonic_initial_point(0.5, -0.25, 1.5, -0.25, startleft, startright); // printf("xleft = (%.3f, %.3f) xright = (%.3f, %.3f)\n", startleft[0], startleft[1], startright[0], startright[1]); xy_to_ij(startleft[0], startleft[1], sample_left); xy_to_ij(startright[0], startright[1], sample_right); // printf("xleft = (%.3f, %.3f) xright = (%.3f, %.3f)\n", xin_left, yin_left, xin_right, yin_right); // init_wave_flat(phi, psi, xy_in); // init_wave_plus(LAMBDA - 0.3MU, 0.5MU, phi, psi, xy_in); // init_wave(LAMBDA - 0.3MU, 0.5MU, phi, psi, xy_in); // init_circular_wave(X_SHOOTER, Y_SHOOTER, phi, psi, xy_in); // printf("Initializing wave\n"); // init_circular_wave(-1.0, 0.0, phi, psi, xy_in); // printf("Wave initialized\n"); // init_circular_wave(0.0, 0.0, phi, psi, xy_in); // add_circular_wave(-1.0, 0.0, LAMBDA, phi, psi, xy_in); // add_circular_wave(1.0, -LAMBDA, 0.0, phi, psi, xy_in); // add_circular_wave(-1.0, 0.0, -LAMBDA, phi, psi, xy_in); init_circular_wave_xplusminus(startleft[0], startleft[1], startright[0], startright[1], phi, psi, xy_in); // init_circular_wave_xplusminus(-0.9, 0.0, 0.81, 0.0, phi, psi, xy_in); // init_circular_wave(-2.0ratio, 0.0, phi, psi, xy_in); // init_planar_wave(XMIN + 0.015, 0.0, phi, psi, xy_in); // init_planar_wave(XMIN + 0.02, 0.0, phi, psi, xy_in); // init_planar_wave(XMIN + 0.5, 0.0, phi, psi, xy_in); // init_wave(-1.5, 0.0, phi, psi, xy_in); // init_wave(0.0, 0.0, phi, psi, xy_in); /* add a drop at another point / // add_drop_to_wave(1.0, 0.7, 0.0, phi, psi); // add_drop_to_wave(1.0, -0.7, 0.0, phi, psi); // add_drop_to_wave(1.0, 0.0, -0.7, phi, psi); blank(); glColor3f(0.0, 0.0, 0.0); // draw_wave(phi, psi, xy_in, 1.0, 0, PLOT); draw_wave_e(phi, psi, total_energy, xy_in, 1.0, 0, PLOT); draw_billiard(); if (DRAW_COLOR_SCHEME) draw_color_bar(PLOT, COLORBAR_RANGE); glutSwapBuffers(); sleep(SLEEP1); for (i=0; i<=INITIAL_TIME + NSTEPS; i++) { //printf("%d\n",i); / compute the variance of the field to adjust color scheme / / the color depends on the field divided by sqrt(1 + variance) / if (SCALE) { scale = sqrt(1.0 + compute_variance(phi,psi, xy_in)); // printf("Scaling factor: %5lg\n", scale); } else scale = 1.0; // draw_wave(phi, psi, xy_in, scale, i, PLOT); draw_wave_e(phi, psi, total_energy, xy_in, scale, i, PLOT); for (j=0; j<NVID; j++) { evolve_wave(phi, psi, phi_tmp, psi_tmp, xy_in); if (SAVE_TIME_SERIES) { wave_value = (long int)(phi[sample_left[0]][sample_left[1]]1.0e16); fprintf(time_series_left, "%019ld\n", wave_value); wave_value = (long int)(phi[sample_right[0]][sample_right[1]]1.0e16); fprintf(time_series_right, "%019ld\n", wave_value); if ((j == 0)&&(i%10 == 0)) printf("Frame %i of %i\n", i, NSTEPS); // fprintf(time_series_right, "%.15f\n", phi[sample_right[0]][sample_right[1]]); } // if (i % 10 == 9) oscillate_linear_wave(0.2scale, 0.15(double)(iNVID + j), -1.5, YMIN, -1.5, YMAX, phi, psi); } draw_billiard(); if (DRAW_COLOR_SCHEME) draw_color_bar(PLOT, COLORBAR_RANGE); /* add oscillating waves / // if (i%345 == 344) // { // add_circular_wave(1.0, -LAMBDA, 0.0, phi, psi, xy_in); // } glutSwapBuffers(); if (MOVIE) { if (i >= INITIAL_TIME) save_frame(); else printf("Initial phase time %i of %i\n", i, INITIAL_TIME); if ((i >= INITIAL_TIME)&&(DOUBLE_MOVIE)) { // draw_wave(phi, psi, xy_in, scale, i, PLOT_B); draw_wave_e(phi, psi, total_energy, xy_in, scale, i, PLOT_B); if (DRAW_COLOR_SCHEME) draw_color_bar(PLOT_B, COLORBAR_RANGE_B); draw_billiard(); glutSwapBuffers(); save_frame_counter(NSTEPS + 21 + counter); counter++; } / it seems that saving too many files too fast can cause trouble with the file system / / so this is to make a pause from time to time - parameter PAUSE may need adjusting / if (i % PAUSE == PAUSE - 1) { printf("Making a short pause\n"); sleep(PSLEEP); s = system("mv wave.tif tif_wave/"); } } } if (MOVIE) { if (DOUBLE_MOVIE) { // draw_wave(phi, psi, xy_in, scale, i, PLOT); draw_wave_e(phi, psi, total_energy, xy_in, scale, NSTEPS, PLOT); draw_billiard(); if (DRAW_COLOR_SCHEME) draw_color_bar(PLOT, COLORBAR_RANGE); glutSwapBuffers(); } for (i=0; i<MID_FRAMES; i++) save_frame(); if (DOUBLE_MOVIE) { // draw_wave(phi, psi, xy_in, scale, i, PLOT_B); draw_wave_e(phi, psi, total_energy, xy_in, scale, NSTEPS, PLOT_B); draw_billiard(); if (DRAW_COLOR_SCHEME) draw_color_bar(PLOT_B, COLORBAR_RANGE_B); glutSwapBuffers(); } for (i=0; i<END_FRAMES; i++) save_frame_counter(NSTEPS + MID_FRAMES + 1 + counter + i); s = system("mv wave.tif tif_wave/"); } for (i=0; i<NX; i++) { free(phi[i]); free(psi[i]); free(phi_tmp[i]); free(psi_tmp[i]); free(total_energy[i]); free(xy_in[i]); } if (SAVE_TIME_SERIES) { fclose(time_series_left); fclose(time_series_right); } } void display(void) { glPushMatrix(); blank(); glutSwapBuffers(); blank(); glutSwapBuffers(); animation(); sleep(SLEEP2); glPopMatrix(); glutDestroyWindow(glutGetWindow()); } int main(int argc, char* argv) { glutInit(&argc, argv); glutInitDisplayMode(GLUT_RGB \| GLUT_DOUBLE \| GLUT_DEPTH); glutInitWindowSize(WINWIDTH,WINHEIGHT); glutCreateWindow("Wave equation in a planar domain"); init(); glutDisplayFunc(display); glutMainLoop(); return 0; }
clib.c	/* Generated by Cython 0.29.25 / / BEGIN: Cython Metadata { "distutils": { "depends": [], "extra_compile_args": [ "-fopenmp" ], "extra_link_args": [ "-fopenmp" ], "include_dirs": [ "/usr/local/Caskroom/miniconda/base/envs/shakemap/lib/python3.8/site-packages/numpy/core/include" ], "libraries": [ "m", "omp" ], "name": "shakemap.c.clib", "sources": [ "shakemap/c/clib.pyx" ] }, "module_name": "shakemap.c.clib" } END: Cython Metadata / #ifndef PY_SSIZE_T_CLEAN #define PY_SSIZE_T_CLEAN #endif / PY_SSIZE_T_CLEAN / #include "Python.h" #ifndef Py_PYTHON_H #error Python headers needed to compile C extensions, please install development version of Python. #elif PY_VERSION_HEX < 0x02060000 \|\| (0x03000000 <= PY_VERSION_HEX && PY_VERSION_HEX < 0x03030000) #error Cython requires Python 2.6+ or Python 3.3+. #else #define CYTHON_ABI "0_29_25" #define CYTHON_HEX_VERSION 0x001D19F0 #define CYTHON_FUTURE_DIVISION 1 #include <stddef.h> #ifndef offsetof #define offsetof(type, member) ( (size_t) & ((type)0) -> member ) #endif #if !defined(WIN32) && !defined(MS_WINDOWS) #ifndef __stdcall #define __stdcall #endif #ifndef __cdecl #define __cdecl #endif #ifndef __fastcall #define __fastcall #endif #endif #ifndef DL_IMPORT #define DL_IMPORT(t) t #endif #ifndef DL_EXPORT #define DL_EXPORT(t) t #endif #define __PYX_COMMA , #ifndef HAVE_LONG_LONG #if PY_VERSION_HEX >= 0x02070000 #define HAVE_LONG_LONG #endif #endif #ifndef PY_LONG_LONG #define PY_LONG_LONG LONG_LONG #endif #ifndef Py_HUGE_VAL #define Py_HUGE_VAL HUGE_VAL #endif #ifdef PYPY_VERSION #define CYTHON_COMPILING_IN_PYPY 1 #define CYTHON_COMPILING_IN_PYSTON 0 #define CYTHON_COMPILING_IN_CPYTHON 0 #undef CYTHON_USE_TYPE_SLOTS #define CYTHON_USE_TYPE_SLOTS 0 #undef CYTHON_USE_PYTYPE_LOOKUP #define CYTHON_USE_PYTYPE_LOOKUP 0 #if PY_VERSION_HEX < 0x03050000 #undef CYTHON_USE_ASYNC_SLOTS #define CYTHON_USE_ASYNC_SLOTS 0 #elif !defined(CYTHON_USE_ASYNC_SLOTS) #define CYTHON_USE_ASYNC_SLOTS 1 #endif #undef CYTHON_USE_PYLIST_INTERNALS #define CYTHON_USE_PYLIST_INTERNALS 0 #undef CYTHON_USE_UNICODE_INTERNALS #define CYTHON_USE_UNICODE_INTERNALS 0 #undef CYTHON_USE_UNICODE_WRITER #define CYTHON_USE_UNICODE_WRITER 0 #undef CYTHON_USE_PYLONG_INTERNALS #define CYTHON_USE_PYLONG_INTERNALS 0 #undef CYTHON_AVOID_BORROWED_REFS #define CYTHON_AVOID_BORROWED_REFS 1 #undef CYTHON_ASSUME_SAFE_MACROS #define CYTHON_ASSUME_SAFE_MACROS 0 #undef CYTHON_UNPACK_METHODS #define CYTHON_UNPACK_METHODS 0 #undef CYTHON_FAST_THREAD_STATE #define CYTHON_FAST_THREAD_STATE 0 #undef CYTHON_FAST_PYCALL #define CYTHON_FAST_PYCALL 0 #undef CYTHON_PEP489_MULTI_PHASE_INIT #define CYTHON_PEP489_MULTI_PHASE_INIT 0 #undef CYTHON_USE_TP_FINALIZE #define CYTHON_USE_TP_FINALIZE 0 #undef CYTHON_USE_DICT_VERSIONS #define CYTHON_USE_DICT_VERSIONS 0 #undef CYTHON_USE_EXC_INFO_STACK #define CYTHON_USE_EXC_INFO_STACK 0 #elif defined(PYSTON_VERSION) #define CYTHON_COMPILING_IN_PYPY 0 #define CYTHON_COMPILING_IN_PYSTON 1 #define CYTHON_COMPILING_IN_CPYTHON 0 #ifndef CYTHON_USE_TYPE_SLOTS #define CYTHON_USE_TYPE_SLOTS 1 #endif #undef CYTHON_USE_PYTYPE_LOOKUP #define CYTHON_USE_PYTYPE_LOOKUP 0 #undef CYTHON_USE_ASYNC_SLOTS #define CYTHON_USE_ASYNC_SLOTS 0 #undef CYTHON_USE_PYLIST_INTERNALS #define CYTHON_USE_PYLIST_INTERNALS 0 #ifndef CYTHON_USE_UNICODE_INTERNALS #define CYTHON_USE_UNICODE_INTERNALS 1 #endif #undef CYTHON_USE_UNICODE_WRITER #define CYTHON_USE_UNICODE_WRITER 0 #undef CYTHON_USE_PYLONG_INTERNALS #define CYTHON_USE_PYLONG_INTERNALS 0 #ifndef CYTHON_AVOID_BORROWED_REFS #define CYTHON_AVOID_BORROWED_REFS 0 #endif #ifndef CYTHON_ASSUME_SAFE_MACROS #define CYTHON_ASSUME_SAFE_MACROS 1 #endif #ifndef CYTHON_UNPACK_METHODS #define CYTHON_UNPACK_METHODS 1 #endif #undef CYTHON_FAST_THREAD_STATE #define CYTHON_FAST_THREAD_STATE 0 #undef CYTHON_FAST_PYCALL #define CYTHON_FAST_PYCALL 0 #undef CYTHON_PEP489_MULTI_PHASE_INIT #define CYTHON_PEP489_MULTI_PHASE_INIT 0 #undef CYTHON_USE_TP_FINALIZE #define CYTHON_USE_TP_FINALIZE 0 #undef CYTHON_USE_DICT_VERSIONS #define CYTHON_USE_DICT_VERSIONS 0 #undef CYTHON_USE_EXC_INFO_STACK #define CYTHON_USE_EXC_INFO_STACK 0 #else #define CYTHON_COMPILING_IN_PYPY 0 #define CYTHON_COMPILING_IN_PYSTON 0 #define CYTHON_COMPILING_IN_CPYTHON 1 #ifndef CYTHON_USE_TYPE_SLOTS #define CYTHON_USE_TYPE_SLOTS 1 #endif #if PY_VERSION_HEX < 0x02070000 #undef CYTHON_USE_PYTYPE_LOOKUP #define CYTHON_USE_PYTYPE_LOOKUP 0 #elif !defined(CYTHON_USE_PYTYPE_LOOKUP) #define CYTHON_USE_PYTYPE_LOOKUP 1 #endif #if PY_MAJOR_VERSION < 3 #undef CYTHON_USE_ASYNC_SLOTS #define CYTHON_USE_ASYNC_SLOTS 0 #elif !defined(CYTHON_USE_ASYNC_SLOTS) #define CYTHON_USE_ASYNC_SLOTS 1 #endif #if PY_VERSION_HEX < 0x02070000 #undef CYTHON_USE_PYLONG_INTERNALS #define CYTHON_USE_PYLONG_INTERNALS 0 #elif !defined(CYTHON_USE_PYLONG_INTERNALS) #define CYTHON_USE_PYLONG_INTERNALS 1 #endif #ifndef CYTHON_USE_PYLIST_INTERNALS #define CYTHON_USE_PYLIST_INTERNALS 1 #endif #ifndef CYTHON_USE_UNICODE_INTERNALS #define CYTHON_USE_UNICODE_INTERNALS 1 #endif #if PY_VERSION_HEX < 0x030300F0 \|\| PY_VERSION_HEX >= 0x030B00A2 #undef CYTHON_USE_UNICODE_WRITER #define CYTHON_USE_UNICODE_WRITER 0 #elif !defined(CYTHON_USE_UNICODE_WRITER) #define CYTHON_USE_UNICODE_WRITER 1 #endif #ifndef CYTHON_AVOID_BORROWED_REFS #define CYTHON_AVOID_BORROWED_REFS 0 #endif #ifndef CYTHON_ASSUME_SAFE_MACROS #define CYTHON_ASSUME_SAFE_MACROS 1 #endif #ifndef CYTHON_UNPACK_METHODS #define CYTHON_UNPACK_METHODS 1 #endif #ifndef CYTHON_FAST_THREAD_STATE #define CYTHON_FAST_THREAD_STATE 1 #endif #ifndef CYTHON_FAST_PYCALL #define CYTHON_FAST_PYCALL (PY_VERSION_HEX < 0x030B00A1) #endif #ifndef CYTHON_PEP489_MULTI_PHASE_INIT #define CYTHON_PEP489_MULTI_PHASE_INIT (PY_VERSION_HEX >= 0x03050000) #endif #ifndef CYTHON_USE_TP_FINALIZE #define CYTHON_USE_TP_FINALIZE (PY_VERSION_HEX >= 0x030400a1) #endif #ifndef CYTHON_USE_DICT_VERSIONS #define CYTHON_USE_DICT_VERSIONS (PY_VERSION_HEX >= 0x030600B1) #endif #ifndef CYTHON_USE_EXC_INFO_STACK #define CYTHON_USE_EXC_INFO_STACK (PY_VERSION_HEX >= 0x030700A3) #endif #endif #if !defined(CYTHON_FAST_PYCCALL) #define CYTHON_FAST_PYCCALL (CYTHON_FAST_PYCALL && PY_VERSION_HEX >= 0x030600B1) #endif #if CYTHON_USE_PYLONG_INTERNALS #if PY_MAJOR_VERSION < 3 #include "longintrepr.h" #endif #undef SHIFT #undef BASE #undef MASK #ifdef SIZEOF_VOID_P enum { __pyx_check_sizeof_voidp = 1 / (int)(SIZEOF_VOID_P == sizeof(void)) }; #endif #endif #ifndef __has_attribute #define __has_attribute(x) 0 #endif #ifndef __has_cpp_attribute #define __has_cpp_attribute(x) 0 #endif #ifndef CYTHON_RESTRICT #if defined(__GNUC__) #define CYTHON_RESTRICT __restrict__ #elif defined(_MSC_VER) && _MSC_VER >= 1400 #define CYTHON_RESTRICT __restrict #elif defined (__STDC_VERSION__) && __STDC_VERSION__ >= 199901L #define CYTHON_RESTRICT restrict #else #define CYTHON_RESTRICT #endif #endif #ifndef CYTHON_UNUSED # if defined(__GNUC__) # if !(defined(__cplusplus)) \|\| (__GNUC__ > 3 \|\| (__GNUC__ == 3 && __GNUC_MINOR__ >= 4)) # define CYTHON_UNUSED __attribute__ ((__unused__)) # else # define CYTHON_UNUSED # endif # elif defined(__ICC) \|\| (defined(__INTEL_COMPILER) && !defined(_MSC_VER)) # define CYTHON_UNUSED __attribute__ ((__unused__)) # else # define CYTHON_UNUSED # endif #endif #ifndef CYTHON_MAYBE_UNUSED_VAR # if defined(__cplusplus) template<class T> void CYTHON_MAYBE_UNUSED_VAR( const T& ) { } # else # define CYTHON_MAYBE_UNUSED_VAR(x) (void)(x) # endif #endif #ifndef CYTHON_NCP_UNUSED # if CYTHON_COMPILING_IN_CPYTHON # define CYTHON_NCP_UNUSED # else # define CYTHON_NCP_UNUSED CYTHON_UNUSED # endif #endif #define __Pyx_void_to_None(void_result) ((void)(void_result), Py_INCREF(Py_None), Py_None) #ifdef _MSC_VER #ifndef _MSC_STDINT_H_ #if _MSC_VER < 1300 typedef unsigned char uint8_t; typedef unsigned int uint32_t; #else typedef unsigned __int8 uint8_t; typedef unsigned __int32 uint32_t; #endif #endif #else #include <stdint.h> #endif #ifndef CYTHON_FALLTHROUGH #if defined(__cplusplus) && __cplusplus >= 201103L #if __has_cpp_attribute(fallthrough) #define CYTHON_FALLTHROUGH [[fallthrough]] #elif __has_cpp_attribute(clang::fallthrough) #define CYTHON_FALLTHROUGH [[clang::fallthrough]] #elif __has_cpp_attribute(gnu::fallthrough) #define CYTHON_FALLTHROUGH [[gnu::fallthrough]] #endif #endif #ifndef CYTHON_FALLTHROUGH #if __has_attribute(fallthrough) #define CYTHON_FALLTHROUGH __attribute__((fallthrough)) #else #define CYTHON_FALLTHROUGH #endif #endif #if defined(__clang__ ) && defined(__apple_build_version__) #if __apple_build_version__ < 7000000 #undef CYTHON_FALLTHROUGH #define CYTHON_FALLTHROUGH #endif #endif #endif #ifndef CYTHON_INLINE #if defined(__clang__) #define CYTHON_INLINE __inline__ __attribute__ ((__unused__)) #elif defined(__GNUC__) #define CYTHON_INLINE __inline__ #elif defined(_MSC_VER) #define CYTHON_INLINE __inline #elif defined (__STDC_VERSION__) && __STDC_VERSION__ >= 199901L #define CYTHON_INLINE inline #else #define CYTHON_INLINE #endif #endif #if CYTHON_COMPILING_IN_PYPY && PY_VERSION_HEX < 0x02070600 && !defined(Py_OptimizeFlag) #define Py_OptimizeFlag 0 #endif #define __PYX_BUILD_PY_SSIZE_T "n" #define CYTHON_FORMAT_SSIZE_T "z" #if PY_MAJOR_VERSION < 3 #define __Pyx_BUILTIN_MODULE_NAME "__builtin__" #define __Pyx_PyCode_New(a, k, l, s, f, code, c, n, v, fv, cell, fn, name, fline, lnos)\ PyCode_New(a+k, l, s, f, code, c, n, v, fv, cell, fn, name, fline, lnos) #define __Pyx_DefaultClassType PyClass_Type #else #define __Pyx_BUILTIN_MODULE_NAME "builtins" #define __Pyx_DefaultClassType PyType_Type #if PY_VERSION_HEX >= 0x030B00A1 static CYTHON_INLINE PyCodeObject __Pyx_PyCode_New(int a, int k, int l, int s, int f, PyObject code, PyObject c, PyObject* n, PyObject v, PyObject fv, PyObject cell, PyObject fn, PyObject name, int fline, PyObject lnos) { PyObject kwds=NULL, argcount=NULL, posonlyargcount=NULL, kwonlyargcount=NULL; PyObject nlocals=NULL, stacksize=NULL, flags=NULL, replace=NULL, call_result=NULL, empty=NULL; const char fn_cstr=NULL; const char name_cstr=NULL; PyCodeObject* co=NULL; PyObject type, value, traceback; PyErr_Fetch(&type, &value, &traceback); if (!(kwds=PyDict_New())) goto end; if (!(argcount=PyLong_FromLong(a))) goto end; if (PyDict_SetItemString(kwds, "co_argcount", argcount) != 0) goto end; if (!(posonlyargcount=PyLong_FromLong(0))) goto end; if (PyDict_SetItemString(kwds, "co_posonlyargcount", posonlyargcount) != 0) goto end; if (!(kwonlyargcount=PyLong_FromLong(k))) goto end; if (PyDict_SetItemString(kwds, "co_kwonlyargcount", kwonlyargcount) != 0) goto end; if (!(nlocals=PyLong_FromLong(l))) goto end; if (PyDict_SetItemString(kwds, "co_nlocals", nlocals) != 0) goto end; if (!(stacksize=PyLong_FromLong(s))) goto end; if (PyDict_SetItemString(kwds, "co_stacksize", stacksize) != 0) goto end; if (!(flags=PyLong_FromLong(f))) goto end; if (PyDict_SetItemString(kwds, "co_flags", flags) != 0) goto end; if (PyDict_SetItemString(kwds, "co_code", code) != 0) goto end; if (PyDict_SetItemString(kwds, "co_consts", c) != 0) goto end; if (PyDict_SetItemString(kwds, "co_names", n) != 0) goto end; if (PyDict_SetItemString(kwds, "co_varnames", v) != 0) goto end; if (PyDict_SetItemString(kwds, "co_freevars", fv) != 0) goto end; if (PyDict_SetItemString(kwds, "co_cellvars", cell) != 0) goto end; if (PyDict_SetItemString(kwds, "co_linetable", lnos) != 0) goto end; if (!(fn_cstr=PyUnicode_AsUTF8AndSize(fn, NULL))) goto end; if (!(name_cstr=PyUnicode_AsUTF8AndSize(name, NULL))) goto end; if (!(co = PyCode_NewEmpty(fn_cstr, name_cstr, fline))) goto end; if (!(replace = PyObject_GetAttrString((PyObject)co, "replace"))) goto cleanup_code_too; if (!(empty = PyTuple_New(0))) goto cleanup_code_too; // unfortunately __pyx_empty_tuple isn't available here if (!(call_result = PyObject_Call(replace, empty, kwds))) goto cleanup_code_too; Py_XDECREF((PyObject)co); co = (PyCodeObject)call_result; call_result = NULL; if (0) { cleanup_code_too: Py_XDECREF((PyObject)co); co = NULL; } end: Py_XDECREF(kwds); Py_XDECREF(argcount); Py_XDECREF(posonlyargcount); Py_XDECREF(kwonlyargcount); Py_XDECREF(nlocals); Py_XDECREF(stacksize); Py_XDECREF(replace); Py_XDECREF(call_result); Py_XDECREF(empty); if (type) { PyErr_Restore(type, value, traceback); } return co; } #else #define __Pyx_PyCode_New(a, k, l, s, f, code, c, n, v, fv, cell, fn, name, fline, lnos)\ PyCode_New(a, k, l, s, f, code, c, n, v, fv, cell, fn, name, fline, lnos) #endif #define __Pyx_DefaultClassType PyType_Type #endif #ifndef Py_TPFLAGS_CHECKTYPES #define Py_TPFLAGS_CHECKTYPES 0 #endif #ifndef Py_TPFLAGS_HAVE_INDEX #define Py_TPFLAGS_HAVE_INDEX 0 #endif #ifndef Py_TPFLAGS_HAVE_NEWBUFFER #define Py_TPFLAGS_HAVE_NEWBUFFER 0 #endif #ifndef Py_TPFLAGS_HAVE_FINALIZE #define Py_TPFLAGS_HAVE_FINALIZE 0 #endif #ifndef METH_STACKLESS #define METH_STACKLESS 0 #endif #if PY_VERSION_HEX <= 0x030700A3 \|\| !defined(METH_FASTCALL) #ifndef METH_FASTCALL #define METH_FASTCALL 0x80 #endif typedef PyObject (__Pyx_PyCFunctionFast) (PyObject self, PyObject const args, Py_ssize_t nargs); typedef PyObject (__Pyx_PyCFunctionFastWithKeywords) (PyObject self, PyObject const args, Py_ssize_t nargs, PyObject kwnames); #else #define __Pyx_PyCFunctionFast _PyCFunctionFast #define __Pyx_PyCFunctionFastWithKeywords _PyCFunctionFastWithKeywords #endif #if CYTHON_FAST_PYCCALL #define __Pyx_PyFastCFunction_Check(func)\ ((PyCFunction_Check(func) && (METH_FASTCALL == (PyCFunction_GET_FLAGS(func) & ~(METH_CLASS \| METH_STATIC \| METH_COEXIST \| METH_KEYWORDS \| METH_STACKLESS))))) #else #define __Pyx_PyFastCFunction_Check(func) 0 #endif #if CYTHON_COMPILING_IN_PYPY && !defined(PyObject_Malloc) #define PyObject_Malloc(s) PyMem_Malloc(s) #define PyObject_Free(p) PyMem_Free(p) #define PyObject_Realloc(p) PyMem_Realloc(p) #endif #if CYTHON_COMPILING_IN_CPYTHON && PY_VERSION_HEX < 0x030400A1 #define PyMem_RawMalloc(n) PyMem_Malloc(n) #define PyMem_RawRealloc(p, n) PyMem_Realloc(p, n) #define PyMem_RawFree(p) PyMem_Free(p) #endif #if CYTHON_COMPILING_IN_PYSTON #define __Pyx_PyCode_HasFreeVars(co) PyCode_HasFreeVars(co) #define __Pyx_PyFrame_SetLineNumber(frame, lineno) PyFrame_SetLineNumber(frame, lineno) #else #define __Pyx_PyCode_HasFreeVars(co) (PyCode_GetNumFree(co) > 0) #define __Pyx_PyFrame_SetLineNumber(frame, lineno) (frame)->f_lineno = (lineno) #endif #if !CYTHON_FAST_THREAD_STATE \|\| PY_VERSION_HEX < 0x02070000 #define __Pyx_PyThreadState_Current PyThreadState_GET() #elif PY_VERSION_HEX >= 0x03060000 #define __Pyx_PyThreadState_Current _PyThreadState_UncheckedGet() #elif PY_VERSION_HEX >= 0x03000000 #define __Pyx_PyThreadState_Current PyThreadState_GET() #else #define __Pyx_PyThreadState_Current _PyThreadState_Current #endif #if PY_VERSION_HEX < 0x030700A2 && !defined(PyThread_tss_create) && !defined(Py_tss_NEEDS_INIT) #include "pythread.h" #define Py_tss_NEEDS_INIT 0 typedef int Py_tss_t; static CYTHON_INLINE int PyThread_tss_create(Py_tss_t key) { key = PyThread_create_key(); return 0; } static CYTHON_INLINE Py_tss_t * PyThread_tss_alloc(void) { Py_tss_t key = (Py_tss_t )PyObject_Malloc(sizeof(Py_tss_t)); key = Py_tss_NEEDS_INIT; return key; } static CYTHON_INLINE void PyThread_tss_free(Py_tss_t key) { PyObject_Free(key); } static CYTHON_INLINE int PyThread_tss_is_created(Py_tss_t key) { return key != Py_tss_NEEDS_INIT; } static CYTHON_INLINE void PyThread_tss_delete(Py_tss_t key) { PyThread_delete_key(key); key = Py_tss_NEEDS_INIT; } static CYTHON_INLINE int PyThread_tss_set(Py_tss_t key, void value) { return PyThread_set_key_value(key, value); } static CYTHON_INLINE void * PyThread_tss_get(Py_tss_t key) { return PyThread_get_key_value(key); } #endif #if CYTHON_COMPILING_IN_CPYTHON \|\| defined(_PyDict_NewPresized) #define __Pyx_PyDict_NewPresized(n) ((n <= 8) ? PyDict_New() : _PyDict_NewPresized(n)) #else #define __Pyx_PyDict_NewPresized(n) PyDict_New() #endif #if PY_MAJOR_VERSION >= 3 \|\| CYTHON_FUTURE_DIVISION #define __Pyx_PyNumber_Divide(x,y) PyNumber_TrueDivide(x,y) #define __Pyx_PyNumber_InPlaceDivide(x,y) PyNumber_InPlaceTrueDivide(x,y) #else #define __Pyx_PyNumber_Divide(x,y) PyNumber_Divide(x,y) #define __Pyx_PyNumber_InPlaceDivide(x,y) PyNumber_InPlaceDivide(x,y) #endif #if CYTHON_COMPILING_IN_CPYTHON && PY_VERSION_HEX >= 0x030500A1 && CYTHON_USE_UNICODE_INTERNALS #define __Pyx_PyDict_GetItemStr(dict, name) _PyDict_GetItem_KnownHash(dict, name, ((PyASCIIObject ) name)->hash) #else #define __Pyx_PyDict_GetItemStr(dict, name) PyDict_GetItem(dict, name) #endif #if PY_VERSION_HEX > 0x03030000 && defined(PyUnicode_KIND) #define CYTHON_PEP393_ENABLED 1 #if defined(PyUnicode_IS_READY) #define __Pyx_PyUnicode_READY(op) (likely(PyUnicode_IS_READY(op)) ?\ 0 : _PyUnicode_Ready((PyObject )(op))) #else #define __Pyx_PyUnicode_READY(op) (0) #endif #define __Pyx_PyUnicode_GET_LENGTH(u) PyUnicode_GET_LENGTH(u) #define __Pyx_PyUnicode_READ_CHAR(u, i) PyUnicode_READ_CHAR(u, i) #define __Pyx_PyUnicode_MAX_CHAR_VALUE(u) PyUnicode_MAX_CHAR_VALUE(u) #define __Pyx_PyUnicode_KIND(u) PyUnicode_KIND(u) #define __Pyx_PyUnicode_DATA(u) PyUnicode_DATA(u) #define __Pyx_PyUnicode_READ(k, d, i) PyUnicode_READ(k, d, i) #define __Pyx_PyUnicode_WRITE(k, d, i, ch) PyUnicode_WRITE(k, d, i, ch) #if defined(PyUnicode_IS_READY) && defined(PyUnicode_GET_SIZE) #if CYTHON_COMPILING_IN_CPYTHON && PY_VERSION_HEX >= 0x03090000 #define __Pyx_PyUnicode_IS_TRUE(u) (0 != (likely(PyUnicode_IS_READY(u)) ? PyUnicode_GET_LENGTH(u) : ((PyCompactUnicodeObject )(u))->wstr_length)) #else #define __Pyx_PyUnicode_IS_TRUE(u) (0 != (likely(PyUnicode_IS_READY(u)) ? PyUnicode_GET_LENGTH(u) : PyUnicode_GET_SIZE(u))) #endif #else #define __Pyx_PyUnicode_IS_TRUE(u) (0 != PyUnicode_GET_LENGTH(u)) #endif #else #define CYTHON_PEP393_ENABLED 0 #define PyUnicode_1BYTE_KIND 1 #define PyUnicode_2BYTE_KIND 2 #define PyUnicode_4BYTE_KIND 4 #define __Pyx_PyUnicode_READY(op) (0) #define __Pyx_PyUnicode_GET_LENGTH(u) PyUnicode_GET_SIZE(u) #define __Pyx_PyUnicode_READ_CHAR(u, i) ((Py_UCS4)(PyUnicode_AS_UNICODE(u)[i])) #define __Pyx_PyUnicode_MAX_CHAR_VALUE(u) ((sizeof(Py_UNICODE) == 2) ? 65535 : 1114111) #define __Pyx_PyUnicode_KIND(u) (sizeof(Py_UNICODE)) #define __Pyx_PyUnicode_DATA(u) ((void)PyUnicode_AS_UNICODE(u)) #define __Pyx_PyUnicode_READ(k, d, i) ((void)(k), (Py_UCS4)(((Py_UNICODE)d)[i])) #define __Pyx_PyUnicode_WRITE(k, d, i, ch) (((void)(k)), ((Py_UNICODE)d)[i] = ch) #define __Pyx_PyUnicode_IS_TRUE(u) (0 != PyUnicode_GET_SIZE(u)) #endif #if CYTHON_COMPILING_IN_PYPY #define __Pyx_PyUnicode_Concat(a, b) PyNumber_Add(a, b) #define __Pyx_PyUnicode_ConcatSafe(a, b) PyNumber_Add(a, b) #else #define __Pyx_PyUnicode_Concat(a, b) PyUnicode_Concat(a, b) #define __Pyx_PyUnicode_ConcatSafe(a, b) ((unlikely((a) == Py_None) \|\| unlikely((b) == Py_None)) ?\ PyNumber_Add(a, b) : __Pyx_PyUnicode_Concat(a, b)) #endif #if CYTHON_COMPILING_IN_PYPY && !defined(PyUnicode_Contains) #define PyUnicode_Contains(u, s) PySequence_Contains(u, s) #endif #if CYTHON_COMPILING_IN_PYPY && !defined(PyByteArray_Check) #define PyByteArray_Check(obj) PyObject_TypeCheck(obj, &PyByteArray_Type) #endif #if CYTHON_COMPILING_IN_PYPY && !defined(PyObject_Format) #define PyObject_Format(obj, fmt) PyObject_CallMethod(obj, "__format__", "O", fmt) #endif #define __Pyx_PyString_FormatSafe(a, b) ((unlikely((a) == Py_None \|\| (PyString_Check(b) && !PyString_CheckExact(b)))) ? PyNumber_Remainder(a, b) : __Pyx_PyString_Format(a, b)) #define __Pyx_PyUnicode_FormatSafe(a, b) ((unlikely((a) == Py_None \|\| (PyUnicode_Check(b) && !PyUnicode_CheckExact(b)))) ? PyNumber_Remainder(a, b) : PyUnicode_Format(a, b)) #if PY_MAJOR_VERSION >= 3 #define __Pyx_PyString_Format(a, b) PyUnicode_Format(a, b) #else #define __Pyx_PyString_Format(a, b) PyString_Format(a, b) #endif #if PY_MAJOR_VERSION < 3 && !defined(PyObject_ASCII) #define PyObject_ASCII(o) PyObject_Repr(o) #endif #if PY_MAJOR_VERSION >= 3 #define PyBaseString_Type PyUnicode_Type #define PyStringObject PyUnicodeObject #define PyString_Type PyUnicode_Type #define PyString_Check PyUnicode_Check #define PyString_CheckExact PyUnicode_CheckExact #ifndef PyObject_Unicode #define PyObject_Unicode PyObject_Str #endif #endif #if PY_MAJOR_VERSION >= 3 #define __Pyx_PyBaseString_Check(obj) PyUnicode_Check(obj) #define __Pyx_PyBaseString_CheckExact(obj) PyUnicode_CheckExact(obj) #else #define __Pyx_PyBaseString_Check(obj) (PyString_Check(obj) \|\| PyUnicode_Check(obj)) #define __Pyx_PyBaseString_CheckExact(obj) (PyString_CheckExact(obj) \|\| PyUnicode_CheckExact(obj)) #endif #ifndef PySet_CheckExact #define PySet_CheckExact(obj) (Py_TYPE(obj) == &PySet_Type) #endif #if PY_VERSION_HEX >= 0x030900A4 #define __Pyx_SET_REFCNT(obj, refcnt) Py_SET_REFCNT(obj, refcnt) #define __Pyx_SET_SIZE(obj, size) Py_SET_SIZE(obj, size) #else #define __Pyx_SET_REFCNT(obj, refcnt) Py_REFCNT(obj) = (refcnt) #define __Pyx_SET_SIZE(obj, size) Py_SIZE(obj) = (size) #endif #if CYTHON_ASSUME_SAFE_MACROS #define __Pyx_PySequence_SIZE(seq) Py_SIZE(seq) #else #define __Pyx_PySequence_SIZE(seq) PySequence_Size(seq) #endif #if PY_MAJOR_VERSION >= 3 #define PyIntObject PyLongObject #define PyInt_Type PyLong_Type #define PyInt_Check(op) PyLong_Check(op) #define PyInt_CheckExact(op) PyLong_CheckExact(op) #define PyInt_FromString PyLong_FromString #define PyInt_FromUnicode PyLong_FromUnicode #define PyInt_FromLong PyLong_FromLong #define PyInt_FromSize_t PyLong_FromSize_t #define PyInt_FromSsize_t PyLong_FromSsize_t #define PyInt_AsLong PyLong_AsLong #define PyInt_AS_LONG PyLong_AS_LONG #define PyInt_AsSsize_t PyLong_AsSsize_t #define PyInt_AsUnsignedLongMask PyLong_AsUnsignedLongMask #define PyInt_AsUnsignedLongLongMask PyLong_AsUnsignedLongLongMask #define PyNumber_Int PyNumber_Long #endif #if PY_MAJOR_VERSION >= 3 #define PyBoolObject PyLongObject #endif #if PY_MAJOR_VERSION >= 3 && CYTHON_COMPILING_IN_PYPY #ifndef PyUnicode_InternFromString #define PyUnicode_InternFromString(s) PyUnicode_FromString(s) #endif #endif #if PY_VERSION_HEX < 0x030200A4 typedef long Py_hash_t; #define __Pyx_PyInt_FromHash_t PyInt_FromLong #define __Pyx_PyInt_AsHash_t __Pyx_PyIndex_AsHash_t #else #define __Pyx_PyInt_FromHash_t PyInt_FromSsize_t #define __Pyx_PyInt_AsHash_t __Pyx_PyIndex_AsSsize_t #endif #if PY_MAJOR_VERSION >= 3 #define __Pyx_PyMethod_New(func, self, klass) ((self) ? 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__Pyx_NewRef(obj) : PySequence_Tuple(obj)) static CYTHON_INLINE Py_ssize_t __Pyx_PyIndex_AsSsize_t(PyObject); static CYTHON_INLINE PyObject __Pyx_PyInt_FromSize_t(size_t); static CYTHON_INLINE Py_hash_t __Pyx_PyIndex_AsHash_t(PyObject); #if CYTHON_ASSUME_SAFE_MACROS #define __pyx_PyFloat_AsDouble(x) (PyFloat_CheckExact(x) ? 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/* PyObjectCall.proto / #if CYTHON_COMPILING_IN_CPYTHON static CYTHON_INLINE PyObject __Pyx_PyObject_Call(PyObject func, PyObject arg, PyObject kw); #else #define __Pyx_PyObject_Call(func, arg, kw) PyObject_Call(func, arg, kw) #endif / PyThreadStateGet.proto / #if CYTHON_FAST_THREAD_STATE #define __Pyx_PyThreadState_declare PyThreadState __pyx_tstate; #define __Pyx_PyThreadState_assign __pyx_tstate = __Pyx_PyThreadState_Current; #define __Pyx_PyErr_Occurred() __pyx_tstate->curexc_type #else #define __Pyx_PyThreadState_declare #define __Pyx_PyThreadState_assign #define __Pyx_PyErr_Occurred() PyErr_Occurred() #endif /* PyErrFetchRestore.proto / #if CYTHON_FAST_THREAD_STATE #define __Pyx_PyErr_Clear() __Pyx_ErrRestore(NULL, NULL, NULL) #define __Pyx_ErrRestoreWithState(type, value, tb) __Pyx_ErrRestoreInState(PyThreadState_GET(), type, value, tb) #define __Pyx_ErrFetchWithState(type, value, tb) __Pyx_ErrFetchInState(PyThreadState_GET(), type, value, tb) #define __Pyx_ErrRestore(type, value, tb) __Pyx_ErrRestoreInState(__pyx_tstate, type, value, tb) #define __Pyx_ErrFetch(type, value, tb) __Pyx_ErrFetchInState(__pyx_tstate, type, value, tb) static CYTHON_INLINE void __Pyx_ErrRestoreInState(PyThreadState tstate, PyObject type, PyObject value, PyObject tb); static CYTHON_INLINE void __Pyx_ErrFetchInState(PyThreadState tstate, PyObject type, PyObject value, PyObject *tb); #if CYTHON_COMPILING_IN_CPYTHON #define __Pyx_PyErr_SetNone(exc) (Py_INCREF(exc), __Pyx_ErrRestore((exc), NULL, NULL)) #else #define __Pyx_PyErr_SetNone(exc) PyErr_SetNone(exc) #endif #else #define __Pyx_PyErr_Clear() PyErr_Clear() #define __Pyx_PyErr_SetNone(exc) PyErr_SetNone(exc) #define __Pyx_ErrRestoreWithState(type, value, tb) PyErr_Restore(type, value, tb) #define __Pyx_ErrFetchWithState(type, value, tb) PyErr_Fetch(type, value, tb) #define __Pyx_ErrRestoreInState(tstate, type, value, tb) PyErr_Restore(type, value, tb) #define __Pyx_ErrFetchInState(tstate, type, value, tb) PyErr_Fetch(type, value, tb) #define __Pyx_ErrRestore(type, value, tb) PyErr_Restore(type, value, tb) #define __Pyx_ErrFetch(type, value, tb) PyErr_Fetch(type, value, tb) #endif / RaiseException.proto / static void __Pyx_Raise(PyObject type, PyObject value, PyObject tb, PyObject cause); / PyCFunctionFastCall.proto / #if CYTHON_FAST_PYCCALL static CYTHON_INLINE PyObject __Pyx_PyCFunction_FastCall(PyObject func, PyObject args, Py_ssize_t nargs); #else #define __Pyx_PyCFunction_FastCall(func, args, nargs) (assert(0), NULL) #endif / PyFunctionFastCall.proto / #if CYTHON_FAST_PYCALL #define __Pyx_PyFunction_FastCall(func, args, nargs)\ __Pyx_PyFunction_FastCallDict((func), (args), (nargs), NULL) #if 1 \|\| PY_VERSION_HEX < 0x030600B1 static PyObject __Pyx_PyFunction_FastCallDict(PyObject func, PyObject args, Py_ssize_t nargs, PyObject kwargs); #else #define __Pyx_PyFunction_FastCallDict(func, args, nargs, kwargs) _PyFunction_FastCallDict(func, args, nargs, kwargs) #endif #define __Pyx_BUILD_ASSERT_EXPR(cond)\ (sizeof(char [1 - 2!(cond)]) - 1) #ifndef Py_MEMBER_SIZE #define Py_MEMBER_SIZE(type, member) sizeof(((type )0)->member) #endif #if CYTHON_FAST_PYCALL static size_t __pyx_pyframe_localsplus_offset = 0; #include "frameobject.h" #define __Pxy_PyFrame_Initialize_Offsets()\ ((void)__Pyx_BUILD_ASSERT_EXPR(sizeof(PyFrameObject) == offsetof(PyFrameObject, f_localsplus) + Py_MEMBER_SIZE(PyFrameObject, f_localsplus)),\ (void)(__pyx_pyframe_localsplus_offset = ((size_t)PyFrame_Type.tp_basicsize) - Py_MEMBER_SIZE(PyFrameObject, f_localsplus))) #define __Pyx_PyFrame_GetLocalsplus(frame)\ (assert(__pyx_pyframe_localsplus_offset), (PyObject *)(((char )(frame)) + __pyx_pyframe_localsplus_offset)) #endif // CYTHON_FAST_PYCALL #endif /* PyObjectCall2Args.proto / static CYTHON_UNUSED PyObject __Pyx_PyObject_Call2Args(PyObject* function, PyObject* arg1, PyObject* arg2); 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/ ImportFrom.proto / static PyObject __Pyx_ImportFrom(PyObject* module, PyObject* name); /* HasAttr.proto / static CYTHON_INLINE int __Pyx_HasAttr(PyObject , PyObject ); / PyObject_GenericGetAttrNoDict.proto / #if CYTHON_USE_TYPE_SLOTS && CYTHON_USE_PYTYPE_LOOKUP && PY_VERSION_HEX < 0x03070000 static CYTHON_INLINE PyObject __Pyx_PyObject_GenericGetAttrNoDict(PyObject* obj, PyObject* attr_name); #else #define __Pyx_PyObject_GenericGetAttrNoDict PyObject_GenericGetAttr #endif /* PyObject_GenericGetAttr.proto / #if CYTHON_USE_TYPE_SLOTS && CYTHON_USE_PYTYPE_LOOKUP && PY_VERSION_HEX < 0x03070000 static PyObject __Pyx_PyObject_GenericGetAttr(PyObject* obj, PyObject* attr_name); #else #define __Pyx_PyObject_GenericGetAttr PyObject_GenericGetAttr #endif /* SetVTable.proto / static int __Pyx_SetVtable(PyObject dict, void vtable); / PyObjectGetAttrStrNoError.proto / static CYTHON_INLINE PyObject __Pyx_PyObject_GetAttrStrNoError(PyObject* obj, PyObject* attr_name); /* SetupReduce.proto / static int __Pyx_setup_reduce(PyObject type_obj); /* CLineInTraceback.proto / #ifdef CYTHON_CLINE_IN_TRACEBACK #define __Pyx_CLineForTraceback(tstate, c_line) (((CYTHON_CLINE_IN_TRACEBACK)) ? c_line : 0) #else static int __Pyx_CLineForTraceback(PyThreadState tstate, int c_line); #endif /* CodeObjectCache.proto / typedef struct { PyCodeObject code_object; int code_line; } __Pyx_CodeObjectCacheEntry; struct __Pyx_CodeObjectCache { int count; int max_count; __Pyx_CodeObjectCacheEntry* entries; }; static struct __Pyx_CodeObjectCache __pyx_code_cache = {0,0,NULL}; static int __pyx_bisect_code_objects(__Pyx_CodeObjectCacheEntry* entries, int count, int code_line); static PyCodeObject __pyx_find_code_object(int code_line); static void __pyx_insert_code_object(int code_line, PyCodeObject code_object); /* AddTraceback.proto / static void __Pyx_AddTraceback(const char funcname, int c_line, int py_line, const char filename); #if PY_MAJOR_VERSION < 3 static int __Pyx_GetBuffer(PyObject obj, Py_buffer view, int flags); static void __Pyx_ReleaseBuffer(Py_buffer view); #else #define __Pyx_GetBuffer PyObject_GetBuffer #define __Pyx_ReleaseBuffer PyBuffer_Release #endif /* BufferStructDeclare.proto / typedef struct { Py_ssize_t shape, strides, suboffsets; } __Pyx_Buf_DimInfo; typedef struct { size_t refcount; Py_buffer pybuffer; } __Pyx_Buffer; typedef struct { __Pyx_Buffer rcbuffer; char data; __Pyx_Buf_DimInfo diminfo[8]; } __Pyx_LocalBuf_ND; / MemviewSliceIsContig.proto / static int __pyx_memviewslice_is_contig(const __Pyx_memviewslice mvs, char order, int ndim); / OverlappingSlices.proto / static int __pyx_slices_overlap(__Pyx_memviewslice slice1, __Pyx_memviewslice slice2, int ndim, size_t itemsize); / Capsule.proto / static CYTHON_INLINE PyObject __pyx_capsule_create(void p, const char sig); /* IsLittleEndian.proto / static CYTHON_INLINE int __Pyx_Is_Little_Endian(void); / BufferFormatCheck.proto / static const char __Pyx_BufFmt_CheckString(__Pyx_BufFmt_Context* ctx, const char* ts); static void __Pyx_BufFmt_Init(__Pyx_BufFmt_Context* ctx, __Pyx_BufFmt_StackElem* stack, __Pyx_TypeInfo* type); /* TypeInfoCompare.proto / static int __pyx_typeinfo_cmp(__Pyx_TypeInfo a, __Pyx_TypeInfo b); / MemviewSliceValidateAndInit.proto / static int __Pyx_ValidateAndInit_memviewslice( int axes_specs, int c_or_f_flag, int buf_flags, int ndim, __Pyx_TypeInfo dtype, __Pyx_BufFmt_StackElem stack[], __Pyx_memviewslice memviewslice, PyObject original_obj); / ObjectToMemviewSlice.proto / static CYTHON_INLINE __Pyx_memviewslice __Pyx_PyObject_to_MemoryviewSlice_d_dc_double(PyObject , int writable_flag); /* ObjectToMemviewSlice.proto / static CYTHON_INLINE __Pyx_memviewslice __Pyx_PyObject_to_MemoryviewSlice_ds_double(PyObject , int writable_flag); /* ObjectToMemviewSlice.proto / static CYTHON_INLINE __Pyx_memviewslice __Pyx_PyObject_to_MemoryviewSlice_dc_double(PyObject , int writable_flag); /* ObjectToMemviewSlice.proto / static CYTHON_INLINE __Pyx_memviewslice __Pyx_PyObject_to_MemoryviewSlice_d_dc_long(PyObject , int writable_flag); /* GCCDiagnostics.proto / #if defined(__GNUC__) && (__GNUC__ > 4 \|\| (__GNUC__ == 4 && __GNUC_MINOR__ >= 6)) #define __Pyx_HAS_GCC_DIAGNOSTIC #endif / MemviewDtypeToObject.proto / static CYTHON_INLINE PyObject __pyx_memview_get_double(const char itemp); static CYTHON_INLINE int __pyx_memview_set_double(const char itemp, PyObject obj); / MemviewSliceCopyTemplate.proto / static __Pyx_memviewslice __pyx_memoryview_copy_new_contig(const __Pyx_memviewslice from_mvs, const char mode, int ndim, size_t sizeof_dtype, int contig_flag, int dtype_is_object); / CIntFromPy.proto / static CYTHON_INLINE long __Pyx_PyInt_As_long(PyObject ); /* CIntFromPy.proto / static CYTHON_INLINE int __Pyx_PyInt_As_int(PyObject ); /* CIntToPy.proto / static CYTHON_INLINE PyObject __Pyx_PyInt_From_int(int value); /* CIntToPy.proto / static CYTHON_INLINE PyObject __Pyx_PyInt_From_long(long value); /* CIntFromPy.proto / static CYTHON_INLINE char __Pyx_PyInt_As_char(PyObject ); /* CheckBinaryVersion.proto / static int __Pyx_check_binary_version(void); / InitStrings.proto / static int __Pyx_InitStrings(__Pyx_StringTabEntry t); static PyObject __pyx_array_get_memview(struct __pyx_array_obj __pyx_v_self); /* proto/ static char __pyx_memoryview_get_item_pointer(struct __pyx_memoryview_obj __pyx_v_self, PyObject __pyx_v_index); /* proto/ static PyObject __pyx_memoryview_is_slice(struct __pyx_memoryview_obj __pyx_v_self, PyObject __pyx_v_obj); /* proto/ static PyObject __pyx_memoryview_setitem_slice_assignment(struct __pyx_memoryview_obj __pyx_v_self, PyObject __pyx_v_dst, PyObject __pyx_v_src); / proto/ static PyObject __pyx_memoryview_setitem_slice_assign_scalar(struct __pyx_memoryview_obj __pyx_v_self, struct __pyx_memoryview_obj __pyx_v_dst, PyObject __pyx_v_value); / proto/ static PyObject __pyx_memoryview_setitem_indexed(struct __pyx_memoryview_obj __pyx_v_self, PyObject __pyx_v_index, PyObject __pyx_v_value); / proto/ static PyObject __pyx_memoryview_convert_item_to_object(struct __pyx_memoryview_obj __pyx_v_self, char __pyx_v_itemp); /* proto/ static PyObject __pyx_memoryview_assign_item_from_object(struct __pyx_memoryview_obj __pyx_v_self, char __pyx_v_itemp, PyObject __pyx_v_value); / proto/ static PyObject __pyx_memoryviewslice_convert_item_to_object(struct __pyx_memoryviewslice_obj __pyx_v_self, char __pyx_v_itemp); /* proto/ static PyObject __pyx_memoryviewslice_assign_item_from_object(struct __pyx_memoryviewslice_obj __pyx_v_self, char __pyx_v_itemp, PyObject __pyx_v_value); / proto/ / Module declarations from 'cython.view' / / Module declarations from 'cython' / / Module declarations from 'libc.math' / / Module declarations from 'shakemap.c.clib' / static PyTypeObject __pyx_array_type = 0; static PyTypeObject __pyx_MemviewEnum_type = 0; static PyTypeObject __pyx_memoryview_type = 0; static PyTypeObject __pyx_memoryviewslice_type = 0; static PyObject generic = 0; static PyObject strided = 0; static PyObject indirect = 0; static PyObject contiguous = 0; static PyObject indirect_contiguous = 0; static int __pyx_memoryview_thread_locks_used; static PyThread_type_lock __pyx_memoryview_thread_locks[8]; static struct __pyx_array_obj __pyx_array_new(PyObject , Py_ssize_t, char , char , char ); /proto/ static void __pyx_align_pointer(void , size_t); /proto/ static PyObject __pyx_memoryview_new(PyObject , int, int, __Pyx_TypeInfo ); /proto/ static CYTHON_INLINE int __pyx_memoryview_check(PyObject ); /proto/ static PyObject _unellipsify(PyObject , int); /proto/ static PyObject assert_direct_dimensions(Py_ssize_t , int); /proto/ static struct __pyx_memoryview_obj __pyx_memview_slice(struct __pyx_memoryview_obj , PyObject ); /proto/ static int __pyx_memoryview_slice_memviewslice(__Pyx_memviewslice , Py_ssize_t, Py_ssize_t, Py_ssize_t, int, int, int , Py_ssize_t, Py_ssize_t, Py_ssize_t, int, int, int, int); /proto/ static char __pyx_pybuffer_index(Py_buffer , char , Py_ssize_t, Py_ssize_t); /proto/ static int __pyx_memslice_transpose(__Pyx_memviewslice ); /proto/ static PyObject __pyx_memoryview_fromslice(__Pyx_memviewslice, int, PyObject ()(char ), int ()(char , PyObject ), int); /proto/ static __Pyx_memviewslice __pyx_memoryview_get_slice_from_memoryview(struct __pyx_memoryview_obj , __Pyx_memviewslice ); /proto/ static void __pyx_memoryview_slice_copy(struct __pyx_memoryview_obj , __Pyx_memviewslice ); /proto/ static PyObject __pyx_memoryview_copy_object(struct __pyx_memoryview_obj ); /proto/ static PyObject __pyx_memoryview_copy_object_from_slice(struct __pyx_memoryview_obj , __Pyx_memviewslice ); /proto/ static Py_ssize_t abs_py_ssize_t(Py_ssize_t); /proto/ static char __pyx_get_best_slice_order(__Pyx_memviewslice , int); /proto/ static void _copy_strided_to_strided(char , Py_ssize_t , char , Py_ssize_t , Py_ssize_t , Py_ssize_t , int, size_t); /proto/ static void copy_strided_to_strided(__Pyx_memviewslice , __Pyx_memviewslice , int, size_t); /proto/ static Py_ssize_t __pyx_memoryview_slice_get_size(__Pyx_memviewslice , int); /proto/ static Py_ssize_t __pyx_fill_contig_strides_array(Py_ssize_t , Py_ssize_t , Py_ssize_t, int, char); /proto/ static void __pyx_memoryview_copy_data_to_temp(__Pyx_memviewslice , __Pyx_memviewslice , char, int); /proto/ static int __pyx_memoryview_err_extents(int, Py_ssize_t, Py_ssize_t); /proto/ static int __pyx_memoryview_err_dim(PyObject , char , int); /proto/ static int __pyx_memoryview_err(PyObject , char ); /proto/ static int __pyx_memoryview_copy_contents(__Pyx_memviewslice, __Pyx_memviewslice, int, int, int); /proto/ static void __pyx_memoryview_broadcast_leading(__Pyx_memviewslice , int, int); /proto/ static void __pyx_memoryview_refcount_copying(__Pyx_memviewslice , int, int, int); /proto/ static void __pyx_memoryview_refcount_objects_in_slice_with_gil(char , Py_ssize_t , Py_ssize_t , int, int); /proto/ static void __pyx_memoryview_refcount_objects_in_slice(char , Py_ssize_t , Py_ssize_t , int, int); /proto/ static void __pyx_memoryview_slice_assign_scalar(__Pyx_memviewslice , int, size_t, void , int); /proto/ static void __pyx_memoryview__slice_assign_scalar(char , Py_ssize_t , Py_ssize_t , int, size_t, void ); /proto/ static PyObject __pyx_unpickle_Enum__set_state(struct __pyx_MemviewEnum_obj , PyObject ); /proto/ static __Pyx_TypeInfo __Pyx_TypeInfo_double = { "double", NULL, sizeof(double), { 0 }, 0, 'R', 0, 0 }; static __Pyx_TypeInfo __Pyx_TypeInfo_long = { "long", NULL, sizeof(long), { 0 }, 0, IS_UNSIGNED(long) ? 'U' : 'I', IS_UNSIGNED(long), 0 }; #define __Pyx_MODULE_NAME "shakemap.c.clib" extern int __pyx_module_is_main_shakemap__c__clib; int __pyx_module_is_main_shakemap__c__clib = 0; / Implementation of 'shakemap.c.clib' / static PyObject __pyx_builtin_range; static PyObject __pyx_builtin_ValueError; static PyObject __pyx_builtin_MemoryError; static PyObject __pyx_builtin_enumerate; static PyObject __pyx_builtin_TypeError; static PyObject __pyx_builtin_Ellipsis; static PyObject __pyx_builtin_id; static PyObject __pyx_builtin_IndexError; static const char __pyx_k_O[] = "O"; static const char __pyx_k_c[] = "c"; static const char __pyx_k_h[] = "h"; static const char __pyx_k_i[] = "i"; static const char __pyx_k_j[] = "j"; static const char __pyx_k_x[] = "x"; static const char __pyx_k_y[] = "y"; static const char __pyx_k_b1[] = "b1"; static const char __pyx_k_b2[] = "b2"; static const char __pyx_k_b3[] = "b3"; static const char __pyx_k_hp[] = "hp"; static const char __pyx_k_id[] = "id"; static const char __pyx_k_iy[] = "iy"; static const char __pyx_k_np[] = "np"; static const char __pyx_k_nx[] = "nx"; static const char __pyx_k_ny[] = "ny"; static const char __pyx_k_cap[] = "cap"; static const char __pyx_k_ix1[] = "ix1"; static const char __pyx_k_ix2[] = "ix2"; static const char __pyx_k_new[] = "__new__"; static const char __pyx_k_obj[] = "obj"; static const char __pyx_k_pop[] = "pop"; static const char __pyx_k_rcp[] = "rcp"; static const char __pyx_k_res[] = "res"; static const char __pyx_k_sdg[] = "sdg"; static const char __pyx_k_sgp[] = "sgp"; static const char __pyx_k_tmp[] = "tmp"; static const char __pyx_k_base[] = "base"; static const char __pyx_k_c12p[] = "c12p"; static const char __pyx_k_dict[] = "__dict__"; static const char __pyx_k_hval[] = "hval"; static const char __pyx_k_ix1p[] = "ix1p"; static const char __pyx_k_ix2p[] = "ix2p"; static const char __pyx_k_lat2[] = "lat2"; static const char __pyx_k_lon2[] = "lon2"; static const char __pyx_k_main[] = "__main__"; static const char __pyx_k_mode[] = "mode"; static const char __pyx_k_name[] = "name"; static const char __pyx_k_ndim[] = "ndim"; static const char __pyx_k_pack[] = "pack"; static const char __pyx_k_size[] = "size"; static const char __pyx_k_step[] = "step"; static const char __pyx_k_stop[] = "stop"; static const char __pyx_k_test[] = "__test__"; static const char __pyx_k_ASCII[] = "ASCII"; static const char __pyx_k_afact[] = "afact"; static const char __pyx_k_bfact[] = "bfact"; static const char __pyx_k_class[] = "__class__"; static const char __pyx_k_error[] = "error"; static const char __pyx_k_flags[] = "flags"; static const char __pyx_k_lats1[] = "lats1"; static const char __pyx_k_lats2[] = "lats2"; static const char __pyx_k_lons1[] = "lons1"; static const char __pyx_k_lons2[] = "lons2"; static const char __pyx_k_numpy[] = "numpy"; static const char __pyx_k_range[] = "range"; static const char __pyx_k_sdarr[] = "sdarr"; static const char __pyx_k_sdsta[] = "sdsta"; static const char __pyx_k_sdval[] = "sdval"; static const char __pyx_k_shape[] = "shape"; static const char __pyx_k_start[] = "start"; static const char __pyx_k_corr12[] = "corr12"; static const char __pyx_k_encode[] = "encode"; static const char __pyx_k_format[] = "format"; static const char __pyx_k_import[] = "__import__"; static const char __pyx_k_name_2[] = "__name__"; static const char __pyx_k_pickle[] = "pickle"; static const char __pyx_k_reduce[] = "__reduce__"; static const char __pyx_k_result[] = "result"; static const char __pyx_k_sdgrid[] = "sdgrid"; static const char __pyx_k_struct[] = "struct"; static const char __pyx_k_unpack[] = "unpack"; static const char __pyx_k_update[] = "update"; static const char __pyx_k_fortran[] = "fortran"; static const char __pyx_k_memview[] = "memview"; static const char __pyx_k_sigma12[] = "sigma12"; static const char __pyx_k_Ellipsis[] = "Ellipsis"; static const char __pyx_k_diameter[] = "diameter"; static const char __pyx_k_getstate[] = "__getstate__"; static const char __pyx_k_itemsize[] = "itemsize"; static const char __pyx_k_pout_sd2[] = "pout_sd2"; static const char __pyx_k_pyx_type[] = "__pyx_type"; static const char __pyx_k_rcmatrix[] = "rcmatrix"; static const char __pyx_k_setstate[] = "__setstate__"; static const char __pyx_k_TypeError[] = "TypeError"; static const char __pyx_k_enumerate[] = "enumerate"; static const char __pyx_k_pyx_state[] = "__pyx_state"; static const char __pyx_k_reduce_ex[] = "__reduce_ex__"; static const char __pyx_k_IndexError[] = "IndexError"; static const char __pyx_k_ValueError[] = "ValueError"; static const char __pyx_k_corr_adj12[] = "corr_adj12"; static const char __pyx_k_pyx_result[] = "__pyx_result"; static const char __pyx_k_pyx_vtable[] = "__pyx_vtable__"; static const char __pyx_k_MemoryError[] = "MemoryError"; static const char __pyx_k_PickleError[] = "PickleError"; static const char __pyx_k_EARTH_RADIUS[] = "EARTH_RADIUS"; static const char __pyx_k_pyx_checksum[] = "__pyx_checksum"; static const char __pyx_k_stringsource[] = "stringsource"; static const char __pyx_k_make_sd_array[] = "make_sd_array"; static const char __pyx_k_pyx_getbuffer[] = "__pyx_getbuffer"; static const char __pyx_k_reduce_cython[] = "__reduce_cython__"; static const char __pyx_k_View_MemoryView[] = "View.MemoryView"; static const char __pyx_k_allocate_buffer[] = "allocate_buffer"; static const char __pyx_k_dtype_is_object[] = "dtype_is_object"; static const char __pyx_k_pyx_PickleError[] = "__pyx_PickleError"; static const char __pyx_k_setstate_cython[] = "__setstate_cython__"; static const char __pyx_k_shakemap_c_clib[] = "shakemap.c.clib"; static const char __pyx_k_make_sigma_matrix[] = "make_sigma_matrix"; static const char __pyx_k_pyx_unpickle_Enum[] = "__pyx_unpickle_Enum"; static const char __pyx_k_cline_in_traceback[] = "cline_in_traceback"; static const char __pyx_k_strided_and_direct[] = "<strided and direct>"; static const char __pyx_k_eval_lb_correlation[] = "eval_lb_correlation"; static const char __pyx_k_shakemap_c_clib_pyx[] = "shakemap/c/clib.pyx"; static const char __pyx_k_strided_and_indirect[] = "<strided and indirect>"; static const char __pyx_k_contiguous_and_direct[] = "<contiguous and direct>"; static const char __pyx_k_MemoryView_of_r_object[] = "<MemoryView of %r object>"; static const char __pyx_k_geodetic_distance_fast[] = "geodetic_distance_fast"; static const char __pyx_k_MemoryView_of_r_at_0x_x[] = "<MemoryView of %r at 0x%x>"; static const char __pyx_k_contiguous_and_indirect[] = "<contiguous and indirect>"; static const char __pyx_k_Cannot_index_with_type_s[] = "Cannot index with type '%s'"; static const char __pyx_k_Invalid_shape_in_axis_d_d[] = "Invalid shape in axis %d: %d."; static const char __pyx_k_geodetic_distance_haversine[] = "geodetic_distance_haversine"; static const char __pyx_k_itemsize_0_for_cython_array[] = "itemsize <= 0 for cython.array"; static const char __pyx_k_unable_to_allocate_array_data[] = "unable to allocate array data."; static const char __pyx_k_strided_and_direct_or_indirect[] = "<strided and direct or indirect>"; static const char __pyx_k_Buffer_view_does_not_expose_stri[] = "Buffer view does not expose strides"; static const char __pyx_k_Can_only_create_a_buffer_that_is[] = "Can only create a buffer that is contiguous in memory."; static const char __pyx_k_Cannot_assign_to_read_only_memor[] = "Cannot assign to read-only memoryview"; static const char __pyx_k_Cannot_create_writable_memory_vi[] = "Cannot create writable memory view from read-only memoryview"; static const char __pyx_k_Empty_shape_tuple_for_cython_arr[] = "Empty shape tuple for cython.array"; static const char __pyx_k_Incompatible_checksums_s_vs_0xb0[] = "Incompatible checksums (%s vs 0xb068931 = (name))"; static const char __pyx_k_Indirect_dimensions_not_supporte[] = "Indirect dimensions not supported"; static const char __pyx_k_Invalid_mode_expected_c_or_fortr[] = "Invalid mode, expected 'c' or 'fortran', got %s"; static const char __pyx_k_Out_of_bounds_on_buffer_access_a[] = "Out of bounds on buffer access (axis %d)"; static const char __pyx_k_Unable_to_convert_item_to_object[] = "Unable to convert item to object"; static const char __pyx_k_got_differing_extents_in_dimensi[] = "got differing extents in dimension %d (got %d and %d)"; static const char __pyx_k_no_default___reduce___due_to_non[] = "no default __reduce__ due to non-trivial __cinit__"; static const char __pyx_k_unable_to_allocate_shape_and_str[] = "unable to allocate shape and strides."; static PyObject __pyx_n_s_ASCII; static PyObject __pyx_kp_s_Buffer_view_does_not_expose_stri; static PyObject __pyx_kp_s_Can_only_create_a_buffer_that_is; static PyObject __pyx_kp_s_Cannot_assign_to_read_only_memor; static PyObject __pyx_kp_s_Cannot_create_writable_memory_vi; static PyObject __pyx_kp_s_Cannot_index_with_type_s; static PyObject __pyx_n_s_EARTH_RADIUS; static PyObject __pyx_n_s_Ellipsis; static PyObject __pyx_kp_s_Empty_shape_tuple_for_cython_arr; static PyObject __pyx_kp_s_Incompatible_checksums_s_vs_0xb0; static PyObject __pyx_n_s_IndexError; static PyObject __pyx_kp_s_Indirect_dimensions_not_supporte; static PyObject __pyx_kp_s_Invalid_mode_expected_c_or_fortr; static PyObject __pyx_kp_s_Invalid_shape_in_axis_d_d; static PyObject __pyx_n_s_MemoryError; static PyObject __pyx_kp_s_MemoryView_of_r_at_0x_x; static PyObject __pyx_kp_s_MemoryView_of_r_object; static PyObject __pyx_n_b_O; static PyObject __pyx_kp_s_Out_of_bounds_on_buffer_access_a; static PyObject __pyx_n_s_PickleError; static PyObject __pyx_n_s_TypeError; static PyObject __pyx_kp_s_Unable_to_convert_item_to_object; static PyObject __pyx_n_s_ValueError; static PyObject __pyx_n_s_View_MemoryView; static PyObject __pyx_n_s_afact; static PyObject __pyx_n_s_allocate_buffer; static PyObject __pyx_n_s_b1; static PyObject __pyx_n_s_b2; static PyObject __pyx_n_s_b3; static PyObject __pyx_n_s_base; static PyObject __pyx_n_s_bfact; static PyObject __pyx_n_s_c; static PyObject __pyx_n_u_c; static PyObject __pyx_n_s_c12p; static PyObject __pyx_n_s_cap; static PyObject __pyx_n_s_class; static PyObject __pyx_n_s_cline_in_traceback; static PyObject __pyx_kp_s_contiguous_and_direct; static PyObject __pyx_kp_s_contiguous_and_indirect; static PyObject __pyx_n_s_corr12; static PyObject __pyx_n_s_corr_adj12; static PyObject __pyx_n_s_diameter; static PyObject __pyx_n_s_dict; static PyObject __pyx_n_s_dtype_is_object; static PyObject __pyx_n_s_encode; static PyObject __pyx_n_s_enumerate; static PyObject __pyx_n_s_error; static PyObject __pyx_n_s_eval_lb_correlation; static PyObject __pyx_n_s_flags; static PyObject __pyx_n_s_format; static PyObject __pyx_n_s_fortran; static PyObject __pyx_n_u_fortran; static PyObject __pyx_n_s_geodetic_distance_fast; static PyObject __pyx_n_s_geodetic_distance_haversine; static PyObject __pyx_n_s_getstate; static PyObject __pyx_kp_s_got_differing_extents_in_dimensi; static PyObject __pyx_n_s_h; static PyObject __pyx_n_s_hp; static 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__pyx_pf_15View_dot_MemoryView_10memoryview_10suboffsets___get__(struct __pyx_memoryview_obj __pyx_v_self); / proto / static PyObject __pyx_pf_15View_dot_MemoryView_10memoryview_4ndim___get__(struct __pyx_memoryview_obj __pyx_v_self); / proto / static PyObject __pyx_pf_15View_dot_MemoryView_10memoryview_8itemsize___get__(struct __pyx_memoryview_obj __pyx_v_self); / proto / static PyObject __pyx_pf_15View_dot_MemoryView_10memoryview_6nbytes___get__(struct __pyx_memoryview_obj __pyx_v_self); / proto / static PyObject __pyx_pf_15View_dot_MemoryView_10memoryview_4size___get__(struct __pyx_memoryview_obj __pyx_v_self); / proto / static Py_ssize_t __pyx_memoryview___pyx_pf_15View_dot_MemoryView_10memoryview_10__len__(struct __pyx_memoryview_obj __pyx_v_self); /* proto / static PyObject __pyx_memoryview___pyx_pf_15View_dot_MemoryView_10memoryview_12__repr__(struct __pyx_memoryview_obj __pyx_v_self); / proto / static PyObject 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double[:]sdsta, double[:]sdarr): * cdef Py_ssize_t ny = corr12.shape[0] * cdef Py_ssize_t nx = corr12.shape[1] # <<<<<<<<<<<<<< * * cdef double c12p / __pyx_v_nx = (__pyx_v_corr12.shape[1]); /* "shakemap/c/clib.pyx":24 * cdef Py_ssize_t x, y * * for y in prange(ny, nogil=True, schedule=dynamic): # <<<<<<<<<<<<<< * c12p = &corr12[y, 0] * cap = &corr_adj12[y, 0] / { #ifdef WITH_THREAD PyThreadState _save; Py_UNBLOCK_THREADS __Pyx_FastGIL_Remember(); #endif /try:/ { __pyx_t_1 = __pyx_v_ny; if ((1 == 0)) abort(); { #if ((defined(__APPLE__) \|\| defined(__OSX__)) && (defined(__GNUC__) && (__GNUC__ > 2 \|\| (__GNUC__ == 2 && (__GNUC_MINOR__ > 95))))) #undef likely #undef unlikely #define likely(x) (x) #define unlikely(x) (x) #endif __pyx_t_3 = (__pyx_t_1 - 0 + 1 - 1/abs(1)) / 1; if (__pyx_t_3 > 0) { #ifdef _OPENMP #pragma omp parallel private(__pyx_t_4, __pyx_t_5, __pyx_t_6, __pyx_t_7, __pyx_t_8) #endif /* _OPENMP / { #ifdef _OPENMP #pragma omp for lastprivate(__pyx_v_c12p) lastprivate(__pyx_v_cap) lastprivate(__pyx_v_sdval) lastprivate(__pyx_v_tmp) lastprivate(__pyx_v_x) firstprivate(__pyx_v_y) lastprivate(__pyx_v_y) #endif / _OPENMP / for (__pyx_t_2 = 0; __pyx_t_2 < __pyx_t_3; __pyx_t_2++){ { __pyx_v_y = (Py_ssize_t)(0 + 1 __pyx_t_2); /* Initialize private variables to invalid values / __pyx_v_c12p = ((double )1); __pyx_v_cap = ((double )1); __pyx_v_sdval = ((double)__PYX_NAN()); __pyx_v_tmp = ((double)__PYX_NAN()); __pyx_v_x = ((Py_ssize_t)0xbad0bad0); / "shakemap/c/clib.pyx":25 * * for y in prange(ny, nogil=True, schedule=dynamic): * c12p = &corr12[y, 0] # <<<<<<<<<<<<<< * cap = &corr_adj12[y, 0] * sdval = sdarr[y] / __pyx_t_4 = __pyx_v_y; __pyx_t_5 = 0; __pyx_v_c12p = (&(((double ) ( / dim=1 / ((char ) (((double ) ( / dim=0 / (__pyx_v_corr12.data + __pyx_t_4 __pyx_v_corr12.strides[0]) )) + __pyx_t_5)) )))); /* "shakemap/c/clib.pyx":26 * for y in prange(ny, nogil=True, schedule=dynamic): * c12p = &corr12[y, 0] * cap = &corr_adj12[y, 0] # <<<<<<<<<<<<<< * sdval = sdarr[y] * for x in range(nx): / __pyx_t_5 = __pyx_v_y; __pyx_t_4 = 0; __pyx_v_cap = (&(((double ) ( / dim=1 / ((char ) (((double ) ( / dim=0 / (__pyx_v_corr_adj12.data + __pyx_t_5 __pyx_v_corr_adj12.strides[0]) )) + __pyx_t_4)) )))); /* "shakemap/c/clib.pyx":27 * c12p = &corr12[y, 0] * cap = &corr_adj12[y, 0] * sdval = sdarr[y] # <<<<<<<<<<<<<< * for x in range(nx): * # Putting these operations all on one line seems to / __pyx_t_4 = __pyx_v_y; __pyx_v_sdval = (((double ) ( / dim=0 / (__pyx_v_sdarr.data + __pyx_t_4 __pyx_v_sdarr.strides[0]) ))); /* "shakemap/c/clib.pyx":28 * cap = &corr_adj12[y, 0] * sdval = sdarr[y] * for x in range(nx): # <<<<<<<<<<<<<< * # Putting these operations all on one line seems to * # allow the compiler to do things that result in the / __pyx_t_6 = __pyx_v_nx; __pyx_t_7 = __pyx_t_6; for (__pyx_t_8 = 0; __pyx_t_8 < __pyx_t_7; __pyx_t_8+=1) { __pyx_v_x = __pyx_t_8; / "shakemap/c/clib.pyx":32 * # allow the compiler to do things that 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dim=0 / ((char ) (((double ) __pyx_v_lons2.data) + __pyx_t_3)) ))))) != 0); if (__pyx_t_4) { } else { __pyx_t_1 = __pyx_t_4; goto __pyx_L4_bool_binop_done; } __pyx_t_3 = 0; __pyx_t_2 = 0; __pyx_t_4 = (((&(((double ) ( / dim=0 / ((char ) (((double ) __pyx_v_lats1.data) + __pyx_t_3)) )))) == (&(((double ) ( / dim=0 / ((char ) (((double ) __pyx_v_lats2.data) + __pyx_t_2)) ))))) != 0); __pyx_t_1 = __pyx_t_4; __pyx_L4_bool_binop_done:; if (__pyx_t_1) { / "shakemap/c/clib.pyx":52 * * if &lons1[0] == &lons2[0] and &lats1[0] == &lats2[0]: * for y in prange(ny, nogil=True, schedule='guided'): # <<<<<<<<<<<<<< * lon2 = lons2[y] * lat2 = lats2[y] / { #ifdef WITH_THREAD PyThreadState _save; Py_UNBLOCK_THREADS __Pyx_FastGIL_Remember(); #endif /try:/ { __pyx_t_5 = __pyx_v_ny; if ((1 == 0)) abort(); { #if ((defined(__APPLE__) \|\| defined(__OSX__)) && (defined(__GNUC__) && (__GNUC__ > 2 \|\| (__GNUC__ == 2 && (__GNUC_MINOR__ > 95))))) #undef likely #undef unlikely #define likely(x) (x) #define unlikely(x) (x) #endif __pyx_t_7 = (__pyx_t_5 - 0 + 1 - 1/abs(1)) / 1; if (__pyx_t_7 > 0) { #ifdef _OPENMP #pragma omp parallel private(__pyx_t_10, __pyx_t_11, __pyx_t_12, __pyx_t_2, __pyx_t_3, __pyx_t_8, __pyx_t_9) #endif /* _OPENMP / { #ifdef _OPENMP #pragma omp for lastprivate(__pyx_v_lat2) lastprivate(__pyx_v_lon2) lastprivate(__pyx_v_x) firstprivate(__pyx_v_y) lastprivate(__pyx_v_y) schedule(guided) #endif / _OPENMP / for (__pyx_t_6 = 0; __pyx_t_6 < __pyx_t_7; __pyx_t_6++){ { __pyx_v_y = (Py_ssize_t)(0 + 1 __pyx_t_6); /* Initialize private variables to invalid values / __pyx_v_lat2 = ((double)__PYX_NAN()); __pyx_v_lon2 = ((double)__PYX_NAN()); __pyx_v_x = ((Py_ssize_t)0xbad0bad0); / "shakemap/c/clib.pyx":53 * if &lons1[0] == &lons2[0] and &lats1[0] == &lats2[0]: * for y in prange(ny, nogil=True, schedule='guided'): * lon2 = lons2[y] # <<<<<<<<<<<<<< * lat2 = lats2[y] * for x in range(y+1): / __pyx_t_2 = __pyx_v_y; __pyx_v_lon2 = (((double ) ( / dim=0 / ((char ) (((double ) 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lat2)*2)) else: / __pyx_t_3 = __pyx_v_x; / "shakemap/c/clib.pyx":60 * sqrt(((lons1[x] - lon2) * * cos(0.5 * (lats1[x] + lat2)))*2 + (lats1[x] - lat2)*2)) # <<<<<<<<<<<<<< else: * for y in prange(ny, nogil=True, schedule=dynamic): / __pyx_t_11 = __pyx_v_x; / "shakemap/c/clib.pyx":57 * for x in range(y+1): * result[y, x] = result[x, y] = ( * EARTH_RADIUS * # <<<<<<<<<<<<<< * sqrt(((lons1[x] - lon2) * * cos(0.5 * (lats1[x] + lat2)))*2 + / __pyx_t_12 = (__pyx_v_EARTH_RADIUS * sqrt((pow((((((double ) ( /* dim=0 / ((char ) (((double ) __pyx_v_lons1.data) + __pyx_t_2)) ))) - __pyx_v_lon2) cos((0.5 * ((((double ) ( /* dim=0 / ((char ) (((double ) __pyx_v_lats1.data) + __pyx_t_3)) ))) + __pyx_v_lat2)))), 2.0) + pow(((((double ) ( / dim=0 / ((char ) (((double ) __pyx_v_lats1.data) + __pyx_t_11)) ))) - __pyx_v_lat2), 2.0)))); / "shakemap/c/clib.pyx":56 * lat2 = lats2[y] * for x in range(y+1): * result[y, x] = result[x, y] = ( # <<<<<<<<<<<<<< * EARTH_RADIUS * * sqrt(((lons1[x] - lon2) * / __pyx_t_11 = __pyx_v_y; __pyx_t_3 = __pyx_v_x; ((double ) ( / dim=1 / ((char ) (((double ) ( / dim=0 / (__pyx_v_result.data + __pyx_t_11 __pyx_v_result.strides[0]) )) + __pyx_t_3)) )) = __pyx_t_12; __pyx_t_3 = __pyx_v_x; __pyx_t_11 = __pyx_v_y; ((double ) ( /* dim=1 / ((char ) (((double ) ( / dim=0 / (__pyx_v_result.data + __pyx_t_3 __pyx_v_result.strides[0]) )) + __pyx_t_11)) )) = __pyx_t_12; } } } } } } #if ((defined(__APPLE__) \|\| defined(__OSX__)) && (defined(__GNUC__) && (__GNUC__ > 2 \|\| (__GNUC__ == 2 && (__GNUC_MINOR__ > 95))))) #undef likely #undef unlikely #define likely(x) __builtin_expect(!!(x), 1) #define unlikely(x) __builtin_expect(!!(x), 0) #endif } /* "shakemap/c/clib.pyx":52 * * if &lons1[0] == &lons2[0] and &lats1[0] == &lats2[0]: * for y in prange(ny, nogil=True, schedule='guided'): # <<<<<<<<<<<<<< * lon2 = lons2[y] * lat2 = lats2[y] / /finally:/ { /normal exit:/{ #ifdef WITH_THREAD __Pyx_FastGIL_Forget(); Py_BLOCK_THREADS #endif goto __pyx_L8; } __pyx_L8:; } } / "shakemap/c/clib.pyx":51 * cdef Py_ssize_t x, y * * if &lons1[0] == &lons2[0] and &lats1[0] == &lats2[0]: # <<<<<<<<<<<<<< * for y in prange(ny, nogil=True, schedule='guided'): * lon2 = lons2[y] / goto __pyx_L3; } / "shakemap/c/clib.pyx":62 * (lats1[x] - lat2)*2)) else: * for y in prange(ny, nogil=True, schedule=dynamic): # <<<<<<<<<<<<<< * res = &result[y, 0] * lon2 = lons2[y] / /else/ { { #ifdef WITH_THREAD PyThreadState _save; Py_UNBLOCK_THREADS __Pyx_FastGIL_Remember(); #endif /try:/ { __pyx_t_7 = __pyx_v_ny; if ((1 == 0)) abort(); { #if ((defined(__APPLE__) \|\| defined(__OSX__)) && (defined(__GNUC__) && (__GNUC__ > 2 \|\| (__GNUC__ == 2 && (__GNUC_MINOR__ > 95))))) #undef likely #undef unlikely #define likely(x) (x) #define unlikely(x) (x) #endif __pyx_t_5 = (__pyx_t_7 - 0 + 1 - 1/abs(1)) / 1; if (__pyx_t_5 > 0) { #ifdef _OPENMP #pragma omp parallel private(__pyx_t_10, __pyx_t_11, __pyx_t_2, __pyx_t_3, __pyx_t_8, __pyx_t_9) #endif /* _OPENMP / { #ifdef _OPENMP #pragma omp for lastprivate(__pyx_v_lat2) lastprivate(__pyx_v_lon2) lastprivate(__pyx_v_res) lastprivate(__pyx_v_x) firstprivate(__pyx_v_y) lastprivate(__pyx_v_y) #endif / _OPENMP / for (__pyx_t_6 = 0; __pyx_t_6 < __pyx_t_5; __pyx_t_6++){ { __pyx_v_y = (Py_ssize_t)(0 + 1 __pyx_t_6); /* Initialize private variables to invalid values / __pyx_v_lat2 = ((double)__PYX_NAN()); __pyx_v_lon2 = ((double)__PYX_NAN()); __pyx_v_res = ((double )1); __pyx_v_x = ((Py_ssize_t)0xbad0bad0); /* "shakemap/c/clib.pyx":63 * else: * for y in prange(ny, nogil=True, schedule=dynamic): * res = &result[y, 0] # <<<<<<<<<<<<<< * lon2 = lons2[y] * lat2 = lats2[y] / __pyx_t_11 = __pyx_v_y; __pyx_t_3 = 0; __pyx_v_res = (&(((double ) ( / dim=1 / ((char ) (((double ) ( / dim=0 / (__pyx_v_result.data + __pyx_t_11 __pyx_v_result.strides[0]) )) + __pyx_t_3)) )))); /* "shakemap/c/clib.pyx":64 * for y in prange(ny, nogil=True, schedule=dynamic): * res = &result[y, 0] * lon2 = lons2[y] # <<<<<<<<<<<<<< * lat2 = lats2[y] * for x in range(nx): / __pyx_t_3 = __pyx_v_y; __pyx_v_lon2 = (((double ) ( / dim=0 / ((char ) (((double ) __pyx_v_lons2.data) + __pyx_t_3)) ))); / "shakemap/c/clib.pyx":65 * res = &result[y, 0] * lon2 = lons2[y] * lat2 = lats2[y] # <<<<<<<<<<<<<< * for x in range(nx): * res[x] = ( / __pyx_t_3 = __pyx_v_y; __pyx_v_lat2 = (((double ) ( / dim=0 / ((char ) (((double ) __pyx_v_lats2.data) + __pyx_t_3)) ))); / "shakemap/c/clib.pyx":66 * lon2 = lons2[y] * lat2 = lats2[y] * for x in range(nx): # <<<<<<<<<<<<<< * res[x] = ( * EARTH_RADIUS * / __pyx_t_8 = __pyx_v_nx; __pyx_t_9 = __pyx_t_8; for (__pyx_t_10 = 0; __pyx_t_10 < __pyx_t_9; __pyx_t_10+=1) { __pyx_v_x = __pyx_t_10; / "shakemap/c/clib.pyx":69 * res[x] = ( * EARTH_RADIUS * * sqrt(((lons1[x] - lon2) * # <<<<<<<<<<<<<< * cos(0.5 * (lats1[x] + lat2)))*2 + (lats1[x] - lat2)*2)) / __pyx_t_3 = __pyx_v_x; /* "shakemap/c/clib.pyx":70 * EARTH_RADIUS * * sqrt(((lons1[x] - lon2) * * cos(0.5 * (lats1[x] + lat2)))*2 + # <<<<<<<<<<<<<< (lats1[x] - lat2)*2)) 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nogil=True, schedule='guided'): # <<<<<<<<<<<<<< * for x in range(y+1): * result[y, x] = result[x, y] = ( / { #ifdef WITH_THREAD PyThreadState _save; Py_UNBLOCK_THREADS __Pyx_FastGIL_Remember(); #endif /try:/ { __pyx_t_5 = __pyx_v_ny; if ((1 == 0)) abort(); { #if ((defined(__APPLE__) \|\| defined(__OSX__)) && (defined(__GNUC__) && (__GNUC__ > 2 \|\| (__GNUC__ == 2 && (__GNUC_MINOR__ > 95))))) #undef likely #undef unlikely #define likely(x) (x) #define unlikely(x) (x) #endif __pyx_t_7 = (__pyx_t_5 - 0 + 1 - 1/abs(1)) / 1; if (__pyx_t_7 > 0) { #ifdef _OPENMP #pragma omp parallel private(__pyx_t_10, __pyx_t_11, __pyx_t_12, __pyx_t_13, __pyx_t_14, __pyx_t_15, __pyx_t_2, __pyx_t_3, __pyx_t_8, __pyx_t_9) #endif /* _OPENMP / { #ifdef _OPENMP #pragma omp for lastprivate(__pyx_v_x) firstprivate(__pyx_v_y) lastprivate(__pyx_v_y) schedule(guided) #endif / _OPENMP / for (__pyx_t_6 = 0; __pyx_t_6 < __pyx_t_7; __pyx_t_6++){ { __pyx_v_y = (Py_ssize_t)(0 + 1 __pyx_t_6); /* Initialize private variables 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cos(lats1[x]) * cos(lats2[y]) * * sin((lons1[x] - lons2[y]) / 2.0)*2))) # <<<<<<<<<<<<<< else: * for y in prange(ny, nogil=True, schedule=dynamic): / __pyx_t_13 = __pyx_v_x; __pyx_t_14 = __pyx_v_y; / "shakemap/c/clib.pyx":91 * for x in range(y+1): * result[y, x] = result[x, y] = ( * diameter * asin(sqrt( # <<<<<<<<<<<<<< * sin((lats1[x] - lats2[y]) / 2.0)*2 + cos(lats1[x]) * cos(lats2[y]) * / __pyx_t_15 = (__pyx_v_diameter asin(sqrt((pow(sin((((((double ) ( /* dim=0 / ((char ) (((double ) __pyx_v_lats1.data) + __pyx_t_2)) ))) - (((double ) ( / dim=0 / ((char ) (((double ) __pyx_v_lats2.data) + __pyx_t_3)) )))) / 2.0)), 2.0) + ((cos((((double ) ( / dim=0 / ((char ) (((double ) __pyx_v_lats1.data) + __pyx_t_11)) )))) cos((((double ) ( /* dim=0 / ((char ) (((double ) __pyx_v_lats2.data) + __pyx_t_12)) ))))) pow(sin((((((double ) ( /* dim=0 / ((char ) (((double ) __pyx_v_lons1.data) + __pyx_t_13)) ))) - (((double ) ( / dim=0 / ((char ) (((double ) __pyx_v_lons2.data) + __pyx_t_14)) )))) / 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"View.MemoryView":850 * start = shape - 1 * else: * start = shape # <<<<<<<<<<<<<< * else: * if negative_step: / /else/ { __pyx_v_start = __pyx_v_shape; } __pyx_L14:; / "View.MemoryView":846 * if start < 0: * start = 0 * elif start >= shape: # <<<<<<<<<<<<<< * if negative_step: * start = shape - 1 / } __pyx_L12:; / "View.MemoryView":841 * * * if have_start: # <<<<<<<<<<<<<< * if start < 0: * start += shape / goto __pyx_L11; } / "View.MemoryView":852 * start = shape * else: * if negative_step: # <<<<<<<<<<<<<< * start = shape - 1 * else: / /else/ { __pyx_t_2 = (__pyx_v_negative_step != 0); if (__pyx_t_2) { / "View.MemoryView":853 * else: * if negative_step: * start = shape - 1 # <<<<<<<<<<<<<< * else: * start = 0 / __pyx_v_start = (__pyx_v_shape - 1); / "View.MemoryView":852 * start = shape * else: * if negative_step: # <<<<<<<<<<<<<< * start = shape - 1 * else: / goto __pyx_L15; } / "View.MemoryView":855 * start = shape - 1 * else: * start = 0 # <<<<<<<<<<<<<< * * if have_stop: / 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memoryview_copy(memoryview memview): # <<<<<<<<<<<<<< * "Create a new memoryview object" * cdef __Pyx_memviewslice memviewslice / / function exit code / __pyx_L1_error:; __Pyx_XDECREF(__pyx_t_1); __Pyx_AddTraceback("View.MemoryView.memoryview_copy", __pyx_clineno, __pyx_lineno, __pyx_filename); __pyx_r = 0; __pyx_L0:; __Pyx_XGIVEREF(__pyx_r); __Pyx_RefNannyFinishContext(); return __pyx_r; } / "View.MemoryView":1087 * * @cname('__pyx_memoryview_copy_object_from_slice') * cdef memoryview_copy_from_slice(memoryview memview, __Pyx_memviewslice memviewslice): # <<<<<<<<<<<<<< """ * Create a new memoryview object from a given memoryview object and slice. / static PyObject __pyx_memoryview_copy_object_from_slice(struct __pyx_memoryview_obj __pyx_v_memview, __Pyx_memviewslice __pyx_v_memviewslice) { PyObject (__pyx_v_to_object_func)(char ); int (__pyx_v_to_dtype_func)(char , PyObject ); PyObject __pyx_r = NULL; __Pyx_RefNannyDeclarations int __pyx_t_1; int __pyx_t_2; PyObject (__pyx_t_3)(char 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code / __pyx_L1_error:; __Pyx_XDECREF(__pyx_t_5); __Pyx_AddTraceback("View.MemoryView.memoryview_copy_from_slice", __pyx_clineno, __pyx_lineno, __pyx_filename); __pyx_r = 0; __pyx_L0:; __Pyx_XGIVEREF(__pyx_r); __Pyx_RefNannyFinishContext(); return __pyx_r; } / "View.MemoryView":1109 * * * cdef Py_ssize_t abs_py_ssize_t(Py_ssize_t arg) nogil: # <<<<<<<<<<<<<< * if arg < 0: * return -arg / static Py_ssize_t abs_py_ssize_t(Py_ssize_t __pyx_v_arg) { Py_ssize_t __pyx_r; int __pyx_t_1; / "View.MemoryView":1110 * * cdef Py_ssize_t abs_py_ssize_t(Py_ssize_t arg) nogil: * if arg < 0: # <<<<<<<<<<<<<< * return -arg * else: / __pyx_t_1 = ((__pyx_v_arg < 0) != 0); if (__pyx_t_1) { / "View.MemoryView":1111 * cdef Py_ssize_t abs_py_ssize_t(Py_ssize_t arg) nogil: * if arg < 0: * return -arg # <<<<<<<<<<<<<< * else: * return arg / __pyx_r = (-__pyx_v_arg); goto __pyx_L0; / "View.MemoryView":1110 * * cdef Py_ssize_t abs_py_ssize_t(Py_ssize_t arg) nogil: * if arg < 0: # <<<<<<<<<<<<<< * return -arg * else: / } / "View.MemoryView":1113 * return -arg * else: * return arg # <<<<<<<<<<<<<< * * @cname('__pyx_get_best_slice_order') / /else/ { __pyx_r = __pyx_v_arg; goto __pyx_L0; } / "View.MemoryView":1109 * * * cdef Py_ssize_t abs_py_ssize_t(Py_ssize_t arg) nogil: # <<<<<<<<<<<<<< * if arg < 0: * return -arg / / function exit code / __pyx_L0:; return __pyx_r; } / "View.MemoryView":1116 * * @cname('__pyx_get_best_slice_order') * cdef char get_best_order(__Pyx_memviewslice mslice, int ndim) nogil: # <<<<<<<<<<<<<< """ * Figure out the best memory access order for a given slice. / static char __pyx_get_best_slice_order(__Pyx_memviewslice __pyx_v_mslice, int __pyx_v_ndim) { int __pyx_v_i; Py_ssize_t __pyx_v_c_stride; Py_ssize_t __pyx_v_f_stride; char __pyx_r; int __pyx_t_1; int __pyx_t_2; int __pyx_t_3; int __pyx_t_4; /* "View.MemoryView":1121 * """ * cdef int i * cdef Py_ssize_t c_stride = 0 # <<<<<<<<<<<<<< * cdef Py_ssize_t f_stride = 0 * / __pyx_v_c_stride = 0; / "View.MemoryView":1122 * cdef int i * cdef Py_ssize_t c_stride = 0 * cdef Py_ssize_t f_stride = 0 # <<<<<<<<<<<<<< * * for i in range(ndim - 1, -1, -1): / __pyx_v_f_stride = 0; / "View.MemoryView":1124 * cdef Py_ssize_t f_stride = 0 * * for i in range(ndim - 1, -1, -1): # <<<<<<<<<<<<<< * if mslice.shape[i] > 1: * c_stride = mslice.strides[i] / for (__pyx_t_1 = (__pyx_v_ndim - 1); __pyx_t_1 > -1; __pyx_t_1-=1) { __pyx_v_i = __pyx_t_1; / "View.MemoryView":1125 * * for i in range(ndim - 1, -1, -1): * if mslice.shape[i] > 1: # <<<<<<<<<<<<<< * c_stride = mslice.strides[i] * break / __pyx_t_2 = (((__pyx_v_mslice->shape[__pyx_v_i]) > 1) != 0); if (__pyx_t_2) { / "View.MemoryView":1126 * for i in range(ndim - 1, -1, -1): * if mslice.shape[i] > 1: * c_stride = mslice.strides[i] # <<<<<<<<<<<<<< * break * / __pyx_v_c_stride = (__pyx_v_mslice->strides[__pyx_v_i]); / "View.MemoryView":1127 * if mslice.shape[i] > 1: * c_stride = mslice.strides[i] * break # <<<<<<<<<<<<<< * * for i in range(ndim): / goto __pyx_L4_break; / "View.MemoryView":1125 * * for i in range(ndim - 1, -1, -1): * if mslice.shape[i] > 1: # <<<<<<<<<<<<<< * c_stride = mslice.strides[i] * break / } } __pyx_L4_break:; / "View.MemoryView":1129 * break * * for i in range(ndim): # <<<<<<<<<<<<<< * if mslice.shape[i] > 1: * f_stride = mslice.strides[i] / __pyx_t_1 = __pyx_v_ndim; __pyx_t_3 = __pyx_t_1; for (__pyx_t_4 = 0; __pyx_t_4 < __pyx_t_3; __pyx_t_4+=1) { __pyx_v_i = __pyx_t_4; / "View.MemoryView":1130 * * for i in range(ndim): * if mslice.shape[i] > 1: # <<<<<<<<<<<<<< * f_stride = mslice.strides[i] * break / __pyx_t_2 = (((__pyx_v_mslice->shape[__pyx_v_i]) > 1) != 0); if (__pyx_t_2) { / "View.MemoryView":1131 * for i in range(ndim): * if mslice.shape[i] > 1: * f_stride = mslice.strides[i] # <<<<<<<<<<<<<< * break * / __pyx_v_f_stride = (__pyx_v_mslice->strides[__pyx_v_i]); / "View.MemoryView":1132 * if mslice.shape[i] > 1: * f_stride = mslice.strides[i] * break # <<<<<<<<<<<<<< * * if abs_py_ssize_t(c_stride) <= abs_py_ssize_t(f_stride): / goto __pyx_L7_break; / "View.MemoryView":1130 * * for i in range(ndim): * if mslice.shape[i] > 1: # <<<<<<<<<<<<<< * f_stride = mslice.strides[i] * break / } } __pyx_L7_break:; / "View.MemoryView":1134 * break * * if abs_py_ssize_t(c_stride) <= abs_py_ssize_t(f_stride): # <<<<<<<<<<<<<< * return 'C' * else: / __pyx_t_2 = ((abs_py_ssize_t(__pyx_v_c_stride) <= abs_py_ssize_t(__pyx_v_f_stride)) != 0); if (__pyx_t_2) { / "View.MemoryView":1135 * * if abs_py_ssize_t(c_stride) <= abs_py_ssize_t(f_stride): * return 'C' # <<<<<<<<<<<<<< * else: * return 'F' / __pyx_r = 'C'; goto __pyx_L0; / "View.MemoryView":1134 * break * * if abs_py_ssize_t(c_stride) <= abs_py_ssize_t(f_stride): # <<<<<<<<<<<<<< * return 'C' * else: / } / "View.MemoryView":1137 * return 'C' * else: * return 'F' # <<<<<<<<<<<<<< * * @cython.cdivision(True) / /else/ { __pyx_r = 'F'; goto __pyx_L0; } / "View.MemoryView":1116 * * @cname('__pyx_get_best_slice_order') * cdef char get_best_order(__Pyx_memviewslice mslice, int ndim) nogil: # <<<<<<<<<<<<<< """ * Figure out the best memory access order for a given slice. / / function exit code / __pyx_L0:; return __pyx_r; } / "View.MemoryView":1140 * * @cython.cdivision(True) * cdef void _copy_strided_to_strided(char src_data, Py_ssize_t src_strides, # <<<<<<<<<<<<<< * char dst_data, Py_ssize_t dst_strides, * Py_ssize_t src_shape, Py_ssize_t dst_shape, / static void _copy_strided_to_strided(char __pyx_v_src_data, Py_ssize_t __pyx_v_src_strides, char __pyx_v_dst_data, Py_ssize_t __pyx_v_dst_strides, Py_ssize_t __pyx_v_src_shape, Py_ssize_t __pyx_v_dst_shape, int __pyx_v_ndim, size_t __pyx_v_itemsize) { CYTHON_UNUSED Py_ssize_t __pyx_v_i; CYTHON_UNUSED Py_ssize_t __pyx_v_src_extent; Py_ssize_t __pyx_v_dst_extent; Py_ssize_t __pyx_v_src_stride; Py_ssize_t __pyx_v_dst_stride; int __pyx_t_1; int __pyx_t_2; int __pyx_t_3; Py_ssize_t __pyx_t_4; Py_ssize_t __pyx_t_5; Py_ssize_t __pyx_t_6; / "View.MemoryView":1147 * * cdef Py_ssize_t i * cdef Py_ssize_t src_extent = src_shape[0] # <<<<<<<<<<<<<< * cdef Py_ssize_t dst_extent = dst_shape[0] * cdef Py_ssize_t src_stride = src_strides[0] / __pyx_v_src_extent = (__pyx_v_src_shape[0]); / "View.MemoryView":1148 * cdef Py_ssize_t i * cdef Py_ssize_t src_extent = src_shape[0] * cdef Py_ssize_t dst_extent = dst_shape[0] # <<<<<<<<<<<<<< * cdef Py_ssize_t src_stride = src_strides[0] * cdef Py_ssize_t dst_stride = dst_strides[0] / __pyx_v_dst_extent = (__pyx_v_dst_shape[0]); / "View.MemoryView":1149 * cdef Py_ssize_t src_extent = src_shape[0] * cdef Py_ssize_t dst_extent = dst_shape[0] * cdef Py_ssize_t src_stride = src_strides[0] # <<<<<<<<<<<<<< * cdef Py_ssize_t dst_stride = dst_strides[0] * / __pyx_v_src_stride = (__pyx_v_src_strides[0]); / "View.MemoryView":1150 * cdef Py_ssize_t dst_extent = dst_shape[0] * cdef Py_ssize_t src_stride = src_strides[0] * cdef Py_ssize_t dst_stride = dst_strides[0] # <<<<<<<<<<<<<< * * if ndim == 1: / __pyx_v_dst_stride = (__pyx_v_dst_strides[0]); / "View.MemoryView":1152 * cdef Py_ssize_t dst_stride = dst_strides[0] * * if ndim == 1: # <<<<<<<<<<<<<< * if (src_stride > 0 and dst_stride > 0 and * <size_t> src_stride == itemsize == <size_t> dst_stride): / __pyx_t_1 = ((__pyx_v_ndim == 1) != 0); if (__pyx_t_1) { / "View.MemoryView":1153 * * if ndim == 1: * if (src_stride > 0 and dst_stride > 0 and # <<<<<<<<<<<<<< * <size_t> src_stride == itemsize == <size_t> dst_stride): * memcpy(dst_data, src_data, itemsize * dst_extent) / __pyx_t_2 = ((__pyx_v_src_stride > 0) != 0); if (__pyx_t_2) { } else { __pyx_t_1 = __pyx_t_2; goto __pyx_L5_bool_binop_done; } __pyx_t_2 = ((__pyx_v_dst_stride > 0) != 0); if (__pyx_t_2) { } else { __pyx_t_1 = __pyx_t_2; goto __pyx_L5_bool_binop_done; } / "View.MemoryView":1154 * if ndim == 1: * if (src_stride > 0 and dst_stride > 0 and * <size_t> src_stride == itemsize == <size_t> dst_stride): # <<<<<<<<<<<<<< * memcpy(dst_data, src_data, itemsize * dst_extent) * else: / __pyx_t_2 = (((size_t)__pyx_v_src_stride) == __pyx_v_itemsize); if (__pyx_t_2) { __pyx_t_2 = (__pyx_v_itemsize == ((size_t)__pyx_v_dst_stride)); } __pyx_t_3 = (__pyx_t_2 != 0); __pyx_t_1 = __pyx_t_3; __pyx_L5_bool_binop_done:; / "View.MemoryView":1153 * * if ndim == 1: * if (src_stride > 0 and dst_stride > 0 and # <<<<<<<<<<<<<< * <size_t> src_stride == itemsize == <size_t> dst_stride): * memcpy(dst_data, src_data, itemsize * dst_extent) / if (__pyx_t_1) { / "View.MemoryView":1155 * if (src_stride > 0 and dst_stride > 0 and * <size_t> src_stride == itemsize == <size_t> dst_stride): * memcpy(dst_data, src_data, itemsize * dst_extent) # <<<<<<<<<<<<<< * else: * for i in range(dst_extent): / (void)(memcpy(__pyx_v_dst_data, __pyx_v_src_data, (__pyx_v_itemsize __pyx_v_dst_extent))); /* "View.MemoryView":1153 * * if ndim == 1: * if (src_stride > 0 and dst_stride > 0 and # <<<<<<<<<<<<<< * <size_t> src_stride == itemsize == <size_t> dst_stride): * memcpy(dst_data, src_data, itemsize * dst_extent) / goto 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__pyx_empty_tuple, 0); } if (unlikely(!o)) return 0; p = ((struct __pyx_MemviewEnum_obj )o); p->name = Py_None; Py_INCREF(Py_None); return o; } static void __pyx_tp_dealloc_Enum(PyObject o) { struct __pyx_MemviewEnum_obj p = (struct __pyx_MemviewEnum_obj )o; #if CYTHON_USE_TP_FINALIZE if (unlikely(PyType_HasFeature(Py_TYPE(o), Py_TPFLAGS_HAVE_FINALIZE) && Py_TYPE(o)->tp_finalize) && !_PyGC_FINALIZED(o)) { if (PyObject_CallFinalizerFromDealloc(o)) return; } #endif PyObject_GC_UnTrack(o); Py_CLEAR(p->name); (Py_TYPE(o)->tp_free)(o); } static int __pyx_tp_traverse_Enum(PyObject o, visitproc v, void a) { int e; struct __pyx_MemviewEnum_obj p = (struct __pyx_MemviewEnum_obj )o; if (p->name) { e = (v)(p->name, a); if (e) return e; } return 0; } static int __pyx_tp_clear_Enum(PyObject o) { PyObject* tmp; struct __pyx_MemviewEnum_obj p = (struct __pyx_MemviewEnum_obj )o; tmp = ((PyObject)p->name); p->name = Py_None; Py_INCREF(Py_None); Py_XDECREF(tmp); return 0; } static PyMethodDef __pyx_methods_Enum[] = { {"__reduce_cython__", (PyCFunction)__pyx_pw___pyx_MemviewEnum_1__reduce_cython__, METH_NOARGS, 0}, {"__setstate_cython__", (PyCFunction)__pyx_pw___pyx_MemviewEnum_3__setstate_cython__, METH_O, 0}, {0, 0, 0, 0} }; static PyTypeObject __pyx_type___pyx_MemviewEnum = { PyVarObject_HEAD_INIT(0, 0) "shakemap.c.clib.Enum", /tp_name/ sizeof(struct __pyx_MemviewEnum_obj), /tp_basicsize/ 0, /tp_itemsize/ __pyx_tp_dealloc_Enum, /tp_dealloc/ #if PY_VERSION_HEX < 0x030800b4 0, /tp_print/ #endif #if PY_VERSION_HEX >= 0x030800b4 0, /tp_vectorcall_offset/ #endif 0, /tp_getattr/ 0, /tp_setattr/ #if PY_MAJOR_VERSION < 3 0, /tp_compare/ #endif #if PY_MAJOR_VERSION >= 3 0, /tp_as_async/ #endif __pyx_MemviewEnum___repr__, /tp_repr/ 0, /tp_as_number/ 0, /tp_as_sequence/ 0, /tp_as_mapping/ 0, /tp_hash/ 0, /tp_call/ 0, /tp_str/ 0, /tp_getattro/ 0, /tp_setattro/ 0, /tp_as_buffer/ Py_TPFLAGS_DEFAULT\|Py_TPFLAGS_HAVE_VERSION_TAG\|Py_TPFLAGS_CHECKTYPES\|Py_TPFLAGS_HAVE_NEWBUFFER\|Py_TPFLAGS_BASETYPE\|Py_TPFLAGS_HAVE_GC, /tp_flags/ 0, /tp_doc/ __pyx_tp_traverse_Enum, /tp_traverse/ __pyx_tp_clear_Enum, /tp_clear/ 0, /tp_richcompare/ 0, /tp_weaklistoffset/ 0, /tp_iter/ 0, /tp_iternext/ __pyx_methods_Enum, /tp_methods/ 0, /tp_members/ 0, /tp_getset/ 0, /tp_base/ 0, /tp_dict/ 0, /tp_descr_get/ 0, /tp_descr_set/ 0, /tp_dictoffset/ __pyx_MemviewEnum___init__, /tp_init/ 0, /tp_alloc/ __pyx_tp_new_Enum, /tp_new/ 0, /tp_free/ 0, /tp_is_gc/ 0, /tp_bases/ 0, /tp_mro/ 0, /tp_cache/ 0, /tp_subclasses/ 0, /tp_weaklist/ 0, /tp_del/ 0, /tp_version_tag/ #if PY_VERSION_HEX >= 0x030400a1 0, /tp_finalize/ #endif #if PY_VERSION_HEX >= 0x030800b1 0, /tp_vectorcall/ #endif #if PY_VERSION_HEX >= 0x030800b4 && PY_VERSION_HEX < 0x03090000 0, /tp_print/ #endif #if PY_VERSION_HEX >= 0x030B00A2 0, /tp_inline_values_offset/ #endif }; static struct __pyx_vtabstruct_memoryview __pyx_vtable_memoryview; static PyObject __pyx_tp_new_memoryview(PyTypeObject t, PyObject a, PyObject k) { struct __pyx_memoryview_obj p; PyObject o; if (likely((t->tp_flags & Py_TPFLAGS_IS_ABSTRACT) == 0)) { o = (t->tp_alloc)(t, 0); } else { o = (PyObject ) PyBaseObject_Type.tp_new(t, __pyx_empty_tuple, 0); } if (unlikely(!o)) return 0; p = ((struct __pyx_memoryview_obj )o); p->__pyx_vtab = __pyx_vtabptr_memoryview; p->obj = Py_None; Py_INCREF(Py_None); p->_size = Py_None; Py_INCREF(Py_None); p->_array_interface = Py_None; Py_INCREF(Py_None); p->view.obj = NULL; if (unlikely(__pyx_memoryview___cinit__(o, a, k) < 0)) goto bad; return o; bad: Py_DECREF(o); o = 0; return NULL; } static void __pyx_tp_dealloc_memoryview(PyObject o) { struct __pyx_memoryview_obj p = (struct __pyx_memoryview_obj )o; #if CYTHON_USE_TP_FINALIZE if (unlikely(PyType_HasFeature(Py_TYPE(o), Py_TPFLAGS_HAVE_FINALIZE) && Py_TYPE(o)->tp_finalize) && !_PyGC_FINALIZED(o)) { if (PyObject_CallFinalizerFromDealloc(o)) return; } #endif PyObject_GC_UnTrack(o); { PyObject etype, eval, etb; PyErr_Fetch(&etype, &eval, &etb); __Pyx_SET_REFCNT(o, Py_REFCNT(o) + 1); __pyx_memoryview___dealloc__(o); __Pyx_SET_REFCNT(o, Py_REFCNT(o) - 1); PyErr_Restore(etype, eval, etb); } Py_CLEAR(p->obj); Py_CLEAR(p->_size); Py_CLEAR(p->_array_interface); (Py_TYPE(o)->tp_free)(o); } static int __pyx_tp_traverse_memoryview(PyObject o, visitproc v, void a) { int e; struct __pyx_memoryview_obj p = (struct __pyx_memoryview_obj )o; if (p->obj) { e = (v)(p->obj, a); if (e) return e; } if (p->_size) { e = (v)(p->_size, a); if (e) return e; } if (p->_array_interface) { e = (v)(p->_array_interface, a); if (e) return e; } if (p->view.obj) { e = (v)(p->view.obj, a); if (e) return e; } return 0; } static int __pyx_tp_clear_memoryview(PyObject o) { PyObject* tmp; struct __pyx_memoryview_obj p = (struct __pyx_memoryview_obj )o; tmp = ((PyObject)p->obj); p->obj = Py_None; Py_INCREF(Py_None); Py_XDECREF(tmp); tmp = ((PyObject)p->_size); 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PyObject __pyx_getprop___pyx_memoryview_shape(PyObject o, CYTHON_UNUSED void x) { return __pyx_pw_15View_dot_MemoryView_10memoryview_5shape_1__get__(o); } static PyObject __pyx_getprop___pyx_memoryview_strides(PyObject o, CYTHON_UNUSED void x) { return __pyx_pw_15View_dot_MemoryView_10memoryview_7strides_1__get__(o); } static PyObject __pyx_getprop___pyx_memoryview_suboffsets(PyObject o, CYTHON_UNUSED void x) { return __pyx_pw_15View_dot_MemoryView_10memoryview_10suboffsets_1__get__(o); } static PyObject __pyx_getprop___pyx_memoryview_ndim(PyObject o, CYTHON_UNUSED void x) { return __pyx_pw_15View_dot_MemoryView_10memoryview_4ndim_1__get__(o); } static PyObject __pyx_getprop___pyx_memoryview_itemsize(PyObject o, CYTHON_UNUSED void x) { return __pyx_pw_15View_dot_MemoryView_10memoryview_8itemsize_1__get__(o); } static PyObject __pyx_getprop___pyx_memoryview_nbytes(PyObject o, CYTHON_UNUSED void x) { return __pyx_pw_15View_dot_MemoryView_10memoryview_6nbytes_1__get__(o); } static 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"" : "s", num_found); } / RaiseDoubleKeywords / static void __Pyx_RaiseDoubleKeywordsError( const char func_name, PyObject* kw_name) { PyErr_Format(PyExc_TypeError, #if PY_MAJOR_VERSION >= 3 "%s() got multiple values for keyword argument '%U'", func_name, kw_name); #else "%s() got multiple values for keyword argument '%s'", func_name, PyString_AsString(kw_name)); #endif } /* ParseKeywords / static int __Pyx_ParseOptionalKeywords( PyObject kwds, PyObject *argnames[], PyObject kwds2, PyObject values[], Py_ssize_t num_pos_args, const char function_name) { PyObject key = 0, value = 0; Py_ssize_t pos = 0; PyObject* name; PyObject* first_kw_arg = argnames + num_pos_args; while (PyDict_Next(kwds, &pos, &key, &value)) { name = first_kw_arg; while (name && (name != key)) name++; if (name) { values[name-argnames] = value; continue; } name = first_kw_arg; #if PY_MAJOR_VERSION < 3 if (likely(PyString_Check(key))) { while (name) { if ((CYTHON_COMPILING_IN_PYPY \|\| PyString_GET_SIZE(name) == PyString_GET_SIZE(key)) && _PyString_Eq(name, key)) { values[name-argnames] = value; break; } name++; } if (name) continue; else { PyObject* argname = argnames; while (argname != first_kw_arg) { if ((argname == key) \|\| ( (CYTHON_COMPILING_IN_PYPY \|\| PyString_GET_SIZE(argname) == PyString_GET_SIZE(key)) && _PyString_Eq(argname, key))) { goto arg_passed_twice; } argname++; } } } else #endif if (likely(PyUnicode_Check(key))) { while (name) { int cmp = (name == key) ? 0 : #if !CYTHON_COMPILING_IN_PYPY && PY_MAJOR_VERSION >= 3 (__Pyx_PyUnicode_GET_LENGTH(name) != __Pyx_PyUnicode_GET_LENGTH(key)) ? 1 : #endif PyUnicode_Compare(name, key); if (cmp < 0 && unlikely(PyErr_Occurred())) goto bad; if (cmp == 0) { values[name-argnames] = value; break; } name++; } if (name) continue; else { PyObject* argname = argnames; while (argname != first_kw_arg) { int cmp = (argname == key) ? 0 : #if !CYTHON_COMPILING_IN_PYPY && PY_MAJOR_VERSION >= 3 (__Pyx_PyUnicode_GET_LENGTH(argname) != __Pyx_PyUnicode_GET_LENGTH(key)) ? 1 : #endif PyUnicode_Compare(argname, key); if (cmp < 0 && unlikely(PyErr_Occurred())) goto bad; if (cmp == 0) goto arg_passed_twice; argname++; } } } else goto invalid_keyword_type; if (kwds2) { if (unlikely(PyDict_SetItem(kwds2, key, value))) goto bad; } else { goto invalid_keyword; } } return 0; arg_passed_twice: __Pyx_RaiseDoubleKeywordsError(function_name, key); goto bad; invalid_keyword_type: PyErr_Format(PyExc_TypeError, "%.200s() keywords must be strings", function_name); goto bad; invalid_keyword: PyErr_Format(PyExc_TypeError, #if PY_MAJOR_VERSION < 3 "%.200s() got an unexpected keyword argument '%.200s'", function_name, PyString_AsString(key)); #else "%s() got an unexpected keyword argument '%U'", function_name, key); #endif bad: return -1; } /* MemviewSliceInit / static int __Pyx_init_memviewslice(struct __pyx_memoryview_obj memview, int ndim, __Pyx_memviewslice memviewslice, int memview_is_new_reference) { __Pyx_RefNannyDeclarations int i, retval=-1; Py_buffer buf = &memview->view; __Pyx_RefNannySetupContext("init_memviewslice", 0); if (unlikely(memviewslice->memview \|\| memviewslice->data)) { PyErr_SetString(PyExc_ValueError, "memviewslice is already initialized!"); goto fail; } if (buf->strides) { for (i = 0; i < ndim; i++) { memviewslice->strides[i] = buf->strides[i]; } } else { Py_ssize_t stride = buf->itemsize; for (i = ndim - 1; i >= 0; i--) { memviewslice->strides[i] = stride; stride = buf->shape[i]; } } for (i = 0; i < ndim; i++) { memviewslice->shape[i] = buf->shape[i]; if (buf->suboffsets) { memviewslice->suboffsets[i] = buf->suboffsets[i]; } else { memviewslice->suboffsets[i] = -1; } } memviewslice->memview = memview; memviewslice->data = (char )buf->buf; if (__pyx_add_acquisition_count(memview) == 0 && !memview_is_new_reference) { Py_INCREF(memview); } retval = 0; goto no_fail; fail: memviewslice->memview = 0; memviewslice->data = 0; retval = -1; no_fail: __Pyx_RefNannyFinishContext(); return retval; } #ifndef Py_NO_RETURN #define Py_NO_RETURN #endif static void __pyx_fatalerror(const char fmt, ...) Py_NO_RETURN { va_list vargs; char msg[200]; #ifdef HAVE_STDARG_PROTOTYPES va_start(vargs, fmt); #else va_start(vargs); #endif vsnprintf(msg, 200, fmt, vargs); va_end(vargs); Py_FatalError(msg); } static CYTHON_INLINE int __pyx_add_acquisition_count_locked(__pyx_atomic_int acquisition_count, PyThread_type_lock lock) { int result; PyThread_acquire_lock(lock, 1); result = (acquisition_count)++; PyThread_release_lock(lock); return result; } static CYTHON_INLINE int __pyx_sub_acquisition_count_locked(__pyx_atomic_int acquisition_count, PyThread_type_lock lock) { int result; PyThread_acquire_lock(lock, 1); result = (acquisition_count)--; PyThread_release_lock(lock); return result; } static CYTHON_INLINE void __Pyx_INC_MEMVIEW(__Pyx_memviewslice memslice, int have_gil, int lineno) { int first_time; struct __pyx_memoryview_obj memview = memslice->memview; if (unlikely(!memview \|\| (PyObject ) memview == Py_None)) return; if (unlikely(__pyx_get_slice_count(memview) < 0)) __pyx_fatalerror("Acquisition count is %d (line %d)", __pyx_get_slice_count(memview), lineno); first_time = __pyx_add_acquisition_count(memview) == 0; if (unlikely(first_time)) { if (have_gil) { Py_INCREF((PyObject ) memview); } else { PyGILState_STATE _gilstate = PyGILState_Ensure(); Py_INCREF((PyObject ) memview); PyGILState_Release(_gilstate); } } } static CYTHON_INLINE void __Pyx_XDEC_MEMVIEW(__Pyx_memviewslice memslice, int have_gil, int lineno) { int last_time; struct __pyx_memoryview_obj memview = memslice->memview; if (unlikely(!memview \|\| (PyObject ) memview == Py_None)) { memslice->memview = NULL; return; } if (unlikely(__pyx_get_slice_count(memview) <= 0)) __pyx_fatalerror("Acquisition count is %d (line %d)", __pyx_get_slice_count(memview), lineno); last_time = __pyx_sub_acquisition_count(memview) == 1; memslice->data = NULL; if (unlikely(last_time)) { if (have_gil) { Py_CLEAR(memslice->memview); } else { PyGILState_STATE _gilstate = PyGILState_Ensure(); Py_CLEAR(memslice->memview); PyGILState_Release(_gilstate); } } else { memslice->memview = NULL; } } / ArgTypeTest / static int __Pyx__ArgTypeTest(PyObject obj, PyTypeObject type, const char name, int exact) { if (unlikely(!type)) { PyErr_SetString(PyExc_SystemError, "Missing type object"); return 0; } else if (exact) { #if PY_MAJOR_VERSION == 2 if ((type == &PyBaseString_Type) && likely(__Pyx_PyBaseString_CheckExact(obj))) return 1; #endif } else { if (likely(__Pyx_TypeCheck(obj, type))) return 1; } PyErr_Format(PyExc_TypeError, "Argument '%.200s' has incorrect type (expected %.200s, got %.200s)", name, type->tp_name, Py_TYPE(obj)->tp_name); return 0; } /* PyObjectCall / #if CYTHON_COMPILING_IN_CPYTHON static CYTHON_INLINE PyObject __Pyx_PyObject_Call(PyObject func, PyObject arg, PyObject kw) { PyObject result; ternaryfunc call = Py_TYPE(func)->tp_call; if (unlikely(!call)) return PyObject_Call(func, arg, kw); if (unlikely(Py_EnterRecursiveCall((char)" while calling a Python object"))) return NULL; result = (call)(func, arg, kw); Py_LeaveRecursiveCall(); if (unlikely(!result) && unlikely(!PyErr_Occurred())) { PyErr_SetString( PyExc_SystemError, "NULL result without error in PyObject_Call"); } return result; } #endif /* PyErrFetchRestore / #if CYTHON_FAST_THREAD_STATE static CYTHON_INLINE void __Pyx_ErrRestoreInState(PyThreadState tstate, PyObject type, PyObject value, PyObject tb) { PyObject tmp_type, tmp_value, tmp_tb; tmp_type = tstate->curexc_type; tmp_value = tstate->curexc_value; tmp_tb = tstate->curexc_traceback; tstate->curexc_type = type; tstate->curexc_value = value; tstate->curexc_traceback = tb; Py_XDECREF(tmp_type); Py_XDECREF(tmp_value); Py_XDECREF(tmp_tb); } static CYTHON_INLINE void __Pyx_ErrFetchInState(PyThreadState tstate, PyObject type, PyObject value, PyObject tb) { type = tstate->curexc_type; value = tstate->curexc_value; tb = tstate->curexc_traceback; tstate->curexc_type = 0; tstate->curexc_value = 0; tstate->curexc_traceback = 0; } #endif /* RaiseException / #if PY_MAJOR_VERSION < 3 static void __Pyx_Raise(PyObject type, PyObject value, PyObject tb, CYTHON_UNUSED PyObject cause) { __Pyx_PyThreadState_declare Py_XINCREF(type); if (!value \|\| value == Py_None) value = NULL; else Py_INCREF(value); if (!tb \|\| tb == Py_None) tb = NULL; else { Py_INCREF(tb); if (!PyTraceBack_Check(tb)) { PyErr_SetString(PyExc_TypeError, "raise: arg 3 must be a traceback or None"); goto raise_error; } } if (PyType_Check(type)) { #if CYTHON_COMPILING_IN_PYPY if (!value) { Py_INCREF(Py_None); value = Py_None; } #endif PyErr_NormalizeException(&type, &value, &tb); } else { if (value) { PyErr_SetString(PyExc_TypeError, "instance exception may not have a separate value"); goto raise_error; } value = type; type = (PyObject) Py_TYPE(type); Py_INCREF(type); if (!PyType_IsSubtype((PyTypeObject )type, (PyTypeObject )PyExc_BaseException)) { PyErr_SetString(PyExc_TypeError, "raise: exception class must be a subclass of BaseException"); goto raise_error; } } __Pyx_PyThreadState_assign __Pyx_ErrRestore(type, value, tb); return; raise_error: Py_XDECREF(value); Py_XDECREF(type); Py_XDECREF(tb); return; } #else static void __Pyx_Raise(PyObject type, PyObject value, PyObject tb, PyObject cause) { PyObject* owned_instance = NULL; if (tb == Py_None) { tb = 0; } else if (tb && !PyTraceBack_Check(tb)) { PyErr_SetString(PyExc_TypeError, "raise: arg 3 must be a traceback or None"); goto bad; } if (value == Py_None) value = 0; if (PyExceptionInstance_Check(type)) { if (value) { PyErr_SetString(PyExc_TypeError, "instance exception may not have a separate value"); goto bad; } value = type; type = (PyObject) Py_TYPE(value); } else if (PyExceptionClass_Check(type)) { PyObject instance_class = NULL; if (value && PyExceptionInstance_Check(value)) { instance_class = (PyObject) Py_TYPE(value); if (instance_class != type) { int is_subclass = PyObject_IsSubclass(instance_class, type); if (!is_subclass) { instance_class = NULL; } else if (unlikely(is_subclass == -1)) { goto bad; } else { type = instance_class; } } } if (!instance_class) { PyObject args; if (!value) args = PyTuple_New(0); else if (PyTuple_Check(value)) { Py_INCREF(value); args = value; } else args = PyTuple_Pack(1, value); if (!args) goto bad; owned_instance = PyObject_Call(type, args, NULL); Py_DECREF(args); if (!owned_instance) goto bad; value = owned_instance; if (!PyExceptionInstance_Check(value)) { PyErr_Format(PyExc_TypeError, "calling %R should have returned an instance of " "BaseException, not %R", type, Py_TYPE(value)); goto bad; } } } else { PyErr_SetString(PyExc_TypeError, "raise: exception class must be a subclass of BaseException"); goto bad; } if (cause) { PyObject fixed_cause; if (cause == Py_None) { fixed_cause = NULL; } else if (PyExceptionClass_Check(cause)) { fixed_cause = PyObject_CallObject(cause, NULL); if (fixed_cause == NULL) goto bad; } else if (PyExceptionInstance_Check(cause)) { fixed_cause = cause; Py_INCREF(fixed_cause); } else { PyErr_SetString(PyExc_TypeError, "exception causes must derive from " "BaseException"); goto bad; } PyException_SetCause(value, fixed_cause); } PyErr_SetObject(type, value); if (tb) { #if CYTHON_COMPILING_IN_PYPY PyObject tmp_type, tmp_value, tmp_tb; PyErr_Fetch(&tmp_type, &tmp_value, &tmp_tb); Py_INCREF(tb); PyErr_Restore(tmp_type, tmp_value, tb); Py_XDECREF(tmp_tb); #else PyThreadState tstate = __Pyx_PyThreadState_Current; PyObject tmp_tb = tstate->curexc_traceback; if (tb != tmp_tb) { Py_INCREF(tb); tstate->curexc_traceback = tb; Py_XDECREF(tmp_tb); } #endif } bad: Py_XDECREF(owned_instance); return; } #endif /* PyCFunctionFastCall / #if CYTHON_FAST_PYCCALL static CYTHON_INLINE PyObject __Pyx_PyCFunction_FastCall(PyObject func_obj, PyObject args, Py_ssize_t nargs) { PyCFunctionObject func = (PyCFunctionObject)func_obj; PyCFunction meth = PyCFunction_GET_FUNCTION(func); PyObject self = PyCFunction_GET_SELF(func); int flags = PyCFunction_GET_FLAGS(func); assert(PyCFunction_Check(func)); assert(METH_FASTCALL == (flags & ~(METH_CLASS \| METH_STATIC \| METH_COEXIST \| METH_KEYWORDS \| METH_STACKLESS))); assert(nargs >= 0); assert(nargs == 0 \|\| args != NULL); /* _PyCFunction_FastCallDict() must not be called with an exception set, because it may clear it (directly or indirectly) and so the caller loses its exception / assert(!PyErr_Occurred()); if ((PY_VERSION_HEX < 0x030700A0) \|\| unlikely(flags & METH_KEYWORDS)) { return (((__Pyx_PyCFunctionFastWithKeywords)(void)meth)) (self, args, nargs, NULL); } else { return (((__Pyx_PyCFunctionFast)(void)meth)) (self, args, nargs); } } #endif / PyFunctionFastCall / #if CYTHON_FAST_PYCALL static PyObject __Pyx_PyFunction_FastCallNoKw(PyCodeObject co, PyObject args, Py_ssize_t na, PyObject globals) { PyFrameObject f; PyThreadState tstate = __Pyx_PyThreadState_Current; PyObject *fastlocals; Py_ssize_t i; PyObject result; assert(globals != NULL); /* XXX Perhaps we should create a specialized PyFrame_New() that doesn't take locals, but does take builtins without sanity checking them. / assert(tstate != NULL); f = PyFrame_New(tstate, co, globals, NULL); if (f == NULL) { return NULL; } fastlocals = __Pyx_PyFrame_GetLocalsplus(f); for (i = 0; i < na; i++) { Py_INCREF(args); fastlocals[i] = args++; } result = PyEval_EvalFrameEx(f,0); ++tstate->recursion_depth; Py_DECREF(f); --tstate->recursion_depth; return result; } #if 1 \|\| PY_VERSION_HEX < 0x030600B1 static PyObject __Pyx_PyFunction_FastCallDict(PyObject func, PyObject args, Py_ssize_t nargs, PyObject kwargs) { PyCodeObject co = (PyCodeObject )PyFunction_GET_CODE(func); PyObject globals = PyFunction_GET_GLOBALS(func); PyObject argdefs = PyFunction_GET_DEFAULTS(func); PyObject closure; #if PY_MAJOR_VERSION >= 3 PyObject kwdefs; #endif PyObject kwtuple, k; PyObject d; Py_ssize_t nd; Py_ssize_t nk; PyObject result; assert(kwargs == NULL \|\| PyDict_Check(kwargs)); nk = kwargs ? PyDict_Size(kwargs) : 0; if (Py_EnterRecursiveCall((char)" while calling a Python object")) { return NULL; } if ( #if PY_MAJOR_VERSION >= 3 co->co_kwonlyargcount == 0 && #endif likely(kwargs == NULL \|\| nk == 0) && co->co_flags == (CO_OPTIMIZED \| CO_NEWLOCALS \| CO_NOFREE)) { if (argdefs == NULL && co->co_argcount == nargs) { result = __Pyx_PyFunction_FastCallNoKw(co, args, nargs, globals); goto done; } else if (nargs == 0 && argdefs != NULL && co->co_argcount == Py_SIZE(argdefs)) { / function called with no arguments, but all parameters have a default value: use default values as arguments ./ args = &PyTuple_GET_ITEM(argdefs, 0); result =__Pyx_PyFunction_FastCallNoKw(co, args, Py_SIZE(argdefs), globals); goto done; } } if (kwargs != NULL) { Py_ssize_t pos, i; kwtuple = PyTuple_New(2 nk); if (kwtuple == NULL) { result = NULL; goto done; } k = &PyTuple_GET_ITEM(kwtuple, 0); pos = i = 0; while (PyDict_Next(kwargs, &pos, &k[i], &k[i+1])) { Py_INCREF(k[i]); Py_INCREF(k[i+1]); i += 2; } nk = i / 2; } else { kwtuple = NULL; k = NULL; } closure = PyFunction_GET_CLOSURE(func); #if PY_MAJOR_VERSION >= 3 kwdefs = PyFunction_GET_KW_DEFAULTS(func); #endif if (argdefs != NULL) { d = &PyTuple_GET_ITEM(argdefs, 0); nd = Py_SIZE(argdefs); } else { d = NULL; nd = 0; } #if PY_MAJOR_VERSION >= 3 result = PyEval_EvalCodeEx((PyObject)co, globals, (PyObject )NULL, args, (int)nargs, k, (int)nk, d, (int)nd, kwdefs, closure); #else result = PyEval_EvalCodeEx(co, globals, (PyObject )NULL, args, (int)nargs, k, (int)nk, d, (int)nd, closure); #endif Py_XDECREF(kwtuple); done: Py_LeaveRecursiveCall(); return result; } #endif #endif / PyObjectCall2Args / static CYTHON_UNUSED PyObject __Pyx_PyObject_Call2Args(PyObject* function, PyObject* arg1, PyObject* arg2) { PyObject args, result = NULL; #if CYTHON_FAST_PYCALL if (PyFunction_Check(function)) { PyObject args[2] = {arg1, arg2}; return __Pyx_PyFunction_FastCall(function, args, 2); } #endif #if CYTHON_FAST_PYCCALL if (__Pyx_PyFastCFunction_Check(function)) { PyObject args[2] = {arg1, arg2}; return __Pyx_PyCFunction_FastCall(function, args, 2); } #endif args = PyTuple_New(2); if (unlikely(!args)) goto done; Py_INCREF(arg1); PyTuple_SET_ITEM(args, 0, arg1); Py_INCREF(arg2); PyTuple_SET_ITEM(args, 1, arg2); Py_INCREF(function); result = __Pyx_PyObject_Call(function, args, NULL); Py_DECREF(args); Py_DECREF(function); done: return result; } /* PyObjectCallMethO / #if CYTHON_COMPILING_IN_CPYTHON static CYTHON_INLINE PyObject __Pyx_PyObject_CallMethO(PyObject func, PyObject arg) { PyObject self, result; PyCFunction cfunc; cfunc = PyCFunction_GET_FUNCTION(func); self = PyCFunction_GET_SELF(func); if (unlikely(Py_EnterRecursiveCall((char)" while calling a Python object"))) return NULL; result = cfunc(self, arg); Py_LeaveRecursiveCall(); if (unlikely(!result) && unlikely(!PyErr_Occurred())) { PyErr_SetString( PyExc_SystemError, "NULL result without error in PyObject_Call"); } return result; } #endif / PyObjectCallOneArg / #if CYTHON_COMPILING_IN_CPYTHON static PyObject __Pyx__PyObject_CallOneArg(PyObject func, PyObject arg) { PyObject result; PyObject args = PyTuple_New(1); if (unlikely(!args)) return NULL; Py_INCREF(arg); PyTuple_SET_ITEM(args, 0, arg); result = __Pyx_PyObject_Call(func, args, NULL); Py_DECREF(args); return result; } static CYTHON_INLINE PyObject* __Pyx_PyObject_CallOneArg(PyObject func, PyObject arg) { #if CYTHON_FAST_PYCALL if (PyFunction_Check(func)) { return __Pyx_PyFunction_FastCall(func, &arg, 1); } #endif if (likely(PyCFunction_Check(func))) { if (likely(PyCFunction_GET_FLAGS(func) & METH_O)) { return __Pyx_PyObject_CallMethO(func, arg); #if CYTHON_FAST_PYCCALL } else if (__Pyx_PyFastCFunction_Check(func)) { return __Pyx_PyCFunction_FastCall(func, &arg, 1); #endif } } return __Pyx__PyObject_CallOneArg(func, arg); } #else static CYTHON_INLINE PyObject* __Pyx_PyObject_CallOneArg(PyObject func, PyObject arg) { PyObject result; PyObject args = PyTuple_Pack(1, arg); if (unlikely(!args)) return NULL; result = __Pyx_PyObject_Call(func, args, NULL); Py_DECREF(args); return result; } #endif /* BytesEquals / static CYTHON_INLINE int __Pyx_PyBytes_Equals(PyObject s1, PyObject* s2, int equals) { #if CYTHON_COMPILING_IN_PYPY return PyObject_RichCompareBool(s1, s2, equals); #else if (s1 == s2) { return (equals == Py_EQ); } else if (PyBytes_CheckExact(s1) & PyBytes_CheckExact(s2)) { const char ps1, ps2; Py_ssize_t length = PyBytes_GET_SIZE(s1); if (length != PyBytes_GET_SIZE(s2)) return (equals == Py_NE); ps1 = PyBytes_AS_STRING(s1); ps2 = PyBytes_AS_STRING(s2); if (ps1[0] != ps2[0]) { return (equals == Py_NE); } else if (length == 1) { return (equals == Py_EQ); } else { int result; #if CYTHON_USE_UNICODE_INTERNALS Py_hash_t hash1, hash2; hash1 = ((PyBytesObject)s1)->ob_shash; hash2 = ((PyBytesObject)s2)->ob_shash; if (hash1 != hash2 && hash1 != -1 && hash2 != -1) { return (equals == Py_NE); } #endif result = memcmp(ps1, ps2, (size_t)length); return (equals == Py_EQ) ? (result == 0) : (result != 0); } } else if ((s1 == Py_None) & PyBytes_CheckExact(s2)) { return (equals == Py_NE); } else if ((s2 == Py_None) & PyBytes_CheckExact(s1)) { return (equals == Py_NE); } else { int result; PyObject* py_result = PyObject_RichCompare(s1, s2, equals); if (!py_result) return -1; result = __Pyx_PyObject_IsTrue(py_result); Py_DECREF(py_result); return result; } #endif } /* UnicodeEquals / static CYTHON_INLINE int __Pyx_PyUnicode_Equals(PyObject s1, PyObject* s2, int equals) { #if CYTHON_COMPILING_IN_PYPY return PyObject_RichCompareBool(s1, s2, equals); #else #if PY_MAJOR_VERSION < 3 PyObject* owned_ref = NULL; #endif int s1_is_unicode, s2_is_unicode; if (s1 == s2) { goto return_eq; } s1_is_unicode = PyUnicode_CheckExact(s1); s2_is_unicode = PyUnicode_CheckExact(s2); #if PY_MAJOR_VERSION < 3 if ((s1_is_unicode & (!s2_is_unicode)) && PyString_CheckExact(s2)) { owned_ref = PyUnicode_FromObject(s2); if (unlikely(!owned_ref)) return -1; s2 = owned_ref; s2_is_unicode = 1; } else if ((s2_is_unicode & (!s1_is_unicode)) && PyString_CheckExact(s1)) { owned_ref = PyUnicode_FromObject(s1); if (unlikely(!owned_ref)) return -1; s1 = owned_ref; s1_is_unicode = 1; } else if (((!s2_is_unicode) & (!s1_is_unicode))) { return __Pyx_PyBytes_Equals(s1, s2, equals); } #endif if (s1_is_unicode & s2_is_unicode) { Py_ssize_t length; int kind; void data1, data2; if (unlikely(__Pyx_PyUnicode_READY(s1) < 0) \|\| unlikely(__Pyx_PyUnicode_READY(s2) < 0)) return -1; length = __Pyx_PyUnicode_GET_LENGTH(s1); if (length != __Pyx_PyUnicode_GET_LENGTH(s2)) { goto return_ne; } #if CYTHON_USE_UNICODE_INTERNALS { Py_hash_t hash1, hash2; #if CYTHON_PEP393_ENABLED hash1 = ((PyASCIIObject)s1)->hash; hash2 = ((PyASCIIObject)s2)->hash; #else hash1 = ((PyUnicodeObject)s1)->hash; hash2 = ((PyUnicodeObject)s2)->hash; #endif if (hash1 != hash2 && hash1 != -1 && hash2 != -1) { goto return_ne; } } #endif kind = __Pyx_PyUnicode_KIND(s1); if (kind != __Pyx_PyUnicode_KIND(s2)) { goto return_ne; } data1 = __Pyx_PyUnicode_DATA(s1); data2 = __Pyx_PyUnicode_DATA(s2); if (__Pyx_PyUnicode_READ(kind, data1, 0) != __Pyx_PyUnicode_READ(kind, data2, 0)) { goto return_ne; } else if (length == 1) { goto return_eq; } else { int result = memcmp(data1, data2, (size_t)(length * kind)); #if PY_MAJOR_VERSION < 3 Py_XDECREF(owned_ref); #endif return (equals == Py_EQ) ? (result == 0) : (result != 0); } } else if ((s1 == Py_None) & s2_is_unicode) { goto return_ne; } else if ((s2 == Py_None) & s1_is_unicode) { goto return_ne; } else { int result; PyObject* py_result = PyObject_RichCompare(s1, s2, equals); #if PY_MAJOR_VERSION < 3 Py_XDECREF(owned_ref); #endif if (!py_result) return -1; result = __Pyx_PyObject_IsTrue(py_result); Py_DECREF(py_result); return result; } return_eq: #if PY_MAJOR_VERSION < 3 Py_XDECREF(owned_ref); #endif return (equals == Py_EQ); return_ne: #if PY_MAJOR_VERSION < 3 Py_XDECREF(owned_ref); #endif return (equals == Py_NE); #endif } /* None / static CYTHON_INLINE Py_ssize_t __Pyx_div_Py_ssize_t(Py_ssize_t a, Py_ssize_t b) { Py_ssize_t q = a / b; Py_ssize_t r = a - qb; q -= ((r != 0) & ((r ^ b) < 0)); return q; } /* GetAttr / static CYTHON_INLINE PyObject __Pyx_GetAttr(PyObject o, PyObject n) { #if CYTHON_USE_TYPE_SLOTS #if PY_MAJOR_VERSION >= 3 if (likely(PyUnicode_Check(n))) #else if (likely(PyString_Check(n))) #endif return __Pyx_PyObject_GetAttrStr(o, n); #endif return PyObject_GetAttr(o, n); } /* GetItemInt / static PyObject __Pyx_GetItemInt_Generic(PyObject o, PyObject j) { PyObject r; if (!j) return NULL; r = PyObject_GetItem(o, j); Py_DECREF(j); return r; } static CYTHON_INLINE PyObject __Pyx_GetItemInt_List_Fast(PyObject o, Py_ssize_t i, CYTHON_NCP_UNUSED int wraparound, CYTHON_NCP_UNUSED int boundscheck) { #if CYTHON_ASSUME_SAFE_MACROS && !CYTHON_AVOID_BORROWED_REFS Py_ssize_t wrapped_i = i; if (wraparound & unlikely(i < 0)) { wrapped_i += PyList_GET_SIZE(o); } if ((!boundscheck) \|\| likely(__Pyx_is_valid_index(wrapped_i, PyList_GET_SIZE(o)))) { PyObject r = PyList_GET_ITEM(o, wrapped_i); Py_INCREF(r); return r; } return __Pyx_GetItemInt_Generic(o, PyInt_FromSsize_t(i)); #else return PySequence_GetItem(o, i); #endif } static CYTHON_INLINE PyObject __Pyx_GetItemInt_Tuple_Fast(PyObject o, Py_ssize_t i, CYTHON_NCP_UNUSED int wraparound, CYTHON_NCP_UNUSED int boundscheck) { #if CYTHON_ASSUME_SAFE_MACROS && !CYTHON_AVOID_BORROWED_REFS Py_ssize_t wrapped_i = i; if (wraparound & unlikely(i < 0)) { wrapped_i += PyTuple_GET_SIZE(o); } if ((!boundscheck) \|\| likely(__Pyx_is_valid_index(wrapped_i, PyTuple_GET_SIZE(o)))) { PyObject r = PyTuple_GET_ITEM(o, wrapped_i); Py_INCREF(r); return r; } return __Pyx_GetItemInt_Generic(o, PyInt_FromSsize_t(i)); #else return PySequence_GetItem(o, i); #endif } static CYTHON_INLINE PyObject __Pyx_GetItemInt_Fast(PyObject o, Py_ssize_t i, int is_list, CYTHON_NCP_UNUSED int wraparound, CYTHON_NCP_UNUSED int boundscheck) { #if CYTHON_ASSUME_SAFE_MACROS && !CYTHON_AVOID_BORROWED_REFS && CYTHON_USE_TYPE_SLOTS if (is_list \|\| PyList_CheckExact(o)) { Py_ssize_t n = ((!wraparound) \| likely(i >= 0)) ? i : i + PyList_GET_SIZE(o); if ((!boundscheck) \|\| (likely(__Pyx_is_valid_index(n, PyList_GET_SIZE(o))))) { PyObject r = PyList_GET_ITEM(o, n); Py_INCREF(r); return r; } } else if (PyTuple_CheckExact(o)) { Py_ssize_t n = ((!wraparound) \| likely(i >= 0)) ? i : i + PyTuple_GET_SIZE(o); if ((!boundscheck) \|\| likely(__Pyx_is_valid_index(n, PyTuple_GET_SIZE(o)))) { PyObject r = PyTuple_GET_ITEM(o, n); Py_INCREF(r); return r; } } else { PySequenceMethods m = Py_TYPE(o)->tp_as_sequence; if (likely(m && m->sq_item)) { if (wraparound && unlikely(i < 0) && likely(m->sq_length)) { Py_ssize_t l = m->sq_length(o); if (likely(l >= 0)) { i += l; } else { if (!PyErr_ExceptionMatches(PyExc_OverflowError)) return NULL; PyErr_Clear(); } } return m->sq_item(o, i); } } #else if (is_list \|\| PySequence_Check(o)) { return PySequence_GetItem(o, i); } #endif return __Pyx_GetItemInt_Generic(o, PyInt_FromSsize_t(i)); } /* ObjectGetItem / #if CYTHON_USE_TYPE_SLOTS static PyObject __Pyx_PyObject_GetIndex(PyObject obj, PyObject index) { PyObject runerr; Py_ssize_t key_value; PySequenceMethods m = Py_TYPE(obj)->tp_as_sequence; if (unlikely(!(m && m->sq_item))) { PyErr_Format(PyExc_TypeError, "'%.200s' object is not subscriptable", Py_TYPE(obj)->tp_name); return NULL; } key_value = __Pyx_PyIndex_AsSsize_t(index); if (likely(key_value != -1 \|\| !(runerr = PyErr_Occurred()))) { return __Pyx_GetItemInt_Fast(obj, key_value, 0, 1, 1); } if (PyErr_GivenExceptionMatches(runerr, PyExc_OverflowError)) { PyErr_Clear(); PyErr_Format(PyExc_IndexError, "cannot fit '%.200s' into an index-sized integer", Py_TYPE(index)->tp_name); } return NULL; } static PyObject __Pyx_PyObject_GetItem(PyObject obj, PyObject* key) { PyMappingMethods m = Py_TYPE(obj)->tp_as_mapping; if (likely(m && m->mp_subscript)) { return m->mp_subscript(obj, key); } return __Pyx_PyObject_GetIndex(obj, key); } #endif / decode_c_string / static CYTHON_INLINE PyObject __Pyx_decode_c_string( const char* cstring, Py_ssize_t start, Py_ssize_t stop, const char* encoding, const char* errors, PyObject* (decode_func)(const char s, Py_ssize_t size, const char errors)) { Py_ssize_t length; if (unlikely((start < 0) \| (stop < 0))) { size_t slen = strlen(cstring); if (unlikely(slen > (size_t) PY_SSIZE_T_MAX)) { PyErr_SetString(PyExc_OverflowError, "c-string too long to convert to Python"); return NULL; } length = (Py_ssize_t) slen; if (start < 0) { start += length; if (start < 0) start = 0; } if (stop < 0) stop += length; } if (unlikely(stop <= start)) return __Pyx_NewRef(__pyx_empty_unicode); length = stop - start; cstring += start; if (decode_func) { return decode_func(cstring, length, errors); } else { return PyUnicode_Decode(cstring, length, encoding, errors); } } / PyErrExceptionMatches / #if CYTHON_FAST_THREAD_STATE static int __Pyx_PyErr_ExceptionMatchesTuple(PyObject exc_type, PyObject tuple) { Py_ssize_t i, n; n = PyTuple_GET_SIZE(tuple); #if PY_MAJOR_VERSION >= 3 for (i=0; i<n; i++) { if (exc_type == PyTuple_GET_ITEM(tuple, i)) return 1; } #endif for (i=0; i<n; i++) { if (__Pyx_PyErr_GivenExceptionMatches(exc_type, PyTuple_GET_ITEM(tuple, i))) return 1; } return 0; } static CYTHON_INLINE int __Pyx_PyErr_ExceptionMatchesInState(PyThreadState tstate, PyObject* err) { PyObject exc_type = tstate->curexc_type; if (exc_type == err) return 1; if (unlikely(!exc_type)) return 0; if (unlikely(PyTuple_Check(err))) return __Pyx_PyErr_ExceptionMatchesTuple(exc_type, err); return __Pyx_PyErr_GivenExceptionMatches(exc_type, err); } #endif / GetAttr3 / static PyObject __Pyx_GetAttr3Default(PyObject d) { __Pyx_PyThreadState_declare __Pyx_PyThreadState_assign if (unlikely(!__Pyx_PyErr_ExceptionMatches(PyExc_AttributeError))) return NULL; __Pyx_PyErr_Clear(); Py_INCREF(d); return d; } static CYTHON_INLINE PyObject __Pyx_GetAttr3(PyObject o, PyObject n, PyObject d) { PyObject r = __Pyx_GetAttr(o, n); return (likely(r)) ? r : __Pyx_GetAttr3Default(d); } /* PyDictVersioning / #if CYTHON_USE_DICT_VERSIONS && CYTHON_USE_TYPE_SLOTS static CYTHON_INLINE PY_UINT64_T __Pyx_get_tp_dict_version(PyObject obj) { PyObject dict = Py_TYPE(obj)->tp_dict; return likely(dict) ? __PYX_GET_DICT_VERSION(dict) : 0; } static CYTHON_INLINE PY_UINT64_T __Pyx_get_object_dict_version(PyObject obj) { PyObject dictptr = NULL; Py_ssize_t offset = Py_TYPE(obj)->tp_dictoffset; if (offset) { #if CYTHON_COMPILING_IN_CPYTHON dictptr = (likely(offset > 0)) ? (PyObject ) ((char )obj + offset) : _PyObject_GetDictPtr(obj); #else dictptr = _PyObject_GetDictPtr(obj); #endif } return (dictptr && dictptr) ? __PYX_GET_DICT_VERSION(dictptr) : 0; } static CYTHON_INLINE int __Pyx_object_dict_version_matches(PyObject obj, PY_UINT64_T tp_dict_version, PY_UINT64_T obj_dict_version) { PyObject dict = Py_TYPE(obj)->tp_dict; if (unlikely(!dict) \|\| unlikely(tp_dict_version != __PYX_GET_DICT_VERSION(dict))) return 0; return obj_dict_version == __Pyx_get_object_dict_version(obj); } #endif / GetModuleGlobalName / #if CYTHON_USE_DICT_VERSIONS static PyObject __Pyx__GetModuleGlobalName(PyObject name, PY_UINT64_T dict_version, PyObject *dict_cached_value) #else static CYTHON_INLINE PyObject __Pyx__GetModuleGlobalName(PyObject name) #endif { PyObject result; #if !CYTHON_AVOID_BORROWED_REFS #if CYTHON_COMPILING_IN_CPYTHON && PY_VERSION_HEX >= 0x030500A1 result = _PyDict_GetItem_KnownHash(__pyx_d, name, ((PyASCIIObject ) name)->hash); __PYX_UPDATE_DICT_CACHE(__pyx_d, result, dict_cached_value, dict_version) if (likely(result)) { return __Pyx_NewRef(result); } else if (unlikely(PyErr_Occurred())) { return NULL; } #else result = PyDict_GetItem(__pyx_d, name); __PYX_UPDATE_DICT_CACHE(__pyx_d, result, dict_cached_value, dict_version) if (likely(result)) { return __Pyx_NewRef(result); } #endif #else result = PyObject_GetItem(__pyx_d, name); __PYX_UPDATE_DICT_CACHE(__pyx_d, result, dict_cached_value, dict_version) if (likely(result)) { return __Pyx_NewRef(result); } PyErr_Clear(); #endif return __Pyx_GetBuiltinName(name); } / RaiseTooManyValuesToUnpack / static CYTHON_INLINE void __Pyx_RaiseTooManyValuesError(Py_ssize_t expected) { PyErr_Format(PyExc_ValueError, "too many values to unpack (expected %" CYTHON_FORMAT_SSIZE_T "d)", expected); } / RaiseNeedMoreValuesToUnpack / static CYTHON_INLINE void __Pyx_RaiseNeedMoreValuesError(Py_ssize_t index) { PyErr_Format(PyExc_ValueError, "need more than %" CYTHON_FORMAT_SSIZE_T "d value%.1s to unpack", index, (index == 1) ? "" : "s"); } / RaiseNoneIterError / static CYTHON_INLINE void __Pyx_RaiseNoneNotIterableError(void) { PyErr_SetString(PyExc_TypeError, "'NoneType' object is not iterable"); } / ExtTypeTest / static CYTHON_INLINE int __Pyx_TypeTest(PyObject obj, PyTypeObject type) { if (unlikely(!type)) { PyErr_SetString(PyExc_SystemError, "Missing type object"); return 0; } if (likely(__Pyx_TypeCheck(obj, type))) return 1; PyErr_Format(PyExc_TypeError, "Cannot convert %.200s to %.200s", Py_TYPE(obj)->tp_name, type->tp_name); return 0; } / GetTopmostException / #if CYTHON_USE_EXC_INFO_STACK static _PyErr_StackItem __Pyx_PyErr_GetTopmostException(PyThreadState tstate) { _PyErr_StackItem exc_info = tstate->exc_info; while ((exc_info->exc_type == NULL \|\| exc_info->exc_type == Py_None) && exc_info->previous_item != NULL) { exc_info = exc_info->previous_item; } return exc_info; } #endif /* SaveResetException / #if CYTHON_FAST_THREAD_STATE static CYTHON_INLINE void __Pyx__ExceptionSave(PyThreadState tstate, PyObject type, PyObject value, PyObject *tb) { #if CYTHON_USE_EXC_INFO_STACK _PyErr_StackItem exc_info = __Pyx_PyErr_GetTopmostException(tstate); type = exc_info->exc_type; value = exc_info->exc_value; tb = exc_info->exc_traceback; #else type = tstate->exc_type; value = tstate->exc_value; tb = tstate->exc_traceback; #endif Py_XINCREF(type); Py_XINCREF(value); Py_XINCREF(tb); } static CYTHON_INLINE void __Pyx__ExceptionReset(PyThreadState tstate, PyObject type, PyObject value, PyObject tb) { PyObject tmp_type, tmp_value, tmp_tb; #if CYTHON_USE_EXC_INFO_STACK _PyErr_StackItem exc_info = tstate->exc_info; tmp_type = exc_info->exc_type; tmp_value = exc_info->exc_value; tmp_tb = exc_info->exc_traceback; exc_info->exc_type = type; exc_info->exc_value = value; exc_info->exc_traceback = tb; #else tmp_type = tstate->exc_type; tmp_value = tstate->exc_value; tmp_tb = tstate->exc_traceback; tstate->exc_type = type; tstate->exc_value = value; tstate->exc_traceback = tb; #endif Py_XDECREF(tmp_type); Py_XDECREF(tmp_value); Py_XDECREF(tmp_tb); } #endif / GetException / #if CYTHON_FAST_THREAD_STATE static int __Pyx__GetException(PyThreadState tstate, PyObject type, PyObject value, PyObject tb) #else static int __Pyx_GetException(PyObject type, PyObject value, PyObject tb) #endif { PyObject local_type, local_value, local_tb; #if CYTHON_FAST_THREAD_STATE PyObject tmp_type, tmp_value, tmp_tb; local_type = tstate->curexc_type; local_value = tstate->curexc_value; local_tb = tstate->curexc_traceback; tstate->curexc_type = 0; tstate->curexc_value = 0; tstate->curexc_traceback = 0; #else PyErr_Fetch(&local_type, &local_value, &local_tb); #endif PyErr_NormalizeException(&local_type, &local_value, &local_tb); #if CYTHON_FAST_THREAD_STATE if (unlikely(tstate->curexc_type)) #else if (unlikely(PyErr_Occurred())) #endif goto bad; #if PY_MAJOR_VERSION >= 3 if (local_tb) { if (unlikely(PyException_SetTraceback(local_value, local_tb) < 0)) goto bad; } #endif Py_XINCREF(local_tb); Py_XINCREF(local_type); Py_XINCREF(local_value); type = local_type; value = local_value; tb = local_tb; #if CYTHON_FAST_THREAD_STATE #if CYTHON_USE_EXC_INFO_STACK { _PyErr_StackItem exc_info = tstate->exc_info; tmp_type = exc_info->exc_type; tmp_value = exc_info->exc_value; tmp_tb = exc_info->exc_traceback; exc_info->exc_type = local_type; exc_info->exc_value = local_value; exc_info->exc_traceback = local_tb; } #else tmp_type = tstate->exc_type; tmp_value = tstate->exc_value; tmp_tb = tstate->exc_traceback; tstate->exc_type = local_type; tstate->exc_value = local_value; tstate->exc_traceback = local_tb; #endif Py_XDECREF(tmp_type); Py_XDECREF(tmp_value); Py_XDECREF(tmp_tb); #else PyErr_SetExcInfo(local_type, local_value, local_tb); #endif return 0; bad: type = 0; value = 0; tb = 0; Py_XDECREF(local_type); Py_XDECREF(local_value); Py_XDECREF(local_tb); return -1; } / SwapException / #if CYTHON_FAST_THREAD_STATE static CYTHON_INLINE void __Pyx__ExceptionSwap(PyThreadState tstate, PyObject type, PyObject value, PyObject *tb) { PyObject tmp_type, tmp_value, tmp_tb; #if CYTHON_USE_EXC_INFO_STACK _PyErr_StackItem exc_info = tstate->exc_info; tmp_type = exc_info->exc_type; tmp_value = exc_info->exc_value; tmp_tb = exc_info->exc_traceback; exc_info->exc_type = type; exc_info->exc_value = value; exc_info->exc_traceback = tb; #else tmp_type = tstate->exc_type; tmp_value = tstate->exc_value; tmp_tb = tstate->exc_traceback; tstate->exc_type = type; tstate->exc_value = value; tstate->exc_traceback = tb; #endif type = tmp_type; value = tmp_value; tb = tmp_tb; } #else static CYTHON_INLINE void __Pyx_ExceptionSwap(PyObject type, PyObject value, PyObject *tb) { PyObject tmp_type, tmp_value, tmp_tb; PyErr_GetExcInfo(&tmp_type, &tmp_value, &tmp_tb); PyErr_SetExcInfo(type, value, tb); type = tmp_type; value = tmp_value; tb = tmp_tb; } #endif /* Import / static PyObject __Pyx_Import(PyObject name, PyObject from_list, int level) { PyObject empty_list = 0; PyObject module = 0; PyObject global_dict = 0; PyObject empty_dict = 0; PyObject list; #if PY_MAJOR_VERSION < 3 PyObject py_import; py_import = __Pyx_PyObject_GetAttrStr(__pyx_b, __pyx_n_s_import); if (!py_import) goto bad; #endif if (from_list) list = from_list; else { empty_list = PyList_New(0); if (!empty_list) goto bad; list = empty_list; } global_dict = PyModule_GetDict(__pyx_m); if (!global_dict) goto bad; empty_dict = PyDict_New(); if (!empty_dict) goto bad; { #if PY_MAJOR_VERSION >= 3 if (level == -1) { if ((1) && (strchr(__Pyx_MODULE_NAME, '.'))) { module = PyImport_ImportModuleLevelObject( name, global_dict, empty_dict, list, 1); if (!module) { if (!PyErr_ExceptionMatches(PyExc_ImportError)) goto bad; PyErr_Clear(); } } level = 0; } #endif if (!module) { #if PY_MAJOR_VERSION < 3 PyObject py_level = PyInt_FromLong(level); if (!py_level) goto bad; module = PyObject_CallFunctionObjArgs(py_import, name, global_dict, empty_dict, list, py_level, (PyObject )NULL); Py_DECREF(py_level); #else module = PyImport_ImportModuleLevelObject( name, global_dict, empty_dict, list, level); #endif } } bad: #if PY_MAJOR_VERSION < 3 Py_XDECREF(py_import); #endif Py_XDECREF(empty_list); Py_XDECREF(empty_dict); return module; } /* FastTypeChecks / #if CYTHON_COMPILING_IN_CPYTHON static int __Pyx_InBases(PyTypeObject a, PyTypeObject b) { while (a) { a = a->tp_base; if (a == b) return 1; } return b == &PyBaseObject_Type; } static CYTHON_INLINE int __Pyx_IsSubtype(PyTypeObject a, PyTypeObject b) { PyObject mro; if (a == b) return 1; mro = a->tp_mro; if (likely(mro)) { Py_ssize_t i, n; n = PyTuple_GET_SIZE(mro); for (i = 0; i < n; i++) { if (PyTuple_GET_ITEM(mro, i) == (PyObject )b) return 1; } return 0; } return __Pyx_InBases(a, b); } #if PY_MAJOR_VERSION == 2 static int __Pyx_inner_PyErr_GivenExceptionMatches2(PyObject err, PyObject* exc_type1, PyObject* exc_type2) { PyObject exception, value, tb; int res; __Pyx_PyThreadState_declare __Pyx_PyThreadState_assign __Pyx_ErrFetch(&exception, &value, &tb); res = exc_type1 ? PyObject_IsSubclass(err, exc_type1) : 0; if (unlikely(res == -1)) { PyErr_WriteUnraisable(err); res = 0; } if (!res) { res = PyObject_IsSubclass(err, exc_type2); if (unlikely(res == -1)) { PyErr_WriteUnraisable(err); res = 0; } } __Pyx_ErrRestore(exception, value, tb); return res; } #else static CYTHON_INLINE int __Pyx_inner_PyErr_GivenExceptionMatches2(PyObject err, PyObject* exc_type1, PyObject exc_type2) { int res = exc_type1 ? __Pyx_IsSubtype((PyTypeObject)err, (PyTypeObject)exc_type1) : 0; if (!res) { res = __Pyx_IsSubtype((PyTypeObject)err, (PyTypeObject)exc_type2); } return res; } #endif static int __Pyx_PyErr_GivenExceptionMatchesTuple(PyObject exc_type, PyObject tuple) { Py_ssize_t i, n; assert(PyExceptionClass_Check(exc_type)); n = PyTuple_GET_SIZE(tuple); #if PY_MAJOR_VERSION >= 3 for (i=0; i<n; i++) { if (exc_type == PyTuple_GET_ITEM(tuple, i)) return 1; } #endif for (i=0; i<n; i++) { PyObject t = PyTuple_GET_ITEM(tuple, i); #if PY_MAJOR_VERSION < 3 if (likely(exc_type == t)) return 1; #endif if (likely(PyExceptionClass_Check(t))) { if (__Pyx_inner_PyErr_GivenExceptionMatches2(exc_type, NULL, t)) return 1; } else { } } return 0; } static CYTHON_INLINE int __Pyx_PyErr_GivenExceptionMatches(PyObject err, PyObject exc_type) { if (likely(err == exc_type)) return 1; if (likely(PyExceptionClass_Check(err))) { if (likely(PyExceptionClass_Check(exc_type))) { return __Pyx_inner_PyErr_GivenExceptionMatches2(err, NULL, exc_type); } else if (likely(PyTuple_Check(exc_type))) { return __Pyx_PyErr_GivenExceptionMatchesTuple(err, exc_type); } else { } } return PyErr_GivenExceptionMatches(err, exc_type); } static CYTHON_INLINE int __Pyx_PyErr_GivenExceptionMatches2(PyObject err, PyObject exc_type1, PyObject exc_type2) { assert(PyExceptionClass_Check(exc_type1)); assert(PyExceptionClass_Check(exc_type2)); if (likely(err == exc_type1 \|\| err == exc_type2)) return 1; if (likely(PyExceptionClass_Check(err))) { return __Pyx_inner_PyErr_GivenExceptionMatches2(err, exc_type1, exc_type2); } return (PyErr_GivenExceptionMatches(err, exc_type1) \|\| PyErr_GivenExceptionMatches(err, exc_type2)); } #endif / PyIntBinop / #if !CYTHON_COMPILING_IN_PYPY static PyObject __Pyx_PyInt_AddObjC(PyObject op1, PyObject op2, CYTHON_UNUSED long intval, int inplace, int zerodivision_check) { (void)inplace; (void)zerodivision_check; #if PY_MAJOR_VERSION < 3 if (likely(PyInt_CheckExact(op1))) { const long b = intval; long x; long a = PyInt_AS_LONG(op1); x = (long)((unsigned long)a + b); if (likely((x^a) >= 0 \|\| (x^b) >= 0)) return PyInt_FromLong(x); return PyLong_Type.tp_as_number->nb_add(op1, op2); } #endif #if CYTHON_USE_PYLONG_INTERNALS if (likely(PyLong_CheckExact(op1))) { const long b = intval; long a, x; #ifdef HAVE_LONG_LONG const PY_LONG_LONG llb = intval; PY_LONG_LONG lla, llx; #endif const digit* digits = ((PyLongObject)op1)->ob_digit; const Py_ssize_t size = Py_SIZE(op1); if (likely(__Pyx_sst_abs(size) <= 1)) { a = likely(size) ? digits[0] : 0; if (size == -1) a = -a; } else { switch (size) { case -2: if (8 sizeof(long) - 1 > 2 * PyLong_SHIFT) { a = -(long) (((((unsigned long)digits[1]) << PyLong_SHIFT) \| (unsigned long)digits[0])); break; #ifdef HAVE_LONG_LONG } else if (8 * sizeof(PY_LONG_LONG) - 1 > 2 * PyLong_SHIFT) { lla = -(PY_LONG_LONG) (((((unsigned PY_LONG_LONG)digits[1]) << PyLong_SHIFT) \| (unsigned PY_LONG_LONG)digits[0])); goto long_long; #endif } CYTHON_FALLTHROUGH; case 2: if (8 * sizeof(long) - 1 > 2 * PyLong_SHIFT) { a = (long) (((((unsigned long)digits[1]) << PyLong_SHIFT) \| (unsigned long)digits[0])); break; #ifdef HAVE_LONG_LONG } else if (8 * sizeof(PY_LONG_LONG) - 1 > 2 * PyLong_SHIFT) { lla = (PY_LONG_LONG) (((((unsigned PY_LONG_LONG)digits[1]) << PyLong_SHIFT) \| (unsigned PY_LONG_LONG)digits[0])); goto long_long; #endif } CYTHON_FALLTHROUGH; case -3: if (8 * sizeof(long) - 1 > 3 * PyLong_SHIFT) { a = -(long) (((((((unsigned long)digits[2]) << PyLong_SHIFT) \| (unsigned long)digits[1]) << PyLong_SHIFT) \| (unsigned long)digits[0])); break; #ifdef HAVE_LONG_LONG } else if (8 * sizeof(PY_LONG_LONG) - 1 > 3 * PyLong_SHIFT) { lla = -(PY_LONG_LONG) (((((((unsigned PY_LONG_LONG)digits[2]) << PyLong_SHIFT) \| (unsigned PY_LONG_LONG)digits[1]) << PyLong_SHIFT) \| (unsigned PY_LONG_LONG)digits[0])); goto long_long; #endif } CYTHON_FALLTHROUGH; case 3: if (8 * sizeof(long) - 1 > 3 * PyLong_SHIFT) { a = (long) (((((((unsigned long)digits[2]) << PyLong_SHIFT) \| (unsigned long)digits[1]) << PyLong_SHIFT) \| (unsigned long)digits[0])); break; #ifdef HAVE_LONG_LONG } else if (8 * sizeof(PY_LONG_LONG) - 1 > 3 * PyLong_SHIFT) { lla = (PY_LONG_LONG) (((((((unsigned PY_LONG_LONG)digits[2]) << PyLong_SHIFT) \| (unsigned PY_LONG_LONG)digits[1]) << PyLong_SHIFT) \| (unsigned PY_LONG_LONG)digits[0])); goto long_long; #endif } CYTHON_FALLTHROUGH; case -4: if (8 * sizeof(long) - 1 > 4 * PyLong_SHIFT) { a = -(long) (((((((((unsigned long)digits[3]) << PyLong_SHIFT) \| (unsigned long)digits[2]) << PyLong_SHIFT) \| (unsigned long)digits[1]) << PyLong_SHIFT) \| (unsigned long)digits[0])); break; #ifdef HAVE_LONG_LONG } else if (8 * sizeof(PY_LONG_LONG) - 1 > 4 * PyLong_SHIFT) { lla = -(PY_LONG_LONG) (((((((((unsigned PY_LONG_LONG)digits[3]) << PyLong_SHIFT) \| (unsigned PY_LONG_LONG)digits[2]) << PyLong_SHIFT) \| (unsigned PY_LONG_LONG)digits[1]) << PyLong_SHIFT) \| (unsigned PY_LONG_LONG)digits[0])); goto long_long; #endif } CYTHON_FALLTHROUGH; case 4: if (8 * sizeof(long) - 1 > 4 * PyLong_SHIFT) { a = (long) (((((((((unsigned long)digits[3]) << PyLong_SHIFT) \| (unsigned long)digits[2]) << PyLong_SHIFT) \| (unsigned long)digits[1]) << PyLong_SHIFT) \| (unsigned long)digits[0])); break; #ifdef HAVE_LONG_LONG } else if (8 * sizeof(PY_LONG_LONG) - 1 > 4 * PyLong_SHIFT) { lla = (PY_LONG_LONG) (((((((((unsigned PY_LONG_LONG)digits[3]) << PyLong_SHIFT) \| (unsigned PY_LONG_LONG)digits[2]) << PyLong_SHIFT) \| (unsigned PY_LONG_LONG)digits[1]) << PyLong_SHIFT) \| (unsigned PY_LONG_LONG)digits[0])); goto long_long; #endif } CYTHON_FALLTHROUGH; default: return PyLong_Type.tp_as_number->nb_add(op1, op2); } } x = a + b; return PyLong_FromLong(x); #ifdef HAVE_LONG_LONG long_long: llx = lla + llb; return PyLong_FromLongLong(llx); #endif } #endif if (PyFloat_CheckExact(op1)) { const long b = intval; double a = PyFloat_AS_DOUBLE(op1); double result; PyFPE_START_PROTECT("add", return NULL) result = ((double)a) + (double)b; PyFPE_END_PROTECT(result) return PyFloat_FromDouble(result); } return (inplace ? PyNumber_InPlaceAdd : PyNumber_Add)(op1, op2); } #endif /* None / static CYTHON_INLINE void __Pyx_RaiseUnboundLocalError(const char varname) { PyErr_Format(PyExc_UnboundLocalError, "local variable '%s' referenced before assignment", varname); } /* None / static CYTHON_INLINE long __Pyx_div_long(long a, long b) { long q = a / b; long r = a - qb; q -= ((r != 0) & ((r ^ b) < 0)); return q; } /* ImportFrom / static PyObject __Pyx_ImportFrom(PyObject* module, PyObject* name) { PyObject* value = __Pyx_PyObject_GetAttrStr(module, name); if (unlikely(!value) && PyErr_ExceptionMatches(PyExc_AttributeError)) { PyErr_Format(PyExc_ImportError, #if PY_MAJOR_VERSION < 3 "cannot import name %.230s", PyString_AS_STRING(name)); #else "cannot import name %S", name); #endif } return value; } /* HasAttr / static CYTHON_INLINE int __Pyx_HasAttr(PyObject o, PyObject n) { PyObject r; if (unlikely(!__Pyx_PyBaseString_Check(n))) { PyErr_SetString(PyExc_TypeError, "hasattr(): attribute name must be string"); return -1; } r = __Pyx_GetAttr(o, n); if (unlikely(!r)) { PyErr_Clear(); return 0; } else { Py_DECREF(r); return 1; } } /* PyObject_GenericGetAttrNoDict / #if CYTHON_USE_TYPE_SLOTS && CYTHON_USE_PYTYPE_LOOKUP && PY_VERSION_HEX < 0x03070000 static PyObject __Pyx_RaiseGenericGetAttributeError(PyTypeObject tp, PyObject attr_name) { PyErr_Format(PyExc_AttributeError, #if PY_MAJOR_VERSION >= 3 "'%.50s' object has no attribute '%U'", tp->tp_name, attr_name); #else "'%.50s' object has no attribute '%.400s'", tp->tp_name, PyString_AS_STRING(attr_name)); #endif return NULL; } static CYTHON_INLINE PyObject* __Pyx_PyObject_GenericGetAttrNoDict(PyObject* obj, PyObject* attr_name) { PyObject descr; PyTypeObject tp = Py_TYPE(obj); if (unlikely(!PyString_Check(attr_name))) { return PyObject_GenericGetAttr(obj, attr_name); } assert(!tp->tp_dictoffset); descr = _PyType_Lookup(tp, attr_name); if (unlikely(!descr)) { return __Pyx_RaiseGenericGetAttributeError(tp, attr_name); } Py_INCREF(descr); #if PY_MAJOR_VERSION < 3 if (likely(PyType_HasFeature(Py_TYPE(descr), Py_TPFLAGS_HAVE_CLASS))) #endif { descrgetfunc f = Py_TYPE(descr)->tp_descr_get; if (unlikely(f)) { PyObject res = f(descr, obj, (PyObject )tp); Py_DECREF(descr); return res; } } return descr; } #endif /* PyObject_GenericGetAttr / #if CYTHON_USE_TYPE_SLOTS && CYTHON_USE_PYTYPE_LOOKUP && PY_VERSION_HEX < 0x03070000 static PyObject __Pyx_PyObject_GenericGetAttr(PyObject* obj, PyObject* attr_name) { if (unlikely(Py_TYPE(obj)->tp_dictoffset)) { return PyObject_GenericGetAttr(obj, attr_name); } return __Pyx_PyObject_GenericGetAttrNoDict(obj, attr_name); } #endif /* SetVTable / static int __Pyx_SetVtable(PyObject dict, void vtable) { #if PY_VERSION_HEX >= 0x02070000 PyObject ob = PyCapsule_New(vtable, 0, 0); #else PyObject ob = PyCObject_FromVoidPtr(vtable, 0); #endif if (!ob) goto bad; if (PyDict_SetItem(dict, __pyx_n_s_pyx_vtable, ob) < 0) goto bad; Py_DECREF(ob); return 0; bad: Py_XDECREF(ob); return -1; } / PyObjectGetAttrStrNoError / static void __Pyx_PyObject_GetAttrStr_ClearAttributeError(void) { __Pyx_PyThreadState_declare __Pyx_PyThreadState_assign if (likely(__Pyx_PyErr_ExceptionMatches(PyExc_AttributeError))) __Pyx_PyErr_Clear(); } static CYTHON_INLINE PyObject __Pyx_PyObject_GetAttrStrNoError(PyObject* obj, PyObject* attr_name) { PyObject result; #if CYTHON_COMPILING_IN_CPYTHON && CYTHON_USE_TYPE_SLOTS && PY_VERSION_HEX >= 0x030700B1 PyTypeObject tp = Py_TYPE(obj); if (likely(tp->tp_getattro == PyObject_GenericGetAttr)) { return _PyObject_GenericGetAttrWithDict(obj, attr_name, NULL, 1); } #endif result = __Pyx_PyObject_GetAttrStr(obj, attr_name); if (unlikely(!result)) { __Pyx_PyObject_GetAttrStr_ClearAttributeError(); } return result; } /* SetupReduce / static int __Pyx_setup_reduce_is_named(PyObject meth, PyObject* name) { int ret; PyObject name_attr; name_attr = __Pyx_PyObject_GetAttrStr(meth, __pyx_n_s_name_2); if (likely(name_attr)) { ret = PyObject_RichCompareBool(name_attr, name, Py_EQ); } else { ret = -1; } if (unlikely(ret < 0)) { PyErr_Clear(); ret = 0; } Py_XDECREF(name_attr); return ret; } static int __Pyx_setup_reduce(PyObject type_obj) { int ret = 0; PyObject object_reduce = NULL; PyObject object_reduce_ex = NULL; PyObject reduce = NULL; PyObject reduce_ex = NULL; PyObject reduce_cython = NULL; PyObject setstate = NULL; PyObject setstate_cython = NULL; #if CYTHON_USE_PYTYPE_LOOKUP if (_PyType_Lookup((PyTypeObject)type_obj, __pyx_n_s_getstate)) goto __PYX_GOOD; #else if (PyObject_HasAttr(type_obj, __pyx_n_s_getstate)) goto __PYX_GOOD; #endif #if CYTHON_USE_PYTYPE_LOOKUP object_reduce_ex = _PyType_Lookup(&PyBaseObject_Type, __pyx_n_s_reduce_ex); if (!object_reduce_ex) goto __PYX_BAD; #else object_reduce_ex = __Pyx_PyObject_GetAttrStr((PyObject)&PyBaseObject_Type, __pyx_n_s_reduce_ex); if (!object_reduce_ex) goto __PYX_BAD; #endif reduce_ex = __Pyx_PyObject_GetAttrStr(type_obj, __pyx_n_s_reduce_ex); if (unlikely(!reduce_ex)) goto __PYX_BAD; if (reduce_ex == object_reduce_ex) { #if CYTHON_USE_PYTYPE_LOOKUP object_reduce = _PyType_Lookup(&PyBaseObject_Type, __pyx_n_s_reduce); if (!object_reduce) goto __PYX_BAD; #else object_reduce = __Pyx_PyObject_GetAttrStr((PyObject)&PyBaseObject_Type, __pyx_n_s_reduce); if (!object_reduce) goto __PYX_BAD; #endif reduce = __Pyx_PyObject_GetAttrStr(type_obj, __pyx_n_s_reduce); if (unlikely(!reduce)) goto __PYX_BAD; if (reduce == object_reduce \|\| __Pyx_setup_reduce_is_named(reduce, __pyx_n_s_reduce_cython)) { reduce_cython = __Pyx_PyObject_GetAttrStrNoError(type_obj, __pyx_n_s_reduce_cython); if (likely(reduce_cython)) { ret = PyDict_SetItem(((PyTypeObject)type_obj)->tp_dict, __pyx_n_s_reduce, reduce_cython); if (unlikely(ret < 0)) goto __PYX_BAD; ret = PyDict_DelItem(((PyTypeObject)type_obj)->tp_dict, __pyx_n_s_reduce_cython); if (unlikely(ret < 0)) goto __PYX_BAD; } else if (reduce == object_reduce \|\| PyErr_Occurred()) { goto __PYX_BAD; } setstate = __Pyx_PyObject_GetAttrStr(type_obj, __pyx_n_s_setstate); if (!setstate) PyErr_Clear(); if (!setstate \|\| __Pyx_setup_reduce_is_named(setstate, __pyx_n_s_setstate_cython)) { setstate_cython = __Pyx_PyObject_GetAttrStrNoError(type_obj, __pyx_n_s_setstate_cython); if (likely(setstate_cython)) { ret = PyDict_SetItem(((PyTypeObject)type_obj)->tp_dict, __pyx_n_s_setstate, setstate_cython); if (unlikely(ret < 0)) goto __PYX_BAD; ret = PyDict_DelItem(((PyTypeObject)type_obj)->tp_dict, __pyx_n_s_setstate_cython); if (unlikely(ret < 0)) goto __PYX_BAD; } else if (!setstate \|\| PyErr_Occurred()) { goto __PYX_BAD; } } PyType_Modified((PyTypeObject)type_obj); } } goto __PYX_GOOD; __PYX_BAD: if (!PyErr_Occurred()) PyErr_Format(PyExc_RuntimeError, "Unable to initialize pickling for %s", ((PyTypeObject)type_obj)->tp_name); ret = -1; __PYX_GOOD: #if !CYTHON_USE_PYTYPE_LOOKUP Py_XDECREF(object_reduce); Py_XDECREF(object_reduce_ex); #endif Py_XDECREF(reduce); Py_XDECREF(reduce_ex); Py_XDECREF(reduce_cython); Py_XDECREF(setstate); Py_XDECREF(setstate_cython); return ret; } /* CLineInTraceback / #ifndef CYTHON_CLINE_IN_TRACEBACK static int __Pyx_CLineForTraceback(CYTHON_NCP_UNUSED PyThreadState tstate, int c_line) { PyObject use_cline; PyObject ptype, pvalue, ptraceback; #if CYTHON_COMPILING_IN_CPYTHON PyObject *cython_runtime_dict; #endif if (unlikely(!__pyx_cython_runtime)) { return c_line; } __Pyx_ErrFetchInState(tstate, &ptype, &pvalue, &ptraceback); #if CYTHON_COMPILING_IN_CPYTHON cython_runtime_dict = _PyObject_GetDictPtr(__pyx_cython_runtime); if (likely(cython_runtime_dict)) { __PYX_PY_DICT_LOOKUP_IF_MODIFIED( use_cline, cython_runtime_dict, __Pyx_PyDict_GetItemStr(cython_runtime_dict, __pyx_n_s_cline_in_traceback)) } else #endif { PyObject use_cline_obj = __Pyx_PyObject_GetAttrStr(__pyx_cython_runtime, __pyx_n_s_cline_in_traceback); if (use_cline_obj) { use_cline = PyObject_Not(use_cline_obj) ? Py_False : Py_True; Py_DECREF(use_cline_obj); } else { PyErr_Clear(); use_cline = NULL; } } if (!use_cline) { c_line = 0; (void) PyObject_SetAttr(__pyx_cython_runtime, __pyx_n_s_cline_in_traceback, Py_False); } else if (use_cline == Py_False \|\| (use_cline != Py_True && PyObject_Not(use_cline) != 0)) { c_line = 0; } __Pyx_ErrRestoreInState(tstate, ptype, pvalue, ptraceback); return c_line; } #endif /* CodeObjectCache / static int __pyx_bisect_code_objects(__Pyx_CodeObjectCacheEntry entries, int count, int code_line) { int start = 0, mid = 0, end = count - 1; if (end >= 0 && code_line > entries[end].code_line) { return count; } while (start < end) { mid = start + (end - start) / 2; if (code_line < entries[mid].code_line) { end = mid; } else if (code_line > entries[mid].code_line) { start = mid + 1; } else { return mid; } } if (code_line <= entries[mid].code_line) { return mid; } else { return mid + 1; } } static PyCodeObject __pyx_find_code_object(int code_line) { PyCodeObject code_object; int pos; if (unlikely(!code_line) \|\| unlikely(!__pyx_code_cache.entries)) { return NULL; } pos = __pyx_bisect_code_objects(__pyx_code_cache.entries, __pyx_code_cache.count, code_line); if (unlikely(pos >= __pyx_code_cache.count) \|\| unlikely(__pyx_code_cache.entries[pos].code_line != code_line)) { return NULL; } code_object = __pyx_code_cache.entries[pos].code_object; Py_INCREF(code_object); return code_object; } static void __pyx_insert_code_object(int code_line, PyCodeObject* code_object) { int pos, i; __Pyx_CodeObjectCacheEntry* entries = __pyx_code_cache.entries; if (unlikely(!code_line)) { return; } if (unlikely(!entries)) { entries = (__Pyx_CodeObjectCacheEntry)PyMem_Malloc(64sizeof(__Pyx_CodeObjectCacheEntry)); if (likely(entries)) { __pyx_code_cache.entries = entries; __pyx_code_cache.max_count = 64; __pyx_code_cache.count = 1; entries[0].code_line = code_line; entries[0].code_object = code_object; Py_INCREF(code_object); } return; } pos = __pyx_bisect_code_objects(__pyx_code_cache.entries, __pyx_code_cache.count, code_line); if ((pos < __pyx_code_cache.count) && unlikely(__pyx_code_cache.entries[pos].code_line == code_line)) { PyCodeObject* tmp = entries[pos].code_object; entries[pos].code_object = code_object; Py_DECREF(tmp); return; } if (__pyx_code_cache.count == __pyx_code_cache.max_count) { int new_max = __pyx_code_cache.max_count + 64; entries = (__Pyx_CodeObjectCacheEntry)PyMem_Realloc( __pyx_code_cache.entries, ((size_t)new_max) sizeof(__Pyx_CodeObjectCacheEntry)); if (unlikely(!entries)) { return; } __pyx_code_cache.entries = entries; __pyx_code_cache.max_count = new_max; } for (i=__pyx_code_cache.count; i>pos; i--) { entries[i] = entries[i-1]; } entries[pos].code_line = code_line; entries[pos].code_object = code_object; __pyx_code_cache.count++; Py_INCREF(code_object); } /* AddTraceback / #include "compile.h" #include "frameobject.h" #include "traceback.h" static PyCodeObject __Pyx_CreateCodeObjectForTraceback( const char funcname, int c_line, int py_line, const char filename) { PyCodeObject py_code = NULL; PyObject py_funcname = NULL; #if PY_MAJOR_VERSION < 3 PyObject py_srcfile = NULL; py_srcfile = PyString_FromString(filename); if (!py_srcfile) goto bad; #endif if (c_line) { #if PY_MAJOR_VERSION < 3 py_funcname = PyString_FromFormat( "%s (%s:%d)", funcname, __pyx_cfilenm, c_line); if (!py_funcname) goto bad; #else py_funcname = PyUnicode_FromFormat( "%s (%s:%d)", funcname, __pyx_cfilenm, c_line); if (!py_funcname) goto bad; funcname = PyUnicode_AsUTF8(py_funcname); if (!funcname) goto bad; #endif } else { #if PY_MAJOR_VERSION < 3 py_funcname = PyString_FromString(funcname); if (!py_funcname) goto bad; #endif } #if PY_MAJOR_VERSION < 3 py_code = __Pyx_PyCode_New( 0, 0, 0, 0, 0, __pyx_empty_bytes, /PyObject code,/ __pyx_empty_tuple, /PyObject consts,/ __pyx_empty_tuple, /PyObject names,/ __pyx_empty_tuple, /PyObject varnames,/ __pyx_empty_tuple, /PyObject freevars,/ __pyx_empty_tuple, /PyObject cellvars,/ py_srcfile, /PyObject filename,/ py_funcname, /PyObject name,/ py_line, __pyx_empty_bytes /PyObject lnotab/ ); Py_DECREF(py_srcfile); #else py_code = PyCode_NewEmpty(filename, funcname, py_line); #endif Py_XDECREF(py_funcname); // XDECREF since it's only set on Py3 if cline return py_code; bad: Py_XDECREF(py_funcname); #if PY_MAJOR_VERSION < 3 Py_XDECREF(py_srcfile); #endif return NULL; } static void __Pyx_AddTraceback(const char funcname, int c_line, int py_line, const char filename) { PyCodeObject py_code = 0; PyFrameObject py_frame = 0; PyThreadState tstate = __Pyx_PyThreadState_Current; if (c_line) { c_line = __Pyx_CLineForTraceback(tstate, c_line); } py_code = __pyx_find_code_object(c_line ? -c_line : py_line); if (!py_code) { py_code = __Pyx_CreateCodeObjectForTraceback( funcname, c_line, py_line, filename); if (!py_code) goto bad; __pyx_insert_code_object(c_line ? -c_line : py_line, py_code); } py_frame = PyFrame_New( tstate, /PyThreadState tstate,/ py_code, /PyCodeObject code,/ __pyx_d, /PyObject globals,/ 0 /PyObject locals/ ); if (!py_frame) goto bad; __Pyx_PyFrame_SetLineNumber(py_frame, py_line); PyTraceBack_Here(py_frame); bad: Py_XDECREF(py_code); Py_XDECREF(py_frame); } #if PY_MAJOR_VERSION < 3 static int __Pyx_GetBuffer(PyObject obj, Py_buffer view, int flags) { if (PyObject_CheckBuffer(obj)) return PyObject_GetBuffer(obj, view, flags); if (__Pyx_TypeCheck(obj, __pyx_array_type)) return __pyx_array_getbuffer(obj, view, flags); if (__Pyx_TypeCheck(obj, __pyx_memoryview_type)) return __pyx_memoryview_getbuffer(obj, view, flags); PyErr_Format(PyExc_TypeError, "'%.200s' does not have the buffer interface", Py_TYPE(obj)->tp_name); return -1; } static void __Pyx_ReleaseBuffer(Py_buffer view) { PyObject obj = view->obj; if (!obj) return; if (PyObject_CheckBuffer(obj)) { PyBuffer_Release(view); return; } if ((0)) {} view->obj = NULL; Py_DECREF(obj); } #endif / MemviewSliceIsContig / static int __pyx_memviewslice_is_contig(const __Pyx_memviewslice mvs, char order, int ndim) { int i, index, step, start; Py_ssize_t itemsize = mvs.memview->view.itemsize; if (order == 'F') { step = 1; start = 0; } else { step = -1; start = ndim - 1; } for (i = 0; i < ndim; i++) { index = start + step i; if (mvs.suboffsets[index] >= 0 \|\| mvs.strides[index] != itemsize) return 0; itemsize = mvs.shape[index]; } return 1; } / OverlappingSlices / static void __pyx_get_array_memory_extents(__Pyx_memviewslice slice, void out_start, void out_end, int ndim, size_t itemsize) { char start, end; int i; start = end = slice->data; for (i = 0; i < ndim; i++) { Py_ssize_t stride = slice->strides[i]; Py_ssize_t extent = slice->shape[i]; if (extent == 0) { out_start = out_end = start; return; } else { if (stride > 0) end += stride * (extent - 1); else start += stride * (extent - 1); } } out_start = start; out_end = end + itemsize; } static int __pyx_slices_overlap(__Pyx_memviewslice slice1, __Pyx_memviewslice slice2, int ndim, size_t itemsize) { void start1, end1, start2, end2; __pyx_get_array_memory_extents(slice1, &start1, &end1, ndim, itemsize); __pyx_get_array_memory_extents(slice2, &start2, &end2, ndim, itemsize); return (start1 < end2) && (start2 < end1); } /* Capsule / static CYTHON_INLINE PyObject __pyx_capsule_create(void p, CYTHON_UNUSED const char sig) { PyObject cobj; #if PY_VERSION_HEX >= 0x02070000 cobj = PyCapsule_New(p, sig, NULL); #else cobj = PyCObject_FromVoidPtr(p, NULL); #endif return cobj; } / IsLittleEndian / static CYTHON_INLINE int __Pyx_Is_Little_Endian(void) { union { uint32_t u32; uint8_t u8[4]; } S; S.u32 = 0x01020304; return S.u8[0] == 4; } / BufferFormatCheck / static void __Pyx_BufFmt_Init(__Pyx_BufFmt_Context ctx, __Pyx_BufFmt_StackElem* stack, __Pyx_TypeInfo* type) { stack[0].field = &ctx->root; stack[0].parent_offset = 0; ctx->root.type = type; ctx->root.name = "buffer dtype"; ctx->root.offset = 0; ctx->head = stack; ctx->head->field = &ctx->root; ctx->fmt_offset = 0; ctx->head->parent_offset = 0; ctx->new_packmode = '@'; ctx->enc_packmode = '@'; ctx->new_count = 1; ctx->enc_count = 0; ctx->enc_type = 0; ctx->is_complex = 0; ctx->is_valid_array = 0; ctx->struct_alignment = 0; while (type->typegroup == 'S') { ++ctx->head; ctx->head->field = type->fields; ctx->head->parent_offset = 0; type = type->fields->type; } } static int __Pyx_BufFmt_ParseNumber(const char** ts) { int count; const char* t = ts; if (t < '0' \|\| t > '9') { return -1; } else { count = t++ - '0'; while (t >= '0' && t <= '9') { count = 10; count += t++ - '0'; } } ts = t; return count; } static int __Pyx_BufFmt_ExpectNumber(const char ts) { int number = __Pyx_BufFmt_ParseNumber(ts); if (number == -1) PyErr_Format(PyExc_ValueError,\ "Does not understand character buffer dtype format string ('%c')", ts); return number; } static void __Pyx_BufFmt_RaiseUnexpectedChar(char ch) { PyErr_Format(PyExc_ValueError, "Unexpected format string character: '%c'", ch); } static const char __Pyx_BufFmt_DescribeTypeChar(char ch, int is_complex) { switch (ch) { case '?': return "'bool'"; case 'c': return "'char'"; case 'b': return "'signed char'"; case 'B': return "'unsigned char'"; case 'h': return "'short'"; case 'H': return "'unsigned short'"; case 'i': return "'int'"; case 'I': return "'unsigned int'"; case 'l': return "'long'"; case 'L': return "'unsigned long'"; case 'q': return "'long long'"; case 'Q': return "'unsigned long long'"; case 'f': return (is_complex ? "'complex float'" : "'float'"); case 'd': return (is_complex ? "'complex double'" : "'double'"); case 'g': return (is_complex ? "'complex long double'" : "'long double'"); case 'T': return "a struct"; case 'O': return "Python object"; case 'P': return "a pointer"; case 's': case 'p': return "a string"; case 0: return "end"; default: return "unparseable format string"; } } static size_t __Pyx_BufFmt_TypeCharToStandardSize(char ch, int is_complex) { switch (ch) { case '?': case 'c': case 'b': case 'B': case 's': case 'p': return 1; case 'h': case 'H': return 2; case 'i': case 'I': case 'l': case 'L': return 4; case 'q': case 'Q': return 8; case 'f': return (is_complex ? 8 : 4); case 'd': return (is_complex ? 16 : 8); case 'g': { PyErr_SetString(PyExc_ValueError, "Python does not define a standard format string size for long double ('g').."); return 0; } case 'O': case 'P': return sizeof(void); default: __Pyx_BufFmt_RaiseUnexpectedChar(ch); return 0; } } static size_t __Pyx_BufFmt_TypeCharToNativeSize(char ch, int is_complex) { switch (ch) { case '?': case 'c': case 'b': case 'B': case 's': case 'p': return 1; case 'h': case 'H': return sizeof(short); case 'i': case 'I': return sizeof(int); case 'l': case 'L': return sizeof(long); #ifdef HAVE_LONG_LONG case 'q': case 'Q': return sizeof(PY_LONG_LONG); #endif case 'f': return sizeof(float) (is_complex ? 2 : 1); case 'd': return sizeof(double) * (is_complex ? 2 : 1); case 'g': return sizeof(long double) * (is_complex ? 2 : 1); case 'O': case 'P': return sizeof(void); default: { __Pyx_BufFmt_RaiseUnexpectedChar(ch); return 0; } } } typedef struct { char c; short x; } __Pyx_st_short; typedef struct { char c; int x; } __Pyx_st_int; typedef struct { char c; long x; } __Pyx_st_long; typedef struct { char c; float x; } __Pyx_st_float; typedef struct { char c; double x; } __Pyx_st_double; typedef struct { char c; long double x; } __Pyx_st_longdouble; typedef struct { char c; void x; } __Pyx_st_void_p; #ifdef HAVE_LONG_LONG typedef struct { char c; PY_LONG_LONG x; } __Pyx_st_longlong; #endif static size_t __Pyx_BufFmt_TypeCharToAlignment(char ch, CYTHON_UNUSED int is_complex) { switch (ch) { case '?': case 'c': case 'b': case 'B': case 's': case 'p': return 1; case 'h': case 'H': return sizeof(__Pyx_st_short) - sizeof(short); case 'i': case 'I': return sizeof(__Pyx_st_int) - sizeof(int); case 'l': case 'L': return sizeof(__Pyx_st_long) - sizeof(long); #ifdef HAVE_LONG_LONG case 'q': case 'Q': return sizeof(__Pyx_st_longlong) - sizeof(PY_LONG_LONG); #endif case 'f': return sizeof(__Pyx_st_float) - sizeof(float); case 'd': return sizeof(__Pyx_st_double) - sizeof(double); case 'g': return sizeof(__Pyx_st_longdouble) - sizeof(long double); case 'P': case 'O': return sizeof(__Pyx_st_void_p) - sizeof(void); default: __Pyx_BufFmt_RaiseUnexpectedChar(ch); return 0; } } / These are for computing the padding at the end of the struct to align on the first member of the struct. This will probably the same as above, but we don't have any guarantees. / typedef struct { short x; char c; } __Pyx_pad_short; typedef struct { int x; char c; } __Pyx_pad_int; typedef struct { long x; char c; } __Pyx_pad_long; typedef struct { float x; char c; } __Pyx_pad_float; typedef struct { double x; char c; } __Pyx_pad_double; typedef struct { long double x; char c; } __Pyx_pad_longdouble; typedef struct { void x; char c; } __Pyx_pad_void_p; #ifdef HAVE_LONG_LONG typedef struct { PY_LONG_LONG x; char c; } __Pyx_pad_longlong; #endif static size_t __Pyx_BufFmt_TypeCharToPadding(char ch, CYTHON_UNUSED int is_complex) { switch (ch) { case '?': case 'c': case 'b': case 'B': case 's': case 'p': return 1; case 'h': case 'H': return sizeof(__Pyx_pad_short) - sizeof(short); case 'i': case 'I': return sizeof(__Pyx_pad_int) - sizeof(int); case 'l': case 'L': return sizeof(__Pyx_pad_long) - sizeof(long); #ifdef HAVE_LONG_LONG case 'q': case 'Q': return sizeof(__Pyx_pad_longlong) - sizeof(PY_LONG_LONG); #endif case 'f': return sizeof(__Pyx_pad_float) - sizeof(float); case 'd': return sizeof(__Pyx_pad_double) - sizeof(double); case 'g': return sizeof(__Pyx_pad_longdouble) - sizeof(long double); case 'P': case 'O': return sizeof(__Pyx_pad_void_p) - sizeof(void); default: __Pyx_BufFmt_RaiseUnexpectedChar(ch); return 0; } } static char __Pyx_BufFmt_TypeCharToGroup(char ch, int is_complex) { switch (ch) { case 'c': return 'H'; case 'b': case 'h': case 'i': case 'l': case 'q': case 's': case 'p': return 'I'; case '?': case 'B': case 'H': case 'I': case 'L': case 'Q': return 'U'; case 'f': case 'd': case 'g': return (is_complex ? 'C' : 'R'); case 'O': return 'O'; case 'P': return 'P'; default: { __Pyx_BufFmt_RaiseUnexpectedChar(ch); return 0; } } } static void __Pyx_BufFmt_RaiseExpected(__Pyx_BufFmt_Context ctx) { if (ctx->head == NULL \|\| ctx->head->field == &ctx->root) { const char* expected; const char* quote; if (ctx->head == NULL) { expected = "end"; quote = ""; } else { expected = ctx->head->field->type->name; quote = "'"; } PyErr_Format(PyExc_ValueError, "Buffer dtype mismatch, expected %s%s%s but got %s", quote, expected, quote, __Pyx_BufFmt_DescribeTypeChar(ctx->enc_type, ctx->is_complex)); } else { __Pyx_StructField* field = ctx->head->field; __Pyx_StructField* parent = (ctx->head - 1)->field; PyErr_Format(PyExc_ValueError, "Buffer dtype mismatch, expected '%s' but got %s in '%s.%s'", field->type->name, __Pyx_BufFmt_DescribeTypeChar(ctx->enc_type, ctx->is_complex), parent->type->name, field->name); } } static int __Pyx_BufFmt_ProcessTypeChunk(__Pyx_BufFmt_Context* ctx) { char group; size_t size, offset, arraysize = 1; if (ctx->enc_type == 0) return 0; if (ctx->head->field->type->arraysize[0]) { int i, ndim = 0; if (ctx->enc_type == 's' \|\| ctx->enc_type == 'p') { ctx->is_valid_array = ctx->head->field->type->ndim == 1; ndim = 1; if (ctx->enc_count != ctx->head->field->type->arraysize[0]) { PyErr_Format(PyExc_ValueError, "Expected a dimension of size %zu, got %zu", ctx->head->field->type->arraysize[0], ctx->enc_count); return -1; } } if (!ctx->is_valid_array) { PyErr_Format(PyExc_ValueError, "Expected %d dimensions, got %d", ctx->head->field->type->ndim, ndim); return -1; } for (i = 0; i < ctx->head->field->type->ndim; i++) { arraysize = ctx->head->field->type->arraysize[i]; } ctx->is_valid_array = 0; ctx->enc_count = 1; } group = __Pyx_BufFmt_TypeCharToGroup(ctx->enc_type, ctx->is_complex); do { __Pyx_StructField field = ctx->head->field; __Pyx_TypeInfo* type = field->type; if (ctx->enc_packmode == '@' \|\| ctx->enc_packmode == '^') { size = __Pyx_BufFmt_TypeCharToNativeSize(ctx->enc_type, ctx->is_complex); } else { size = __Pyx_BufFmt_TypeCharToStandardSize(ctx->enc_type, ctx->is_complex); } if (ctx->enc_packmode == '@') { size_t align_at = __Pyx_BufFmt_TypeCharToAlignment(ctx->enc_type, ctx->is_complex); size_t align_mod_offset; if (align_at == 0) return -1; align_mod_offset = ctx->fmt_offset % align_at; if (align_mod_offset > 0) ctx->fmt_offset += align_at - align_mod_offset; if (ctx->struct_alignment == 0) ctx->struct_alignment = __Pyx_BufFmt_TypeCharToPadding(ctx->enc_type, ctx->is_complex); } if (type->size != size \|\| type->typegroup != group) { if (type->typegroup == 'C' && type->fields != NULL) { size_t parent_offset = ctx->head->parent_offset + field->offset; ++ctx->head; ctx->head->field = type->fields; ctx->head->parent_offset = parent_offset; continue; } if ((type->typegroup == 'H' \|\| group == 'H') && type->size == size) { } else { __Pyx_BufFmt_RaiseExpected(ctx); return -1; } } offset = ctx->head->parent_offset + field->offset; if (ctx->fmt_offset != offset) { PyErr_Format(PyExc_ValueError, "Buffer dtype mismatch; next field is at offset %" CYTHON_FORMAT_SSIZE_T "d but %" CYTHON_FORMAT_SSIZE_T "d expected", (Py_ssize_t)ctx->fmt_offset, (Py_ssize_t)offset); return -1; } ctx->fmt_offset += size; if (arraysize) ctx->fmt_offset += (arraysize - 1) * size; --ctx->enc_count; while (1) { if (field == &ctx->root) { ctx->head = NULL; if (ctx->enc_count != 0) { __Pyx_BufFmt_RaiseExpected(ctx); return -1; } break; } ctx->head->field = ++field; if (field->type == NULL) { --ctx->head; field = ctx->head->field; continue; } else if (field->type->typegroup == 'S') { size_t parent_offset = ctx->head->parent_offset + field->offset; if (field->type->fields->type == NULL) continue; field = field->type->fields; ++ctx->head; ctx->head->field = field; ctx->head->parent_offset = parent_offset; break; } else { break; } } } while (ctx->enc_count); ctx->enc_type = 0; ctx->is_complex = 0; return 0; } static PyObject * __pyx_buffmt_parse_array(__Pyx_BufFmt_Context* ctx, const char** tsp) { const char ts = tsp; int i = 0, number, ndim; ++ts; if (ctx->new_count != 1) { PyErr_SetString(PyExc_ValueError, "Cannot handle repeated arrays in format string"); return NULL; } if (__Pyx_BufFmt_ProcessTypeChunk(ctx) == -1) return NULL; ndim = ctx->head->field->type->ndim; while (ts && ts != ')') { switch (ts) { case ' ': case '\f': case '\r': case '\n': case '\t': case '\v': continue; default: break; } number = __Pyx_BufFmt_ExpectNumber(&ts); if (number == -1) return NULL; if (i < ndim && (size_t) number != ctx->head->field->type->arraysize[i]) return PyErr_Format(PyExc_ValueError, "Expected a dimension of size %zu, got %d", ctx->head->field->type->arraysize[i], number); if (ts != ',' && ts != ')') return PyErr_Format(PyExc_ValueError, "Expected a comma in format string, got '%c'", ts); if (ts == ',') ts++; i++; } if (i != ndim) return PyErr_Format(PyExc_ValueError, "Expected %d dimension(s), got %d", ctx->head->field->type->ndim, i); if (!ts) { PyErr_SetString(PyExc_ValueError, "Unexpected end of format string, expected ')'"); return NULL; } ctx->is_valid_array = 1; ctx->new_count = 1; tsp = ++ts; return Py_None; } static const char __Pyx_BufFmt_CheckString(__Pyx_BufFmt_Context* ctx, const char* ts) { int got_Z = 0; while (1) { switch(ts) { case 0: if (ctx->enc_type != 0 && ctx->head == NULL) { __Pyx_BufFmt_RaiseExpected(ctx); return NULL; } if (__Pyx_BufFmt_ProcessTypeChunk(ctx) == -1) return NULL; if (ctx->head != NULL) { __Pyx_BufFmt_RaiseExpected(ctx); return NULL; } return ts; case ' ': case '\r': case '\n': ++ts; break; case '<': if (!__Pyx_Is_Little_Endian()) { PyErr_SetString(PyExc_ValueError, "Little-endian buffer not supported on big-endian compiler"); return NULL; } ctx->new_packmode = '='; ++ts; break; case '>': case '!': if (__Pyx_Is_Little_Endian()) { PyErr_SetString(PyExc_ValueError, "Big-endian buffer not supported on little-endian compiler"); return NULL; } ctx->new_packmode = '='; ++ts; break; case '=': case '@': case '^': ctx->new_packmode = ts++; break; case 'T': { const char* ts_after_sub; size_t i, struct_count = ctx->new_count; size_t struct_alignment = ctx->struct_alignment; ctx->new_count = 1; ++ts; if (ts != '{') { PyErr_SetString(PyExc_ValueError, "Buffer acquisition: Expected '{' after 'T'"); return NULL; } if (__Pyx_BufFmt_ProcessTypeChunk(ctx) == -1) return NULL; ctx->enc_type = 0; ctx->enc_count = 0; ctx->struct_alignment = 0; ++ts; ts_after_sub = ts; for (i = 0; i != struct_count; ++i) { ts_after_sub = __Pyx_BufFmt_CheckString(ctx, ts); if (!ts_after_sub) return NULL; } ts = ts_after_sub; if (struct_alignment) ctx->struct_alignment = struct_alignment; } break; case '}': { size_t alignment = ctx->struct_alignment; ++ts; if (__Pyx_BufFmt_ProcessTypeChunk(ctx) == -1) return NULL; ctx->enc_type = 0; if (alignment && ctx->fmt_offset % alignment) { ctx->fmt_offset += alignment - (ctx->fmt_offset % alignment); } } return ts; case 'x': if (__Pyx_BufFmt_ProcessTypeChunk(ctx) == -1) return NULL; ctx->fmt_offset += ctx->new_count; ctx->new_count = 1; ctx->enc_count = 0; ctx->enc_type = 0; ctx->enc_packmode = ctx->new_packmode; ++ts; break; case 'Z': got_Z = 1; ++ts; if (ts != 'f' && ts != 'd' && ts != 'g') { __Pyx_BufFmt_RaiseUnexpectedChar('Z'); return NULL; } CYTHON_FALLTHROUGH; case '?': case 'c': case 'b': case 'B': case 'h': case 'H': case 'i': case 'I': case 'l': case 'L': case 'q': case 'Q': case 'f': case 'd': case 'g': case 'O': case 'p': if ((ctx->enc_type == ts) && (got_Z == ctx->is_complex) && (ctx->enc_packmode == ctx->new_packmode) && (!ctx->is_valid_array)) { ctx->enc_count += ctx->new_count; ctx->new_count = 1; got_Z = 0; ++ts; break; } CYTHON_FALLTHROUGH; case 's': if (__Pyx_BufFmt_ProcessTypeChunk(ctx) == -1) return NULL; ctx->enc_count = ctx->new_count; ctx->enc_packmode = ctx->new_packmode; ctx->enc_type = ts; ctx->is_complex = got_Z; ++ts; ctx->new_count = 1; got_Z = 0; break; case ':': ++ts; while(ts != ':') ++ts; ++ts; break; case '(': if (!__pyx_buffmt_parse_array(ctx, &ts)) return NULL; break; default: { int number = __Pyx_BufFmt_ExpectNumber(&ts); if (number == -1) return NULL; ctx->new_count = (size_t)number; } } } } / TypeInfoCompare / static int __pyx_typeinfo_cmp(__Pyx_TypeInfo a, __Pyx_TypeInfo b) { int i; if (!a \|\| !b) return 0; if (a == b) return 1; if (a->size != b->size \|\| a->typegroup != b->typegroup \|\| a->is_unsigned != b->is_unsigned \|\| a->ndim != b->ndim) { if (a->typegroup == 'H' \|\| b->typegroup == 'H') { return a->size == b->size; } else { return 0; } } if (a->ndim) { for (i = 0; i < a->ndim; i++) if (a->arraysize[i] != b->arraysize[i]) return 0; } if (a->typegroup == 'S') { if (a->flags != b->flags) return 0; if (a->fields \|\| b->fields) { if (!(a->fields && b->fields)) return 0; for (i = 0; a->fields[i].type && b->fields[i].type; i++) { __Pyx_StructField field_a = a->fields + i; __Pyx_StructField field_b = b->fields + i; if (field_a->offset != field_b->offset \|\| !__pyx_typeinfo_cmp(field_a->type, field_b->type)) return 0; } return !a->fields[i].type && !b->fields[i].type; } } return 1; } / MemviewSliceValidateAndInit / static int __pyx_check_strides(Py_buffer buf, int dim, int ndim, int spec) { if (buf->shape[dim] <= 1) return 1; if (buf->strides) { if (spec & __Pyx_MEMVIEW_CONTIG) { if (spec & (__Pyx_MEMVIEW_PTR\|__Pyx_MEMVIEW_FULL)) { if (unlikely(buf->strides[dim] != sizeof(void ))) { PyErr_Format(PyExc_ValueError, "Buffer is not indirectly contiguous " "in dimension %d.", dim); goto fail; } } else if (unlikely(buf->strides[dim] != buf->itemsize)) { PyErr_SetString(PyExc_ValueError, "Buffer and memoryview are not contiguous " "in the same dimension."); goto fail; } } if (spec & __Pyx_MEMVIEW_FOLLOW) { Py_ssize_t stride = buf->strides[dim]; if (stride < 0) stride = -stride; if (unlikely(stride < buf->itemsize)) { PyErr_SetString(PyExc_ValueError, "Buffer and memoryview are not contiguous " "in the same dimension."); goto fail; } } } else { if (unlikely(spec & __Pyx_MEMVIEW_CONTIG && dim != ndim - 1)) { PyErr_Format(PyExc_ValueError, "C-contiguous buffer is not contiguous in " "dimension %d", dim); goto fail; } else if (unlikely(spec & (__Pyx_MEMVIEW_PTR))) { PyErr_Format(PyExc_ValueError, "C-contiguous buffer is not indirect in " "dimension %d", dim); goto fail; } else if (unlikely(buf->suboffsets)) { PyErr_SetString(PyExc_ValueError, "Buffer exposes suboffsets but no strides"); goto fail; } } return 1; fail: return 0; } static int __pyx_check_suboffsets(Py_buffer buf, int dim, CYTHON_UNUSED int ndim, int spec) { if (spec & __Pyx_MEMVIEW_DIRECT) { if (unlikely(buf->suboffsets && buf->suboffsets[dim] >= 0)) { PyErr_Format(PyExc_ValueError, "Buffer not compatible with direct access " "in dimension %d.", dim); goto fail; } } if (spec & __Pyx_MEMVIEW_PTR) { if (unlikely(!buf->suboffsets \|\| (buf->suboffsets[dim] < 0))) { PyErr_Format(PyExc_ValueError, "Buffer is not indirectly accessible " "in dimension %d.", dim); goto fail; } } return 1; fail: return 0; } static int __pyx_verify_contig(Py_buffer buf, int ndim, int c_or_f_flag) { int i; if (c_or_f_flag & __Pyx_IS_F_CONTIG) { Py_ssize_t stride = 1; for (i = 0; i < ndim; i++) { if (unlikely(stride buf->itemsize != buf->strides[i] && buf->shape[i] > 1)) { PyErr_SetString(PyExc_ValueError, "Buffer not fortran contiguous."); goto fail; } stride = stride * buf->shape[i]; } } else if (c_or_f_flag & __Pyx_IS_C_CONTIG) { Py_ssize_t stride = 1; for (i = ndim - 1; i >- 1; i--) { if (unlikely(stride * buf->itemsize != buf->strides[i] && buf->shape[i] > 1)) { PyErr_SetString(PyExc_ValueError, "Buffer not C contiguous."); goto fail; } stride = stride * buf->shape[i]; } } return 1; fail: return 0; } static int __Pyx_ValidateAndInit_memviewslice( int axes_specs, int c_or_f_flag, int buf_flags, int ndim, __Pyx_TypeInfo dtype, __Pyx_BufFmt_StackElem stack[], __Pyx_memviewslice memviewslice, PyObject original_obj) { struct __pyx_memoryview_obj memview, new_memview; __Pyx_RefNannyDeclarations Py_buffer buf; int i, spec = 0, retval = -1; __Pyx_BufFmt_Context ctx; int from_memoryview = __pyx_memoryview_check(original_obj); __Pyx_RefNannySetupContext("ValidateAndInit_memviewslice", 0); if (from_memoryview && __pyx_typeinfo_cmp(dtype, ((struct __pyx_memoryview_obj ) original_obj)->typeinfo)) { memview = (struct __pyx_memoryview_obj ) original_obj; new_memview = NULL; } else { memview = (struct __pyx_memoryview_obj ) __pyx_memoryview_new( original_obj, buf_flags, 0, dtype); new_memview = memview; if (unlikely(!memview)) goto fail; } buf = &memview->view; if (unlikely(buf->ndim != ndim)) { PyErr_Format(PyExc_ValueError, "Buffer has wrong number of dimensions (expected %d, got %d)", ndim, buf->ndim); goto fail; } if (new_memview) { __Pyx_BufFmt_Init(&ctx, stack, dtype); if (unlikely(!__Pyx_BufFmt_CheckString(&ctx, buf->format))) goto fail; } if (unlikely((unsigned) buf->itemsize != dtype->size)) { PyErr_Format(PyExc_ValueError, "Item size of buffer (%" CYTHON_FORMAT_SSIZE_T "u byte%s) " "does not match size of '%s' (%" CYTHON_FORMAT_SSIZE_T "u byte%s)", buf->itemsize, (buf->itemsize > 1) ? "s" : "", dtype->name, dtype->size, (dtype->size > 1) ? "s" : ""); goto fail; } if (buf->len > 0) { for (i = 0; i < ndim; i++) { spec = axes_specs[i]; if (unlikely(!__pyx_check_strides(buf, i, ndim, spec))) goto fail; if (unlikely(!__pyx_check_suboffsets(buf, i, ndim, spec))) goto fail; } if (unlikely(buf->strides && !__pyx_verify_contig(buf, ndim, c_or_f_flag))) goto fail; } if (unlikely(__Pyx_init_memviewslice(memview, ndim, memviewslice, new_memview != NULL) == -1)) { goto fail; } retval = 0; goto no_fail; fail: Py_XDECREF(new_memview); retval = -1; no_fail: __Pyx_RefNannyFinishContext(); return retval; } /* ObjectToMemviewSlice / static CYTHON_INLINE __Pyx_memviewslice __Pyx_PyObject_to_MemoryviewSlice_d_dc_double(PyObject obj, int writable_flag) { __Pyx_memviewslice result = { 0, 0, { 0 }, { 0 }, { 0 } }; __Pyx_BufFmt_StackElem stack[1]; int axes_specs[] = { (__Pyx_MEMVIEW_DIRECT \| __Pyx_MEMVIEW_FOLLOW), (__Pyx_MEMVIEW_DIRECT \| __Pyx_MEMVIEW_CONTIG) }; int retcode; if (obj == Py_None) { result.memview = (struct __pyx_memoryview_obj ) Py_None; return result; } retcode = __Pyx_ValidateAndInit_memviewslice(axes_specs, __Pyx_IS_C_CONTIG, (PyBUF_C_CONTIGUOUS \| PyBUF_FORMAT) \| writable_flag, 2, &__Pyx_TypeInfo_double, stack, &result, obj); if (unlikely(retcode == -1)) goto __pyx_fail; return result; __pyx_fail: result.memview = NULL; result.data = NULL; return result; } / ObjectToMemviewSlice / static CYTHON_INLINE __Pyx_memviewslice __Pyx_PyObject_to_MemoryviewSlice_ds_double(PyObject obj, int writable_flag) { __Pyx_memviewslice result = { 0, 0, { 0 }, { 0 }, { 0 } }; __Pyx_BufFmt_StackElem stack[1]; int axes_specs[] = { (__Pyx_MEMVIEW_DIRECT \| __Pyx_MEMVIEW_STRIDED) }; int retcode; if (obj == Py_None) { result.memview = (struct __pyx_memoryview_obj ) Py_None; return result; } retcode = __Pyx_ValidateAndInit_memviewslice(axes_specs, 0, PyBUF_RECORDS_RO \| writable_flag, 1, &__Pyx_TypeInfo_double, stack, &result, obj); if (unlikely(retcode == -1)) goto __pyx_fail; return result; __pyx_fail: result.memview = NULL; result.data = NULL; return result; } / ObjectToMemviewSlice / static CYTHON_INLINE __Pyx_memviewslice __Pyx_PyObject_to_MemoryviewSlice_dc_double(PyObject obj, int writable_flag) { __Pyx_memviewslice result = { 0, 0, { 0 }, { 0 }, { 0 } }; __Pyx_BufFmt_StackElem stack[1]; int axes_specs[] = { (__Pyx_MEMVIEW_DIRECT \| __Pyx_MEMVIEW_CONTIG) }; int retcode; if (obj == Py_None) { result.memview = (struct __pyx_memoryview_obj ) Py_None; return result; } retcode = __Pyx_ValidateAndInit_memviewslice(axes_specs, __Pyx_IS_C_CONTIG, (PyBUF_C_CONTIGUOUS \| PyBUF_FORMAT) \| writable_flag, 1, &__Pyx_TypeInfo_double, stack, &result, obj); if (unlikely(retcode == -1)) goto __pyx_fail; return result; __pyx_fail: result.memview = NULL; result.data = NULL; return result; } / ObjectToMemviewSlice / static CYTHON_INLINE __Pyx_memviewslice __Pyx_PyObject_to_MemoryviewSlice_d_dc_long(PyObject obj, int writable_flag) { __Pyx_memviewslice result = { 0, 0, { 0 }, { 0 }, { 0 } }; __Pyx_BufFmt_StackElem stack[1]; int axes_specs[] = { (__Pyx_MEMVIEW_DIRECT \| __Pyx_MEMVIEW_FOLLOW), (__Pyx_MEMVIEW_DIRECT \| __Pyx_MEMVIEW_CONTIG) }; int retcode; if (obj == Py_None) { result.memview = (struct __pyx_memoryview_obj ) Py_None; return result; } retcode = __Pyx_ValidateAndInit_memviewslice(axes_specs, __Pyx_IS_C_CONTIG, (PyBUF_C_CONTIGUOUS \| PyBUF_FORMAT) \| writable_flag, 2, &__Pyx_TypeInfo_long, stack, &result, obj); if (unlikely(retcode == -1)) goto __pyx_fail; return result; __pyx_fail: result.memview = NULL; result.data = NULL; return result; } / CIntFromPyVerify / #define __PYX_VERIFY_RETURN_INT(target_type, func_type, func_value)\ __PYX__VERIFY_RETURN_INT(target_type, func_type, func_value, 0) #define __PYX_VERIFY_RETURN_INT_EXC(target_type, func_type, func_value)\ __PYX__VERIFY_RETURN_INT(target_type, func_type, func_value, 1) #define __PYX__VERIFY_RETURN_INT(target_type, func_type, func_value, exc)\ {\ func_type value = func_value;\ if (sizeof(target_type) < sizeof(func_type)) {\ if (unlikely(value != (func_type) (target_type) value)) {\ func_type zero = 0;\ if (exc && unlikely(value == (func_type)-1 && PyErr_Occurred()))\ return (target_type) -1;\ if (is_unsigned && unlikely(value < zero))\ goto raise_neg_overflow;\ else\ goto raise_overflow;\ }\ }\ return (target_type) value;\ } / MemviewDtypeToObject / static CYTHON_INLINE PyObject __pyx_memview_get_double(const char itemp) { return (PyObject ) PyFloat_FromDouble((double ) itemp); } static CYTHON_INLINE int __pyx_memview_set_double(const char itemp, PyObject obj) { double value = __pyx_PyFloat_AsDouble(obj); if ((value == (double)-1) && PyErr_Occurred()) return 0; (double ) itemp = value; return 1; } /* MemviewSliceCopyTemplate / static __Pyx_memviewslice __pyx_memoryview_copy_new_contig(const __Pyx_memviewslice from_mvs, const char mode, int ndim, size_t sizeof_dtype, int contig_flag, int dtype_is_object) { __Pyx_RefNannyDeclarations int i; __Pyx_memviewslice new_mvs = { 0, 0, { 0 }, { 0 }, { 0 } }; struct __pyx_memoryview_obj from_memview = from_mvs->memview; Py_buffer buf = &from_memview->view; PyObject shape_tuple = NULL; PyObject temp_int = NULL; struct __pyx_array_obj array_obj = NULL; struct __pyx_memoryview_obj memview_obj = NULL; __Pyx_RefNannySetupContext("__pyx_memoryview_copy_new_contig", 0); for (i = 0; i < ndim; i++) { if (unlikely(from_mvs->suboffsets[i] >= 0)) { PyErr_Format(PyExc_ValueError, "Cannot copy memoryview slice with " "indirect dimensions (axis %d)", i); goto fail; } } shape_tuple = PyTuple_New(ndim); if (unlikely(!shape_tuple)) { goto fail; } __Pyx_GOTREF(shape_tuple); for(i = 0; i < ndim; i++) { temp_int = PyInt_FromSsize_t(from_mvs->shape[i]); if(unlikely(!temp_int)) { goto fail; } else { PyTuple_SET_ITEM(shape_tuple, i, temp_int); temp_int = NULL; } } array_obj = __pyx_array_new(shape_tuple, sizeof_dtype, buf->format, (char ) mode, NULL); if (unlikely(!array_obj)) { goto fail; } __Pyx_GOTREF(array_obj); memview_obj = (struct __pyx_memoryview_obj ) __pyx_memoryview_new( (PyObject ) array_obj, contig_flag, dtype_is_object, from_mvs->memview->typeinfo); if (unlikely(!memview_obj)) goto fail; if (unlikely(__Pyx_init_memviewslice(memview_obj, ndim, &new_mvs, 1) < 0)) goto fail; if (unlikely(__pyx_memoryview_copy_contents(from_mvs, new_mvs, ndim, ndim, dtype_is_object) < 0)) goto fail; goto no_fail; fail: __Pyx_XDECREF(new_mvs.memview); new_mvs.memview = NULL; new_mvs.data = NULL; no_fail: __Pyx_XDECREF(shape_tuple); __Pyx_XDECREF(temp_int); __Pyx_XDECREF(array_obj); __Pyx_RefNannyFinishContext(); return new_mvs; } / CIntFromPy / static CYTHON_INLINE long __Pyx_PyInt_As_long(PyObject x) { #ifdef __Pyx_HAS_GCC_DIAGNOSTIC #pragma GCC diagnostic push #pragma GCC diagnostic ignored "-Wconversion" #endif const long neg_one = (long) -1, const_zero = (long) 0; #ifdef __Pyx_HAS_GCC_DIAGNOSTIC #pragma GCC diagnostic pop #endif const int is_unsigned = neg_one > const_zero; #if PY_MAJOR_VERSION < 3 if (likely(PyInt_Check(x))) { if (sizeof(long) < sizeof(long)) { __PYX_VERIFY_RETURN_INT(long, long, PyInt_AS_LONG(x)) } else { long val = PyInt_AS_LONG(x); if (is_unsigned && unlikely(val < 0)) { goto raise_neg_overflow; } return (long) val; } } else #endif if (likely(PyLong_Check(x))) { if (is_unsigned) { #if CYTHON_USE_PYLONG_INTERNALS const digit* digits = ((PyLongObject)x)->ob_digit; switch (Py_SIZE(x)) { case 0: return (long) 0; case 1: __PYX_VERIFY_RETURN_INT(long, digit, digits[0]) case 2: if (8 sizeof(long) > 1 * PyLong_SHIFT) { if (8 * sizeof(unsigned long) > 2 * PyLong_SHIFT) { __PYX_VERIFY_RETURN_INT(long, unsigned long, (((((unsigned long)digits[1]) << PyLong_SHIFT) \| (unsigned long)digits[0]))) } else if (8 * sizeof(long) >= 2 * PyLong_SHIFT) { return (long) (((((long)digits[1]) << PyLong_SHIFT) \| (long)digits[0])); } } break; case 3: if (8 * sizeof(long) > 2 * PyLong_SHIFT) { if (8 * sizeof(unsigned long) > 3 * PyLong_SHIFT) { __PYX_VERIFY_RETURN_INT(long, unsigned long, (((((((unsigned long)digits[2]) << PyLong_SHIFT) \| (unsigned long)digits[1]) << PyLong_SHIFT) \| (unsigned long)digits[0]))) } else if (8 * sizeof(long) >= 3 * PyLong_SHIFT) { return (long) (((((((long)digits[2]) << PyLong_SHIFT) \| (long)digits[1]) << PyLong_SHIFT) \| (long)digits[0])); } } break; case 4: if (8 * sizeof(long) > 3 * PyLong_SHIFT) { if (8 * sizeof(unsigned long) > 4 * PyLong_SHIFT) { __PYX_VERIFY_RETURN_INT(long, unsigned long, (((((((((unsigned long)digits[3]) << PyLong_SHIFT) \| (unsigned long)digits[2]) << PyLong_SHIFT) \| (unsigned long)digits[1]) << PyLong_SHIFT) \| (unsigned long)digits[0]))) } else if (8 * sizeof(long) >= 4 * PyLong_SHIFT) { return (long) (((((((((long)digits[3]) << PyLong_SHIFT) \| (long)digits[2]) << PyLong_SHIFT) \| (long)digits[1]) << PyLong_SHIFT) \| (long)digits[0])); } } break; } #endif #if CYTHON_COMPILING_IN_CPYTHON if (unlikely(Py_SIZE(x) < 0)) { goto raise_neg_overflow; } #else { int result = PyObject_RichCompareBool(x, Py_False, Py_LT); if (unlikely(result < 0)) return (long) -1; if (unlikely(result == 1)) goto raise_neg_overflow; } #endif if (sizeof(long) <= sizeof(unsigned long)) { __PYX_VERIFY_RETURN_INT_EXC(long, unsigned long, PyLong_AsUnsignedLong(x)) #ifdef HAVE_LONG_LONG } else if (sizeof(long) <= sizeof(unsigned PY_LONG_LONG)) { __PYX_VERIFY_RETURN_INT_EXC(long, unsigned PY_LONG_LONG, PyLong_AsUnsignedLongLong(x)) #endif } } else { #if CYTHON_USE_PYLONG_INTERNALS const digit* digits = ((PyLongObject)x)->ob_digit; switch (Py_SIZE(x)) { case 0: return (long) 0; case -1: __PYX_VERIFY_RETURN_INT(long, sdigit, (sdigit) (-(sdigit)digits[0])) case 1: __PYX_VERIFY_RETURN_INT(long, digit, +digits[0]) case -2: if (8 sizeof(long) - 1 > 1 * PyLong_SHIFT) { if (8 * sizeof(unsigned long) > 2 * PyLong_SHIFT) { __PYX_VERIFY_RETURN_INT(long, long, -(long) (((((unsigned long)digits[1]) << PyLong_SHIFT) \| (unsigned long)digits[0]))) } else if (8 * sizeof(long) - 1 > 2 * PyLong_SHIFT) { return (long) (((long)-1)(((((long)digits[1]) << PyLong_SHIFT) \| (long)digits[0]))); } } break; case 2: if (8 sizeof(long) > 1 * PyLong_SHIFT) { if (8 * sizeof(unsigned long) > 2 * PyLong_SHIFT) { __PYX_VERIFY_RETURN_INT(long, unsigned long, (((((unsigned long)digits[1]) << PyLong_SHIFT) \| (unsigned long)digits[0]))) } else if (8 * sizeof(long) - 1 > 2 * PyLong_SHIFT) { return (long) ((((((long)digits[1]) << PyLong_SHIFT) \| (long)digits[0]))); } } break; case -3: if (8 * sizeof(long) - 1 > 2 * PyLong_SHIFT) { if (8 * sizeof(unsigned long) > 3 * PyLong_SHIFT) { __PYX_VERIFY_RETURN_INT(long, long, -(long) (((((((unsigned long)digits[2]) << PyLong_SHIFT) \| (unsigned long)digits[1]) << PyLong_SHIFT) \| (unsigned long)digits[0]))) } else if (8 * sizeof(long) - 1 > 3 * PyLong_SHIFT) { return (long) (((long)-1)(((((((long)digits[2]) << PyLong_SHIFT) \| (long)digits[1]) << PyLong_SHIFT) \| (long)digits[0]))); } } break; case 3: if (8 sizeof(long) > 2 * PyLong_SHIFT) { if (8 * sizeof(unsigned long) > 3 * PyLong_SHIFT) { __PYX_VERIFY_RETURN_INT(long, unsigned long, (((((((unsigned long)digits[2]) << PyLong_SHIFT) \| (unsigned long)digits[1]) << PyLong_SHIFT) \| (unsigned long)digits[0]))) } else if (8 * sizeof(long) - 1 > 3 * PyLong_SHIFT) { return (long) ((((((((long)digits[2]) << PyLong_SHIFT) \| (long)digits[1]) << PyLong_SHIFT) \| (long)digits[0]))); } } break; case -4: if (8 * sizeof(long) - 1 > 3 * PyLong_SHIFT) { if (8 * sizeof(unsigned long) > 4 * PyLong_SHIFT) { __PYX_VERIFY_RETURN_INT(long, long, -(long) (((((((((unsigned long)digits[3]) << PyLong_SHIFT) \| (unsigned long)digits[2]) << PyLong_SHIFT) \| (unsigned long)digits[1]) << PyLong_SHIFT) \| (unsigned long)digits[0]))) } else if (8 * sizeof(long) - 1 > 4 * PyLong_SHIFT) { return (long) (((long)-1)(((((((((long)digits[3]) << PyLong_SHIFT) \| (long)digits[2]) << PyLong_SHIFT) \| (long)digits[1]) << PyLong_SHIFT) \| (long)digits[0]))); } } break; case 4: if (8 sizeof(long) > 3 * PyLong_SHIFT) { if (8 * sizeof(unsigned long) > 4 * PyLong_SHIFT) { __PYX_VERIFY_RETURN_INT(long, unsigned long, (((((((((unsigned long)digits[3]) << PyLong_SHIFT) \| (unsigned long)digits[2]) << PyLong_SHIFT) \| (unsigned long)digits[1]) << PyLong_SHIFT) \| (unsigned long)digits[0]))) } else if (8 * sizeof(long) - 1 > 4 * PyLong_SHIFT) { return (long) ((((((((((long)digits[3]) << PyLong_SHIFT) \| (long)digits[2]) << PyLong_SHIFT) \| (long)digits[1]) << PyLong_SHIFT) \| (long)digits[0]))); } } break; } #endif if (sizeof(long) <= sizeof(long)) { __PYX_VERIFY_RETURN_INT_EXC(long, long, PyLong_AsLong(x)) #ifdef HAVE_LONG_LONG } else if (sizeof(long) <= sizeof(PY_LONG_LONG)) { __PYX_VERIFY_RETURN_INT_EXC(long, PY_LONG_LONG, PyLong_AsLongLong(x)) #endif } } { #if CYTHON_COMPILING_IN_PYPY && !defined(_PyLong_AsByteArray) PyErr_SetString(PyExc_RuntimeError, "_PyLong_AsByteArray() not available in PyPy, cannot convert large numbers"); #else long val; PyObject v = __Pyx_PyNumber_IntOrLong(x); #if PY_MAJOR_VERSION < 3 if (likely(v) && !PyLong_Check(v)) { PyObject tmp = v; v = PyNumber_Long(tmp); Py_DECREF(tmp); } #endif if (likely(v)) { int one = 1; int is_little = (int)(unsigned char )&one; unsigned char bytes = (unsigned char )&val; int ret = _PyLong_AsByteArray((PyLongObject )v, bytes, sizeof(val), is_little, !is_unsigned); Py_DECREF(v); if (likely(!ret)) return val; } #endif return (long) -1; } } else { long val; PyObject tmp = __Pyx_PyNumber_IntOrLong(x); if (!tmp) return (long) -1; val = __Pyx_PyInt_As_long(tmp); Py_DECREF(tmp); return val; } raise_overflow: PyErr_SetString(PyExc_OverflowError, "value too large to convert to long"); return (long) -1; raise_neg_overflow: PyErr_SetString(PyExc_OverflowError, "can't convert negative value to long"); return (long) -1; } /* CIntFromPy / static CYTHON_INLINE int __Pyx_PyInt_As_int(PyObject x) { #ifdef __Pyx_HAS_GCC_DIAGNOSTIC #pragma GCC diagnostic push #pragma GCC diagnostic ignored "-Wconversion" #endif const int neg_one = (int) -1, const_zero = (int) 0; #ifdef __Pyx_HAS_GCC_DIAGNOSTIC #pragma GCC diagnostic pop #endif const int is_unsigned = neg_one > const_zero; #if PY_MAJOR_VERSION < 3 if (likely(PyInt_Check(x))) { if (sizeof(int) < sizeof(long)) { __PYX_VERIFY_RETURN_INT(int, long, PyInt_AS_LONG(x)) } else { long val = PyInt_AS_LONG(x); if (is_unsigned && unlikely(val < 0)) { goto raise_neg_overflow; } return (int) val; } } else #endif if (likely(PyLong_Check(x))) { if (is_unsigned) { #if CYTHON_USE_PYLONG_INTERNALS const digit* digits = ((PyLongObject)x)->ob_digit; switch (Py_SIZE(x)) { case 0: return (int) 0; case 1: __PYX_VERIFY_RETURN_INT(int, digit, digits[0]) case 2: if (8 sizeof(int) > 1 * PyLong_SHIFT) { if (8 * sizeof(unsigned long) > 2 * PyLong_SHIFT) { __PYX_VERIFY_RETURN_INT(int, unsigned long, (((((unsigned long)digits[1]) << PyLong_SHIFT) \| (unsigned long)digits[0]))) } else if (8 * sizeof(int) >= 2 * PyLong_SHIFT) { return (int) (((((int)digits[1]) << PyLong_SHIFT) \| (int)digits[0])); } } break; case 3: if (8 * sizeof(int) > 2 * PyLong_SHIFT) { if (8 * sizeof(unsigned long) > 3 * PyLong_SHIFT) { __PYX_VERIFY_RETURN_INT(int, unsigned long, (((((((unsigned long)digits[2]) << PyLong_SHIFT) \| (unsigned long)digits[1]) << PyLong_SHIFT) \| (unsigned long)digits[0]))) } else if (8 * sizeof(int) >= 3 * PyLong_SHIFT) { return (int) (((((((int)digits[2]) << PyLong_SHIFT) \| (int)digits[1]) << PyLong_SHIFT) \| (int)digits[0])); } } break; case 4: if (8 * sizeof(int) > 3 * PyLong_SHIFT) { if (8 * sizeof(unsigned long) > 4 * PyLong_SHIFT) { __PYX_VERIFY_RETURN_INT(int, unsigned long, (((((((((unsigned long)digits[3]) << PyLong_SHIFT) \| (unsigned long)digits[2]) << PyLong_SHIFT) \| (unsigned long)digits[1]) << PyLong_SHIFT) \| (unsigned long)digits[0]))) } else if (8 * sizeof(int) >= 4 * PyLong_SHIFT) { return (int) (((((((((int)digits[3]) << PyLong_SHIFT) \| (int)digits[2]) << PyLong_SHIFT) \| (int)digits[1]) << PyLong_SHIFT) \| (int)digits[0])); } } break; } #endif #if CYTHON_COMPILING_IN_CPYTHON if (unlikely(Py_SIZE(x) < 0)) { goto raise_neg_overflow; } #else { int result = PyObject_RichCompareBool(x, Py_False, Py_LT); if (unlikely(result < 0)) return (int) -1; if (unlikely(result == 1)) goto raise_neg_overflow; } #endif if (sizeof(int) <= sizeof(unsigned long)) { __PYX_VERIFY_RETURN_INT_EXC(int, unsigned long, PyLong_AsUnsignedLong(x)) #ifdef HAVE_LONG_LONG } else if (sizeof(int) <= sizeof(unsigned PY_LONG_LONG)) { __PYX_VERIFY_RETURN_INT_EXC(int, unsigned PY_LONG_LONG, PyLong_AsUnsignedLongLong(x)) #endif } } else { #if CYTHON_USE_PYLONG_INTERNALS const digit* digits = ((PyLongObject)x)->ob_digit; switch (Py_SIZE(x)) { case 0: return (int) 0; case -1: __PYX_VERIFY_RETURN_INT(int, sdigit, (sdigit) (-(sdigit)digits[0])) case 1: __PYX_VERIFY_RETURN_INT(int, digit, +digits[0]) case -2: if (8 sizeof(int) - 1 > 1 * PyLong_SHIFT) { if (8 * sizeof(unsigned long) > 2 * PyLong_SHIFT) { __PYX_VERIFY_RETURN_INT(int, long, -(long) (((((unsigned long)digits[1]) << PyLong_SHIFT) \| (unsigned long)digits[0]))) } else if (8 * sizeof(int) - 1 > 2 * PyLong_SHIFT) { return (int) (((int)-1)(((((int)digits[1]) << PyLong_SHIFT) \| (int)digits[0]))); } } break; case 2: if (8 sizeof(int) > 1 * PyLong_SHIFT) { if (8 * sizeof(unsigned long) > 2 * PyLong_SHIFT) { __PYX_VERIFY_RETURN_INT(int, unsigned long, (((((unsigned long)digits[1]) << PyLong_SHIFT) \| (unsigned long)digits[0]))) } else if (8 * sizeof(int) - 1 > 2 * PyLong_SHIFT) { return (int) ((((((int)digits[1]) << PyLong_SHIFT) \| (int)digits[0]))); } } break; case -3: if (8 * sizeof(int) - 1 > 2 * PyLong_SHIFT) { if (8 * sizeof(unsigned long) > 3 * PyLong_SHIFT) { __PYX_VERIFY_RETURN_INT(int, long, -(long) (((((((unsigned long)digits[2]) << PyLong_SHIFT) \| (unsigned long)digits[1]) << PyLong_SHIFT) \| (unsigned long)digits[0]))) } else if (8 * sizeof(int) - 1 > 3 * PyLong_SHIFT) { return (int) (((int)-1)(((((((int)digits[2]) << PyLong_SHIFT) \| (int)digits[1]) << PyLong_SHIFT) \| (int)digits[0]))); } } break; case 3: if (8 sizeof(int) > 2 * PyLong_SHIFT) { if (8 * sizeof(unsigned long) > 3 * PyLong_SHIFT) { __PYX_VERIFY_RETURN_INT(int, unsigned long, (((((((unsigned long)digits[2]) << PyLong_SHIFT) \| (unsigned long)digits[1]) << PyLong_SHIFT) \| (unsigned long)digits[0]))) } else if (8 * sizeof(int) - 1 > 3 * PyLong_SHIFT) { return (int) ((((((((int)digits[2]) << PyLong_SHIFT) \| (int)digits[1]) << PyLong_SHIFT) \| (int)digits[0]))); } } break; case -4: if (8 * sizeof(int) - 1 > 3 * PyLong_SHIFT) { if (8 * sizeof(unsigned long) > 4 * PyLong_SHIFT) { __PYX_VERIFY_RETURN_INT(int, long, -(long) (((((((((unsigned long)digits[3]) << PyLong_SHIFT) \| (unsigned long)digits[2]) << PyLong_SHIFT) \| (unsigned long)digits[1]) << PyLong_SHIFT) \| (unsigned long)digits[0]))) } else if (8 * sizeof(int) - 1 > 4 * PyLong_SHIFT) { return (int) (((int)-1)(((((((((int)digits[3]) << PyLong_SHIFT) \| (int)digits[2]) << PyLong_SHIFT) \| (int)digits[1]) << PyLong_SHIFT) \| (int)digits[0]))); } } break; case 4: if (8 sizeof(int) > 3 * PyLong_SHIFT) { if (8 * sizeof(unsigned long) > 4 * PyLong_SHIFT) { __PYX_VERIFY_RETURN_INT(int, unsigned long, (((((((((unsigned long)digits[3]) << PyLong_SHIFT) \| (unsigned long)digits[2]) << PyLong_SHIFT) \| (unsigned long)digits[1]) << PyLong_SHIFT) \| (unsigned long)digits[0]))) } else if (8 * sizeof(int) - 1 > 4 * PyLong_SHIFT) { return (int) ((((((((((int)digits[3]) << PyLong_SHIFT) \| (int)digits[2]) << PyLong_SHIFT) \| (int)digits[1]) << PyLong_SHIFT) \| (int)digits[0]))); } } break; } #endif if (sizeof(int) <= sizeof(long)) { __PYX_VERIFY_RETURN_INT_EXC(int, long, PyLong_AsLong(x)) #ifdef HAVE_LONG_LONG } else if (sizeof(int) <= sizeof(PY_LONG_LONG)) { __PYX_VERIFY_RETURN_INT_EXC(int, PY_LONG_LONG, PyLong_AsLongLong(x)) #endif } } { #if CYTHON_COMPILING_IN_PYPY && !defined(_PyLong_AsByteArray) PyErr_SetString(PyExc_RuntimeError, "_PyLong_AsByteArray() not available in PyPy, cannot convert large numbers"); #else int val; PyObject v = __Pyx_PyNumber_IntOrLong(x); #if PY_MAJOR_VERSION < 3 if (likely(v) && !PyLong_Check(v)) { PyObject tmp = v; v = PyNumber_Long(tmp); Py_DECREF(tmp); } #endif if (likely(v)) { int one = 1; int is_little = (int)(unsigned char )&one; unsigned char bytes = (unsigned char )&val; int ret = _PyLong_AsByteArray((PyLongObject )v, bytes, sizeof(val), is_little, !is_unsigned); Py_DECREF(v); if (likely(!ret)) return val; } #endif return (int) -1; } } else { int val; PyObject tmp = __Pyx_PyNumber_IntOrLong(x); if (!tmp) return (int) -1; val = __Pyx_PyInt_As_int(tmp); Py_DECREF(tmp); return val; } raise_overflow: PyErr_SetString(PyExc_OverflowError, "value too large to convert to int"); return (int) -1; raise_neg_overflow: PyErr_SetString(PyExc_OverflowError, "can't convert negative value to int"); return (int) -1; } /* CIntToPy / static CYTHON_INLINE PyObject __Pyx_PyInt_From_int(int value) { #ifdef __Pyx_HAS_GCC_DIAGNOSTIC #pragma GCC diagnostic push #pragma GCC diagnostic ignored "-Wconversion" #endif const int neg_one = (int) -1, const_zero = (int) 0; #ifdef __Pyx_HAS_GCC_DIAGNOSTIC #pragma GCC diagnostic pop #endif const int is_unsigned = neg_one > const_zero; if (is_unsigned) { if (sizeof(int) < sizeof(long)) { return PyInt_FromLong((long) value); } else if (sizeof(int) <= sizeof(unsigned long)) { return PyLong_FromUnsignedLong((unsigned long) value); #ifdef HAVE_LONG_LONG } else if (sizeof(int) <= sizeof(unsigned PY_LONG_LONG)) { return PyLong_FromUnsignedLongLong((unsigned PY_LONG_LONG) value); #endif } } else { if (sizeof(int) <= sizeof(long)) { return PyInt_FromLong((long) value); #ifdef HAVE_LONG_LONG } else if (sizeof(int) <= sizeof(PY_LONG_LONG)) { return PyLong_FromLongLong((PY_LONG_LONG) value); #endif } } { int one = 1; int little = (int)(unsigned char )&one; unsigned char bytes = (unsigned char )&value; return _PyLong_FromByteArray(bytes, sizeof(int), little, !is_unsigned); } } /* CIntToPy / static CYTHON_INLINE PyObject __Pyx_PyInt_From_long(long value) { #ifdef __Pyx_HAS_GCC_DIAGNOSTIC #pragma GCC diagnostic push #pragma GCC diagnostic ignored "-Wconversion" #endif const long neg_one = (long) -1, const_zero = (long) 0; #ifdef __Pyx_HAS_GCC_DIAGNOSTIC #pragma GCC diagnostic pop #endif const int is_unsigned = neg_one > const_zero; if (is_unsigned) { if (sizeof(long) < sizeof(long)) { return PyInt_FromLong((long) value); } else if (sizeof(long) <= sizeof(unsigned long)) { return PyLong_FromUnsignedLong((unsigned long) value); #ifdef HAVE_LONG_LONG } else if (sizeof(long) <= sizeof(unsigned PY_LONG_LONG)) { return PyLong_FromUnsignedLongLong((unsigned PY_LONG_LONG) value); #endif } } else { if (sizeof(long) <= sizeof(long)) { return PyInt_FromLong((long) value); #ifdef HAVE_LONG_LONG } else if (sizeof(long) <= sizeof(PY_LONG_LONG)) { return PyLong_FromLongLong((PY_LONG_LONG) value); #endif } } { int one = 1; int little = (int)(unsigned char )&one; unsigned char bytes = (unsigned char )&value; return _PyLong_FromByteArray(bytes, sizeof(long), little, !is_unsigned); } } /* CIntFromPy / static CYTHON_INLINE char __Pyx_PyInt_As_char(PyObject x) { #ifdef __Pyx_HAS_GCC_DIAGNOSTIC #pragma GCC diagnostic push #pragma GCC diagnostic ignored "-Wconversion" #endif const char neg_one = (char) -1, const_zero = (char) 0; #ifdef __Pyx_HAS_GCC_DIAGNOSTIC #pragma GCC diagnostic pop #endif const int is_unsigned = neg_one > const_zero; #if PY_MAJOR_VERSION < 3 if (likely(PyInt_Check(x))) { if (sizeof(char) < sizeof(long)) { __PYX_VERIFY_RETURN_INT(char, long, PyInt_AS_LONG(x)) } else { long val = PyInt_AS_LONG(x); if (is_unsigned && unlikely(val < 0)) { goto raise_neg_overflow; } return (char) val; } } else #endif if (likely(PyLong_Check(x))) { if (is_unsigned) { #if CYTHON_USE_PYLONG_INTERNALS const digit* digits = ((PyLongObject)x)->ob_digit; switch (Py_SIZE(x)) { case 0: return (char) 0; case 1: __PYX_VERIFY_RETURN_INT(char, digit, digits[0]) case 2: if (8 sizeof(char) > 1 * PyLong_SHIFT) { if (8 * sizeof(unsigned long) > 2 * PyLong_SHIFT) { __PYX_VERIFY_RETURN_INT(char, unsigned long, (((((unsigned long)digits[1]) << PyLong_SHIFT) \| (unsigned long)digits[0]))) } else if (8 * sizeof(char) >= 2 * PyLong_SHIFT) { return (char) (((((char)digits[1]) << PyLong_SHIFT) \| (char)digits[0])); } } break; case 3: if (8 * sizeof(char) > 2 * PyLong_SHIFT) { if (8 * sizeof(unsigned long) > 3 * PyLong_SHIFT) { __PYX_VERIFY_RETURN_INT(char, unsigned long, (((((((unsigned long)digits[2]) << PyLong_SHIFT) \| (unsigned long)digits[1]) << PyLong_SHIFT) \| (unsigned long)digits[0]))) } else if (8 * sizeof(char) >= 3 * PyLong_SHIFT) { return (char) (((((((char)digits[2]) << PyLong_SHIFT) \| (char)digits[1]) << PyLong_SHIFT) \| (char)digits[0])); } } break; case 4: if (8 * sizeof(char) > 3 * PyLong_SHIFT) { if (8 * sizeof(unsigned long) > 4 * PyLong_SHIFT) { __PYX_VERIFY_RETURN_INT(char, unsigned long, (((((((((unsigned long)digits[3]) << PyLong_SHIFT) \| (unsigned long)digits[2]) << PyLong_SHIFT) \| (unsigned long)digits[1]) << PyLong_SHIFT) \| (unsigned long)digits[0]))) } else if (8 * sizeof(char) >= 4 * PyLong_SHIFT) { return (char) (((((((((char)digits[3]) << PyLong_SHIFT) \| (char)digits[2]) << PyLong_SHIFT) \| (char)digits[1]) << PyLong_SHIFT) \| (char)digits[0])); } } break; } #endif #if CYTHON_COMPILING_IN_CPYTHON if (unlikely(Py_SIZE(x) < 0)) { goto raise_neg_overflow; } #else { int result = PyObject_RichCompareBool(x, Py_False, Py_LT); if (unlikely(result < 0)) return (char) -1; if (unlikely(result == 1)) goto raise_neg_overflow; } #endif if (sizeof(char) <= sizeof(unsigned long)) { __PYX_VERIFY_RETURN_INT_EXC(char, unsigned long, PyLong_AsUnsignedLong(x)) #ifdef HAVE_LONG_LONG } else if (sizeof(char) <= sizeof(unsigned PY_LONG_LONG)) { __PYX_VERIFY_RETURN_INT_EXC(char, unsigned PY_LONG_LONG, PyLong_AsUnsignedLongLong(x)) #endif } } else { #if CYTHON_USE_PYLONG_INTERNALS const digit* digits = ((PyLongObject)x)->ob_digit; switch (Py_SIZE(x)) { case 0: return (char) 0; case -1: __PYX_VERIFY_RETURN_INT(char, sdigit, (sdigit) (-(sdigit)digits[0])) case 1: __PYX_VERIFY_RETURN_INT(char, digit, +digits[0]) case -2: if (8 sizeof(char) - 1 > 1 * PyLong_SHIFT) { if (8 * sizeof(unsigned long) > 2 * PyLong_SHIFT) { __PYX_VERIFY_RETURN_INT(char, long, -(long) (((((unsigned long)digits[1]) << PyLong_SHIFT) \| (unsigned long)digits[0]))) } else if (8 * sizeof(char) - 1 > 2 * PyLong_SHIFT) { return (char) (((char)-1)(((((char)digits[1]) << PyLong_SHIFT) \| (char)digits[0]))); } } break; case 2: if (8 sizeof(char) > 1 * PyLong_SHIFT) { if (8 * sizeof(unsigned long) > 2 * PyLong_SHIFT) { __PYX_VERIFY_RETURN_INT(char, unsigned long, (((((unsigned long)digits[1]) << PyLong_SHIFT) \| (unsigned long)digits[0]))) } else if (8 * sizeof(char) - 1 > 2 * PyLong_SHIFT) { return (char) ((((((char)digits[1]) << PyLong_SHIFT) \| (char)digits[0]))); } } break; case -3: if (8 * sizeof(char) - 1 > 2 * PyLong_SHIFT) { if (8 * sizeof(unsigned long) > 3 * PyLong_SHIFT) { __PYX_VERIFY_RETURN_INT(char, long, -(long) (((((((unsigned long)digits[2]) << PyLong_SHIFT) \| (unsigned long)digits[1]) << PyLong_SHIFT) \| (unsigned long)digits[0]))) } else if (8 * sizeof(char) - 1 > 3 * PyLong_SHIFT) { return (char) (((char)-1)(((((((char)digits[2]) << PyLong_SHIFT) \| (char)digits[1]) << PyLong_SHIFT) \| (char)digits[0]))); } } break; case 3: if (8 sizeof(char) > 2 * PyLong_SHIFT) { if (8 * sizeof(unsigned long) > 3 * PyLong_SHIFT) { __PYX_VERIFY_RETURN_INT(char, unsigned long, (((((((unsigned long)digits[2]) << PyLong_SHIFT) \| (unsigned long)digits[1]) << PyLong_SHIFT) \| (unsigned long)digits[0]))) } else if (8 * sizeof(char) - 1 > 3 * PyLong_SHIFT) { return (char) ((((((((char)digits[2]) << PyLong_SHIFT) \| (char)digits[1]) << PyLong_SHIFT) \| (char)digits[0]))); } } break; case -4: if (8 * sizeof(char) - 1 > 3 * PyLong_SHIFT) { if (8 * sizeof(unsigned long) > 4 * PyLong_SHIFT) { __PYX_VERIFY_RETURN_INT(char, long, -(long) (((((((((unsigned long)digits[3]) << PyLong_SHIFT) \| (unsigned long)digits[2]) << PyLong_SHIFT) \| (unsigned long)digits[1]) << PyLong_SHIFT) \| (unsigned long)digits[0]))) } else if (8 * sizeof(char) - 1 > 4 * PyLong_SHIFT) { return (char) (((char)-1)(((((((((char)digits[3]) << PyLong_SHIFT) \| (char)digits[2]) << PyLong_SHIFT) \| (char)digits[1]) << PyLong_SHIFT) \| (char)digits[0]))); } } break; case 4: if (8 sizeof(char) > 3 * PyLong_SHIFT) { if (8 * sizeof(unsigned long) > 4 * PyLong_SHIFT) { __PYX_VERIFY_RETURN_INT(char, unsigned long, (((((((((unsigned long)digits[3]) << PyLong_SHIFT) \| (unsigned long)digits[2]) << PyLong_SHIFT) \| (unsigned long)digits[1]) << PyLong_SHIFT) \| (unsigned long)digits[0]))) } else if (8 * sizeof(char) - 1 > 4 * PyLong_SHIFT) { return (char) ((((((((((char)digits[3]) << PyLong_SHIFT) \| (char)digits[2]) << PyLong_SHIFT) \| (char)digits[1]) << PyLong_SHIFT) \| (char)digits[0]))); } } break; } #endif if (sizeof(char) <= sizeof(long)) { __PYX_VERIFY_RETURN_INT_EXC(char, long, PyLong_AsLong(x)) #ifdef HAVE_LONG_LONG } else if (sizeof(char) <= sizeof(PY_LONG_LONG)) { __PYX_VERIFY_RETURN_INT_EXC(char, PY_LONG_LONG, PyLong_AsLongLong(x)) #endif } } { #if CYTHON_COMPILING_IN_PYPY && !defined(_PyLong_AsByteArray) PyErr_SetString(PyExc_RuntimeError, "_PyLong_AsByteArray() not available in PyPy, cannot convert large numbers"); #else char val; PyObject v = __Pyx_PyNumber_IntOrLong(x); #if PY_MAJOR_VERSION < 3 if (likely(v) && !PyLong_Check(v)) { PyObject tmp = v; v = PyNumber_Long(tmp); Py_DECREF(tmp); } #endif if (likely(v)) { int one = 1; int is_little = (int)(unsigned char )&one; unsigned char bytes = (unsigned char )&val; int ret = _PyLong_AsByteArray((PyLongObject )v, bytes, sizeof(val), is_little, !is_unsigned); Py_DECREF(v); if (likely(!ret)) return val; } #endif return (char) -1; } } else { char val; PyObject tmp = __Pyx_PyNumber_IntOrLong(x); if (!tmp) return (char) -1; val = __Pyx_PyInt_As_char(tmp); Py_DECREF(tmp); return val; } raise_overflow: PyErr_SetString(PyExc_OverflowError, "value too large to convert to char"); return (char) -1; raise_neg_overflow: PyErr_SetString(PyExc_OverflowError, "can't convert negative value to char"); return (char) -1; } /* CheckBinaryVersion / static int __Pyx_check_binary_version(void) { char ctversion[4], rtversion[4]; PyOS_snprintf(ctversion, 4, "%d.%d", PY_MAJOR_VERSION, PY_MINOR_VERSION); PyOS_snprintf(rtversion, 4, "%s", Py_GetVersion()); if (ctversion[0] != rtversion[0] \|\| ctversion[2] != rtversion[2]) { char message[200]; PyOS_snprintf(message, sizeof(message), "compiletime version %s of module '%.100s' " "does not match runtime version %s", ctversion, __Pyx_MODULE_NAME, rtversion); return PyErr_WarnEx(NULL, message, 1); } return 0; } / InitStrings / static int __Pyx_InitStrings(__Pyx_StringTabEntry t) { while (t->p) { #if PY_MAJOR_VERSION < 3 if (t->is_unicode) { t->p = PyUnicode_DecodeUTF8(t->s, t->n - 1, NULL); } else if (t->intern) { t->p = PyString_InternFromString(t->s); } else { t->p = PyString_FromStringAndSize(t->s, t->n - 1); } #else if (t->is_unicode \| t->is_str) { if (t->intern) { t->p = PyUnicode_InternFromString(t->s); } else if (t->encoding) { t->p = PyUnicode_Decode(t->s, t->n - 1, t->encoding, NULL); } else { t->p = PyUnicode_FromStringAndSize(t->s, t->n - 1); } } else { t->p = PyBytes_FromStringAndSize(t->s, t->n - 1); } #endif if (!t->p) return -1; if (PyObject_Hash(t->p) == -1) return -1; ++t; } return 0; } static CYTHON_INLINE PyObject __Pyx_PyUnicode_FromString(const char* c_str) { return __Pyx_PyUnicode_FromStringAndSize(c_str, (Py_ssize_t)strlen(c_str)); } static CYTHON_INLINE const char* __Pyx_PyObject_AsString(PyObject* o) { Py_ssize_t ignore; return __Pyx_PyObject_AsStringAndSize(o, &ignore); } #if __PYX_DEFAULT_STRING_ENCODING_IS_ASCII \|\| __PYX_DEFAULT_STRING_ENCODING_IS_DEFAULT #if !CYTHON_PEP393_ENABLED static const char* __Pyx_PyUnicode_AsStringAndSize(PyObject* o, Py_ssize_t length) { char defenc_c; PyObject* defenc = _PyUnicode_AsDefaultEncodedString(o, NULL); if (!defenc) return NULL; defenc_c = PyBytes_AS_STRING(defenc); #if __PYX_DEFAULT_STRING_ENCODING_IS_ASCII { char* end = defenc_c + PyBytes_GET_SIZE(defenc); char* c; for (c = defenc_c; c < end; c++) { if ((unsigned char) (c) >= 128) { PyUnicode_AsASCIIString(o); return NULL; } } } #endif length = PyBytes_GET_SIZE(defenc); return defenc_c; } #else static CYTHON_INLINE const char* __Pyx_PyUnicode_AsStringAndSize(PyObject* o, Py_ssize_t length) { if (unlikely(__Pyx_PyUnicode_READY(o) == -1)) return NULL; #if __PYX_DEFAULT_STRING_ENCODING_IS_ASCII if (likely(PyUnicode_IS_ASCII(o))) { length = PyUnicode_GET_LENGTH(o); return PyUnicode_AsUTF8(o); } else { PyUnicode_AsASCIIString(o); return NULL; } #else return PyUnicode_AsUTF8AndSize(o, length); #endif } #endif #endif static CYTHON_INLINE const char* __Pyx_PyObject_AsStringAndSize(PyObject* o, Py_ssize_t length) { #if __PYX_DEFAULT_STRING_ENCODING_IS_ASCII \|\| __PYX_DEFAULT_STRING_ENCODING_IS_DEFAULT if ( #if PY_MAJOR_VERSION < 3 && __PYX_DEFAULT_STRING_ENCODING_IS_ASCII __Pyx_sys_getdefaultencoding_not_ascii && #endif PyUnicode_Check(o)) { return __Pyx_PyUnicode_AsStringAndSize(o, length); } else #endif #if (!CYTHON_COMPILING_IN_PYPY) \|\| (defined(PyByteArray_AS_STRING) && defined(PyByteArray_GET_SIZE)) if (PyByteArray_Check(o)) { length = PyByteArray_GET_SIZE(o); return PyByteArray_AS_STRING(o); } else #endif { char* result; int r = PyBytes_AsStringAndSize(o, &result, length); if (unlikely(r < 0)) { return NULL; } else { return result; } } } static CYTHON_INLINE int __Pyx_PyObject_IsTrue(PyObject* x) { int is_true = x == Py_True; if (is_true \| (x == Py_False) \| (x == Py_None)) return is_true; else return PyObject_IsTrue(x); } static CYTHON_INLINE int __Pyx_PyObject_IsTrueAndDecref(PyObject* x) { int retval; if (unlikely(!x)) return -1; retval = __Pyx_PyObject_IsTrue(x); Py_DECREF(x); return retval; } static PyObject* __Pyx_PyNumber_IntOrLongWrongResultType(PyObject* result, const char* type_name) { #if PY_MAJOR_VERSION >= 3 if (PyLong_Check(result)) { if (PyErr_WarnFormat(PyExc_DeprecationWarning, 1, "__int__ returned non-int (type %.200s). " "The ability to return an instance of a strict subclass of int " "is deprecated, and may be removed in a future version of Python.", Py_TYPE(result)->tp_name)) { Py_DECREF(result); return NULL; } return result; } #endif PyErr_Format(PyExc_TypeError, "__%.4s__ returned non-%.4s (type %.200s)", type_name, type_name, Py_TYPE(result)->tp_name); Py_DECREF(result); return NULL; } static CYTHON_INLINE PyObject* __Pyx_PyNumber_IntOrLong(PyObject* x) { #if CYTHON_USE_TYPE_SLOTS PyNumberMethods m; #endif const char name = NULL; PyObject res = NULL; #if PY_MAJOR_VERSION < 3 if (likely(PyInt_Check(x) \|\| PyLong_Check(x))) #else if (likely(PyLong_Check(x))) #endif return __Pyx_NewRef(x); #if CYTHON_USE_TYPE_SLOTS m = Py_TYPE(x)->tp_as_number; #if PY_MAJOR_VERSION < 3 if (m && m->nb_int) { name = "int"; res = m->nb_int(x); } else if (m && m->nb_long) { name = "long"; res = m->nb_long(x); } #else if (likely(m && m->nb_int)) { name = "int"; res = m->nb_int(x); } #endif #else if (!PyBytes_CheckExact(x) && !PyUnicode_CheckExact(x)) { res = PyNumber_Int(x); } #endif if (likely(res)) { #if PY_MAJOR_VERSION < 3 if (unlikely(!PyInt_Check(res) && !PyLong_Check(res))) { #else if (unlikely(!PyLong_CheckExact(res))) { #endif return __Pyx_PyNumber_IntOrLongWrongResultType(res, name); } } else if (!PyErr_Occurred()) { PyErr_SetString(PyExc_TypeError, "an integer is required"); } return res; } static CYTHON_INLINE Py_ssize_t __Pyx_PyIndex_AsSsize_t(PyObject b) { Py_ssize_t ival; PyObject x; #if PY_MAJOR_VERSION < 3 if (likely(PyInt_CheckExact(b))) { if (sizeof(Py_ssize_t) >= sizeof(long)) return PyInt_AS_LONG(b); else return PyInt_AsSsize_t(b); } #endif if (likely(PyLong_CheckExact(b))) { #if CYTHON_USE_PYLONG_INTERNALS const digit digits = ((PyLongObject)b)->ob_digit; const Py_ssize_t size = Py_SIZE(b); if (likely(__Pyx_sst_abs(size) <= 1)) { ival = likely(size) ? digits[0] : 0; if (size == -1) ival = -ival; return ival; } else { switch (size) { case 2: if (8 sizeof(Py_ssize_t) > 2 * PyLong_SHIFT) { return (Py_ssize_t) (((((size_t)digits[1]) << PyLong_SHIFT) \| (size_t)digits[0])); } break; case -2: if (8 * sizeof(Py_ssize_t) > 2 * PyLong_SHIFT) { return -(Py_ssize_t) (((((size_t)digits[1]) << PyLong_SHIFT) \| (size_t)digits[0])); } break; case 3: if (8 * sizeof(Py_ssize_t) > 3 * PyLong_SHIFT) { return (Py_ssize_t) (((((((size_t)digits[2]) << PyLong_SHIFT) \| (size_t)digits[1]) << PyLong_SHIFT) \| (size_t)digits[0])); } break; case -3: if (8 * sizeof(Py_ssize_t) > 3 * PyLong_SHIFT) { return -(Py_ssize_t) (((((((size_t)digits[2]) << PyLong_SHIFT) \| (size_t)digits[1]) << PyLong_SHIFT) \| (size_t)digits[0])); } break; case 4: if (8 * sizeof(Py_ssize_t) > 4 * PyLong_SHIFT) { return (Py_ssize_t) (((((((((size_t)digits[3]) << PyLong_SHIFT) \| (size_t)digits[2]) << PyLong_SHIFT) \| (size_t)digits[1]) << PyLong_SHIFT) \| (size_t)digits[0])); } break; case -4: if (8 * sizeof(Py_ssize_t) > 4 * PyLong_SHIFT) { return -(Py_ssize_t) (((((((((size_t)digits[3]) << PyLong_SHIFT) \| (size_t)digits[2]) << PyLong_SHIFT) \| (size_t)digits[1]) << PyLong_SHIFT) \| (size_t)digits[0])); } break; } } #endif return PyLong_AsSsize_t(b); } x = PyNumber_Index(b); if (!x) return -1; ival = PyInt_AsSsize_t(x); Py_DECREF(x); return ival; } static CYTHON_INLINE Py_hash_t __Pyx_PyIndex_AsHash_t(PyObject* o) { if (sizeof(Py_hash_t) == sizeof(Py_ssize_t)) { return (Py_hash_t) __Pyx_PyIndex_AsSsize_t(o); #if PY_MAJOR_VERSION < 3 } else if (likely(PyInt_CheckExact(o))) { return PyInt_AS_LONG(o); #endif } else { Py_ssize_t ival; PyObject x; x = PyNumber_Index(o); if (!x) return -1; ival = PyInt_AsLong(x); Py_DECREF(x); return ival; } } static CYTHON_INLINE PyObject __Pyx_PyBool_FromLong(long b) { return b ? __Pyx_NewRef(Py_True) : __Pyx_NewRef(Py_False); } static CYTHON_INLINE PyObject * __Pyx_PyInt_FromSize_t(size_t ival) { return PyInt_FromSize_t(ival); } #endif /* Py_PYTHON_H */
GB_unaryop__identity_int16_uint64.c	//------------------------------------------------------------------------------ // GB_unaryop: hard-coded functions for each built-in unary operator //------------------------------------------------------------------------------ // SuiteSparse:GraphBLAS, Timothy A. Davis, (c) 2017-2020, All Rights Reserved. // http://suitesparse.com See GraphBLAS/Doc/License.txt for license. //------------------------------------------------------------------------------ // If this file is in the Generated/ folder, do not edit it (auto-generated). #include "GB.h" #ifndef GBCOMPACT #include "GB_control.h" #include "GB_iterator.h" #include "GB_unaryop__include.h" // C=unop(A) is defined by the following types and operators: // op(A) function: GB_unop__identity_int16_uint64 // op(A') function: GB_tran__identity_int16_uint64 // C type: int16_t // A type: uint64_t // cast: int16_t cij = (int16_t) aij // unaryop: cij = aij #define GB_ATYPE \ uint64_t #define GB_CTYPE \ int16_t // aij = Ax [pA] #define GB_GETA(aij,Ax,pA) \ uint64_t aij = Ax [pA] #define GB_CX(p) Cx [p] // unary operator #define GB_OP(z, x) \ z = x ; // casting #define GB_CASTING(z, aij) \ int16_t z = (int16_t) aij ; // cij = op (cast (aij)) #define GB_CAST_OP(pC,pA) \ { \ /* aij = Ax [pA] / \ GB_GETA (aij, Ax, pA) ; \ / Cx [pC] = op (cast (aij)) / \ GB_CASTING (z, aij) ; \ GB_OP (GB_CX (pC), z) ; \ } // disable this operator and use the generic case if these conditions hold #define GB_DISABLE \ (GxB_NO_IDENTITY \|\| GxB_NO_INT16 \|\| GxB_NO_UINT64) //------------------------------------------------------------------------------ // Cx = op (cast (Ax)): apply a unary operator //------------------------------------------------------------------------------ GrB_Info GB_unop__identity_int16_uint64 ( int16_t Cx, // Cx and Ax may be aliased uint64_t Ax, int64_t anz, int nthreads ) { #if GB_DISABLE return (GrB_NO_VALUE) ; #else int64_t p ; #pragma omp parallel for num_threads(nthreads) schedule(static) for (p = 0 ; p < anz ; p++) { GB_CAST_OP (p, p) ; } return (GrB_SUCCESS) ; #endif } //------------------------------------------------------------------------------ // C = op (cast (A')): transpose, typecast, and apply a unary operator //------------------------------------------------------------------------------ GrB_Info GB_tran__identity_int16_uint64 ( GrB_Matrix C, const GrB_Matrix A, int64_t GB_RESTRICT Rowcounts, GBI_single_iterator Iter, const int64_t GB_RESTRICT A_slice, int naslice ) { #if GB_DISABLE return (GrB_NO_VALUE) ; #else #define GB_PHASE_2_OF_2 #include "GB_unaryop_transpose.c" return (GrB_SUCCESS) ; #endif } #endif
3d25pt.lbpar.c	#include <omp.h> #include <math.h> #define ceild(n,d) ceil(((double)(n))/((double)(d))) #define floord(n,d) floor(((double)(n))/((double)(d))) #define max(x,y) ((x) > (y)? (x) : (y)) #define min(x,y) ((x) < (y)? (x) : (y)) /* * Order-2, 3D 25 point stencil * Adapted from PLUTO and Pochoir test bench * * Tareq Malas / #include <stdio.h> #include <stdlib.h> #include <sys/time.h> #ifdef LIKWID_PERFMON #include <likwid.h> #endif #include "print_utils.h" #define TESTS 2 #define MAX(a,b) ((a) > (b) ? a : b) #define MIN(a,b) ((a) < (b) ? a : b) #ifndef min #define min(x,y) ((x) < (y)? (x) : (y)) #endif / Subtract the `struct timeval' values X and Y, * storing the result in RESULT. * * Return 1 if the difference is negative, otherwise 0. / int timeval_subtract(struct timeval result, struct timeval x, struct timeval y) { /* Perform the carry for the later subtraction by updating y. / if (x->tv_usec < y->tv_usec) { int nsec = (y->tv_usec - x->tv_usec) / 1000000 + 1; y->tv_usec -= 1000000 nsec; y->tv_sec += nsec; } if (x->tv_usec - y->tv_usec > 1000000) { int nsec = (x->tv_usec - y->tv_usec) / 1000000; y->tv_usec += 1000000 * nsec; y->tv_sec -= nsec; } /* Compute the time remaining to wait. * tv_usec is certainly positive. / result->tv_sec = x->tv_sec - y->tv_sec; result->tv_usec = x->tv_usec - y->tv_usec; / Return 1 if result is negative. / return x->tv_sec < y->tv_sec; } int main(int argc, char argv[]) { int t, i, j, k, test; int Nx, Ny, Nz, Nt; if (argc > 3) { Nx = atoi(argv[1])+8; Ny = atoi(argv[2])+8; Nz = atoi(argv[3])+8; } if (argc > 4) Nt = atoi(argv[4]); double **A = (double ) malloc(sizeof(double)2); double *roc2 = (double ) malloc(sizeof(double)); A[0] = (double ) malloc(sizeof(double)Nz); A[1] = (double ) malloc(sizeof(double)Nz); roc2 = (double ) malloc(sizeof(double)Nz); for(i=0; i<Nz; i++){ A[0][i] = (double) malloc(sizeof(double)Ny); A[1][i] = (double) malloc(sizeof(double)Ny); roc2[i] = (double) malloc(sizeof(double)Ny); for(j=0;j<Ny;j++){ A[0][i][j] = (double) malloc(sizeof(double)Nx); A[1][i][j] = (double) malloc(sizeof(double)Nx); roc2[i][j] = (double) malloc(sizeof(double)Nx); } } // tile size information, including extra element to decide the list length int tile_size = (int) malloc(sizeof(int)); tile_size[0] = -1; // The list is modified here before source-to-source transformations tile_size = (int) realloc((void )tile_size, sizeof(int)5); tile_size[0] = 8; tile_size[1] = 8; tile_size[2] = 16; tile_size[3] = 1024; tile_size[4] = -1; // for timekeeping int ts_return = -1; struct timeval start, end, result; double tdiff = 0.0, min_tdiff=1.e100; const int BASE = 1024; // initialize variables // srand(42); for (i = 1; i < Nz; i++) { for (j = 1; j < Ny; j++) { for (k = 1; k < Nx; k++) { A[0][i][j][k] = 1.0 * (rand() % BASE); roc2[i][j][k] = 2.0 * (rand() % BASE); } } } #ifdef LIKWID_PERFMON LIKWID_MARKER_INIT; #pragma omp parallel { LIKWID_MARKER_THREADINIT; #pragma omp barrier LIKWID_MARKER_START("calc"); } #endif int num_threads = 1; #if defined(_OPENMP) num_threads = omp_get_max_threads(); #endif const double coef0 = -0.28472; const double coef1 = 0.16000; const double coef2 = -0.02000; const double coef3 = 0.00254; const double coef4 = -0.00018; for(test=0; test<TESTS; test++){ gettimeofday(&start, 0); // serial execution - Addition: 6 && Multiplication: 2 /* Copyright (C) 1991-2014 Free Software Foundation, Inc. This file is part of the GNU C Library. The GNU C Library is free software; you can redistribute it and/or modify it under the terms of the GNU Lesser General Public License as published by the Free Software Foundation; either version 2.1 of the License, or (at your option) any later version. The GNU C Library is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU Lesser General Public License for more details. You should have received a copy of the GNU Lesser General Public License along with the GNU C Library; if not, see <http://www.gnu.org/licenses/>. / / This header is separate from features.h so that the compiler can include it implicitly at the start of every compilation. It must not itself include <features.h> or any other header that includes <features.h> because the implicit include comes before any feature test macros that may be defined in a source file before it first explicitly includes a system header. GCC knows the name of this header in order to preinclude it. / / glibc's intent is to support the IEC 559 math functionality, real and complex. If the GCC (4.9 and later) predefined macros specifying compiler intent are available, use them to determine whether the overall intent is to support these features; otherwise, presume an older compiler has intent to support these features and define these macros by default. / / wchar_t uses ISO/IEC 10646 (2nd ed., published 2011-03-15) / Unicode 6.0. / / We do not support C11 <threads.h>. / int t1, t2, t3, t4, t5, t6, t7, t8; int lb, ub, lbp, ubp, lb2, ub2; register int lbv, ubv; / Start of CLooG code / if ((Nt >= 1) && (Nx >= 9) && (Ny >= 9) && (Nz >= 9)) { for (t1=-1;t1<=Nt-1;t1++) { lbp=ceild(t1+1,2); ubp=min(floord(4Nt+Nz-9,8),floord(4t1+Nz-2,8)); #pragma omp parallel for private(lbv,ubv,t3,t4,t5,t6,t7,t8) for (t2=lbp;t2<=ubp;t2++) { for (t3=max(ceild(t1-2,4),ceild(8t2-Nz-3,16));t3<=min(floord(4Nt+Ny-9,16),floord(4t1+Ny-1,16));t3++) { for (t4=max(max(ceild(t1-254,256),ceild(8t2-Nz-1011,1024)),ceild(16t3-Ny-1011,1024));t4<=min(min(floord(4Nt+Nx-9,1024),floord(4t1+Nx-1,1024)),floord(16t3+Nx+3,1024));t4++) { for (t5=max(max(max(max(0,ceild(8t2-Nz+5,4)),ceild(16t3-Ny+5,4)),ceild(1024t4-Nx+5,4)),t1);t5<=min(min(min(Nt-1,t1+1),4t3+2),256t4+254);t5++) { for (t6=max(max(8t2,4t5+4),-8t1+8t2+8t5-7);t6<=min(min(8t2+7,-8t1+8t2+8t5),4t5+Nz-5);t6++) { for (t7=max(16t3,4t5+4);t7<=min(16t3+15,4t5+Ny-5);t7++) { lbv=max(1024t4,4t5+4); ubv=min(1024t4+1023,4t5+Nx-5); #pragma ivdep #pragma vector always for (t8=lbv;t8<=ubv;t8++) { A[( t5 + 1) % 2][ (-4t5+t6)][ (-4t5+t7)][ (-4t5+t8)] = (((2.0 A[ t5 % 2][ (-4t5+t6)][ (-4t5+t7)][ (-4t5+t8)]) - A[( t5 + 1) % 2][ (-4t5+t6)][ (-4t5+t7)][ (-4t5+t8)]) + (roc2[ (-4t5+t6)][ (-4t5+t7)][ (-4t5+t8)] (((((coef0 * A[ t5 % 2][ (-4t5+t6)][ (-4t5+t7)][ (-4t5+t8)]) + (coef1 (((((A[ t5 % 2][ (-4t5+t6) - 1][ (-4t5+t7)][ (-4t5+t8)] + A[ t5 % 2][ (-4t5+t6) + 1][ (-4t5+t7)][ (-4t5+t8)]) + A[ t5 % 2][ (-4t5+t6)][ (-4t5+t7) - 1][ (-4t5+t8)]) + A[ t5 % 2][ (-4t5+t6)][ (-4t5+t7) + 1][ (-4t5+t8)]) + A[ t5 % 2][ (-4t5+t6)][ (-4t5+t7)][ (-4t5+t8) - 1]) + A[ t5 % 2][ (-4t5+t6)][ (-4t5+t7)][ (-4t5+t8) + 1]))) + (coef2 * (((((A[ t5 % 2][ (-4t5+t6) - 2][ (-4t5+t7)][ (-4t5+t8)] + A[ t5 % 2][ (-4t5+t6) + 2][ (-4t5+t7)][ (-4t5+t8)]) + A[ t5 % 2][ (-4t5+t6)][ (-4t5+t7) - 2][ (-4t5+t8)]) + A[ t5 % 2][ (-4t5+t6)][ (-4t5+t7) + 2][ (-4t5+t8)]) + A[ t5 % 2][ (-4t5+t6)][ (-4t5+t7)][ (-4t5+t8) - 2]) + A[ t5 % 2][ (-4t5+t6)][ (-4t5+t7)][ (-4t5+t8) + 2]))) + (coef3 * (((((A[ t5 % 2][ (-4t5+t6) - 3][ (-4t5+t7)][ (-4t5+t8)] + A[ t5 % 2][ (-4t5+t6) + 3][ (-4t5+t7)][ (-4t5+t8)]) + A[ t5 % 2][ (-4t5+t6)][ (-4t5+t7) - 3][ (-4t5+t8)]) + A[ t5 % 2][ (-4t5+t6)][ (-4t5+t7) + 3][ (-4t5+t8)]) + A[ t5 % 2][ (-4t5+t6)][ (-4t5+t7)][ (-4t5+t8) - 3]) + A[ t5 % 2][ (-4t5+t6)][ (-4t5+t7)][ (-4t5+t8) + 3]))) + (coef4 * (((((A[ t5 % 2][ (-4t5+t6) - 4][ (-4t5+t7)][ (-4t5+t8)] + A[ t5 % 2][ (-4t5+t6) + 4][ (-4t5+t7)][ (-4t5+t8)]) + A[ t5 % 2][ (-4t5+t6)][ (-4t5+t7) - 4][ (-4t5+t8)]) + A[ t5 % 2][ (-4t5+t6)][ (-4t5+t7) + 4][ (-4t5+t8)]) + A[ t5 % 2][ (-4t5+t6)][ (-4t5+t7)][ (-4t5+t8) - 4]) + A[ t5 % 2][ (-4t5+t6)][ (-4t5+t7)][ (-4t5+t8) + 4])))));; } } } } } } } } } /* End of CLooG code / gettimeofday(&end, 0); ts_return = timeval_subtract(&result, &end, &start); tdiff = (double) (result.tv_sec + result.tv_usec 1.0e-6); min_tdiff = MIN(min_tdiff, tdiff); printf("Rank 0 TEST# %d time: %f\n", test, tdiff); } PRINT_RESULTS(4, "constant") #ifdef LIKWID_PERFMON #pragma omp parallel { LIKWID_MARKER_STOP("calc"); } LIKWID_MARKER_CLOSE; #endif // Free allocated arrays for(i=0; i<Nz; i++){ for(j=0;j<Ny;j++){ free(A[0][i][j]); free(A[1][i][j]); free(roc2[i][j]); } free(A[0][i]); free(A[1][i]); free(roc2[i]); } free(A[0]); free(A[1]); free(roc2); return 0; }
3d7pt_var.c	/* * Order-1, 3D 7 point stencil with variable coefficients * Adapted from PLUTO and Pochoir test bench * * Tareq Malas / #include <stdio.h> #include <stdlib.h> #include <sys/time.h> #ifdef LIKWID_PERFMON #include <likwid.h> #endif #include "print_utils.h" #define TESTS 2 #define MAX(a,b) ((a) > (b) ? a : b) #define MIN(a,b) ((a) < (b) ? a : b) / Subtract the `struct timeval' values X and Y, * storing the result in RESULT. * * Return 1 if the difference is negative, otherwise 0. / int timeval_subtract(struct timeval result, struct timeval x, struct timeval y) { /* Perform the carry for the later subtraction by updating y. / if (x->tv_usec < y->tv_usec) { int nsec = (y->tv_usec - x->tv_usec) / 1000000 + 1; y->tv_usec -= 1000000 nsec; y->tv_sec += nsec; } if (x->tv_usec - y->tv_usec > 1000000) { int nsec = (x->tv_usec - y->tv_usec) / 1000000; y->tv_usec += 1000000 * nsec; y->tv_sec -= nsec; } /* Compute the time remaining to wait. * tv_usec is certainly positive. / result->tv_sec = x->tv_sec - y->tv_sec; result->tv_usec = x->tv_usec - y->tv_usec; / Return 1 if result is negative. / return x->tv_sec < y->tv_sec; } int main(int argc, char argv[]) { int t, i, j, k, m, test; int Nx, Ny, Nz, Nt; if (argc > 3) { Nx = atoi(argv[1])+2; Ny = atoi(argv[2])+2; Nz = atoi(argv[3])+2; } if (argc > 4) Nt = atoi(argv[4]); // allocate the arrays double **A = (double ) malloc(sizeof(double)2); for(m=0; m<2;m++){ A[m] = (double *) malloc(sizeof(double)Nz); for(i=0; i<Nz; i++){ A[m][i] = (double) malloc(sizeof(double)Ny); for(j=0;j<Ny;j++){ A[m][i][j] = (double) malloc(sizeof(double)Nx); } } } double *coef = (double ) malloc(sizeof(double)7); for(m=0; m<7;m++){ coef[m] = (double *) malloc(sizeof(double)Nz); for(i=0; i<Nz; i++){ coef[m][i] = (double) malloc(sizeof(double)Ny); for(j=0;j<Ny;j++){ coef[m][i][j] = (double) malloc(sizeof(double)Nx); } } } // tile size information, including extra element to decide the list length int tile_size = (int) malloc(sizeof(int)); tile_size[0] = -1; // The list is modified here before source-to-source transformations tile_size = (int) realloc((void )tile_size, sizeof(int)5); tile_size[0] = 16; tile_size[1] = 16; tile_size[2] = 16; tile_size[3] = 512; tile_size[4] = -1; // for timekeeping int ts_return = -1; struct timeval start, end, result; double tdiff = 0.0, min_tdiff=1.e100; const int BASE = 1024; // initialize variables // srand(42); for (i = 1; i < Nz; i++) { for (j = 1; j < Ny; j++) { for (k = 1; k < Nx; k++) { A[0][i][j][k] = 1.0 * (rand() % BASE); } } } for (m=0; m<7; m++) { for (i=1; i<Nz; i++) { for (j=1; j<Ny; j++) { for (k=1; k<Nx; k++) { coef[m][i][j][k] = 1.0 * (rand() % BASE); } } } } #ifdef LIKWID_PERFMON LIKWID_MARKER_INIT; #pragma omp parallel { LIKWID_MARKER_THREADINIT; #pragma omp barrier LIKWID_MARKER_START("calc"); } #endif int num_threads = 1; #if defined(_OPENMP) num_threads = omp_get_max_threads(); #endif for(test=0; test<TESTS; test++){ gettimeofday(&start, 0); // serial execution - Addition: 6 && Multiplication: 2 #pragma scop for (t = 0; t < Nt-1; t++) { for (i = 1; i < Nz-1; i++) { for (j = 1; j < Ny-1; j++) { for (k = 1; k < Nx-1; k++) { A[(t+1)%2][i][j][k] = coef[0][i][j][k] * A[t%2][i ][j ][k ] + coef[1][i][j][k] * A[t%2][i-1][j ][k ] + coef[2][i][j][k] * A[t%2][i ][j-1][k ] + coef[3][i][j][k] * A[t%2][i ][j ][k-1] + coef[4][i][j][k] * A[t%2][i+1][j ][k ] + coef[5][i][j][k] * A[t%2][i ][j+1][k ] + coef[6][i][j][k] * A[t%2][i ][j ][k+1]; } } } } #pragma endscop gettimeofday(&end, 0); ts_return = timeval_subtract(&result, &end, &start); tdiff = (double) (result.tv_sec + result.tv_usec * 1.0e-6); min_tdiff = min(min_tdiff, tdiff); printf("Rank 0 TEST# %d time: %f\n", test, tdiff); } PRINT_RESULTS(1, "variable no-symmetry") #ifdef LIKWID_PERFMON #pragma omp parallel { LIKWID_MARKER_STOP("calc"); } LIKWID_MARKER_CLOSE; #endif // Free allocated arrays for(i=0; i<Nz; i++){ for(j=0;j<Ny;j++){ free(A[0][i][j]); free(A[1][i][j]); } free(A[0][i]); free(A[1][i]); } free(A[0]); free(A[1]); for(m=0; m<7;m++){ for(i=0; i<Nz; i++){ for(j=0;j<Ny;j++){ free(coef[m][i][j]); } free(coef[m][i]); } free(coef[m]); } return 0; }
for.c	#include <omp.h> #include <stdio.h> #define CHUNKSIZE 10 #define N 100 main () { int i, chunk; float a[N], b[N], c[N]; /* Some initializations / for (i=0; i < N; i++) a[i] = b[i] = i 1.0; chunk = CHUNKSIZE; #pragma omp parallel shared(a,b,c,chunk) private(i) { #pragma omp for schedule(dynamic,chunk) for (i=0; i < N; i++) c[i] = a[i] + b[i]; } /* end of parallel section */ for (i=0; i<N; i++) printf("c[%d] = %3.1f\n", i, c[i]); }
master.c	// OpenMP Master Example #include <omp.h> #include <stdio.h> #include <stdlib.h> int main( int argc, char** argv ) { int num_threads = 0; // Number of Threads int thread_id = 0; // ID Number of Running Thread #pragma omp parallel private( num_threads, thread_id ) { // Get the Thread Number thread_id = omp_get_thread_num( ); printf( "Hello World from Thread %d\n", thread_id ); // Have Master Print Total Number of Threads Used #pragma omp master { num_threads = omp_get_num_threads( ); printf( "Number of Threads = %d\n", num_threads ); } } return 0; } // End master.c - EWG SDG
merge_tasks_unnested.c	#include <stdlib.h> #include <stdio.h> #include <string.h> #include <omp.h> /* OpenMP Parallel Mergesort - STasking * * @author: ANDREW VAILLANCOURT * 2019 / void merge(int a[], int size, int temp[]); void insertion_sort(int a[], int size); void mergesort_serial(int a[], int size, int temp[], int thresh); void mergesort_parallel_omp(int a[], int size, int temp[], int threads, int thresh); void run_omp(int a[], int size, int temp[], int threads, int thresh); void par_mergesort (int a[], int size, int temp[], int threads, int thresh); int main(int argc, char argv[]) { if (argc != 4) { printf("Usage: %s array_size threshold num_threads\n", argv[0]); return 1; } int size = atoi(argv[1]); // Array size int thresh = atoi(argv[2]); // point at which sort switches to insertion int threads = atoi(argv[3]); // Requested number of threads double start, end; // Check nested parallelism availability omp_set_nested(1); if (omp_get_nested() != 1) { puts("Warning: Nested parallelism desired but unavailable"); } // Check processors and threads int processors = omp_get_num_procs(); // Available processors if (threads > processors) { printf("Warning: %d threads requested, will run_omp on %d processors available\n",threads, processors); omp_set_num_threads(threads); } int max_threads = omp_get_max_threads(); // Max available threads if (threads > max_threads) // Requested threads are more than max available { printf("Error: Cannot use %d threads, only %d threads available\n", threads, max_threads); return 1; } // Array allocation int a = malloc(sizeof(int) size); int temp = malloc(sizeof(int) size); if (a == NULL \|\| temp == NULL) { printf("Error: Could not allocate array of size %d\n", size); return 1; } // array initialization int i; srand(314159); for (i = 0; i < size; i++) { a[i] = rand() % size; } // run sort and get time start = omp_get_wtime(); run_omp(a, size, temp, threads, thresh); end = omp_get_wtime(); printf("%.4f\n", end - start); // check sorted for (i = 1; i < size; i++) { if (!(a[i - 1] <= a[i])) { printf("Error: final array not sorted => a[%d]=%d > a[%d]=%d\n", i - 1, a[i - 1], i, a[i]); return 1; } } return 0; } void run_omp(int a[], int size, int temp[], int threads, int thresh) { //omp_set_nested(1); // Enable nested parallelism, if available par_mergesort(a, size, temp, threads, thresh); } // OpenMP merge sort with given number of threads void mergesort_parallel_omp(int a[], int size, int temp[], int threads, int thresh) { if (threads == 1) { mergesort_serial(a, size, temp, thresh); } else if (threads > 1) { #pragma omp task { mergesort_parallel_omp(a, size / 2, temp, threads / 2, thresh); } #pragma omp task { mergesort_parallel_omp(a + size / 2, size - size / 2, temp + size / 2, threads - threads / 2, thresh); } #pragma omp taskwait { merge(a, size, temp); } } else { printf("Error: %d threads\n", threads); return; } } void par_mergesort (int a[], int size, int temp[], int threads, int thresh) { #pragma omp parallel { #pragma omp single nowait mergesort_parallel_omp (a, size, temp, threads, thresh); } } // only called if num_threads = 1 void mergesort_serial(int a[], int size, int temp[], int thresh) { // Switch to insertion sort for small arrays if (size <= thresh) { insertion_sort(a, size); return; } mergesort_serial(a, size / 2, temp, thresh); mergesort_serial(a + size / 2, size - size / 2, temp, thresh); merge(a, size, temp); } void merge(int a[], int size, int temp[]) { int i1 = 0; int i2 = size / 2; int tempi = 0; while (i1 < size / 2 && i2 < size) { if (a[i1] < a[i2]) { temp[tempi] = a[i1]; i1++; } else { temp[tempi] = a[i2]; i2++; } tempi++; } while (i1 < size / 2) { temp[tempi] = a[i1]; i1++; tempi++; } while (i2 < size) { temp[tempi] = a[i2]; i2++; tempi++; } // Copy sorted temp array into main array, a memcpy(a, temp, size * sizeof(int)); } void insertion_sort(int a[], int size) { int i; for (i = 0; i < size; i++) { int j, v = a[i]; for (j = i - 1; j >= 0; j--) { if (a[j] <= v) break; a[j + 1] = a[j]; } a[j + 1] = v; } }
utils.h	/* * Licensed to the Apache Software Foundation (ASF) under one * or more contributor license agreements. See the NOTICE file * distributed with this work for additional information * regarding copyright ownership. The ASF licenses this file * to you under the Apache License, Version 2.0 (the * "License"); you may not use this file except in compliance * with the License. You may obtain a copy of the License at * * http://www.apache.org/licenses/LICENSE-2.0 * * Unless required by applicable law or agreed to in writing, * software distributed under the License is distributed on an * "AS IS" BASIS, WITHOUT WARRANTIES OR CONDITIONS OF ANY * KIND, either express or implied. See the License for the * specific language governing permissions and limitations * under the License. / /! * Copyright (c) 2015 by Contributors * \file utils.h * \brief Basic utilility functions. / #ifndef MXNET_COMMON_UTILS_H_ #define MXNET_COMMON_UTILS_H_ #include <dmlc/logging.h> #include <dmlc/omp.h> #include <nnvm/graph.h> #include <mxnet/engine.h> #include <mxnet/ndarray.h> #include <mxnet/op_attr_types.h> #include <mxnet/graph_attr_types.h> #include <nnvm/graph_attr_types.h> #include <memory> #include <vector> #include <type_traits> #include <utility> #include <random> #include <string> #include <thread> #include <algorithm> #include <functional> #include <limits> #include "../operator/mxnet_op.h" #if MXNET_USE_MKLDNN == 1 #include "../operator/nn/mkldnn/mkldnn_base-inl.h" #endif #if defined(_WIN32) \|\| defined(_WIN64) \|\| defined(__WINDOWS__) #include <windows.h> #else #include <unistd.h> #endif namespace mxnet { namespace common { #if defined(_WIN32) \|\| defined(_WIN64) \|\| defined(__WINDOWS__) inline size_t current_process_id() { return ::GetCurrentProcessId(); } #else inline size_t current_process_id() { return getpid(); } #endif /! * \brief IndPtr should be non-negative, in non-decreasing order, start with 0 * and end with value equal with size of indices. / struct csr_indptr_check { template<typename DType, typename IType> MSHADOW_XINLINE static void Map(int i, DType out, const IType* indptr, const nnvm::dim_t end, const nnvm::dim_t idx_size) { if (indptr[i+1] < 0 \|\| indptr[i+1] < indptr[i] \|\| (i == 0 && indptr[i] != 0) \|\| (i == end - 1 && indptr[end] != idx_size)) out = kCSRIndPtrErr; } }; /! * \brief Indices should be non-negative, less than the number of columns * and in ascending order per row. / struct csr_idx_check { template<typename DType, typename IType, typename RType> MSHADOW_XINLINE static void Map(int i, DType out, const IType* idx, const RType* indptr, const nnvm::dim_t ncols) { for (RType j = indptr[i]; j < indptr[i+1]; j++) { if (idx[j] >= ncols \|\| idx[j] < 0 \|\| (j < indptr[i+1] - 1 && idx[j] >= idx[j+1])) { out = kCSRIdxErr; break; } } } }; /! * \brief Indices of RSPNDArray should be non-negative, * less than the size of first dimension and in ascending order / struct rsp_idx_check { template<typename DType, typename IType> MSHADOW_XINLINE static void Map(int i, DType out, const IType* idx, const nnvm::dim_t end, const nnvm::dim_t nrows) { if ((i < end && idx[i+1] <= idx[i]) \|\| idx[i] < 0 \|\| idx[i] >= nrows) out = kRSPIdxErr; } }; template<typename xpu> void CheckFormatWrapper(const RunContext &rctx, const NDArray &input, const TBlob &err_cpu, const bool full_check); /! * \brief Check the validity of CSRNDArray. * \param rctx Execution context. * \param input Input NDArray of CSRStorage. * \param err_cpu Error number on cpu. * \param full_check If true, rigorous check, O(N) operations, * otherwise basic check, O(1) operations. / template<typename xpu> void CheckFormatCSRImpl(const RunContext &rctx, const NDArray &input, const TBlob &err_cpu, const bool full_check) { using namespace op::mxnet_op; CHECK_EQ(input.storage_type(), kCSRStorage) << "CheckFormatCSRImpl is for CSRNDArray"; const mxnet::TShape shape = input.shape(); const mxnet::TShape idx_shape = input.aux_shape(csr::kIdx); const mxnet::TShape indptr_shape = input.aux_shape(csr::kIndPtr); const mxnet::TShape storage_shape = input.storage_shape(); if ((shape.ndim() != 2) \|\| (idx_shape.ndim() != 1 \|\| indptr_shape.ndim() != 1 \|\| storage_shape.ndim() != 1) \|\| (indptr_shape[0] != shape[0] + 1) \|\| (idx_shape[0] != storage_shape[0])) { MSHADOW_TYPE_SWITCH(err_cpu.type_flag_, DType, { DType err = err_cpu.dptr<DType>(); err = kCSRShapeErr; }); return; } if (full_check) { MSHADOW_TYPE_SWITCH(err_cpu.type_flag_, DType, { MSHADOW_IDX_TYPE_SWITCH(input.aux_type(csr::kIndPtr), RType, { MSHADOW_IDX_TYPE_SWITCH(input.aux_type(csr::kIdx), IType, { mshadow::Stream<xpu> s = rctx.get_stream<xpu>(); NDArray ret_xpu = NDArray(mshadow::Shape1(1), rctx.get_ctx(), false, err_cpu.type_flag_); TBlob val_xpu = ret_xpu.data(); Kernel<set_to_int<kNormalErr>, xpu>::Launch(s, val_xpu.Size(), val_xpu.dptr<DType>()); Kernel<csr_indptr_check, xpu>::Launch(s, indptr_shape[0] - 1, val_xpu.dptr<DType>(), input.aux_data(csr::kIndPtr).dptr<RType>(), indptr_shape[0] - 1, idx_shape[0]); // no need to check indices if indices are empty if (idx_shape[0] != 0) { Kernel<csr_idx_check, xpu>::Launch(s, indptr_shape[0] - 1, val_xpu.dptr<DType>(), input.aux_data(csr::kIdx).dptr<IType>(), input.aux_data(csr::kIndPtr).dptr<RType>(), shape[1]); } mshadow::Copy(err_cpu.get<cpu, 1, DType>(), val_xpu.get<xpu, 1, DType>(s), s); }); }); }); } } /! \brief Check the validity of RowSparseNDArray. * \param rctx Execution context. * \param input Input NDArray of RowSparseStorage. * \param err_cpu Error number on cpu. * \param full_check If true, rigorous check, O(N) operations, * otherwise basic check, O(1) operations. / template<typename xpu> void CheckFormatRSPImpl(const RunContext &rctx, const NDArray &input, const TBlob &err_cpu, const bool full_check) { using namespace op::mxnet_op; CHECK_EQ(input.storage_type(), kRowSparseStorage) << "CheckFormatRSPImpl is for RSPNDArray"; const mxnet::TShape idx_shape = input.aux_shape(rowsparse::kIdx); if (idx_shape[0] != input.storage_shape()[0]) { MSHADOW_TYPE_SWITCH(err_cpu.type_flag_, DType, { DType err = err_cpu.dptr<DType>(); err = kRSPShapeErr; }); return; } if (idx_shape[0] == 0) { return; } if (full_check) { MSHADOW_TYPE_SWITCH(err_cpu.type_flag_, DType, { MSHADOW_IDX_TYPE_SWITCH(input.aux_type(rowsparse::kIdx), IType, { mshadow::Stream<xpu> s = rctx.get_stream<xpu>(); NDArray ret_xpu = NDArray(mshadow::Shape1(1), rctx.get_ctx(), false, err_cpu.type_flag_); TBlob val_xpu = ret_xpu.data(); Kernel<set_to_int<kNormalErr>, xpu>::Launch(s, val_xpu.Size(), val_xpu.dptr<DType>()); Kernel<rsp_idx_check, xpu>::Launch(s, idx_shape[0], val_xpu.dptr<DType>(), input.aux_data(rowsparse::kIdx).dptr<IType>(), idx_shape[0] - 1, input.shape()[0]); mshadow::Copy(err_cpu.get<cpu, 1, DType>(), val_xpu.get<xpu, 1, DType>(s), s); }); }); } } template<typename xpu> void CheckFormatImpl(const RunContext &rctx, const NDArray &input, const TBlob &err_cpu, const bool full_check) { int stype = input.storage_type(); if (stype == kCSRStorage) { CheckFormatCSRImpl<xpu>(rctx, input, err_cpu, full_check); } else if (stype == kRowSparseStorage) { CheckFormatRSPImpl<xpu>(rctx, input, err_cpu, full_check); } else if (stype == kDefaultStorage) { // no-op for default storage } else { LOG(FATAL) << "Unknown storage type " << stype; } } /! \brief Pick rows specified by user input index array from a row sparse ndarray and save them in the output sparse ndarray. / template<typename xpu> void SparseRetainOpForwardRspWrapper(mshadow::Stream<xpu> s, const NDArray& input_nd, const TBlob& idx_data, const OpReqType req, NDArray* output_nd); /* \brief Casts tensor storage type to the new type. / template<typename xpu> void CastStorageDispatch(const OpContext& ctx, const NDArray& input, const NDArray& output); /! \brief returns true if all storage types in `vstorage` are the same as target `stype`. * false is returned for empty inputs. / inline bool ContainsOnlyStorage(const StorageTypeVector& vstorage, const NDArrayStorageType stype) { if (!vstorage.empty()) { for (const auto& i : vstorage) { if (i != stype) return false; } return true; } return false; } /! \brief returns true if all storage types in `vstorage` are the same as target `stype1` * or `stype2'. Sets boolean if both found. * false is returned for empty inputs. / inline bool ContainsOnlyStorage(const StorageTypeVector& vstorage, const NDArrayStorageType stype1, const NDArrayStorageType stype2, bool has_both) { if (has_both) { has_both = false; } if (!vstorage.empty()) { uint8_t has = 0; for (const auto i : vstorage) { if (i == stype1) { has \|= 1; } else if (i == stype2) { has \|= 2; } else { return false; } } if (has_both) { has_both = has == 3; } return true; } return false; } /! \brief returns true if the storage types of arrays in `ndarrays` are the same as target `stype`. false is returned for empty inputs. / inline bool ContainsOnlyStorage(const std::vector<NDArray>& ndarrays, const NDArrayStorageType stype) { if (!ndarrays.empty()) { for (const auto& nd : ndarrays) { if (nd.storage_type() != stype) { return false; } } return true; } return false; } /! \brief returns true if the storage types of arrays in `ndarrays` * are the same as targets `stype1` or `stype2`. false is returned for empty inputs. / inline bool ContainsOnlyStorage(const std::vector<NDArray>& ndarrays, const NDArrayStorageType stype1, const NDArrayStorageType stype2, bool has_both) { if (has_both) { has_both = false; } if (!ndarrays.empty()) { uint8_t has = 0; for (const auto& nd : ndarrays) { const NDArrayStorageType stype = nd.storage_type(); if (stype == stype1) { has \|= 1; } else if (stype == stype2) { has \|= 2; } else { return false; } } if (has_both) { has_both = has == 3; } return true; } return false; } /! \brief returns true if storage type of any array in `ndarrays` is the same as the target `stype`. false is returned for empty inputs. / inline bool ContainsStorageType(const std::vector<NDArray>& ndarrays, const NDArrayStorageType stype) { if (!ndarrays.empty()) { for (const auto& nd : ndarrays) { if (nd.storage_type() == stype) { return true; } } } return false; } /! \brief returns true if any storage type `ndstype` in `ndstypes` * is the same as the target `stype`. false is returned for empty inputs. / inline bool ContainsStorageType(const std::vector<int>& ndstypes, const NDArrayStorageType stype) { if (!ndstypes.empty()) { for (const auto& ndstype : ndstypes) { if (ndstype == stype) { return true; } } } return false; } /! \brief get string representation of dispatch_mode / inline std::string dispatch_mode_string(const DispatchMode x) { switch (x) { case DispatchMode::kFCompute: return "fcompute"; case DispatchMode::kFComputeEx: return "fcompute_ex"; case DispatchMode::kFComputeFallback: return "fcompute_fallback"; case DispatchMode::kVariable: return "variable"; case DispatchMode::kUndefined: return "undefined"; } return "unknown"; } /! \brief get string representation of storage_type / inline std::string stype_string(const int x) { switch (x) { case kDefaultStorage: return "default"; case kCSRStorage: return "csr"; case kRowSparseStorage: return "row_sparse"; } return "unknown"; } /! \brief get string representation of device type / inline std::string dev_type_string(const int dev_type) { switch (dev_type) { case Context::kCPU: return "cpu"; case Context::kGPU: return "gpu"; case Context::kCPUPinned: return "cpu_pinned"; case Context::kCPUShared: return "cpu_shared"; } return "unknown"; } /! \brief get string representation of the operator stypes / inline std::string operator_stype_string(const nnvm::NodeAttrs& attrs, const int dev_mask, const std::vector<int>& in_attrs, const std::vector<int>& out_attrs) { std::ostringstream os; os << "operator = " << attrs.op->name << "\ninput storage types = ["; for (const int attr : in_attrs) { os << stype_string(attr) << ", "; } os << "]\n" << "output storage types = ["; for (const int attr : out_attrs) { os << stype_string(attr) << ", "; } os << "]\n" << "params = {"; for (auto kv : attrs.dict) { os << "\"" << kv.first << "\" : " << kv.second << ", "; } os << "}\n" << "context.dev_mask = " << dev_type_string(dev_mask); return os.str(); } /! \brief get string representation of the operator / inline std::string operator_string(const nnvm::NodeAttrs& attrs, const OpContext& ctx, const std::vector<NDArray>& inputs, const std::vector<OpReqType>& req, const std::vector<NDArray>& outputs) { std::string result = ""; std::vector<int> in_stypes; std::vector<int> out_stypes; in_stypes.reserve(inputs.size()); out_stypes.reserve(outputs.size()); auto xform = [](const NDArray arr) -> int { return arr.storage_type(); }; std::transform(inputs.begin(), inputs.end(), std::back_inserter(in_stypes), xform); std::transform(outputs.begin(), outputs.end(), std::back_inserter(out_stypes), xform); result += operator_stype_string(attrs, ctx.run_ctx.ctx.dev_mask(), in_stypes, out_stypes); return result; } /! \brief log message once. Intended for storage fallback warning messages. / inline void LogOnce(const std::string& message) { typedef dmlc::ThreadLocalStore<std::unordered_set<std::string>> LogStore; auto log_store = LogStore::Get(); if (log_store->find(message) == log_store->end()) { LOG(INFO) << message; log_store->insert(message); } } /! \brief log storage fallback event / inline void LogStorageFallback(const nnvm::NodeAttrs& attrs, const int dev_mask, const std::vector<int> in_attrs, const std::vector<int>* out_attrs) { static bool log = dmlc::GetEnv("MXNET_STORAGE_FALLBACK_LOG_VERBOSE", true); if (!log) return; const std::string op_str = operator_stype_string(attrs, dev_mask, in_attrs, out_attrs); std::ostringstream os; const char* warning = "\nThe operator with default storage type will be dispatched " "for execution. You're seeing this warning message because the operator above is unable " "to process the given ndarrays with specified storage types, context and parameter. " "Temporary dense ndarrays are generated in order to execute the operator. " "This does not affect the correctness of the programme. " "You can set environment variable MXNET_STORAGE_FALLBACK_LOG_VERBOSE to " "0 to suppress this warning."; os << "\nStorage type fallback detected:\n" << op_str << warning; LogOnce(os.str()); #if MXNET_USE_MKLDNN == 1 if (!MKLDNNEnvSet()) common::LogOnce("MXNET_MKLDNN_ENABLED flag is off. " "You can re-enable by setting MXNET_MKLDNN_ENABLED=1"); if (GetMKLDNNCacheSize() != -1) common::LogOnce("MXNET_MKLDNN_CACHE_NUM is set." "Should only be set if " "your model has variable input shapes, " "as cache size may grow unbounded"); #endif } // heuristic to dermine number of threads per GPU inline int GetNumThreadsPerGPU() { // This is resource efficient option. return dmlc::GetEnv("MXNET_GPU_WORKER_NTHREADS", 2); } // heuristic to get number of matching colors. // this decides how much parallelism we can get in each GPU. inline int GetExecNumMatchColor() { // This is resource efficient option. int num_match_color = dmlc::GetEnv("MXNET_EXEC_NUM_TEMP", 1); return std::min(num_match_color, GetNumThreadsPerGPU()); } template<typename T, typename V> V ParallelAccumulate(const T* a, const int n, V start) { V sum = start; #pragma omp parallel for reduction(+:sum) for (int i = 0; i < n; ++i) { sum += a[i]; } return sum; } /! \brief * Helper function for ParallelSort. * DO NOT call this function directly. * Use the interface ParallelSort instead. * Ref: https://github.com/dmlc/difacto/blob/master/src/common/parallel_sort.h / template<typename RandomIt, typename Compare> void ParallelSortHelper(RandomIt first, size_t len, size_t grainsize, const Compare& comp) { if (len < grainsize) { std::sort(first, first+len, comp); } else { std::thread thr(ParallelSortHelper<RandomIt, Compare>, first, len/2, grainsize, comp); ParallelSortHelper(first+len/2, len - len/2, grainsize, comp); thr.join(); std::inplace_merge(first, first+len/2, first+len, comp); } } /! * \brief * Sort the elements in the range [first, last) into the ascending order defined by * the comparator comp. * If the length of the range [first, last) is greater than a certain threshold, * the range will be recursively divided into two and assign two threads * to sort each half range. * Ref: https://github.com/dmlc/difacto/blob/master/src/common/parallel_sort.h / template<typename RandomIt, typename Compare> void ParallelSort(RandomIt first, RandomIt last, size_t num_threads, Compare comp) { const auto num = std::distance(first, last); size_t grainsize = std::max(num / num_threads + 5, static_cast<size_t>(102416)); ParallelSortHelper(first, num, grainsize, comp); } /! \brief * Sort the elements in the range [first, last) into ascending order. * The elements are compared using the default < operator. * If the length of the range [first, last) is greater than a certain threshold, * the range will be recursively divided into two and assign two threads * to sort each half range. * Ref: https://github.com/dmlc/difacto/blob/master/src/common/parallel_sort.h / template<typename RandomIt> void ParallelSort(RandomIt first, RandomIt last, size_t num_threads) { ParallelSort(first, last, num_threads, std::less<typename std::iterator_traits<RandomIt>::value_type>()); } /! * \brief Random Engine / typedef std::mt19937 RANDOM_ENGINE; /! * \brief Helper functions. / namespace helper { /! * \brief Helper for non-array type `T`. / template <class T> struct UniqueIf { /! * \brief Type of `T`. / using SingleObject = std::unique_ptr<T>; }; /! * \brief Helper for an array of unknown bound `T`. / template <class T> struct UniqueIf<T[]> { /! * \brief Type of `T`. / using UnknownBound = std::unique_ptr<T[]>; }; /! * \brief Helper for an array of known bound `T`. / template <class T, size_t kSize> struct UniqueIf<T[kSize]> { /! * \brief Type of `T`. / using KnownBound = void; }; } // namespace helper /! * \brief Constructs an object of type `T` and wraps it in a * `std``::``unique_ptr`. * \param args List of arguments with which an instance of `T` will be * constructed. * \return `std``::``unique_ptr` of an instance of type `T`. * * Constructs a non-array type `T`. The arguments `args` are passed to the * constructor of `T`. The function does not participate in the overload * resolution if `T` is an array type. / template <class T, class... Args> typename helper::UniqueIf<T>::SingleObject MakeUnique(Args&&... args) { return std::unique_ptr<T>(new T(std::forward<Args>(args)...)); } /! * \brief Constructs an object of type `T` and wraps it in a * `std``::``unique_ptr`. * \param n The size of the array to construct. * \return `std``::``unique_ptr` of an instance of type `T`. * * Constructs an array of unknown bound `T`. The function does not participate * in the overload resolution unless `T` is an array of unknown bound. / template <class T> typename helper::UniqueIf<T>::UnknownBound MakeUnique(size_t n) { using U = typename std::remove_extent<T>::type; return std::unique_ptr<T>(new U[n]{}); } /! * \brief Constructs an object of type `T` and wraps it in a * `std``::``unique_ptr`. * \param args List of arguments with which an instance of `T` will be * constructed. * * Constructs an arrays of known bound is disallowed. / template <class T, class... Args> typename helper::UniqueIf<T>::KnownBound MakeUnique(Args&&... args) = delete; template<typename FCompType> FCompType GetFCompute(const nnvm::Op op, const std::string& name, const Context& ctx) { static auto& fcompute_cpu = nnvm::Op::GetAttr<FCompType>(name + "<cpu>"); static auto& fcompute_gpu = nnvm::Op::GetAttr<FCompType>(name + "<gpu>"); if (ctx.dev_mask() == cpu::kDevMask) { return fcompute_cpu.get(op, nullptr); } else if (ctx.dev_mask() == gpu::kDevMask) { return fcompute_gpu.get(op, nullptr); } else { LOG(FATAL) << "Unknown device mask " << ctx.dev_mask(); return nullptr; } } /! \brief Return the max integer value representable in the type `T` without loss of precision. / template <typename T> constexpr size_t MaxIntegerValue() { return std::is_integral<T>::value ? std::numeric_limits<T>::max(): size_t(2) << (std::numeric_limits<T>::digits - 1); } template <> constexpr size_t MaxIntegerValue<mshadow::half::half_t>() { return size_t(2) << 10; } MSHADOW_XINLINE int ilog2ul(size_t a) { int k = 1; while (a >>= 1) ++k; return k; } MSHADOW_XINLINE int ilog2ui(unsigned int a) { int k = 1; while (a >>= 1) ++k; return k; } /! * \brief Return an NDArray of all zeros. / inline NDArray InitZeros(const NDArrayStorageType stype, const mxnet::TShape &shape, const Context &ctx, const int dtype) { // NDArray with default storage if (stype == kDefaultStorage) { NDArray ret(shape, ctx, false, dtype); ret = 0; return ret; } // NDArray with non-default storage. Storage allocation is always delayed. return NDArray(stype, shape, ctx, true, dtype); } /! * \brief Helper to add a NDArray of zeros to a std::vector. / inline void EmplaceBackZeros(const NDArrayStorageType stype, const mxnet::TShape &shape, const Context &ctx, const int dtype, std::vector<NDArray> vec) { // NDArray with default storage if (stype == kDefaultStorage) { vec->emplace_back(shape, ctx, false, dtype); vec->back() = 0; } else { // NDArray with non-default storage. Storage allocation is always delayed. vec->emplace_back(stype, shape, ctx, true, dtype); } } /! \brief parallelize copy by OpenMP. / template<typename DType> inline void ParallelCopy(DType dst, const DType* src, index_t size) { static index_t copy_block_size = dmlc::GetEnv("MXNET_CPU_PARALLEL_COPY_SIZE", 200000); if (size >= copy_block_size) { #pragma omp parallel for num_threads(engine::OpenMP::Get()->GetRecommendedOMPThreadCount()) for (index_t i = 0; i < size; ++i) { dst[i] = src[i]; } } else { std::memcpy(dst, src, sizeof(DType) * size); } } /! \brief If numpy compatibility is turned off (default), the shapes passed in * by users follow the legacy shape definition: * 1. 0 ndim means the shape is completely unknown. * 2. 0 dim size means the dim size is unknown. * We need to convert those shapes to use the numpy shape definition: * 1. 0 ndim means it's a scalar tensor. * 2. -1 ndim means the shape is unknown. * 3. 0 dim size means no elements in that dimension. * 4. -1 dim size means the dimension's size is unknown. * so that operator's infer shape function can work in backend. * \param shape to be converted. * Note: It is possible that the shape to be converted is already * numpy compatible. For example, when a subgraph operator's infer * shape function is called from the infer shape pass of the whole * graph, its input/output shapes have been converted to numpy * compatible shapes. / inline void ConvertToNumpyShape(mxnet::TShape shape) { if (shape->ndim() == 0) { // legacy shape ndim = 0 means unknown shape = mxnet::TShape(); // unknown shape ndim = -1 } else { for (int j = 0; j < shape->ndim(); ++j) { if ((shape)[j] == 0) { // legacy shape dim_size = 0 means unknown (shape)[j] = -1; // unknown dim size = -1 } } } } inline void ConvertToNumpyShape(mxnet::ShapeVector shapes) { for (size_t i = 0; i < shapes->size(); ++i) { ConvertToNumpyShape(&(shapes->at(i))); } } /! \brief This is function is used to convert shapes returned by * the infer shape functions/pass to the legacy shape definition. / inline void ConvertToLegacyShape(mxnet::TShape shape) { if (!mxnet::ndim_is_known(shape)) { shape = mxnet::TShape(0, -1); } else { for (int j = 0; j < shape->ndim(); ++j) { if (!mxnet::dim_size_is_known(shape, j)) { (shape)[j] = 0; } } } } inline void ConvertToLegacyShape(mxnet::ShapeVector* shapes) { for (size_t i = 0; i < shapes->size(); ++i) { ConvertToLegacyShape(&(shapes->at(i))); } } } // namespace common } // namespace mxnet #endif // MXNET_COMMON_UTILS_H_
DRB011-minusminus-orig-yes.c	/* Copyright (C) 1991-2018 Free Software Foundation, Inc. This file is part of the GNU C Library. The GNU C Library is free software; you can redistribute it andor modify it under the terms of the GNU Lesser General Public License as published by the Free Software Foundation; either version 2.1 of the License, or (at your option) any later version. The GNU C Library is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU Lesser General Public License for more details. You should have received a copy of the GNU Lesser General Public License along with the GNU C Library; if not, see <http:www.gnu.org/licenses/>. / / This header is separate from features.h so that the compiler can include it implicitly at the start of every compilation. It must not itself include <features.h> or any other header that includes <features.h> because the implicit include comes before any feature test macros that may be defined in a source file before it first explicitly includes a system header. GCC knows the name of this header in order to preinclude it. / / glibc's intent is to support the IEC 559 math functionality, real and complex. If the GCC (4.9 and later) predefined macros specifying compiler intent are available, use them to determine whether the overall intent is to support these features; otherwise, presume an older compiler has intent to support these features and define these macros by default. / / wchar_t uses Unicode 10.0.0. Version 10.0 of the Unicode Standard is synchronized with ISOIEC 10646:2017, fifth edition, plus the following additions from Amendment 1 to the fifth edition: - 56 emoji characters - 285 hentaigana - 3 additional Zanabazar Square characters / / Copyright (c) 2017, Lawrence Livermore National Security, LLC. Produced at the Lawrence Livermore National Laboratory Written by Chunhua Liao, Pei-Hung Lin, Joshua Asplund, Markus Schordan, and Ian Karlin (email: liao6@llnl.gov, lin32@llnl.gov, asplund1@llnl.gov, schordan1@llnl.gov, karlin1@llnl.gov) LLNL-CODE-732144 All rights reserved. This file is part of DataRaceBench. For details, see https:github.comLLNL/dataracebench. Please also see the LICENSE file for our additional BSD notice. Redistribution and use in source and binary forms, with or without modification, are permitted provided that the following conditions are met: * Redistributions of source code must retain the above copyright notice, this list of conditions and the disclaimer below. * Redistributions in binary form must reproduce the above copyright notice, this list of conditions and the disclaimer (as noted below) in the documentation and/or other materials provided with the distribution. * Neither the name of the LLNS/LLNL nor the names of its contributors may be used to endorse or promote products derived from this software without specific prior written permission. THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL LAWRENCE LIVERMORE NATIONAL SECURITY, LLC, THE U.S. DEPARTMENT OF ENERGY OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. / / The -- operation on numNodes2 is not protected, causing data race. Data race pair: numNodes2@74:7 vs. numNodes2@74:7 / #include <stdlib.h> #include <stdio.h> int main(int argc, char argv[]) { int i; int len = 100; int numNodes = len, numNodes2 = 0; int x[100]; /* initialize x[] */ int _ret_val_0; #pragma cetus private(i) #pragma loop name main#0 #pragma cetus parallel #pragma omp parallel for private(i) for (i=0; i<len; i ++ ) { if ((i%2)==0) { x[i]=5; } else { x[i]=( - 5); } } #pragma cetus private(i) #pragma loop name main#1 #pragma cetus reduction(+: numNodes2) #pragma cetus parallel #pragma omp parallel for private(i) reduction(+: numNodes2) for (i=(numNodes-1); i>( - 1); -- i) { if (x[i]<=0) { numNodes2 -- ; } } printf("numNodes2 = %d\n", numNodes2); _ret_val_0=0; return _ret_val_0; }
use_memory.c	/* * This is just a test, to do a sanity check * on the actual peak_memusage * $Id$ * / #include <stdio.h> / print / #include <stdlib.h> / malloc / #include <unistd.h> / optarg / #ifdef COMPILE_MPI #include <mpi.h> #endif #define MAX_SIZE 2147483647 #define DEFAULT_SIZE 1000000 #define MAX_REPEAT 100 void printUsage(char argv) { fprintf(stderr, "\nUsage:\n%s [-s size] [-r repetitions] [-d delay (ms)] \n\n", argv[0]); exit(1); } void parseInt(int data, char param) { if (param != NULL) data = atoi(param); } int main(int argc, char *argv) { int i, j, last, size = DEFAULT_SIZE, repeat = 1, delay=1000; int spare_data, c, error, rank, poolsize; char ch_size = NULL, ch_repeat = NULL, ch_delay=NULL, ch_rank="thread"; #ifdef COMPILE_MPI if(error = MPI_Init(NULL, NULL)) { fprintf(stderr, "MPI INIT error: %d", error); return 1; } if(error = MPI_Comm_rank(MPI_COMM_WORLD, &rank)) { fprintf(stderr, "MPI RANK error: %d", error); return 1; } if(error = MPI_Comm_size(MPI_COMM_WORLD, &poolsize)) { fprintf(stderr, "MPI SIZE error: %d", error); return 1; } ch_rank="task"; #endif while ((c = getopt (argc, argv, "s:r:d:")) != -1) { switch(c) { case 's': ch_size = optarg; break; case 'r': ch_repeat = optarg; break; case 'd': ch_delay = optarg; break; default: printUsage(argv); } } parseInt(&size, ch_size); parseInt(&repeat, ch_repeat); parseInt(&delay, ch_delay); if (size <= 0 \|\| size > MAX_SIZE \|\| repeat < 1 \|\| repeat > MAX_REPEAT \|\| delay < 0) { fprintf(stderr, "size:%d, repeat:%d, delay:%f\n", size, repeat, delay); printUsage(argv); } #ifdef COMPILE_OMP #pragma omp parallel default(none) private(rank, poolsize, i, j, last, spare_data) shared(size, delay, repeat, ch_rank) { rank = omp_get_thread_num(); poolsize = omp_get_num_threads(); #elif !defined COMPILE_MPI rank = 0; poolsize = 1; #endif for(i=0; i<repeat; i++) { last = size (rank+1); / every rank will have a different number / int amount = lastsizeof(int); printf("Allocating, using and freeing %d ints (%.2f MiB) in %s %d/%d\n", last, amount/1048576., ch_rank, rank, poolsize); spare_data = malloc(amount); for (j=0; j<last; j++) spare_data[j] = 24; usleep(delay * 1000); } free(spare_data); #ifdef COMPILE_MPI if(error = MPI_Finalize()) { fprintf(stderr, "MPI FINALIZE error: %d", error); return 1; } #else #ifdef COMPILE_OMP } #endif #endif return 0; }
image.c	/* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % IIIII M M AAA GGGG EEEEE % % I MM MM A A G E % % I M M M AAAAA G GG EEE % % I M M A A G G E % % IIIII M M A A GGGG EEEEE % % % % % % MagickCore Image Methods % % % % Software Design % % Cristy % % July 1992 % % % % % % Copyright 1999-2020 ImageMagick Studio LLC, a non-profit organization % % dedicated to making software imaging solutions freely available. % % % % You may not use this file except in compliance with the License. You may % % obtain a copy of the License at % % % % https://imagemagick.org/script/license.php % % % % Unless required by applicable law or agreed to in writing, software % % distributed under the License is distributed on an "AS IS" BASIS, % % WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. % % See the License for the specific language governing permissions and % % limitations under the License. % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % / / Include declarations. / #include "MagickCore/studio.h" #include "MagickCore/animate.h" #include "MagickCore/artifact.h" #include "MagickCore/attribute.h" #include "MagickCore/blob.h" #include "MagickCore/blob-private.h" #include "MagickCore/cache.h" #include "MagickCore/cache-private.h" #include "MagickCore/cache-view.h" #include "MagickCore/channel.h" #include "MagickCore/client.h" #include "MagickCore/color.h" #include "MagickCore/color-private.h" #include "MagickCore/colormap.h" #include "MagickCore/colorspace.h" #include "MagickCore/colorspace-private.h" #include "MagickCore/composite.h" #include "MagickCore/composite-private.h" #include "MagickCore/compress.h" #include "MagickCore/constitute.h" #include "MagickCore/delegate.h" #include "MagickCore/display.h" #include "MagickCore/draw.h" #include "MagickCore/enhance.h" #include "MagickCore/exception.h" #include "MagickCore/exception-private.h" #include "MagickCore/gem.h" #include "MagickCore/geometry.h" #include "MagickCore/histogram.h" #include "MagickCore/image-private.h" #include "MagickCore/list.h" #include "MagickCore/magic.h" #include "MagickCore/magick.h" #include "MagickCore/magick-private.h" #include "MagickCore/memory_.h" #include "MagickCore/memory-private.h" #include "MagickCore/module.h" #include "MagickCore/monitor.h" #include "MagickCore/monitor-private.h" #include "MagickCore/option.h" #include "MagickCore/paint.h" #include "MagickCore/pixel-accessor.h" #include "MagickCore/profile.h" #include "MagickCore/property.h" #include "MagickCore/quantize.h" #include "MagickCore/random_.h" #include "MagickCore/resource_.h" #include "MagickCore/segment.h" #include "MagickCore/semaphore.h" #include "MagickCore/signature-private.h" #include "MagickCore/statistic.h" #include "MagickCore/string_.h" #include "MagickCore/string-private.h" #include "MagickCore/thread-private.h" #include "MagickCore/threshold.h" #include "MagickCore/timer.h" #include "MagickCore/timer-private.h" #include "MagickCore/token.h" #include "MagickCore/token-private.h" #include "MagickCore/utility.h" #include "MagickCore/utility-private.h" #include "MagickCore/version.h" #include "MagickCore/xwindow-private.h" / Constant declaration. / const char BackgroundColor[] = "#ffffff", / white / BorderColor[] = "#dfdfdf", / gray / DefaultTileFrame[] = "15x15+3+3", DefaultTileGeometry[] = "120x120+4+3>", DefaultTileLabel[] = "%f\n%G\n%b", ForegroundColor[] = "#000", / black / LoadImageTag[] = "Load/Image", LoadImagesTag[] = "Load/Images", MatteColor[] = "#bdbdbd", / gray / PSDensityGeometry[] = "72.0x72.0", PSPageGeometry[] = "612x792", SaveImageTag[] = "Save/Image", SaveImagesTag[] = "Save/Images", TransparentColor[] = "#00000000"; / transparent black / const double DefaultResolution = 72.0; / %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % A c q u i r e I m a g e % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % AcquireImage() returns a pointer to an image structure initialized to % default values. % % The format of the AcquireImage method is: % % Image AcquireImage(const ImageInfo image_info,ExceptionInfo exception) % % A description of each parameter follows: % % o image_info: Many of the image default values are set from this % structure. For example, filename, compression, depth, background color, % and others. % % o exception: return any errors or warnings in this structure. % / MagickExport Image AcquireImage(const ImageInfo image_info, ExceptionInfo exception) { const char option; Image image; MagickStatusType flags; / Allocate image structure. / (void) LogMagickEvent(TraceEvent,GetMagickModule(),"..."); image=(Image ) AcquireCriticalMemory(sizeof(image)); (void) memset(image,0,sizeof(image)); /* Initialize Image structure. / (void) CopyMagickString(image->magick,"MIFF",MagickPathExtent); image->storage_class=DirectClass; image->depth=MAGICKCORE_QUANTUM_DEPTH; image->colorspace=sRGBColorspace; image->rendering_intent=PerceptualIntent; image->gamma=1.000f/2.200f; image->chromaticity.red_primary.x=0.6400f; image->chromaticity.red_primary.y=0.3300f; image->chromaticity.red_primary.z=0.0300f; image->chromaticity.green_primary.x=0.3000f; image->chromaticity.green_primary.y=0.6000f; image->chromaticity.green_primary.z=0.1000f; image->chromaticity.blue_primary.x=0.1500f; image->chromaticity.blue_primary.y=0.0600f; image->chromaticity.blue_primary.z=0.7900f; image->chromaticity.white_point.x=0.3127f; image->chromaticity.white_point.y=0.3290f; image->chromaticity.white_point.z=0.3583f; image->interlace=NoInterlace; image->ticks_per_second=UndefinedTicksPerSecond; image->compose=OverCompositeOp; (void) QueryColorCompliance(MatteColor,AllCompliance,&image->matte_color, exception); (void) QueryColorCompliance(BackgroundColor,AllCompliance, &image->background_color,exception); (void) QueryColorCompliance(BorderColor,AllCompliance,&image->border_color, exception); (void) QueryColorCompliance(TransparentColor,AllCompliance, &image->transparent_color,exception); GetTimerInfo(&image->timer); image->cache=AcquirePixelCache(0); image->channel_mask=DefaultChannels; image->channel_map=AcquirePixelChannelMap(); image->blob=CloneBlobInfo((BlobInfo ) NULL); image->timestamp=GetMagickTime(); image->debug=IsEventLogging(); image->reference_count=1; image->semaphore=AcquireSemaphoreInfo(); image->signature=MagickCoreSignature; if (image_info == (ImageInfo ) NULL) return(image); / Transfer image info. / SetBlobExempt(image,image_info->file != (FILE ) NULL ? MagickTrue : MagickFalse); (void) CopyMagickString(image->filename,image_info->filename, MagickPathExtent); (void) CopyMagickString(image->magick_filename,image_info->filename, MagickPathExtent); (void) CopyMagickString(image->magick,image_info->magick,MagickPathExtent); if (image_info->size != (char ) NULL) { (void) ParseAbsoluteGeometry(image_info->size,&image->extract_info); image->columns=image->extract_info.width; image->rows=image->extract_info.height; image->offset=image->extract_info.x; image->extract_info.x=0; image->extract_info.y=0; } if (image_info->extract != (char ) NULL) { RectangleInfo geometry; (void) memset(&geometry,0,sizeof(geometry)); flags=ParseAbsoluteGeometry(image_info->extract,&geometry); if (((flags & XValue) != 0) \|\| ((flags & YValue) != 0)) { image->extract_info=geometry; Swap(image->columns,image->extract_info.width); Swap(image->rows,image->extract_info.height); } } image->compression=image_info->compression; image->quality=image_info->quality; image->endian=image_info->endian; image->interlace=image_info->interlace; image->units=image_info->units; if (image_info->density != (char ) NULL) { GeometryInfo geometry_info; flags=ParseGeometry(image_info->density,&geometry_info); if ((flags & RhoValue) != 0) image->resolution.x=geometry_info.rho; image->resolution.y=image->resolution.x; if ((flags & SigmaValue) != 0) image->resolution.y=geometry_info.sigma; } if (image_info->page != (char ) NULL) { char geometry; image->page=image->extract_info; geometry=GetPageGeometry(image_info->page); (void) ParseAbsoluteGeometry(geometry,&image->page); geometry=DestroyString(geometry); } if (image_info->depth != 0) image->depth=image_info->depth; image->dither=image_info->dither; image->matte_color=image_info->matte_color; image->background_color=image_info->background_color; image->border_color=image_info->border_color; image->transparent_color=image_info->transparent_color; image->ping=image_info->ping; image->progress_monitor=image_info->progress_monitor; image->client_data=image_info->client_data; if (image_info->cache != (void ) NULL) ClonePixelCacheMethods(image->cache,image_info->cache); /* Set all global options that map to per-image settings. / (void) SyncImageSettings(image_info,image,exception); / Global options that are only set for new images. / option=GetImageOption(image_info,"delay"); if (option != (const char ) NULL) { GeometryInfo geometry_info; flags=ParseGeometry(option,&geometry_info); if ((flags & GreaterValue) != 0) { if (image->delay > (size_t) floor(geometry_info.rho+0.5)) image->delay=(size_t) floor(geometry_info.rho+0.5); } else if ((flags & LessValue) != 0) { if (image->delay < (size_t) floor(geometry_info.rho+0.5)) image->ticks_per_second=(ssize_t) floor(geometry_info.sigma+0.5); } else image->delay=(size_t) floor(geometry_info.rho+0.5); if ((flags & SigmaValue) != 0) image->ticks_per_second=(ssize_t) floor(geometry_info.sigma+0.5); } option=GetImageOption(image_info,"dispose"); if (option != (const char ) NULL) image->dispose=(DisposeType) ParseCommandOption(MagickDisposeOptions, MagickFalse,option); return(image); } / %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % A c q u i r e I m a g e I n f o % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % AcquireImageInfo() allocates the ImageInfo structure. % % The format of the AcquireImageInfo method is: % % ImageInfo AcquireImageInfo(void) % / MagickExport ImageInfo AcquireImageInfo(void) { ImageInfo image_info; image_info=(ImageInfo ) AcquireCriticalMemory(sizeof(image_info)); GetImageInfo(image_info); return(image_info); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % A c q u i r e N e x t I m a g e % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % AcquireNextImage() initializes the next image in a sequence to % default values. The next member of image points to the newly allocated % image. If there is a memory shortage, next is assigned NULL. % % The format of the AcquireNextImage method is: % % void AcquireNextImage(const ImageInfo image_info,Image image, % ExceptionInfo exception) % % A description of each parameter follows: % % o image_info: Many of the image default values are set from this % structure. For example, filename, compression, depth, background color, % and others. % % o image: the image. % % o exception: return any errors or warnings in this structure. % / MagickExport void AcquireNextImage(const ImageInfo image_info,Image image, ExceptionInfo exception) { / Allocate image structure. / assert(image != (Image ) NULL); assert(image->signature == MagickCoreSignature); if (image->debug != MagickFalse) (void) LogMagickEvent(TraceEvent,GetMagickModule(),"%s",image->filename); image->next=AcquireImage(image_info,exception); if (GetNextImageInList(image) == (Image ) NULL) return; (void) CopyMagickString(GetNextImageInList(image)->filename,image->filename, MagickPathExtent); if (image_info != (ImageInfo ) NULL) (void) CopyMagickString(GetNextImageInList(image)->filename, image_info->filename,MagickPathExtent); DestroyBlob(GetNextImageInList(image)); image->next->blob=ReferenceBlob(image->blob); image->next->endian=image->endian; image->next->scene=image->scene+1; image->next->previous=image; } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % A p p e n d I m a g e s % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % AppendImages() takes all images from the current image pointer to the end % of the image list and appends them to each other top-to-bottom if the % stack parameter is true, otherwise left-to-right. % % The current gravity setting effects how the image is justified in the % final image. % % The format of the AppendImages method is: % % Image AppendImages(const Image images,const MagickBooleanType stack, % ExceptionInfo exception) % % A description of each parameter follows: % % o images: the image sequence. % % o stack: A value other than 0 stacks the images top-to-bottom. % % o exception: return any errors or warnings in this structure. % / MagickExport Image AppendImages(const Image images, const MagickBooleanType stack,ExceptionInfo exception) { #define AppendImageTag "Append/Image" CacheView append_view; Image append_image; MagickBooleanType homogeneous_colorspace, status; MagickOffsetType n; PixelTrait alpha_trait; RectangleInfo geometry; register const Image next; size_t depth, height, number_images, width; ssize_t x_offset, y, y_offset; /* Compute maximum area of appended area. / assert(images != (Image ) NULL); assert(images->signature == MagickCoreSignature); if (images->debug != MagickFalse) (void) LogMagickEvent(TraceEvent,GetMagickModule(),"%s",images->filename); assert(exception != (ExceptionInfo ) NULL); assert(exception->signature == MagickCoreSignature); alpha_trait=images->alpha_trait; number_images=1; width=images->columns; height=images->rows; depth=images->depth; homogeneous_colorspace=MagickTrue; next=GetNextImageInList(images); for ( ; next != (Image ) NULL; next=GetNextImageInList(next)) { if (next->depth > depth) depth=next->depth; if (next->colorspace != images->colorspace) homogeneous_colorspace=MagickFalse; if (next->alpha_trait != UndefinedPixelTrait) alpha_trait=BlendPixelTrait; number_images++; if (stack != MagickFalse) { if (next->columns > width) width=next->columns; height+=next->rows; continue; } width+=next->columns; if (next->rows > height) height=next->rows; } /* Append images. / append_image=CloneImage(images,width,height,MagickTrue,exception); if (append_image == (Image ) NULL) return((Image ) NULL); if (SetImageStorageClass(append_image,DirectClass,exception) == MagickFalse) { append_image=DestroyImage(append_image); return((Image ) NULL); } if (homogeneous_colorspace == MagickFalse) (void) SetImageColorspace(append_image,sRGBColorspace,exception); append_image->depth=depth; append_image->alpha_trait=alpha_trait; append_image->page=images->page; (void) SetImageBackgroundColor(append_image,exception); status=MagickTrue; x_offset=0; y_offset=0; next=images; append_view=AcquireAuthenticCacheView(append_image,exception); for (n=0; n < (MagickOffsetType) number_images; n++) { CacheView image_view; MagickBooleanType proceed; SetGeometry(append_image,&geometry); GravityAdjustGeometry(next->columns,next->rows,next->gravity,&geometry); if (stack != MagickFalse) x_offset-=geometry.x; else y_offset-=geometry.y; image_view=AcquireVirtualCacheView(next,exception); #if defined(MAGICKCORE_OPENMP_SUPPORT) #pragma omp parallel for schedule(static) shared(status) \ magick_number_threads(next,next,next->rows,1) #endif for (y=0; y < (ssize_t) next->rows; y++) { MagickBooleanType sync; PixelInfo pixel; register const Quantum magick_restrict p; register Quantum magick_restrict q; register ssize_t x; if (status == MagickFalse) continue; p=GetCacheViewVirtualPixels(image_view,0,y,next->columns,1,exception); q=QueueCacheViewAuthenticPixels(append_view,x_offset,y+y_offset, next->columns,1,exception); if ((p == (const Quantum ) NULL) \|\| (q == (Quantum ) NULL)) { status=MagickFalse; continue; } GetPixelInfo(next,&pixel); for (x=0; x < (ssize_t) next->columns; x++) { GetPixelInfoPixel(next,p,&pixel); SetPixelViaPixelInfo(append_image,&pixel,q); p+=GetPixelChannels(next); q+=GetPixelChannels(append_image); } sync=SyncCacheViewAuthenticPixels(append_view,exception); if (sync == MagickFalse) status=MagickFalse; } image_view=DestroyCacheView(image_view); if (stack == MagickFalse) { x_offset+=(ssize_t) next->columns; y_offset=0; } else { x_offset=0; y_offset+=(ssize_t) next->rows; } proceed=SetImageProgress(append_image,AppendImageTag,n,number_images); if (proceed == MagickFalse) break; next=GetNextImageInList(next); } append_view=DestroyCacheView(append_view); if (status == MagickFalse) append_image=DestroyImage(append_image); return(append_image); } / %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % C a t c h I m a g e E x c e p t i o n % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % CatchImageException() returns if no exceptions are found in the image % sequence, otherwise it determines the most severe exception and reports % it as a warning or error depending on the severity. % % The format of the CatchImageException method is: % % ExceptionType CatchImageException(Image image) % % A description of each parameter follows: % % o image: An image sequence. % / MagickExport ExceptionType CatchImageException(Image image) { ExceptionInfo exception; ExceptionType severity; assert(image != (const Image ) NULL); assert(image->signature == MagickCoreSignature); if (image->debug != MagickFalse) (void) LogMagickEvent(TraceEvent,GetMagickModule(),"%s",image->filename); exception=AcquireExceptionInfo(); CatchException(exception); severity=exception->severity; exception=DestroyExceptionInfo(exception); return(severity); } / %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % C l i p I m a g e P a t h % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % ClipImagePath() sets the image clip mask based any clipping path information % if it exists. % % The format of the ClipImagePath method is: % % MagickBooleanType ClipImagePath(Image image,const char pathname, % const MagickBooleanType inside,ExceptionInfo exception) % % A description of each parameter follows: % % o image: the image. % % o pathname: name of clipping path resource. If name is preceded by #, use % clipping path numbered by name. % % o inside: if non-zero, later operations take effect inside clipping path. % Otherwise later operations take effect outside clipping path. % % o exception: return any errors or warnings in this structure. % / MagickExport MagickBooleanType ClipImage(Image image,ExceptionInfo exception) { return(ClipImagePath(image,"#1",MagickTrue,exception)); } MagickExport MagickBooleanType ClipImagePath(Image image,const char pathname, const MagickBooleanType inside,ExceptionInfo exception) { #define ClipImagePathTag "ClipPath/Image" char property; const char value; Image clip_mask; ImageInfo image_info; assert(image != (const Image ) NULL); assert(image->signature == MagickCoreSignature); if (image->debug != MagickFalse) (void) LogMagickEvent(TraceEvent,GetMagickModule(),"%s",image->filename); assert(pathname != NULL); property=AcquireString(pathname); (void) FormatLocaleString(property,MagickPathExtent,"8BIM:1999,2998:%s", pathname); value=GetImageProperty(image,property,exception); property=DestroyString(property); if (value == (const char ) NULL) { ThrowFileException(exception,OptionError,"NoClipPathDefined", image->filename); return(MagickFalse); } image_info=AcquireImageInfo(); (void) CopyMagickString(image_info->filename,image->filename, MagickPathExtent); (void) ConcatenateMagickString(image_info->filename,pathname, MagickPathExtent); clip_mask=BlobToImage(image_info,value,strlen(value),exception); image_info=DestroyImageInfo(image_info); if (clip_mask == (Image ) NULL) return(MagickFalse); if (clip_mask->storage_class == PseudoClass) { (void) SyncImage(clip_mask,exception); if (SetImageStorageClass(clip_mask,DirectClass,exception) == MagickFalse) return(MagickFalse); } if (inside == MagickFalse) (void) NegateImage(clip_mask,MagickFalse,exception); (void) FormatLocaleString(clip_mask->magick_filename,MagickPathExtent, "8BIM:1999,2998:%s\nPS",pathname); (void) SetImageMask(image,WritePixelMask,clip_mask,exception); clip_mask=DestroyImage(clip_mask); return(MagickTrue); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % C l o n e I m a g e % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % CloneImage() copies an image and returns the copy as a new image object. % % If the specified columns and rows is 0, an exact copy of the image is % returned, otherwise the pixel data is undefined and must be initialized % with the QueueAuthenticPixels() and SyncAuthenticPixels() methods. On % failure, a NULL image is returned and exception describes the reason for the % failure. % % The format of the CloneImage method is: % % Image CloneImage(const Image image,const size_t columns, % const size_t rows,const MagickBooleanType orphan, % ExceptionInfo exception) % % A description of each parameter follows: % % o image: the image. % % o columns: the number of columns in the cloned image. % % o rows: the number of rows in the cloned image. % % o detach: With a value other than 0, the cloned image is detached from % its parent I/O stream. % % o exception: return any errors or warnings in this structure. % / MagickExport Image CloneImage(const Image image,const size_t columns, const size_t rows,const MagickBooleanType detach,ExceptionInfo exception) { Image clone_image; double scale; size_t length; /* Clone the image. / assert(image != (const Image ) NULL); assert(image->signature == MagickCoreSignature); if (image->debug != MagickFalse) (void) LogMagickEvent(TraceEvent,GetMagickModule(),"%s",image->filename); assert(exception != (ExceptionInfo ) NULL); assert(exception->signature == MagickCoreSignature); if ((image->columns == 0) \|\| (image->rows == 0)) { (void) ThrowMagickException(exception,GetMagickModule(),CorruptImageError, "NegativeOrZeroImageSize","`%s'",image->filename); return((Image ) NULL); } clone_image=(Image ) AcquireCriticalMemory(sizeof(clone_image)); (void) memset(clone_image,0,sizeof(clone_image)); clone_image->signature=MagickCoreSignature; clone_image->storage_class=image->storage_class; clone_image->number_channels=image->number_channels; clone_image->number_meta_channels=image->number_meta_channels; clone_image->metacontent_extent=image->metacontent_extent; clone_image->colorspace=image->colorspace; clone_image->alpha_trait=image->alpha_trait; clone_image->channels=image->channels; clone_image->mask_trait=image->mask_trait; clone_image->columns=image->columns; clone_image->rows=image->rows; clone_image->dither=image->dither; clone_image->image_info=CloneImageInfo(image->image_info); (void) CloneImageProfiles(clone_image,image); (void) CloneImageProperties(clone_image,image); (void) CloneImageArtifacts(clone_image,image); GetTimerInfo(&clone_image->timer); if (image->ascii85 != (void ) NULL) Ascii85Initialize(clone_image); clone_image->extent=image->extent; clone_image->magick_columns=image->magick_columns; clone_image->magick_rows=image->magick_rows; clone_image->type=image->type; clone_image->channel_mask=image->channel_mask; clone_image->channel_map=ClonePixelChannelMap(image->channel_map); (void) CopyMagickString(clone_image->magick_filename,image->magick_filename, MagickPathExtent); (void) CopyMagickString(clone_image->magick,image->magick,MagickPathExtent); (void) CopyMagickString(clone_image->filename,image->filename, MagickPathExtent); clone_image->progress_monitor=image->progress_monitor; clone_image->client_data=image->client_data; clone_image->reference_count=1; clone_image->next=image->next; clone_image->previous=image->previous; clone_image->list=NewImageList(); if (detach == MagickFalse) clone_image->blob=ReferenceBlob(image->blob); else { clone_image->next=NewImageList(); clone_image->previous=NewImageList(); clone_image->blob=CloneBlobInfo((BlobInfo ) NULL); } clone_image->ping=image->ping; clone_image->debug=IsEventLogging(); clone_image->semaphore=AcquireSemaphoreInfo(); if (image->colormap != (PixelInfo ) NULL) { /* Allocate and copy the image colormap. / clone_image->colors=image->colors; length=(size_t) image->colors; clone_image->colormap=(PixelInfo ) AcquireQuantumMemory(length+1, sizeof(clone_image->colormap)); if (clone_image->colormap == (PixelInfo ) NULL) { clone_image=DestroyImage(clone_image); ThrowImageException(ResourceLimitError,"MemoryAllocationFailed"); } (void) memcpy(clone_image->colormap,image->colormap,length* sizeof(clone_image->colormap)); } if ((columns == 0) \|\| (rows == 0)) { if (image->montage != (char ) NULL) (void) CloneString(&clone_image->montage,image->montage); if (image->directory != (char ) NULL) (void) CloneString(&clone_image->directory,image->directory); clone_image->cache=ReferencePixelCache(image->cache); return(clone_image); } scale=1.0; if (image->columns != 0) scale=(double) columns/(double) image->columns; clone_image->page.width=(size_t) floor(scaleimage->page.width+0.5); clone_image->page.x=(ssize_t) ceil(scaleimage->page.x-0.5); clone_image->tile_offset.x=(ssize_t) ceil(scaleimage->tile_offset.x-0.5); scale=1.0; if (image->rows != 0) scale=(double) rows/(double) image->rows; clone_image->page.height=(size_t) floor(scaleimage->page.height+0.5); clone_image->page.y=(ssize_t) ceil(scaleimage->page.y-0.5); clone_image->tile_offset.y=(ssize_t) ceil(scaleimage->tile_offset.y-0.5); clone_image->cache=ClonePixelCache(image->cache); if (SetImageExtent(clone_image,columns,rows,exception) == MagickFalse) clone_image=DestroyImage(clone_image); return(clone_image); } / %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % C l o n e I m a g e I n f o % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % CloneImageInfo() makes a copy of the given image info structure. If % NULL is specified, a new image info structure is created initialized to % default values. % % The format of the CloneImageInfo method is: % % ImageInfo CloneImageInfo(const ImageInfo image_info) % % A description of each parameter follows: % % o image_info: the image info. % / MagickExport ImageInfo CloneImageInfo(const ImageInfo image_info) { ImageInfo clone_info; clone_info=AcquireImageInfo(); if (image_info == (ImageInfo ) NULL) return(clone_info); clone_info->compression=image_info->compression; clone_info->temporary=image_info->temporary; clone_info->adjoin=image_info->adjoin; clone_info->antialias=image_info->antialias; clone_info->scene=image_info->scene; clone_info->number_scenes=image_info->number_scenes; clone_info->depth=image_info->depth; if (image_info->size != (char ) NULL) (void) CloneString(&clone_info->size,image_info->size); if (image_info->extract != (char ) NULL) (void) CloneString(&clone_info->extract,image_info->extract); if (image_info->scenes != (char ) NULL) (void) CloneString(&clone_info->scenes,image_info->scenes); if (image_info->page != (char ) NULL) (void) CloneString(&clone_info->page,image_info->page); clone_info->interlace=image_info->interlace; clone_info->endian=image_info->endian; clone_info->units=image_info->units; clone_info->quality=image_info->quality; if (image_info->sampling_factor != (char ) NULL) (void) CloneString(&clone_info->sampling_factor, image_info->sampling_factor); if (image_info->server_name != (char ) NULL) (void) CloneString(&clone_info->server_name,image_info->server_name); if (image_info->font != (char ) NULL) (void) CloneString(&clone_info->font,image_info->font); if (image_info->texture != (char ) NULL) (void) CloneString(&clone_info->texture,image_info->texture); if (image_info->density != (char ) NULL) (void) CloneString(&clone_info->density,image_info->density); clone_info->pointsize=image_info->pointsize; clone_info->fuzz=image_info->fuzz; clone_info->matte_color=image_info->matte_color; clone_info->background_color=image_info->background_color; clone_info->border_color=image_info->border_color; clone_info->transparent_color=image_info->transparent_color; clone_info->dither=image_info->dither; clone_info->monochrome=image_info->monochrome; clone_info->colorspace=image_info->colorspace; clone_info->type=image_info->type; clone_info->orientation=image_info->orientation; clone_info->ping=image_info->ping; clone_info->verbose=image_info->verbose; clone_info->progress_monitor=image_info->progress_monitor; clone_info->client_data=image_info->client_data; clone_info->cache=image_info->cache; if (image_info->cache != (void ) NULL) clone_info->cache=ReferencePixelCache(image_info->cache); if (image_info->profile != (void ) NULL) clone_info->profile=(void ) CloneStringInfo((StringInfo ) image_info->profile); SetImageInfoFile(clone_info,image_info->file); SetImageInfoBlob(clone_info,image_info->blob,image_info->length); clone_info->stream=image_info->stream; clone_info->custom_stream=image_info->custom_stream; (void) CopyMagickString(clone_info->magick,image_info->magick, MagickPathExtent); (void) CopyMagickString(clone_info->unique,image_info->unique, MagickPathExtent); (void) CopyMagickString(clone_info->filename,image_info->filename, MagickPathExtent); clone_info->channel=image_info->channel; (void) CloneImageOptions(clone_info,image_info); clone_info->debug=IsEventLogging(); clone_info->signature=image_info->signature; return(clone_info); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % C o p y I m a g e P i x e l s % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % CopyImagePixels() copies pixels from the source image as defined by the % geometry the destination image at the specified offset. % % The format of the CopyImagePixels method is: % % MagickBooleanType CopyImagePixels(Image image,const Image source_image, % const RectangleInfo geometry,const OffsetInfo offset, % ExceptionInfo exception); % % A description of each parameter follows: % % o image: the destination image. % % o source_image: the source image. % % o geometry: define the dimensions of the source pixel rectangle. % % o offset: define the offset in the destination image. % % o exception: return any errors or warnings in this structure. % / MagickExport MagickBooleanType CopyImagePixels(Image image, const Image source_image,const RectangleInfo geometry, const OffsetInfo offset,ExceptionInfo exception) { #define CopyImageTag "Copy/Image" CacheView image_view, source_view; MagickBooleanType status; MagickOffsetType progress; ssize_t y; assert(image != (Image ) NULL); if (image->debug != MagickFalse) (void) LogMagickEvent(TraceEvent,GetMagickModule(),"..."); assert(source_image != (Image ) NULL); assert(geometry != (RectangleInfo ) NULL); assert(offset != (OffsetInfo ) NULL); if ((offset->x < 0) \|\| (offset->y < 0) \|\| ((ssize_t) (offset->x+geometry->width) > (ssize_t) image->columns) \|\| ((ssize_t) (offset->y+geometry->height) > (ssize_t) image->rows)) ThrowBinaryException(OptionError,"GeometryDoesNotContainImage", image->filename); if (SetImageStorageClass(image,DirectClass,exception) == MagickFalse) return(MagickFalse); / Copy image pixels. / status=MagickTrue; progress=0; source_view=AcquireVirtualCacheView(source_image,exception); image_view=AcquireAuthenticCacheView(image,exception); #if defined(MAGICKCORE_OPENMP_SUPPORT) #pragma omp parallel for schedule(static) shared(progress,status) \ magick_number_threads(image,source_image,geometry->height,1) #endif for (y=0; y < (ssize_t) geometry->height; y++) { MagickBooleanType sync; register const Quantum magick_restrict p; register ssize_t x; register Quantum magick_restrict q; if (status == MagickFalse) continue; p=GetCacheViewVirtualPixels(source_view,geometry->x,y+geometry->y, geometry->width,1,exception); q=QueueCacheViewAuthenticPixels(image_view,offset->x,y+offset->y, geometry->width,1,exception); if ((p == (const Quantum ) NULL) \|\| (q == (Quantum ) NULL)) { status=MagickFalse; continue; } for (x=0; x < (ssize_t) geometry->width; x++) { register ssize_t i; for (i=0; i < (ssize_t) GetPixelChannels(image); i++) { PixelChannel channel = GetPixelChannelChannel(image,i); PixelTrait traits = GetPixelChannelTraits(image,channel); PixelTrait source_traits=GetPixelChannelTraits(source_image,channel); if ((traits == UndefinedPixelTrait) \|\| ((traits & UpdatePixelTrait) == 0) \|\| (source_traits == UndefinedPixelTrait)) continue; SetPixelChannel(image,channel,p[i],q); } p+=GetPixelChannels(source_image); q+=GetPixelChannels(image); } sync=SyncCacheViewAuthenticPixels(image_view,exception); if (sync == MagickFalse) status=MagickFalse; if (image->progress_monitor != (MagickProgressMonitor) NULL) { MagickBooleanType proceed; #if defined(MAGICKCORE_OPENMP_SUPPORT) #pragma omp atomic #endif progress++; proceed=SetImageProgress(image,CopyImageTag,progress,image->rows); if (proceed == MagickFalse) status=MagickFalse; } } source_view=DestroyCacheView(source_view); image_view=DestroyCacheView(image_view); return(status); } / %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % D e s t r o y I m a g e % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % DestroyImage() dereferences an image, deallocating memory associated with % the image if the reference count becomes zero. % % The format of the DestroyImage method is: % % Image DestroyImage(Image image) % % A description of each parameter follows: % % o image: the image. % / MagickExport Image DestroyImage(Image image) { MagickBooleanType destroy; / Dereference image. / assert(image != (Image ) NULL); assert(image->signature == MagickCoreSignature); if (image->debug != MagickFalse) (void) LogMagickEvent(TraceEvent,GetMagickModule(),"%s",image->filename); destroy=MagickFalse; LockSemaphoreInfo(image->semaphore); image->reference_count--; if (image->reference_count == 0) destroy=MagickTrue; UnlockSemaphoreInfo(image->semaphore); if (destroy == MagickFalse) return((Image ) NULL); / Destroy image. / DestroyImagePixels(image); image->channel_map=DestroyPixelChannelMap(image->channel_map); if (image->montage != (char ) NULL) image->montage=DestroyString(image->montage); if (image->directory != (char ) NULL) image->directory=DestroyString(image->directory); if (image->colormap != (PixelInfo ) NULL) image->colormap=(PixelInfo ) RelinquishMagickMemory(image->colormap); if (image->geometry != (char ) NULL) image->geometry=DestroyString(image->geometry); DestroyImageProfiles(image); DestroyImageProperties(image); DestroyImageArtifacts(image); if (image->ascii85 != (Ascii85Info ) NULL) image->ascii85=(Ascii85Info ) RelinquishMagickMemory(image->ascii85); if (image->image_info != (ImageInfo ) NULL) image->image_info=DestroyImageInfo(image->image_info); DestroyBlob(image); if (image->semaphore != (SemaphoreInfo ) NULL) RelinquishSemaphoreInfo(&image->semaphore); image->signature=(~MagickCoreSignature); image=(Image ) RelinquishMagickMemory(image); return(image); } / %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % D e s t r o y I m a g e I n f o % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % DestroyImageInfo() deallocates memory associated with an ImageInfo % structure. % % The format of the DestroyImageInfo method is: % % ImageInfo DestroyImageInfo(ImageInfo image_info) % % A description of each parameter follows: % % o image_info: the image info. % / MagickExport ImageInfo DestroyImageInfo(ImageInfo image_info) { assert(image_info != (ImageInfo ) NULL); assert(image_info->signature == MagickCoreSignature); if (image_info->debug != MagickFalse) (void) LogMagickEvent(TraceEvent,GetMagickModule(),"%s", image_info->filename); if (image_info->size != (char ) NULL) image_info->size=DestroyString(image_info->size); if (image_info->extract != (char ) NULL) image_info->extract=DestroyString(image_info->extract); if (image_info->scenes != (char ) NULL) image_info->scenes=DestroyString(image_info->scenes); if (image_info->page != (char ) NULL) image_info->page=DestroyString(image_info->page); if (image_info->sampling_factor != (char ) NULL) image_info->sampling_factor=DestroyString( image_info->sampling_factor); if (image_info->server_name != (char ) NULL) image_info->server_name=DestroyString( image_info->server_name); if (image_info->font != (char ) NULL) image_info->font=DestroyString(image_info->font); if (image_info->texture != (char ) NULL) image_info->texture=DestroyString(image_info->texture); if (image_info->density != (char ) NULL) image_info->density=DestroyString(image_info->density); if (image_info->cache != (void ) NULL) image_info->cache=DestroyPixelCache(image_info->cache); if (image_info->profile != (StringInfo ) NULL) image_info->profile=(void ) DestroyStringInfo((StringInfo ) image_info->profile); DestroyImageOptions(image_info); image_info->signature=(~MagickCoreSignature); image_info=(ImageInfo ) RelinquishMagickMemory(image_info); return(image_info); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % + D i s a s s o c i a t e I m a g e S t r e a m % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % DisassociateImageStream() disassociates the image stream. It checks if the % blob of the specified image is referenced by other images. If the reference % count is higher then 1 a new blob is assigned to the specified image. % % The format of the DisassociateImageStream method is: % % void DisassociateImageStream(const Image image) % % A description of each parameter follows: % % o image: the image. % / MagickExport void DisassociateImageStream(Image image) { assert(image != (Image ) NULL); assert(image->signature == MagickCoreSignature); if (image->debug != MagickFalse) (void) LogMagickEvent(TraceEvent,GetMagickModule(),"%s",image->filename); DisassociateBlob(image); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % G e t I m a g e I n f o % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % GetImageInfo() initializes image_info to default values. % % The format of the GetImageInfo method is: % % void GetImageInfo(ImageInfo image_info) % % A description of each parameter follows: % % o image_info: the image info. % / MagickExport void GetImageInfo(ImageInfo image_info) { char synchronize; ExceptionInfo exception; / File and image dimension members. / (void) LogMagickEvent(TraceEvent,GetMagickModule(),"..."); assert(image_info != (ImageInfo ) NULL); (void) memset(image_info,0,sizeof(image_info)); image_info->adjoin=MagickTrue; image_info->interlace=NoInterlace; image_info->channel=DefaultChannels; image_info->quality=UndefinedCompressionQuality; image_info->antialias=MagickTrue; image_info->dither=MagickTrue; synchronize=GetEnvironmentValue("MAGICK_SYNCHRONIZE"); if (synchronize != (const char ) NULL) { image_info->synchronize=IsStringTrue(synchronize); synchronize=DestroyString(synchronize); } exception=AcquireExceptionInfo(); (void) QueryColorCompliance(BackgroundColor,AllCompliance, &image_info->background_color,exception); (void) QueryColorCompliance(BorderColor,AllCompliance, &image_info->border_color,exception); (void) QueryColorCompliance(MatteColor,AllCompliance,&image_info->matte_color, exception); (void) QueryColorCompliance(TransparentColor,AllCompliance, &image_info->transparent_color,exception); exception=DestroyExceptionInfo(exception); image_info->debug=IsEventLogging(); image_info->signature=MagickCoreSignature; } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % G e t I m a g e I n f o F i l e % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % GetImageInfoFile() returns the image info file member. % % The format of the GetImageInfoFile method is: % % FILE GetImageInfoFile(const ImageInfo image_info) % % A description of each parameter follows: % % o image_info: the image info. % / MagickExport FILE GetImageInfoFile(const ImageInfo image_info) { return(image_info->file); } / %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % G e t I m a g e M a s k % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % GetImageMask() returns the mask associated with the image. % % The format of the GetImageMask method is: % % Image GetImageMask(const Image image,const PixelMask type, % ExceptionInfo exception) % % A description of each parameter follows: % % o image: the image. % % o type: the mask type, ReadPixelMask or WritePixelMask. % / MagickExport Image GetImageMask(const Image image,const PixelMask type, ExceptionInfo exception) { CacheView mask_view, image_view; Image mask_image; MagickBooleanType status; ssize_t y; /* Get image mask. / assert(image != (Image ) NULL); if (image->debug != MagickFalse) (void) LogMagickEvent(TraceEvent,GetMagickModule(),"..."); assert(image->signature == MagickCoreSignature); switch (type) { case ReadPixelMask: { if ((image->channels & ReadMaskChannel) == 0) return((Image ) NULL); break; } case WritePixelMask: { if ((image->channels & WriteMaskChannel) == 0) return((Image ) NULL); break; } default: { if ((image->channels & CompositeMaskChannel) == 0) return((Image ) NULL); break; } } mask_image=AcquireImage((ImageInfo ) NULL,exception); status=SetImageExtent(mask_image,image->columns,image->rows,exception); if (status == MagickFalse) return(DestroyImage(mask_image)); status=MagickTrue; mask_image->alpha_trait=UndefinedPixelTrait; (void) SetImageColorspace(mask_image,GRAYColorspace,exception); image_view=AcquireVirtualCacheView(image,exception); mask_view=AcquireAuthenticCacheView(mask_image,exception); for (y=0; y < (ssize_t) image->rows; y++) { register const Quantum magick_restrict p; register Quantum magick_restrict q; register ssize_t x; if (status == MagickFalse) continue; p=GetCacheViewVirtualPixels(image_view,0,y,image->columns,1,exception); q=GetCacheViewAuthenticPixels(mask_view,0,y,mask_image->columns,1, exception); if ((p == (const Quantum ) NULL) \|\| (q == (Quantum ) NULL)) { status=MagickFalse; continue; } for (x=0; x < (ssize_t) image->columns; x++) { switch (type) { case ReadPixelMask: { SetPixelGray(mask_image,GetPixelReadMask(image,p),q); break; } case WritePixelMask: { SetPixelGray(mask_image,GetPixelWriteMask(image,p),q); break; } default: { SetPixelGray(mask_image,GetPixelCompositeMask(image,p),q); break; } } p+=GetPixelChannels(image); q+=GetPixelChannels(mask_image); } if (SyncCacheViewAuthenticPixels(mask_view,exception) == MagickFalse) status=MagickFalse; } mask_view=DestroyCacheView(mask_view); image_view=DestroyCacheView(image_view); if (status == MagickFalse) mask_image=DestroyImage(mask_image); return(mask_image); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % + G e t I m a g e R e f e r e n c e C o u n t % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % GetImageReferenceCount() returns the image reference count. % % The format of the GetReferenceCount method is: % % ssize_t GetImageReferenceCount(Image image) % % A description of each parameter follows: % % o image: the image. % / MagickExport ssize_t GetImageReferenceCount(Image image) { ssize_t reference_count; assert(image != (Image ) NULL); assert(image->signature == MagickCoreSignature); if (image->debug != MagickFalse) (void) LogMagickEvent(TraceEvent,GetMagickModule(),"%s",image->filename); LockSemaphoreInfo(image->semaphore); reference_count=image->reference_count; UnlockSemaphoreInfo(image->semaphore); return(reference_count); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % G e t I m a g e V i r t u a l P i x e l M e t h o d % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % GetImageVirtualPixelMethod() gets the "virtual pixels" method for the % image. A virtual pixel is any pixel access that is outside the boundaries % of the image cache. % % The format of the GetImageVirtualPixelMethod() method is: % % VirtualPixelMethod GetImageVirtualPixelMethod(const Image image) % % A description of each parameter follows: % % o image: the image. % / MagickExport VirtualPixelMethod GetImageVirtualPixelMethod(const Image image) { assert(image != (Image ) NULL); assert(image->signature == MagickCoreSignature); if (image->debug != MagickFalse) (void) LogMagickEvent(TraceEvent,GetMagickModule(),"%s",image->filename); return(GetPixelCacheVirtualMethod(image)); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % I n t e r p r e t I m a g e F i l e n a m e % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % InterpretImageFilename() interprets embedded characters in an image filename. % The filename length is returned. % % The format of the InterpretImageFilename method is: % % size_t InterpretImageFilename(const ImageInfo image_info,Image image, % const char format,int value,char filename,ExceptionInfo exception) % % A description of each parameter follows. % % o image_info: the image info.. % % o image: the image. % % o format: A filename describing the format to use to write the numeric % argument. Only the first numeric format identifier is replaced. % % o value: Numeric value to substitute into format filename. % % o filename: return the formatted filename in this character buffer. % % o exception: return any errors or warnings in this structure. % / MagickExport size_t InterpretImageFilename(const ImageInfo image_info, Image image,const char format,int value,char filename, ExceptionInfo exception) { char q; int c; MagickBooleanType canonical; register const char p; ssize_t field_width, offset; canonical=MagickFalse; offset=0; (void) CopyMagickString(filename,format,MagickPathExtent); for (p=strchr(format,'%'); p != (char ) NULL; p=strchr(p+1,'%')) { q=(char ) p+1; if (q == '%') { p=q+1; continue; } field_width=0; if (q == '0') field_width=(ssize_t) strtol(q,&q,10); switch (q) { case 'd': case 'o': case 'x': { q++; c=(q); q='\0'; (void) FormatLocaleString(filename+(p-format-offset),(size_t) (MagickPathExtent-(p-format-offset)),p,value); offset+=(4-field_width); q=c; (void) ConcatenateMagickString(filename,q,MagickPathExtent); canonical=MagickTrue; if ((q-1) != '%') break; p++; break; } case '[': { char pattern[MagickPathExtent]; const char option; register char r; register ssize_t i; ssize_t depth; /* Image option. / if (strchr(p,']') == (char ) NULL) break; depth=1; r=q+1; for (i=0; (i < (MagickPathExtent-1L)) && (r != '\0'); i++) { if (r == '[') depth++; if (r == ']') depth--; if (depth <= 0) break; pattern[i]=(r++); } pattern[i]='\0'; if (LocaleNCompare(pattern,"filename:",9) != 0) break; option=(const char ) NULL; if (image != (Image ) NULL) option=GetImageProperty(image,pattern,exception); if ((option == (const char ) NULL) && (image != (Image ) NULL)) option=GetImageArtifact(image,pattern); if ((option == (const char ) NULL) && (image_info != (ImageInfo ) NULL)) option=GetImageOption(image_info,pattern); if (option == (const char ) NULL) break; q--; c=(q); q='\0'; (void) CopyMagickString(filename+(p-format-offset),option,(size_t) (MagickPathExtent-(p-format-offset))); offset+=strlen(pattern)-strlen(option)+3; q=c; (void) ConcatenateMagickString(filename,r+1,MagickPathExtent); canonical=MagickTrue; if ((q-1) != '%') break; p++; break; } default: break; } } if (canonical == MagickFalse) (void) CopyMagickString(filename,format,MagickPathExtent); else for (q=filename; q != '\0'; q++) if ((q == '%') && ((q+1) == '%')) (void) CopyMagickString(q,q+1,(size_t) (MagickPathExtent-(q-filename))); return(strlen(filename)); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % I s H i g h D y n a m i c R a n g e I m a g e % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % IsHighDynamicRangeImage() returns MagickTrue if any pixel component is % non-integer or exceeds the bounds of the quantum depth (e.g. for Q16 % 0..65535. % % The format of the IsHighDynamicRangeImage method is: % % MagickBooleanType IsHighDynamicRangeImage(const Image image, % ExceptionInfo exception) % % A description of each parameter follows: % % o image: the image. % % o exception: return any errors or warnings in this structure. % / MagickExport MagickBooleanType IsHighDynamicRangeImage(const Image image, ExceptionInfo exception) { #if !defined(MAGICKCORE_HDRI_SUPPORT) (void) image; (void) exception; return(MagickFalse); #else CacheView image_view; MagickBooleanType status; ssize_t y; assert(image != (Image ) NULL); assert(image->signature == MagickCoreSignature); if (image->debug != MagickFalse) (void) LogMagickEvent(TraceEvent,GetMagickModule(),"%s",image->filename); status=MagickTrue; image_view=AcquireVirtualCacheView(image,exception); #if defined(MAGICKCORE_OPENMP_SUPPORT) #pragma omp parallel for schedule(static) shared(status) \ magick_number_threads(image,image,image->rows,1) #endif for (y=0; y < (ssize_t) image->rows; y++) { register const Quantum p; register ssize_t x; if (status == MagickFalse) continue; p=GetCacheViewVirtualPixels(image_view,0,y,image->columns,1,exception); if (p == (const Quantum ) NULL) { status=MagickFalse; continue; } for (x=0; x < (ssize_t) image->columns; x++) { register ssize_t i; for (i=0; i < (ssize_t) GetPixelChannels(image); i++) { double pixel; PixelTrait traits; traits=GetPixelChannelTraits(image,(PixelChannel) i); if (traits == UndefinedPixelTrait) continue; pixel=(double) p[i]; if ((pixel < 0.0) \|\| (pixel > QuantumRange) \|\| (pixel != (double) ((QuantumAny) pixel))) break; } p+=GetPixelChannels(image); if (i < (ssize_t) GetPixelChannels(image)) status=MagickFalse; } if (x < (ssize_t) image->columns) status=MagickFalse; } image_view=DestroyCacheView(image_view); return(status != MagickFalse ? MagickFalse : MagickTrue); #endif } / %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % I s I m a g e O b j e c t % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % IsImageObject() returns MagickTrue if the image sequence contains a valid % set of image objects. % % The format of the IsImageObject method is: % % MagickBooleanType IsImageObject(const Image image) % % A description of each parameter follows: % % o image: the image. % / MagickExport MagickBooleanType IsImageObject(const Image image) { register const Image p; assert(image != (Image ) NULL); if (image->debug != MagickFalse) (void) LogMagickEvent(TraceEvent,GetMagickModule(),"..."); for (p=image; p != (Image ) NULL; p=GetNextImageInList(p)) if (p->signature != MagickCoreSignature) return(MagickFalse); return(MagickTrue); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % I s T a i n t I m a g e % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % IsTaintImage() returns MagickTrue any pixel in the image has been altered % since it was first constituted. % % The format of the IsTaintImage method is: % % MagickBooleanType IsTaintImage(const Image image) % % A description of each parameter follows: % % o image: the image. % / MagickExport MagickBooleanType IsTaintImage(const Image image) { char magick[MagickPathExtent], filename[MagickPathExtent]; register const Image p; assert(image != (Image ) NULL); if (image->debug != MagickFalse) (void) LogMagickEvent(TraceEvent,GetMagickModule(),"..."); assert(image->signature == MagickCoreSignature); (void) CopyMagickString(magick,image->magick,MagickPathExtent); (void) CopyMagickString(filename,image->filename,MagickPathExtent); for (p=image; p != (Image ) NULL; p=GetNextImageInList(p)) { if (p->taint != MagickFalse) return(MagickTrue); if (LocaleCompare(p->magick,magick) != 0) return(MagickTrue); if (LocaleCompare(p->filename,filename) != 0) return(MagickTrue); } return(MagickFalse); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % M o d i f y I m a g e % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % ModifyImage() ensures that there is only a single reference to the image % to be modified, updating the provided image pointer to point to a clone of % the original image if necessary. % % The format of the ModifyImage method is: % % MagickBooleanType ModifyImage(Image image,ExceptionInfo exception) % % A description of each parameter follows: % % o image: the image. % % o exception: return any errors or warnings in this structure. % / MagickExport MagickBooleanType ModifyImage(Image image, ExceptionInfo exception) { Image clone_image; assert(image != (Image ) NULL); assert(image != (Image ) NULL); assert((image)->signature == MagickCoreSignature); if ((image)->debug != MagickFalse) (void) LogMagickEvent(TraceEvent,GetMagickModule(),"%s",(image)->filename); if (GetImageReferenceCount(image) <= 1) return(MagickTrue); clone_image=CloneImage(image,0,0,MagickTrue,exception); LockSemaphoreInfo((image)->semaphore); (image)->reference_count--; UnlockSemaphoreInfo((image)->semaphore); image=clone_image; return(MagickTrue); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % N e w M a g i c k I m a g e % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % NewMagickImage() creates a blank image canvas of the specified size and % background color. % % The format of the NewMagickImage method is: % % Image NewMagickImage(const ImageInfo image_info,const size_t width, % const size_t height,const PixelInfo background, % ExceptionInfo exception) % % A description of each parameter follows: % % o image: the image. % % o width: the image width. % % o height: the image height. % % o background: the image color. % % o exception: return any errors or warnings in this structure. % / MagickExport Image NewMagickImage(const ImageInfo image_info, const size_t width,const size_t height,const PixelInfo background, ExceptionInfo exception) { CacheView image_view; Image image; MagickBooleanType status; ssize_t y; assert(image_info != (const ImageInfo ) NULL); if (image_info->debug != MagickFalse) (void) LogMagickEvent(TraceEvent,GetMagickModule(),"..."); assert(image_info->signature == MagickCoreSignature); assert(background != (const PixelInfo ) NULL); image=AcquireImage(image_info,exception); image->columns=width; image->rows=height; image->colorspace=background->colorspace; image->alpha_trait=background->alpha_trait; image->fuzz=background->fuzz; image->depth=background->depth; status=MagickTrue; image_view=AcquireAuthenticCacheView(image,exception); #if defined(MAGICKCORE_OPENMP_SUPPORT) #pragma omp parallel for schedule(static) shared(status) \ magick_number_threads(image,image,image->rows,1) #endif for (y=0; y < (ssize_t) image->rows; y++) { register Quantum magick_restrict q; register ssize_t x; if (status == MagickFalse) continue; q=QueueCacheViewAuthenticPixels(image_view,0,y,image->columns,1,exception); if (q == (Quantum ) NULL) { status=MagickFalse; continue; } for (x=0; x < (ssize_t) image->columns; x++) { SetPixelViaPixelInfo(image,background,q); q+=GetPixelChannels(image); } if (SyncCacheViewAuthenticPixels(image_view,exception) == MagickFalse) status=MagickFalse; } image_view=DestroyCacheView(image_view); if (status == MagickFalse) image=DestroyImage(image); return(image); } / %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % R e f e r e n c e I m a g e % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % ReferenceImage() increments the reference count associated with an image % returning a pointer to the image. % % The format of the ReferenceImage method is: % % Image ReferenceImage(Image image) % % A description of each parameter follows: % % o image: the image. % / MagickExport Image ReferenceImage(Image image) { assert(image != (Image ) NULL); if (image->debug != MagickFalse) (void) LogMagickEvent(TraceEvent,GetMagickModule(),"..."); assert(image->signature == MagickCoreSignature); LockSemaphoreInfo(image->semaphore); image->reference_count++; UnlockSemaphoreInfo(image->semaphore); return(image); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % R e s e t I m a g e P a g e % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % ResetImagePage() resets the image page canvas and position. % % The format of the ResetImagePage method is: % % MagickBooleanType ResetImagePage(Image image,const char page) % % A description of each parameter follows: % % o image: the image. % % o page: the relative page specification. % / MagickExport MagickBooleanType ResetImagePage(Image image,const char page) { MagickStatusType flags; RectangleInfo geometry; assert(image != (Image ) NULL); assert(image->signature == MagickCoreSignature); if (image->debug != MagickFalse) (void) LogMagickEvent(TraceEvent,GetMagickModule(),"%s",image->filename); flags=ParseAbsoluteGeometry(page,&geometry); if ((flags & WidthValue) != 0) { if ((flags & HeightValue) == 0) geometry.height=geometry.width; image->page.width=geometry.width; image->page.height=geometry.height; } if ((flags & AspectValue) != 0) { if ((flags & XValue) != 0) image->page.x+=geometry.x; if ((flags & YValue) != 0) image->page.y+=geometry.y; } else { if ((flags & XValue) != 0) { image->page.x=geometry.x; if ((image->page.width == 0) && (geometry.x > 0)) image->page.width=image->columns+geometry.x; } if ((flags & YValue) != 0) { image->page.y=geometry.y; if ((image->page.height == 0) && (geometry.y > 0)) image->page.height=image->rows+geometry.y; } } return(MagickTrue); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % R e s e t I m a g e P i x e l s % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % ResetImagePixels() reset the image pixels, that is, all the pixel components % are zereod. % % The format of the SetImage method is: % % MagickBooleanType ResetImagePixels(Image image, % ExceptionInfo exception) % % A description of each parameter follows: % % o image: the image. % % o exception: return any errors or warnings in this structure. % / MagickExport MagickBooleanType ResetImagePixels(Image image, ExceptionInfo exception) { CacheView image_view; MagickBooleanType status; size_t length; ssize_t y; void pixels; assert(image != (Image ) NULL); if (image->debug != MagickFalse) (void) LogMagickEvent(TraceEvent,GetMagickModule(),"..."); assert(image->signature == MagickCoreSignature); pixels=AcquirePixelCachePixels(image,&length,exception); if (pixels != (void ) NULL) { / Reset in-core image pixels. / (void) memset(pixels,0,length); return(MagickTrue); } / Reset image pixels. / status=MagickTrue; image_view=AcquireAuthenticCacheView(image,exception); #if defined(MAGICKCORE_OPENMP_SUPPORT) #pragma omp parallel for schedule(static) shared(status) \ magick_number_threads(image,image,image->rows,1) #endif for (y=0; y < (ssize_t) image->rows; y++) { register Quantum magick_restrict q; register ssize_t x; if (status == MagickFalse) continue; q=QueueCacheViewAuthenticPixels(image_view,0,y,image->columns,1,exception); if (q == (Quantum ) NULL) { status=MagickFalse; continue; } for (x=0; x < (ssize_t) image->columns; x++) { (void) memset(q,0,GetPixelChannels(image)sizeof(Quantum)); q+=GetPixelChannels(image); } if (SyncCacheViewAuthenticPixels(image_view,exception) == MagickFalse) status=MagickFalse; } image_view=DestroyCacheView(image_view); return(status); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % S e t I m a g e A l p h a % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % SetImageAlpha() sets the alpha levels of the image. % % The format of the SetImageAlpha method is: % % MagickBooleanType SetImageAlpha(Image image,const Quantum alpha, % ExceptionInfo exception) % % A description of each parameter follows: % % o image: the image. % % o alpha: the level of transparency: 0 is fully transparent and QuantumRange % is fully opaque. % % o exception: return any errors or warnings in this structure. % / MagickExport MagickBooleanType SetImageAlpha(Image image,const Quantum alpha, ExceptionInfo exception) { CacheView image_view; MagickBooleanType status; ssize_t y; assert(image != (Image ) NULL); if (image->debug != MagickFalse) (void) LogMagickEvent(TraceEvent,GetMagickModule(),"..."); assert(image->signature == MagickCoreSignature); image->alpha_trait=BlendPixelTrait; status=MagickTrue; image_view=AcquireAuthenticCacheView(image,exception); #if defined(MAGICKCORE_OPENMP_SUPPORT) #pragma omp parallel for schedule(static) shared(status) \ magick_number_threads(image,image,image->rows,1) #endif for (y=0; y < (ssize_t) image->rows; y++) { register Quantum magick_restrict q; register ssize_t x; if (status == MagickFalse) continue; q=GetCacheViewAuthenticPixels(image_view,0,y,image->columns,1,exception); if (q == (Quantum ) NULL) { status=MagickFalse; continue; } for (x=0; x < (ssize_t) image->columns; x++) { SetPixelAlpha(image,alpha,q); q+=GetPixelChannels(image); } if (SyncCacheViewAuthenticPixels(image_view,exception) == MagickFalse) status=MagickFalse; } image_view=DestroyCacheView(image_view); return(status); } / %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % S e t I m a g e B a c k g r o u n d C o l o r % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % SetImageBackgroundColor() initializes the image pixels to the image % background color. The background color is defined by the background_color % member of the image structure. % % The format of the SetImage method is: % % MagickBooleanType SetImageBackgroundColor(Image image, % ExceptionInfo exception) % % A description of each parameter follows: % % o image: the image. % % o exception: return any errors or warnings in this structure. % / MagickExport MagickBooleanType SetImageBackgroundColor(Image image, ExceptionInfo exception) { CacheView image_view; MagickBooleanType status; PixelInfo background; ssize_t y; assert(image != (Image ) NULL); if (image->debug != MagickFalse) (void) LogMagickEvent(TraceEvent,GetMagickModule(),"..."); assert(image->signature == MagickCoreSignature); if (SetImageStorageClass(image,DirectClass,exception) == MagickFalse) return(MagickFalse); if ((image->background_color.alpha_trait != UndefinedPixelTrait) && (image->alpha_trait == UndefinedPixelTrait)) (void) SetImageAlphaChannel(image,OnAlphaChannel,exception); ConformPixelInfo(image,&image->background_color,&background,exception); / Set image background color. / status=MagickTrue; image_view=AcquireAuthenticCacheView(image,exception); for (y=0; y < (ssize_t) image->rows; y++) { register Quantum magick_restrict q; register ssize_t x; if (status == MagickFalse) continue; q=QueueCacheViewAuthenticPixels(image_view,0,y,image->columns,1,exception); if (q == (Quantum ) NULL) { status=MagickFalse; continue; } for (x=0; x < (ssize_t) image->columns; x++) { SetPixelViaPixelInfo(image,&background,q); q+=GetPixelChannels(image); } if (SyncCacheViewAuthenticPixels(image_view,exception) == MagickFalse) status=MagickFalse; } image_view=DestroyCacheView(image_view); return(status); } / %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % S e t I m a g e C h a n n e l M a s k % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % SetImageChannelMask() sets the image channel mask from the specified channel % mask. % % The format of the SetImageChannelMask method is: % % ChannelType SetImageChannelMask(Image image, % const ChannelType channel_mask) % % A description of each parameter follows: % % o image: the image. % % o channel_mask: the channel mask. % / MagickExport ChannelType SetImageChannelMask(Image image, const ChannelType channel_mask) { return(SetPixelChannelMask(image,channel_mask)); } / %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % S e t I m a g e C o l o r % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % SetImageColor() set the entire image canvas to the specified color. % % The format of the SetImageColor method is: % % MagickBooleanType SetImageColor(Image image,const PixelInfo color, % ExeptionInfo exception) % % A description of each parameter follows: % % o image: the image. % % o background: the image color. % % o exception: return any errors or warnings in this structure. % / MagickExport MagickBooleanType SetImageColor(Image image, const PixelInfo color,ExceptionInfo exception) { CacheView image_view; MagickBooleanType status; ssize_t y; assert(image != (Image ) NULL); if (image->debug != MagickFalse) (void) LogMagickEvent(TraceEvent,GetMagickModule(),"..."); assert(image->signature == MagickCoreSignature); assert(color != (const PixelInfo ) NULL); image->colorspace=color->colorspace; image->alpha_trait=color->alpha_trait; image->fuzz=color->fuzz; image->depth=color->depth; status=MagickTrue; image_view=AcquireAuthenticCacheView(image,exception); #if defined(MAGICKCORE_OPENMP_SUPPORT) #pragma omp parallel for schedule(static) shared(status) \ magick_number_threads(image,image,image->rows,1) #endif for (y=0; y < (ssize_t) image->rows; y++) { register Quantum magick_restrict q; register ssize_t x; if (status == MagickFalse) continue; q=QueueCacheViewAuthenticPixels(image_view,0,y,image->columns,1,exception); if (q == (Quantum ) NULL) { status=MagickFalse; continue; } for (x=0; x < (ssize_t) image->columns; x++) { SetPixelViaPixelInfo(image,color,q); q+=GetPixelChannels(image); } if (SyncCacheViewAuthenticPixels(image_view,exception) == MagickFalse) status=MagickFalse; } image_view=DestroyCacheView(image_view); return(status); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % S e t I m a g e S t o r a g e C l a s s % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % SetImageStorageClass() sets the image class: DirectClass for true color % images or PseudoClass for colormapped images. % % The format of the SetImageStorageClass method is: % % MagickBooleanType SetImageStorageClass(Image image, % const ClassType storage_class,ExceptionInfo exception) % % A description of each parameter follows: % % o image: the image. % % o storage_class: The image class. % % o exception: return any errors or warnings in this structure. % / MagickExport MagickBooleanType SetImageStorageClass(Image image, const ClassType storage_class,ExceptionInfo exception) { assert(image != (Image ) NULL); assert(image->signature == MagickCoreSignature); if (image->debug != MagickFalse) (void) LogMagickEvent(TraceEvent,GetMagickModule(),"%s",image->filename); assert(exception != (ExceptionInfo ) NULL); assert(exception->signature == MagickCoreSignature); image->storage_class=storage_class; return(SyncImagePixelCache(image,exception)); } / %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % S e t I m a g e E x t e n t % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % SetImageExtent() sets the image size (i.e. columns & rows). % % The format of the SetImageExtent method is: % % MagickBooleanType SetImageExtent(Image image,const size_t columns, % const size_t rows,ExceptionInfo exception) % % A description of each parameter follows: % % o image: the image. % % o columns: The image width in pixels. % % o rows: The image height in pixels. % % o exception: return any errors or warnings in this structure. % / MagickExport MagickBooleanType SetImageExtent(Image image,const size_t columns, const size_t rows,ExceptionInfo exception) { if ((columns == 0) \|\| (rows == 0)) ThrowBinaryException(ImageError,"NegativeOrZeroImageSize",image->filename); image->columns=columns; image->rows=rows; if (image->depth == 0) { image->depth=8; (void) ThrowMagickException(exception,GetMagickModule(),ImageError, "ImageDepthNotSupported","`%s'",image->filename); } if (image->depth > (8sizeof(MagickSizeType))) { image->depth=8sizeof(MagickSizeType); (void) ThrowMagickException(exception,GetMagickModule(),ImageError, "ImageDepthNotSupported","`%s'",image->filename); } return(SyncImagePixelCache(image,exception)); } / %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % + S e t I m a g e I n f o % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % SetImageInfo() initializes the 'magick' field of the ImageInfo structure. % It is set to a type of image format based on the prefix or suffix of the % filename. For example, 'ps:image' returns PS indicating a Postscript image. % JPEG is returned for this filename: 'image.jpg'. The filename prefix has % precendence over the suffix. Use an optional index enclosed in brackets % after a file name to specify a desired scene of a multi-resolution image % format like Photo CD (e.g. img0001.pcd[4]). A True (non-zero) return value % indicates success. % % The format of the SetImageInfo method is: % % MagickBooleanType SetImageInfo(ImageInfo image_info, % const unsigned int frames,ExceptionInfo exception) % % A description of each parameter follows: % % o image_info: the image info. % % o frames: the number of images you intend to write. % % o exception: return any errors or warnings in this structure. % / MagickExport MagickBooleanType SetImageInfo(ImageInfo image_info, const unsigned int frames,ExceptionInfo exception) { char component[MagickPathExtent], magic[MagickPathExtent], #if defined(MAGICKCORE_ZLIB_DELEGATE) \|\| defined(MAGICKCORE_BZLIB_DELEGATE) path[MagickPathExtent], #endif q; const MagicInfo magic_info; const MagickInfo magick_info; ExceptionInfo sans_exception; Image image; MagickBooleanType status; register const char p; ssize_t count; / Look for 'image.format' in filename. / assert(image_info != (ImageInfo ) NULL); assert(image_info->signature == MagickCoreSignature); if (image_info->debug != MagickFalse) (void) LogMagickEvent(TraceEvent,GetMagickModule(),"%s", image_info->filename); component='\0'; GetPathComponent(image_info->filename,SubimagePath,component); if (component != '\0') { /* Look for scene specification (e.g. img0001.pcd[4]). / if (IsSceneGeometry(component,MagickFalse) == MagickFalse) { if (IsGeometry(component) != MagickFalse) (void) CloneString(&image_info->extract,component); } else { size_t first, last; (void) CloneString(&image_info->scenes,component); image_info->scene=StringToUnsignedLong(image_info->scenes); image_info->number_scenes=image_info->scene; p=image_info->scenes; for (q=(char ) image_info->scenes; q != '\0'; p++) { while ((isspace((int) ((unsigned char) p)) != 0) \|\| (p == ',')) p++; first=(size_t) strtol(p,&q,10); last=first; while (isspace((int) ((unsigned char) q)) != 0) q++; if (q == '-') last=(size_t) strtol(q+1,&q,10); if (first > last) Swap(first,last); if (first < image_info->scene) image_info->scene=first; if (last > image_info->number_scenes) image_info->number_scenes=last; p=q; } image_info->number_scenes-=image_info->scene-1; } } component='\0'; if (image_info->magick == '\0') GetPathComponent(image_info->filename,ExtensionPath,component); #if defined(MAGICKCORE_ZLIB_DELEGATE) if (component != '\0') if ((LocaleCompare(component,"gz") == 0) \|\| (LocaleCompare(component,"Z") == 0) \|\| (LocaleCompare(component,"svgz") == 0) \|\| (LocaleCompare(component,"wmz") == 0)) { (void) CopyMagickString(path,image_info->filename,MagickPathExtent); path[strlen(path)-strlen(component)-1]='\0'; GetPathComponent(path,ExtensionPath,component); } #endif #if defined(MAGICKCORE_BZLIB_DELEGATE) if (component != '\0') if (LocaleCompare(component,"bz2") == 0) { (void) CopyMagickString(path,image_info->filename,MagickPathExtent); path[strlen(path)-strlen(component)-1]='\0'; GetPathComponent(path,ExtensionPath,component); } #endif image_info->affirm=MagickFalse; sans_exception=AcquireExceptionInfo(); if ((component != '\0') && (IsGlob(component) == MagickFalse)) { MagickFormatType format_type; register ssize_t i; static const char format_type_formats[] = { "AUTOTRACE", "BROWSE", "DCRAW", "EDIT", "LAUNCH", "MPEG:DECODE", "MPEG:ENCODE", "PRINT", "PS:ALPHA", "PS:CMYK", "PS:COLOR", "PS:GRAY", "PS:MONO", "SCAN", "SHOW", "WIN", (char ) NULL }; /* User specified image format. / (void) CopyMagickString(magic,component,MagickPathExtent); LocaleUpper(magic); / Look for explicit image formats. / format_type=UndefinedFormatType; magick_info=GetMagickInfo(magic,sans_exception); if ((magick_info != (const MagickInfo ) NULL) && (magick_info->format_type != UndefinedFormatType)) format_type=magick_info->format_type; i=0; while ((format_type == UndefinedFormatType) && (format_type_formats[i] != (char ) NULL)) { if ((magic == format_type_formats[i]) && (LocaleCompare(magic,format_type_formats[i]) == 0)) format_type=ExplicitFormatType; i++; } if (format_type == UndefinedFormatType) (void) CopyMagickString(image_info->magick,magic,MagickPathExtent); else if (format_type == ExplicitFormatType) { image_info->affirm=MagickTrue; (void) CopyMagickString(image_info->magick,magic,MagickPathExtent); } if (LocaleCompare(magic,"RGB") == 0) image_info->affirm=MagickFalse; / maybe SGI disguised as RGB / } / Look for explicit 'format:image' in filename. / magic='\0'; GetPathComponent(image_info->filename,MagickPath,magic); if (magic == '\0') { (void) CopyMagickString(magic,image_info->magick,MagickPathExtent); magick_info=GetMagickInfo(magic,sans_exception); if (frames == 0) GetPathComponent(image_info->filename,CanonicalPath,component); else GetPathComponent(image_info->filename,SubcanonicalPath,component); (void) CopyMagickString(image_info->filename,component,MagickPathExtent); } else { const DelegateInfo delegate_info; /* User specified image format. / LocaleUpper(magic); magick_info=GetMagickInfo(magic,sans_exception); delegate_info=GetDelegateInfo(magic,"",sans_exception); if (delegate_info == (const DelegateInfo ) NULL) delegate_info=GetDelegateInfo("",magic,sans_exception); if (((magick_info != (const MagickInfo ) NULL) \|\| (delegate_info != (const DelegateInfo ) NULL)) && (IsMagickConflict(magic) == MagickFalse)) { image_info->affirm=MagickTrue; (void) CopyMagickString(image_info->magick,magic,MagickPathExtent); GetPathComponent(image_info->filename,CanonicalPath,component); (void) CopyMagickString(image_info->filename,component, MagickPathExtent); } } sans_exception=DestroyExceptionInfo(sans_exception); if ((magick_info == (const MagickInfo ) NULL) \|\| (GetMagickEndianSupport(magick_info) == MagickFalse)) image_info->endian=UndefinedEndian; if ((image_info->adjoin != MagickFalse) && (frames > 1)) { / Test for multiple image support (e.g. image%02d.png). / (void) InterpretImageFilename(image_info,(Image ) NULL, image_info->filename,(int) image_info->scene,component,exception); if ((LocaleCompare(component,image_info->filename) != 0) && (strchr(component,'%') == (char ) NULL)) image_info->adjoin=MagickFalse; } if ((image_info->adjoin != MagickFalse) && (frames > 0)) { / Some image formats do not support multiple frames per file. / magick_info=GetMagickInfo(magic,exception); if (magick_info != (const MagickInfo ) NULL) if (GetMagickAdjoin(magick_info) == MagickFalse) image_info->adjoin=MagickFalse; } if (image_info->affirm != MagickFalse) return(MagickTrue); if (frames == 0) { unsigned char magick; size_t magick_size; / Determine the image format from the first few bytes of the file. / magick_size=GetMagicPatternExtent(exception); if (magick_size == 0) return(MagickFalse); image=AcquireImage(image_info,exception); (void) CopyMagickString(image->filename,image_info->filename, MagickPathExtent); status=OpenBlob(image_info,image,ReadBinaryBlobMode,exception); if (status == MagickFalse) { image=DestroyImage(image); return(MagickFalse); } if ((IsBlobSeekable(image) == MagickFalse) \|\| (IsBlobExempt(image) != MagickFalse)) { / Copy image to seekable temporary file. / component='\0'; status=ImageToFile(image,component,exception); (void) CloseBlob(image); if (status == MagickFalse) { image=DestroyImage(image); return(MagickFalse); } SetImageInfoFile(image_info,(FILE ) NULL); (void) CopyMagickString(image->filename,component,MagickPathExtent); status=OpenBlob(image_info,image,ReadBinaryBlobMode,exception); if (status == MagickFalse) { image=DestroyImage(image); return(MagickFalse); } (void) CopyMagickString(image_info->filename,component, MagickPathExtent); image_info->temporary=MagickTrue; } magick=(unsigned char ) AcquireMagickMemory(magick_size); if (magick == (unsigned char ) NULL) { (void) CloseBlob(image); image=DestroyImage(image); return(MagickFalse); } (void) memset(magick,0,magick_size); count=ReadBlob(image,magick_size,magick); (void) SeekBlob(image,-((MagickOffsetType) count),SEEK_CUR); (void) CloseBlob(image); image=DestroyImage(image); / Check magic cache. / sans_exception=AcquireExceptionInfo(); magic_info=GetMagicInfo(magick,(size_t) count,sans_exception); magick=(unsigned char ) RelinquishMagickMemory(magick); if ((magic_info != (const MagicInfo ) NULL) && (GetMagicName(magic_info) != (char ) NULL)) { /* Try to use magick_info that was determined earlier by the extension / if ((magick_info != (const MagickInfo ) NULL) && (GetMagickUseExtension(magick_info) != MagickFalse) && (LocaleCompare(magick_info->magick_module,GetMagicName( magic_info)) == 0)) (void) CopyMagickString(image_info->magick,magick_info->name, MagickPathExtent); else { (void) CopyMagickString(image_info->magick,GetMagicName( magic_info),MagickPathExtent); magick_info=GetMagickInfo(image_info->magick,sans_exception); } if ((magick_info == (const MagickInfo ) NULL) \|\| (GetMagickEndianSupport(magick_info) == MagickFalse)) image_info->endian=UndefinedEndian; sans_exception=DestroyExceptionInfo(sans_exception); return(MagickTrue); } magick_info=GetMagickInfo(image_info->magick,sans_exception); if ((magick_info == (const MagickInfo ) NULL) \|\| (GetMagickEndianSupport(magick_info) == MagickFalse)) image_info->endian=UndefinedEndian; sans_exception=DestroyExceptionInfo(sans_exception); } return(MagickTrue); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % S e t I m a g e I n f o B l o b % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % SetImageInfoBlob() sets the image info blob member. % % The format of the SetImageInfoBlob method is: % % void SetImageInfoBlob(ImageInfo image_info,const void blob, % const size_t length) % % A description of each parameter follows: % % o image_info: the image info. % % o blob: the blob. % % o length: the blob length. % / MagickExport void SetImageInfoBlob(ImageInfo image_info,const void blob, const size_t length) { assert(image_info != (ImageInfo ) NULL); assert(image_info->signature == MagickCoreSignature); if (image_info->debug != MagickFalse) (void) LogMagickEvent(TraceEvent,GetMagickModule(),"%s", image_info->filename); image_info->blob=(void ) blob; image_info->length=length; } / %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % S e t I m a g e I n f o C u s t o m S t r e a m % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % SetImageInfoCustomStream() sets the image info custom stream handlers. % % The format of the SetImageInfoCustomStream method is: % % void SetImageInfoCustomStream(ImageInfo image_info, % CustomStreamInfo custom_stream) % % A description of each parameter follows: % % o image_info: the image info. % % o custom_stream: your custom stream methods. % / MagickExport void SetImageInfoCustomStream(ImageInfo image_info, CustomStreamInfo custom_stream) { assert(image_info != (ImageInfo ) NULL); assert(image_info->signature == MagickCoreSignature); if (image_info->debug != MagickFalse) (void) LogMagickEvent(TraceEvent,GetMagickModule(),"%s", image_info->filename); image_info->custom_stream=(CustomStreamInfo ) custom_stream; } / %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % S e t I m a g e I n f o F i l e % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % SetImageInfoFile() sets the image info file member. % % The format of the SetImageInfoFile method is: % % void SetImageInfoFile(ImageInfo image_info,FILE file) % % A description of each parameter follows: % % o image_info: the image info. % % o file: the file. % / MagickExport void SetImageInfoFile(ImageInfo image_info,FILE file) { assert(image_info != (ImageInfo ) NULL); assert(image_info->signature == MagickCoreSignature); if (image_info->debug != MagickFalse) (void) LogMagickEvent(TraceEvent,GetMagickModule(),"%s", image_info->filename); image_info->file=file; } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % S e t I m a g e M a s k % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % SetImageMask() associates a mask with the image. The mask must be the same % dimensions as the image. % % The format of the SetImageMask method is: % % MagickBooleanType SetImageMask(Image image,const PixelMask type, % const Image mask,ExceptionInfo exception) % % A description of each parameter follows: % % o image: the image. % % o type: the mask type, ReadPixelMask or WritePixelMask. % % o mask: the image mask. % % o exception: return any errors or warnings in this structure. % / MagickExport MagickBooleanType SetImageMask(Image image,const PixelMask type, const Image mask,ExceptionInfo exception) { CacheView mask_view, image_view; MagickBooleanType status; ssize_t y; / Set image mask. / assert(image != (Image ) NULL); if (image->debug != MagickFalse) (void) LogMagickEvent(TraceEvent,GetMagickModule(),"..."); assert(image->signature == MagickCoreSignature); if (mask == (const Image ) NULL) { switch (type) { case ReadPixelMask: { image->channels=(ChannelType) (image->channels & ~ReadMaskChannel); break; } case WritePixelMask: { image->channels=(ChannelType) (image->channels & ~WriteMaskChannel); } default: { image->channels=(ChannelType) (image->channels & ~CompositeMaskChannel); break; } } return(SyncImagePixelCache(image,exception)); } switch (type) { case ReadPixelMask: { image->channels=(ChannelType) (image->channels \| ReadMaskChannel); break; } case WritePixelMask: { image->channels=(ChannelType) (image->channels \| WriteMaskChannel); break; } default: { image->channels=(ChannelType) (image->channels \| CompositeMaskChannel); break; } } if (SyncImagePixelCache(image,exception) == MagickFalse) return(MagickFalse); status=MagickTrue; image->mask_trait=UpdatePixelTrait; mask_view=AcquireVirtualCacheView(mask,exception); image_view=AcquireAuthenticCacheView(image,exception); #if defined(MAGICKCORE_OPENMP_SUPPORT) #pragma omp parallel for schedule(static) shared(status) \ magick_number_threads(mask,image,image->rows,1) #endif for (y=0; y < (ssize_t) image->rows; y++) { register const Quantum magick_restrict p; register Quantum magick_restrict q; register ssize_t x; if (status == MagickFalse) continue; p=GetCacheViewVirtualPixels(mask_view,0,y,mask->columns,1,exception); q=GetCacheViewAuthenticPixels(image_view,0,y,image->columns,1,exception); if ((p == (const Quantum ) NULL) \|\| (q == (Quantum ) NULL)) { status=MagickFalse; continue; } for (x=0; x < (ssize_t) image->columns; x++) { MagickRealType intensity; intensity=0.0; if ((x < (ssize_t) mask->columns) && (y < (ssize_t) mask->rows)) intensity=GetPixelIntensity(mask,p); switch (type) { case ReadPixelMask: { SetPixelReadMask(image,ClampToQuantum(intensity),q); break; } case WritePixelMask: { SetPixelWriteMask(image,ClampToQuantum(intensity),q); break; } default: { SetPixelCompositeMask(image,ClampToQuantum(intensity),q); break; } } p+=GetPixelChannels(mask); q+=GetPixelChannels(image); } if (SyncCacheViewAuthenticPixels(image_view,exception) == MagickFalse) status=MagickFalse; } image->mask_trait=UndefinedPixelTrait; mask_view=DestroyCacheView(mask_view); image_view=DestroyCacheView(image_view); return(status); } / %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % S e t I m a g e R e g i o n M a s k % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % SetImageRegionMask() associates a mask with the image as defined by the % specified region. % % The format of the SetImageRegionMask method is: % % MagickBooleanType SetImageRegionMask(Image image,const PixelMask type, % const RectangleInfo region,ExceptionInfo exception) % % A description of each parameter follows: % % o image: the image. % % o type: the mask type, ReadPixelMask or WritePixelMask. % % o geometry: the mask region. % % o exception: return any errors or warnings in this structure. % / MagickExport MagickBooleanType SetImageRegionMask(Image image, const PixelMask type,const RectangleInfo region,ExceptionInfo exception) { CacheView image_view; MagickBooleanType status; ssize_t y; /* Set image mask as defined by the region. / assert(image != (Image ) NULL); if (image->debug != MagickFalse) (void) LogMagickEvent(TraceEvent,GetMagickModule(),"..."); assert(image->signature == MagickCoreSignature); if (region == (const RectangleInfo ) NULL) { switch (type) { case ReadPixelMask: { image->channels=(ChannelType) (image->channels & ~ReadMaskChannel); break; } case WritePixelMask: { image->channels=(ChannelType) (image->channels & ~WriteMaskChannel); break; } default: { image->channels=(ChannelType) (image->channels & ~CompositeMaskChannel); break; } } return(SyncImagePixelCache(image,exception)); } switch (type) { case ReadPixelMask: { image->channels=(ChannelType) (image->channels \| ReadMaskChannel); break; } case WritePixelMask: { image->channels=(ChannelType) (image->channels \| WriteMaskChannel); break; } default: { image->channels=(ChannelType) (image->channels \| CompositeMaskChannel); break; } } if (SyncImagePixelCache(image,exception) == MagickFalse) return(MagickFalse); status=MagickTrue; image->mask_trait=UpdatePixelTrait; image_view=AcquireAuthenticCacheView(image,exception); #if defined(MAGICKCORE_OPENMP_SUPPORT) #pragma omp parallel for schedule(static) shared(status) \ magick_number_threads(image,image,image->rows,1) #endif for (y=0; y < (ssize_t) image->rows; y++) { register Quantum magick_restrict q; register ssize_t x; if (status == MagickFalse) continue; q=GetCacheViewAuthenticPixels(image_view,0,y,image->columns,1,exception); if (q == (Quantum ) NULL) { status=MagickFalse; continue; } for (x=0; x < (ssize_t) image->columns; x++) { Quantum pixel; pixel=QuantumRange; if (((x >= region->x) && (x < (region->x+(ssize_t) region->width))) && ((y >= region->y) && (y < (region->y+(ssize_t) region->height)))) pixel=(Quantum) 0; switch (type) { case ReadPixelMask: { SetPixelReadMask(image,pixel,q); break; } case WritePixelMask: { SetPixelWriteMask(image,pixel,q); break; } default: { SetPixelCompositeMask(image,pixel,q); break; } } q+=GetPixelChannels(image); } if (SyncCacheViewAuthenticPixels(image_view,exception) == MagickFalse) status=MagickFalse; } image->mask_trait=UndefinedPixelTrait; image_view=DestroyCacheView(image_view); return(status); } / %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % S e t I m a g e V i r t u a l P i x e l M e t h o d % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % SetImageVirtualPixelMethod() sets the "virtual pixels" method for the % image and returns the previous setting. A virtual pixel is any pixel access % that is outside the boundaries of the image cache. % % The format of the SetImageVirtualPixelMethod() method is: % % VirtualPixelMethod SetImageVirtualPixelMethod(Image image, % const VirtualPixelMethod virtual_pixel_method,ExceptionInfo exception) % % A description of each parameter follows: % % o image: the image. % % o virtual_pixel_method: choose the type of virtual pixel. % % o exception: return any errors or warnings in this structure. % / MagickExport VirtualPixelMethod SetImageVirtualPixelMethod(Image image, const VirtualPixelMethod virtual_pixel_method,ExceptionInfo exception) { assert(image != (const Image ) NULL); assert(image->signature == MagickCoreSignature); if (image->debug != MagickFalse) (void) LogMagickEvent(TraceEvent,GetMagickModule(),"%s",image->filename); return(SetPixelCacheVirtualMethod(image,virtual_pixel_method,exception)); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % S m u s h I m a g e s % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % SmushImages() takes all images from the current image pointer to the end % of the image list and smushes them to each other top-to-bottom if the % stack parameter is true, otherwise left-to-right. % % The current gravity setting now effects how the image is justified in the % final image. % % The format of the SmushImages method is: % % Image SmushImages(const Image images,const MagickBooleanType stack, % ExceptionInfo exception) % % A description of each parameter follows: % % o images: the image sequence. % % o stack: A value other than 0 stacks the images top-to-bottom. % % o offset: minimum distance in pixels between images. % % o exception: return any errors or warnings in this structure. % / static ssize_t SmushXGap(const Image smush_image,const Image images, const ssize_t offset,ExceptionInfo exception) { CacheView left_view, right_view; const Image left_image, right_image; RectangleInfo left_geometry, right_geometry; register const Quantum p; register ssize_t i, y; size_t gap; ssize_t x; if (images->previous == (Image ) NULL) return(0); right_image=images; SetGeometry(smush_image,&right_geometry); GravityAdjustGeometry(right_image->columns,right_image->rows, right_image->gravity,&right_geometry); left_image=images->previous; SetGeometry(smush_image,&left_geometry); GravityAdjustGeometry(left_image->columns,left_image->rows, left_image->gravity,&left_geometry); gap=right_image->columns; left_view=AcquireVirtualCacheView(left_image,exception); right_view=AcquireVirtualCacheView(right_image,exception); for (y=0; y < (ssize_t) smush_image->rows; y++) { for (x=(ssize_t) left_image->columns-1; x > 0; x--) { p=GetCacheViewVirtualPixels(left_view,x,left_geometry.y+y,1,1,exception); if ((p == (const Quantum ) NULL) \|\| (GetPixelAlpha(left_image,p) != TransparentAlpha) \|\| ((left_image->columns-x-1) >= gap)) break; } i=(ssize_t) left_image->columns-x-1; for (x=0; x < (ssize_t) right_image->columns; x++) { p=GetCacheViewVirtualPixels(right_view,x,right_geometry.y+y,1,1, exception); if ((p == (const Quantum ) NULL) \|\| (GetPixelAlpha(right_image,p) != TransparentAlpha) \|\| ((x+i) >= (ssize_t) gap)) break; } if ((x+i) < (ssize_t) gap) gap=(size_t) (x+i); } right_view=DestroyCacheView(right_view); left_view=DestroyCacheView(left_view); if (y < (ssize_t) smush_image->rows) return(offset); return((ssize_t) gap-offset); } static ssize_t SmushYGap(const Image smush_image,const Image images, const ssize_t offset,ExceptionInfo exception) { CacheView bottom_view, top_view; const Image bottom_image, top_image; RectangleInfo bottom_geometry, top_geometry; register const Quantum p; register ssize_t i, x; size_t gap; ssize_t y; if (images->previous == (Image ) NULL) return(0); bottom_image=images; SetGeometry(smush_image,&bottom_geometry); GravityAdjustGeometry(bottom_image->columns,bottom_image->rows, bottom_image->gravity,&bottom_geometry); top_image=images->previous; SetGeometry(smush_image,&top_geometry); GravityAdjustGeometry(top_image->columns,top_image->rows,top_image->gravity, &top_geometry); gap=bottom_image->rows; top_view=AcquireVirtualCacheView(top_image,exception); bottom_view=AcquireVirtualCacheView(bottom_image,exception); for (x=0; x < (ssize_t) smush_image->columns; x++) { for (y=(ssize_t) top_image->rows-1; y > 0; y--) { p=GetCacheViewVirtualPixels(top_view,top_geometry.x+x,y,1,1,exception); if ((p == (const Quantum ) NULL) \|\| (GetPixelAlpha(top_image,p) != TransparentAlpha) \|\| ((top_image->rows-y-1) >= gap)) break; } i=(ssize_t) top_image->rows-y-1; for (y=0; y < (ssize_t) bottom_image->rows; y++) { p=GetCacheViewVirtualPixels(bottom_view,bottom_geometry.x+x,y,1,1, exception); if ((p == (const Quantum ) NULL) \|\| (GetPixelAlpha(bottom_image,p) != TransparentAlpha) \|\| ((y+i) >= (ssize_t) gap)) break; } if ((y+i) < (ssize_t) gap) gap=(size_t) (y+i); } bottom_view=DestroyCacheView(bottom_view); top_view=DestroyCacheView(top_view); if (x < (ssize_t) smush_image->columns) return(offset); return((ssize_t) gap-offset); } MagickExport Image SmushImages(const Image images, const MagickBooleanType stack,const ssize_t offset,ExceptionInfo exception) { #define SmushImageTag "Smush/Image" const Image image; Image smush_image; MagickBooleanType proceed, status; MagickOffsetType n; PixelTrait alpha_trait; RectangleInfo geometry; register const Image next; size_t height, number_images, width; ssize_t x_offset, y_offset; /* Compute maximum area of smushed area. / assert(images != (Image ) NULL); assert(images->signature == MagickCoreSignature); if (images->debug != MagickFalse) (void) LogMagickEvent(TraceEvent,GetMagickModule(),"%s",images->filename); assert(exception != (ExceptionInfo ) NULL); assert(exception->signature == MagickCoreSignature); image=images; alpha_trait=image->alpha_trait; number_images=1; width=image->columns; height=image->rows; next=GetNextImageInList(image); for ( ; next != (Image ) NULL; next=GetNextImageInList(next)) { if (next->alpha_trait != UndefinedPixelTrait) alpha_trait=BlendPixelTrait; number_images++; if (stack != MagickFalse) { if (next->columns > width) width=next->columns; height+=next->rows; if (next->previous != (Image ) NULL) height+=offset; continue; } width+=next->columns; if (next->previous != (Image ) NULL) width+=offset; if (next->rows > height) height=next->rows; } /* Smush images. / smush_image=CloneImage(image,width,height,MagickTrue,exception); if (smush_image == (Image ) NULL) return((Image ) NULL); if (SetImageStorageClass(smush_image,DirectClass,exception) == MagickFalse) { smush_image=DestroyImage(smush_image); return((Image ) NULL); } smush_image->alpha_trait=alpha_trait; (void) SetImageBackgroundColor(smush_image,exception); status=MagickTrue; x_offset=0; y_offset=0; for (n=0; n < (MagickOffsetType) number_images; n++) { SetGeometry(smush_image,&geometry); GravityAdjustGeometry(image->columns,image->rows,image->gravity,&geometry); if (stack != MagickFalse) { x_offset-=geometry.x; y_offset-=SmushYGap(smush_image,image,offset,exception); } else { x_offset-=SmushXGap(smush_image,image,offset,exception); y_offset-=geometry.y; } status=CompositeImage(smush_image,image,OverCompositeOp,MagickTrue,x_offset, y_offset,exception); proceed=SetImageProgress(image,SmushImageTag,n,number_images); if (proceed == MagickFalse) break; if (stack == MagickFalse) { x_offset+=(ssize_t) image->columns; y_offset=0; } else { x_offset=0; y_offset+=(ssize_t) image->rows; } image=GetNextImageInList(image); } if (stack == MagickFalse) smush_image->columns=(size_t) x_offset; else smush_image->rows=(size_t) y_offset; if (status == MagickFalse) smush_image=DestroyImage(smush_image); return(smush_image); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % S t r i p I m a g e % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % StripImage() strips an image of all profiles and comments. % % The format of the StripImage method is: % % MagickBooleanType StripImage(Image image,ExceptionInfo exception) % % A description of each parameter follows: % % o image: the image. % % o exception: return any errors or warnings in this structure. % / MagickExport MagickBooleanType StripImage(Image image,ExceptionInfo exception) { MagickBooleanType status; assert(image != (Image ) NULL); if (image->debug != MagickFalse) (void) LogMagickEvent(TraceEvent,GetMagickModule(),"..."); (void) exception; DestroyImageProfiles(image); (void) DeleteImageProperty(image,"comment"); (void) DeleteImageProperty(image,"date:create"); (void) DeleteImageProperty(image,"date:modify"); status=SetImageArtifact(image,"png:exclude-chunk", "bKGD,caNv,cHRM,eXIf,gAMA,iCCP,iTXt,pHYs,sRGB,tEXt,zCCP,zTXt,date"); return(status); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % + S y n c I m a g e % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % SyncImage() initializes the red, green, and blue intensities of each pixel % as defined by the colormap index. % % The format of the SyncImage method is: % % MagickBooleanType SyncImage(Image image,ExceptionInfo exception) % % A description of each parameter follows: % % o image: the image. % % o exception: return any errors or warnings in this structure. % / static inline Quantum PushColormapIndex(Image image,const Quantum index, MagickBooleanType range_exception) { if ((size_t) index < image->colors) return(index); range_exception=MagickTrue; return((Quantum) 0); } MagickExport MagickBooleanType SyncImage(Image image,ExceptionInfo exception) { CacheView image_view; MagickBooleanType range_exception, status, taint; ssize_t y; assert(image != (Image ) NULL); if (image->debug != MagickFalse) (void) LogMagickEvent(TraceEvent,GetMagickModule(),"..."); assert(image->signature == MagickCoreSignature); if (image->ping != MagickFalse) return(MagickTrue); if (image->storage_class != PseudoClass) return(MagickFalse); assert(image->colormap != (PixelInfo ) NULL); range_exception=MagickFalse; status=MagickTrue; taint=image->taint; image_view=AcquireAuthenticCacheView(image,exception); #if defined(MAGICKCORE_OPENMP_SUPPORT) #pragma omp parallel for schedule(static) shared(range_exception,status) \ magick_number_threads(image,image,image->rows,1) #endif for (y=0; y < (ssize_t) image->rows; y++) { Quantum index; register Quantum magick_restrict q; register ssize_t x; if (status == MagickFalse) continue; q=GetCacheViewAuthenticPixels(image_view,0,y,image->columns,1,exception); if (q == (Quantum ) NULL) { status=MagickFalse; continue; } for (x=0; x < (ssize_t) image->columns; x++) { index=PushColormapIndex(image,GetPixelIndex(image,q),&range_exception); SetPixelViaPixelInfo(image,image->colormap+(ssize_t) index,q); q+=GetPixelChannels(image); } if (SyncCacheViewAuthenticPixels(image_view,exception) == MagickFalse) status=MagickFalse; } image_view=DestroyCacheView(image_view); image->taint=taint; if ((image->ping == MagickFalse) && (range_exception != MagickFalse)) (void) ThrowMagickException(exception,GetMagickModule(), CorruptImageWarning,"InvalidColormapIndex","`%s'",image->filename); return(status); } / %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % S y n c I m a g e S e t t i n g s % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % SyncImageSettings() syncs any image_info global options into per-image % attributes. % % Note: in IMv6 free form 'options' were always mapped into 'artifacts', so % that operations and coders can find such settings. In IMv7 if a desired % per-image artifact is not set, then it will directly look for a global % option as a fallback, as such this copy is no longer needed, only the % link set up. % % The format of the SyncImageSettings method is: % % MagickBooleanType SyncImageSettings(const ImageInfo image_info, % Image image,ExceptionInfo exception) % MagickBooleanType SyncImagesSettings(const ImageInfo image_info, % Image image,ExceptionInfo exception) % % A description of each parameter follows: % % o image_info: the image info. % % o image: the image. % % o exception: return any errors or warnings in this structure. % / MagickExport MagickBooleanType SyncImagesSettings(ImageInfo image_info, Image images,ExceptionInfo exception) { Image image; assert(image_info != (const ImageInfo ) NULL); assert(image_info->signature == MagickCoreSignature); assert(images != (Image ) NULL); assert(images->signature == MagickCoreSignature); if (images->debug != MagickFalse) (void) LogMagickEvent(TraceEvent,GetMagickModule(),"%s",images->filename); image=images; for ( ; image != (Image ) NULL; image=GetNextImageInList(image)) (void) SyncImageSettings(image_info,image,exception); (void) DeleteImageOption(image_info,"page"); return(MagickTrue); } MagickExport MagickBooleanType SyncImageSettings(const ImageInfo image_info, Image image,ExceptionInfo exception) { const char option; GeometryInfo geometry_info; MagickStatusType flags; ResolutionType units; /* Sync image options. / assert(image_info != (const ImageInfo ) NULL); assert(image_info->signature == MagickCoreSignature); assert(image != (Image ) NULL); assert(image->signature == MagickCoreSignature); if (image->debug != MagickFalse) (void) LogMagickEvent(TraceEvent,GetMagickModule(),"%s",image->filename); option=GetImageOption(image_info,"background"); if (option != (const char ) NULL) (void) QueryColorCompliance(option,AllCompliance,&image->background_color, exception); option=GetImageOption(image_info,"black-point-compensation"); if (option != (const char ) NULL) image->black_point_compensation=(MagickBooleanType) ParseCommandOption( MagickBooleanOptions,MagickFalse,option); option=GetImageOption(image_info,"blue-primary"); if (option != (const char ) NULL) { flags=ParseGeometry(option,&geometry_info); image->chromaticity.blue_primary.x=geometry_info.rho; image->chromaticity.blue_primary.y=geometry_info.sigma; if ((flags & SigmaValue) == 0) image->chromaticity.blue_primary.y=image->chromaticity.blue_primary.x; } option=GetImageOption(image_info,"bordercolor"); if (option != (const char ) NULL) (void) QueryColorCompliance(option,AllCompliance,&image->border_color, exception); / FUTURE: do not sync compose to per-image compose setting here / option=GetImageOption(image_info,"compose"); if (option != (const char ) NULL) image->compose=(CompositeOperator) ParseCommandOption(MagickComposeOptions, MagickFalse,option); /* -- / option=GetImageOption(image_info,"compress"); if (option != (const char ) NULL) image->compression=(CompressionType) ParseCommandOption( MagickCompressOptions,MagickFalse,option); option=GetImageOption(image_info,"debug"); if (option != (const char ) NULL) image->debug=(MagickBooleanType) ParseCommandOption(MagickBooleanOptions, MagickFalse,option); option=GetImageOption(image_info,"density"); if (option != (const char ) NULL) { flags=ParseGeometry(option,&geometry_info); image->resolution.x=geometry_info.rho; image->resolution.y=geometry_info.sigma; if ((flags & SigmaValue) == 0) image->resolution.y=image->resolution.x; } option=GetImageOption(image_info,"depth"); if (option != (const char ) NULL) image->depth=StringToUnsignedLong(option); option=GetImageOption(image_info,"endian"); if (option != (const char ) NULL) image->endian=(EndianType) ParseCommandOption(MagickEndianOptions, MagickFalse,option); option=GetImageOption(image_info,"filter"); if (option != (const char ) NULL) image->filter=(FilterType) ParseCommandOption(MagickFilterOptions, MagickFalse,option); option=GetImageOption(image_info,"fuzz"); if (option != (const char ) NULL) image->fuzz=StringToDoubleInterval(option,(double) QuantumRange+1.0); option=GetImageOption(image_info,"gravity"); if (option != (const char ) NULL) image->gravity=(GravityType) ParseCommandOption(MagickGravityOptions, MagickFalse,option); option=GetImageOption(image_info,"green-primary"); if (option != (const char ) NULL) { flags=ParseGeometry(option,&geometry_info); image->chromaticity.green_primary.x=geometry_info.rho; image->chromaticity.green_primary.y=geometry_info.sigma; if ((flags & SigmaValue) == 0) image->chromaticity.green_primary.y=image->chromaticity.green_primary.x; } option=GetImageOption(image_info,"intent"); if (option != (const char ) NULL) image->rendering_intent=(RenderingIntent) ParseCommandOption( MagickIntentOptions,MagickFalse,option); option=GetImageOption(image_info,"intensity"); if (option != (const char ) NULL) image->intensity=(PixelIntensityMethod) ParseCommandOption( MagickPixelIntensityOptions,MagickFalse,option); option=GetImageOption(image_info,"interlace"); if (option != (const char ) NULL) image->interlace=(InterlaceType) ParseCommandOption(MagickInterlaceOptions, MagickFalse,option); option=GetImageOption(image_info,"interpolate"); if (option != (const char ) NULL) image->interpolate=(PixelInterpolateMethod) ParseCommandOption( MagickInterpolateOptions,MagickFalse,option); option=GetImageOption(image_info,"loop"); if (option != (const char ) NULL) image->iterations=StringToUnsignedLong(option); option=GetImageOption(image_info,"mattecolor"); if (option != (const char ) NULL) (void) QueryColorCompliance(option,AllCompliance,&image->matte_color, exception); option=GetImageOption(image_info,"orient"); if (option != (const char ) NULL) image->orientation=(OrientationType) ParseCommandOption( MagickOrientationOptions,MagickFalse,option); option=GetImageOption(image_info,"page"); if (option != (const char ) NULL) { char geometry; geometry=GetPageGeometry(option); flags=ParseAbsoluteGeometry(geometry,&image->page); geometry=DestroyString(geometry); } option=GetImageOption(image_info,"quality"); if (option != (const char ) NULL) image->quality=StringToUnsignedLong(option); option=GetImageOption(image_info,"red-primary"); if (option != (const char ) NULL) { flags=ParseGeometry(option,&geometry_info); image->chromaticity.red_primary.x=geometry_info.rho; image->chromaticity.red_primary.y=geometry_info.sigma; if ((flags & SigmaValue) == 0) image->chromaticity.red_primary.y=image->chromaticity.red_primary.x; } if (image_info->quality != UndefinedCompressionQuality) image->quality=image_info->quality; option=GetImageOption(image_info,"scene"); if (option != (const char ) NULL) image->scene=StringToUnsignedLong(option); option=GetImageOption(image_info,"taint"); if (option != (const char ) NULL) image->taint=(MagickBooleanType) ParseCommandOption(MagickBooleanOptions, MagickFalse,option); option=GetImageOption(image_info,"tile-offset"); if (option != (const char ) NULL) { char geometry; geometry=GetPageGeometry(option); flags=ParseAbsoluteGeometry(geometry,&image->tile_offset); geometry=DestroyString(geometry); } option=GetImageOption(image_info,"transparent-color"); if (option != (const char ) NULL) (void) QueryColorCompliance(option,AllCompliance,&image->transparent_color, exception); option=GetImageOption(image_info,"type"); if (option != (const char ) NULL) image->type=(ImageType) ParseCommandOption(MagickTypeOptions,MagickFalse, option); option=GetImageOption(image_info,"units"); units=image_info->units; if (option != (const char ) NULL) units=(ResolutionType) ParseCommandOption(MagickResolutionOptions, MagickFalse,option); if (units != UndefinedResolution) { if (image->units != units) switch (image->units) { case PixelsPerInchResolution: { if (units == PixelsPerCentimeterResolution) { image->resolution.x/=2.54; image->resolution.y/=2.54; } break; } case PixelsPerCentimeterResolution: { if (units == PixelsPerInchResolution) { image->resolution.x=(double) ((size_t) (100.02.54 image->resolution.x+0.5))/100.0; image->resolution.y=(double) ((size_t) (100.02.54 image->resolution.y+0.5))/100.0; } break; } default: break; } image->units=units; option=GetImageOption(image_info,"density"); if (option != (const char ) NULL) { flags=ParseGeometry(option,&geometry_info); image->resolution.x=geometry_info.rho; image->resolution.y=geometry_info.sigma; if ((flags & SigmaValue) == 0) image->resolution.y=image->resolution.x; } } option=GetImageOption(image_info,"virtual-pixel"); if (option != (const char ) NULL) (void) SetImageVirtualPixelMethod(image,(VirtualPixelMethod) ParseCommandOption(MagickVirtualPixelOptions,MagickFalse,option), exception); option=GetImageOption(image_info,"white-point"); if (option != (const char ) NULL) { flags=ParseGeometry(option,&geometry_info); image->chromaticity.white_point.x=geometry_info.rho; image->chromaticity.white_point.y=geometry_info.sigma; if ((flags & SigmaValue) == 0) image->chromaticity.white_point.y=image->chromaticity.white_point.x; } / Pointer to allow the lookup of pre-image artifact will fallback to a global option setting/define. This saves a lot of duplication of global options into per-image artifacts, while ensuring only specifically set per-image artifacts are preserved when parenthesis ends. / if (image->image_info != (ImageInfo ) NULL) image->image_info=DestroyImageInfo(image->image_info); image->image_info=CloneImageInfo(image_info); return(MagickTrue); }
grid.c	#include <stdio.h> #include <stdlib.h> #include <stdbool.h> #include <mpi.h> #include <math.h> #include <string.h> #include "grid.h" #include "common.h" double k_coeff(int i, int j, struct Grid* grid) { return 4.0 + __x(grid, i) + __y(grid, j); } void init_inter(struct Grid* grid) { int height = grid->height, width = grid->width; //#pragma omp parallel for /for (int i = 0; i < width; ++i) for (int j = 0; j < height; ++j) { (grid->inter)[idx(i, j, height)] = 1.0 + cos(M_PI __x(grid, i) * __y(grid, j)); (grid->resid)[idx(i, j, height)] = grid->rank; }/ memset(grid->inter, 0, sizeof(double) grid->width * grid->height); memset(grid->resid, 0, sizeof(double) * grid->width * grid->height); } void init_b_con(struct Grid* grid) { int height = grid->height, width = grid->width, width_ = width - 1, height_ = height - 1; #pragma omp parallel for for (int i = 0; i < width; ++i) for (int j = 0; j < height; ++j) { double x = __x(grid, i), y = __y(grid, j); (grid->b_con)[idx(i, j, height)] = PI_SQR * (4 + x + y) * (xx + yy) * cos(M_PI * x * y) + M_PI * (x + y) * sin(M_PI * x * y); } if (!grid->mpi_top) for (int i = 0; i < width; ++i) { double x = __x(grid, i), y = __y(grid, height_); (grid->b_con)[idx(i, height_, height)] += 2.0 * grid->y_h_inv * (- M_PI * (5.0 + x) * x * sin(M_PI * x) + 1.0 + cos(M_PI * x)); } if (!grid->mpi_right) for (int j = 0; j < height; ++j) { double x = __x(grid, width_), y = __y(grid, j); (grid->b_con)[idx(width_, j, height)] += 2.0 * grid->x_h_inv * (- (6.0 + y) * (M_PI * y * sin(2.0 * M_PI * y)) + 1.0 + cos(2.0 * M_PI * y)); } // memset(grid->b_con, 0, sizeof(double) * grid->width * grid->height); } void init_grid(struct Grid* grid, int* coords, int* dims, int* grid_size, int rank, MPI_Comm* mpi_world) { // setup coord structure int grid_x = grid_size[0] / dims[0]; int grid_x_rem = grid_size[0] % dims[0]; int grid_y = grid_size[1] / dims[1]; int grid_y_rem = grid_size[1] % dims[1]; grid->mpi_world = mpi_world; grid->left = grid_x * coords[0] + (min(grid_x_rem, coords[0])); grid->bot = grid_y * coords[1] + (min(grid_y_rem, coords[1])); grid->right = grid->left + grid_x + (coords[0] < grid_x_rem); grid->top = grid->bot + grid_y + (coords[1] < grid_y_rem); grid->width = grid->right - grid->left; grid->height = grid->top - grid->bot; grid->rank = rank; (grid->coords)[0] = coords[0]; (grid->coords)[1] = coords[1]; // figure edges out grid->mpi_left = grid->left != 0; grid->mpi_bot = grid->bot != 0; grid->mpi_right = grid->right != grid_size[0]; grid->mpi_top = grid->top != grid_size[1]; // allocate inter grid->inter = malloc_array(grid->width, grid->height); grid->resid = malloc_array(grid->width, grid->height); grid->b_con = malloc_array(grid->width, grid->height); grid->x_h = X_W / (grid_size[0] - 1); grid->y_h = Y_H / (grid_size[0] - 1); grid->x_h_2 = grid->x_h * 0.5; grid->y_h_2 = grid->y_h * 0.5; grid->x_h_inv = 1.0 / grid->x_h; grid->y_h_inv = 1.0 / grid->y_h; grid->x_start = grid->left * grid->x_h; grid->y_start = grid->bot * grid->y_h; // allocate guest arrays, when required if (grid->mpi_left) { grid->guest_left = malloc_array(1, grid->height); } if (grid->mpi_right) { grid->guest_right = malloc_array(1, grid->height); } if (grid->mpi_bot) { grid->guest_bot = malloc_array(grid->width, 1); grid->buf_bot = malloc_array(grid->width, 1); } if (grid->mpi_top) { grid->guest_top = malloc_array(grid->width, 1); grid->buf_top = malloc_array(grid->width, 1); } init_inter(grid); init_b_con(grid); } void display_grid_coords(struct Grid* grid) { printf("Rank %i grid coords: MPI %3ix%-3i X %4ix%-4i Y %4ix%-4i\n" "MPI communication square:\n" ".%1i.\n" "%1ix%-1i\n" ".%1i.\n", grid->rank, (grid->coords)[0], (grid->coords)[1], grid->left, grid->right, grid->bot, grid->top, grid->mpi_left, grid->mpi_bot, grid->mpi_top, grid->mpi_right); } void unmake_grid(struct Grid* grid) { free(grid->inter); free(grid->resid); free(grid->b_con); if (grid->mpi_left) { free(grid->guest_left); } if (grid->mpi_right) { free(grid->guest_right); } if (grid->mpi_bot) { free(grid->guest_bot); free(grid->buf_bot); } if (grid->mpi_top) { free(grid->guest_top); free(grid->buf_top); } } double operator(struct Grid* grid, double k, double base, double x_fwd, double x_bwd, double y_fwd, double y_bwd) { operator_vars; return -(x_h_inv * ( (k + x_h_2) * x_h_inv * (x_fwd - base) -(k - x_h_2) * x_h_inv * (base - x_bwd)) + y_h_inv * ( (k + y_h_2) * y_h_inv * (y_fwd - base) -(k - y_h_2) * y_h_inv * (base - y_bwd))); } double operator_left(struct Grid* grid, double k, double base, double x_fwd, double y_fwd, double y_bwd) { operator_vars; return - 2.0 * x_h_inv * (k + x_h_2) * x_h_inv * (x_fwd - base) - y_h_inv * ( (k + y_h_2) * y_h_inv * (y_fwd - base) -(k - y_h_2) * y_h_inv * (base - y_bwd)); } double operator_right(struct Grid* grid, double k, double base, double x_bwd, double y_fwd, double y_bwd) { operator_vars; return 2.0 * x_h_inv * (k - x_h_2) * x_h_inv * (base - x_bwd) + 2.0 * x_h_inv * base - y_h_inv * ( (k + y_h_2) * y_h_inv * (y_fwd - base) -(k - y_h_2) * y_h_inv * (base - y_bwd)); } double operator_bot(struct Grid* grid, double k, double base, double x_fwd, double x_bwd, double y_fwd) { operator_vars; return - 2.0 * y_h_inv * (k + y_h_2) * y_h_inv * (y_fwd - base) - x_h_inv * ( (k + x_h_2) * x_h_inv * (x_fwd - base) -(k - x_h_2) * x_h_inv * (base - x_bwd)); } double operator_top(struct Grid* grid, double k, double base, double x_fwd, double x_bwd, double y_bwd) { operator_vars; return 2.0 * y_h_inv * (k - y_h_2) * y_h_inv * (base - y_bwd) + 2.0 * y_h_inv * base - x_h_inv * ( (k + x_h_2) * x_h_inv * (x_fwd - base) -(k - x_h_2) * x_h_inv * (base - x_bwd)); } double operator_top_right(struct Grid* grid, double k, double base, double x_bwd, double y_bwd) { operator_vars; return 2.0 * x_h_inv * (k - x_h_2) * x_h_inv * (base - x_bwd) + 2.0 * y_h_inv * (k - y_h_2) * y_h_inv * (base - y_bwd) + 2.0 * (x_h_inv + y_h_inv) * base; } double operator_top_left(struct Grid* grid, double k, double base, double x_fwd, double y_bwd) { operator_vars; return -2.0 * x_h_inv * (k + x_h_2) * x_h_inv * (x_fwd - base) + 2.0 * y_h_inv * (k - y_h_2) * y_h_inv * (base - y_bwd) + 2.0 * y_h_inv * base; } double operator_bot_right(struct Grid* grid, double k, double base, double x_bwd, double y_fwd) { operator_vars; return 2.0 * x_h_inv * (k - x_h_2) * x_h_inv * (base - x_bwd) -2.0 * y_h_inv * (k + y_h_2) * y_h_inv * (y_fwd - base) + 2.0 * x_h_inv * base; } double operator_bot_left(struct Grid* grid, double k, double base, double x_fwd, double y_fwd) { operator_vars; return - 2.0 * x_h_inv * (k + x_h_2) * x_h_inv * (x_fwd - base) - 2.0 * y_h_inv * (k + y_h_2) * y_h_inv * (y_fwd - base); } void internal_op(struct Grid* grid, int resid) { common_vars; if (resid) { grid->norm = 0; grid->scalar = 0; } #pragma omp parallel for reduction(+:norm,scalar) for (int i = 1; i < width_; ++i) for (int j = 1; j < height_; ++j) { index_factory(i, j); resid_arr_switch; (left_arr) = operator( grid, k_coeff(i, j, grid), right_arr[base_idx], right_arr[x_fwd_idx], right_arr[x_bwd_idx], right_arr[y_fwd_idx], right_arr[y_bwd_idx] ) - (resid ? 0 : 1) grid->b_con[base_idx]; resid_loc_norm_advance; } resid_glob_norm_advance(1.0); } void border_op_left(struct Grid* grid, int resid) { common_vars; #pragma omp parallel for reduction(+:norm,scalar) for (int j = 1; j < height_; ++j) { index_factory(0, j); resid_arr_switch; if (grid->mpi_left) { (left_arr) = operator( grid, k_coeff(0, j, grid), right_arr[base_idx], right_arr[x_fwd_idx], grid->guest_left[j], right_arr[y_fwd_idx], right_arr[y_bwd_idx] ) - (resid ? 0 : 1) grid->b_con[base_idx]; } else { (left_arr) = operator_left( grid, k_coeff(0, j, grid), right_arr[base_idx], right_arr[x_fwd_idx], right_arr[y_fwd_idx], right_arr[y_bwd_idx] ) - (resid ? 0 : 1) grid->b_con[base_idx]; } resid_loc_norm_advance; } resid_glob_norm_advance(0.5); } void border_op_right(struct Grid* grid, int resid) { common_vars; #pragma omp parallel for reduction(+:norm,scalar) for (int j = 1; j < height_; ++j) { index_factory(width_, j); resid_arr_switch; if (grid->mpi_right) { (left_arr) = operator( grid, k_coeff(width_, j, grid), right_arr[base_idx], grid->guest_right[j], right_arr[x_bwd_idx], right_arr[y_fwd_idx], right_arr[y_bwd_idx] ) - (resid ? 0 : 1) grid->b_con[base_idx]; } else { (left_arr) = operator_right( grid, k_coeff(width_, j, grid), right_arr[base_idx], right_arr[x_bwd_idx], right_arr[y_fwd_idx], right_arr[y_bwd_idx] ) - (resid ? 0 : 1) grid->b_con[base_idx]; } resid_loc_norm_advance; } resid_glob_norm_advance(0.5); } void border_op_bot(struct Grid* grid, int resid) { common_vars; #pragma omp parallel for reduction(+:norm,scalar) for (int i = 1; i < width_; ++i) { index_factory(i, 0); resid_arr_switch; if (grid->mpi_bot) { (left_arr) = operator( grid, k_coeff(i, 0, grid), right_arr[base_idx], right_arr[x_fwd_idx], right_arr[x_bwd_idx], right_arr[y_fwd_idx], grid->guest_bot[i] ) - (resid ? 0 : 1) grid->b_con[base_idx]; } else { (left_arr) = operator_bot( grid, k_coeff(i, 0, grid), right_arr[base_idx], right_arr[x_fwd_idx], right_arr[x_bwd_idx], right_arr[y_fwd_idx] ) - (resid ? 0 : 1) grid->b_con[base_idx]; } resid_loc_norm_advance; } resid_glob_norm_advance(0.5); } void border_op_top(struct Grid* grid, int resid) { common_vars; #pragma omp parallel for reduction(+:norm,scalar) for (int i = 1; i < width_; ++i) { index_factory(i, height_); resid_arr_switch; if (grid->mpi_top) { (left_arr) = operator( grid, k_coeff(i, height_, grid), right_arr[base_idx], right_arr[x_fwd_idx], right_arr[x_bwd_idx], grid->guest_top[i], right_arr[y_bwd_idx] ) - (resid ? 0 : 1) grid->b_con[base_idx]; } else { (left_arr) = operator_top( grid, k_coeff(i, height_, grid), right_arr[base_idx], right_arr[x_fwd_idx], right_arr[x_bwd_idx], right_arr[y_bwd_idx] ) - (resid ? 0 : 1) grid->b_con[base_idx]; } resid_loc_norm_advance; } resid_glob_norm_advance(0.5); } void corner_op_top_right(struct Grid* grid, int resid) { common_vars; operator_vars; index_factory(width_, height_); resid_arr_switch; double base = right_arr[base_idx], x_bwd = right_arr[x_bwd_idx], y_bwd = right_arr[y_bwd_idx]; if ((!grid->mpi_top) && (!grid->mpi_right)) (left_arr) = operator_top_right(grid, k_coeff(width_, height_, grid), base, x_bwd, y_bwd) - (resid ? 0 : 1) grid->b_con[base_idx]; else if (!grid->mpi_top) (left_arr) = operator_top(grid, k_coeff(width_, height_, grid), base, grid->guest_right[height_], x_bwd, y_bwd) - (resid ? 0 : 1) grid->b_con[base_idx]; else if (!grid->mpi_right) (left_arr) = operator_right(grid, k_coeff(width_, height_, grid), base, x_bwd, grid->guest_top[width_], y_bwd) - (resid ? 0 : 1) grid->b_con[base_idx]; else (left_arr) = operator(grid, k_coeff(width_, height_, grid), base, grid->guest_right[height_], x_bwd, grid->guest_top[width_], y_bwd) - (resid ? 0 : 1) grid->b_con[base_idx]; resid_glob_norm_advance(0.25); } void corner_op_top_left(struct Grid* grid, int resid) { common_vars; operator_vars; index_factory(0, height_); resid_arr_switch; double base = right_arr[base_idx], x_fwd = right_arr[x_fwd_idx], y_bwd = right_arr[y_bwd_idx]; if ((!grid->mpi_top) && (!grid->mpi_left)) (left_arr) = operator_top_left(grid, k_coeff(0, height_, grid), base, x_fwd, y_bwd) - (resid ? 0 : 1) grid->b_con[base_idx]; else if (!grid->mpi_top) (left_arr) = operator_top(grid, k_coeff(0, height_, grid), base, x_fwd, grid->guest_left[height_], y_bwd) - (resid ? 0 : 1) grid->b_con[base_idx]; else if (!grid->mpi_left) (left_arr) = operator_left(grid, k_coeff(0, height_, grid), base, x_fwd, grid->guest_top[0], y_bwd) - (resid ? 0 : 1) grid->b_con[base_idx]; else (left_arr) = operator(grid, k_coeff(0, height_, grid), base, x_fwd, grid->guest_left[height_], grid->guest_top[0], y_bwd) - (resid ? 0 : 1) grid->b_con[base_idx]; resid_glob_norm_advance(0.25); } void corner_op_bot_right(struct Grid* grid, int resid) { common_vars; operator_vars; index_factory(width_, 0); resid_arr_switch; double base = right_arr[base_idx], x_bwd = right_arr[x_bwd_idx], y_fwd = right_arr[y_fwd_idx]; if ((!grid->mpi_bot) && (!grid->mpi_right)) (left_arr) = operator_bot_right(grid, k_coeff(width_, 0, grid), base, x_bwd, y_fwd) - (resid ? 0 : 1) grid->b_con[base_idx]; else if (!grid->mpi_right) (left_arr) = operator_right(grid, k_coeff(width_, 0, grid), base, x_bwd, y_fwd, grid->guest_bot[width_]) - (resid ? 0 : 1) grid->b_con[base_idx]; else if (!grid->mpi_bot) (left_arr) = operator_bot(grid, k_coeff(width_, 0, grid), base, grid->guest_right[0], x_bwd, y_fwd) - (resid ? 0 : 1) grid->b_con[base_idx]; else (left_arr) = operator(grid, k_coeff(width_, 0, grid), base, grid->guest_right[0], x_bwd, y_fwd, grid->guest_bot[width_]) - (resid ? 0 : 1) grid->b_con[base_idx]; resid_glob_norm_advance(0.25); } void corner_op_bot_left(struct Grid* grid, int resid) { common_vars; operator_vars; index_factory(0, 0); resid_arr_switch; double base = right_arr[base_idx], x_fwd = right_arr[x_fwd_idx], y_fwd = right_arr[y_fwd_idx]; if ((!grid->mpi_bot) && (!grid->mpi_left)) (left_arr) = operator_bot_left(grid, k_coeff(0, 0, grid), base, x_fwd, y_fwd) - (resid ? 0 : 1) grid->b_con[base_idx]; else if (!grid->mpi_left) (left_arr) = operator_left(grid, k_coeff(0, 0, grid), base, x_fwd, y_fwd, grid->guest_bot[0]) - (resid ? 0 : 1) grid->b_con[base_idx]; else if (!grid->mpi_bot) (left_arr) = operator_bot(grid, k_coeff(0, 0, grid), base, x_fwd, grid->guest_left[0], y_fwd) - (resid ? 0 : 1) grid->b_con[base_idx]; else (left_arr) = operator(grid, k_coeff(0, 0, grid), base, x_fwd, grid->guest_left[0], y_fwd, grid->guest_bot[0]) - (resid ? 0 : 1) grid->b_con[base_idx]; resid_glob_norm_advance(0.25); } void border_op(struct Grid* grid, int resid) { border_op_left(grid, resid); border_op_right(grid, resid); border_op_top(grid, resid); border_op_bot(grid, resid); corner_op_top_right(grid, resid); corner_op_top_left(grid, resid); corner_op_bot_right(grid, resid); corner_op_bot_left(grid, resid); } void display_grid_h(struct Grid* grid) { int height = grid->height, width = grid->width; printf("x_h: %f, y_h: %f\n", grid->x_h, grid->y_h); for (int i = 0; i < width; ++i) { for (int j = 0; j < height; ++j) printf("(%-2.2f %2.2f)", __x(grid, i), __y(grid, j)); //printf("%-2.2f ", k_coeff(i, j, grid)); printf("\n"); } } void display_grid_arr(struct Grid* grid, double* arr, double displacement) { int height = grid->height, width = grid->width; for (int i = 0; i < width; ++i) { for (int j = 0; j < height; ++j) printf("%9.2e ", arr[idx(i, j, height)] + displacement); printf("\n"); } } void display_grid_arr_idx(struct Grid* grid) { int height = grid->height, width = grid->width; for (int i = 0; i < width; ++i) { for (int j = 0; j < height; ++j) { printf("%-3i ", idx(i, j, height)); } printf("\n"); } } void dump_array(struct Grid* grid, double* arr, int counter, int grid_size) { int height = grid->height, width = grid->width; char full_name[80]; // hardcoded for maximum FIRE sprintf(full_name, "data/mpi_four/%i_%i_%i", grid_size, grid->rank, counter); FILE* file = fopen(full_name, "w"); fprintf(file, "["); for (int i = 0; i < width; ++i) { fprintf(file, "["); for (int j = 0; j < height; ++j) { fprintf(file, "%f,", arr[idx(i, j, height)]); } fprintf(file, "],\n"); } fprintf(file, "]\n"); fclose(file); } double max_abs_resid(struct Grid* grid) { double max_abs_resid = 0, max_abs_resid_2 = 0; int max_i = 0, max_j = 0; for (int i = 0; i < grid->width-1; ++i) for (int j = 0; j < grid->height-1; ++j) { if (fabs(grid->resid[idx(i, j, grid->height)]) > max_abs_resid) { max_abs_resid = fabs(grid->resid[idx(i, j, grid->height)]); max_i = i; max_j = j; } } //printf("Max resid i,j: (%i, %i)\n", max_i, max_j); MPI_Reduce(&max_abs_resid, &max_abs_resid_2, 1, MPI_DOUBLE, MPI_MAX, 0, (grid->mpi_world)); return max_abs_resid_2; } double max_solution_error(struct Grid grid) { double max_sol_err = -1, max_sol_err_2; int max_i = 0, max_j = 0; for (int i = 0; i < grid->width; ++i) for (int j = 0; j < grid->height; ++j) { double sol_err = fabs(grid->inter[idx(i, j, grid->height)] - (1 + cos(M_PI * __x(grid, i) * __y(grid, j)))); if (sol_err > max_sol_err) { max_sol_err = sol_err; max_i = i; max_j = j; } } MPI_Reduce(&max_sol_err, &max_sol_err_2, 1, MPI_DOUBLE, MPI_MAX, 0, (grid->mpi_world)); return max_sol_err_2; } double norm_abs_solution_error(struct Grid grid) { double norm = 0, norm_2 = 0; int max_i = 0, max_j = 0; for (int i = 0; i < grid->width; ++i) for (int j = 0; j < grid->height; ++j) { double sol_err = fabs(grid->inter[idx(i, j, grid->height)] - (1 + cos(M_PI * __x(grid, i) * __y(grid, j)))); norm += sol_err * sol_err * (((i > 0) && (i < grid->width-1)) ? 1 : 0.5) * (((j > 0) && (j < grid->height-1)) ? 1 : 0.5); } norm = grid->x_h grid->y_h; MPI_Reduce(&norm, &norm_2, 1, MPI_DOUBLE, MPI_SUM, 0, (grid->mpi_world)); return sqrt(norm_2); } void display_solution(struct Grid grid) { int height = grid->height, width = grid->width; for (int i = 0; i < width; ++i) { for (int j = 0; j < height; ++j) printf("%7.2e ", (1 + cos(M_PI * __x(grid, i) * __y(grid, j)))); printf("\n"); } } void async_send_guests(struct Grid* grid, bool resid) { MPI_Comm* mpi_world = grid->mpi_world; // ignore this, sync is done by recieve MPI_Request request; double send_arr; int rc, dest_rank, junk_rank, height = grid->height, width = grid->width, height_ = height - 1, width_ = width - 1; // set the right send arrays if (resid) { send_arr = grid->resid; } else { send_arr = grid->inter; } if (grid->mpi_left) { mpi_wrap(MPI_Cart_shift((mpi_world), 0, -1, &junk_rank, &dest_rank), (mpi_world), rc); mpi_wrap(MPI_Isend(&(send_arr[idx(0, 0, height)]), height, MPI_DOUBLE, dest_rank, 0, (mpi_world), &request), (mpi_world), rc); mpi_wrap(MPI_Request_free(&request), (mpi_world), rc); } if (grid->mpi_right) { mpi_wrap(MPI_Cart_shift((mpi_world), 0, 1, &junk_rank, &dest_rank), (mpi_world), rc); mpi_wrap(MPI_Isend(&(send_arr[idx(width_, 0, height)]), height, MPI_DOUBLE, dest_rank, 0, (mpi_world), &request), (mpi_world), rc); mpi_wrap(MPI_Request_free(&request), (mpi_world), rc); } if (grid->mpi_bot) { mpi_wrap(MPI_Cart_shift((mpi_world), 1, -1, &junk_rank, &dest_rank), (mpi_world), rc); for (int i = 0; i < width; ++i) grid->buf_bot[i] = send_arr[idx(i, 0, height)]; mpi_wrap(MPI_Isend(grid->buf_bot, width, MPI_DOUBLE, dest_rank, 0, (mpi_world), &request), (mpi_world), rc); mpi_wrap(MPI_Request_free(&request), (mpi_world), rc); } if (grid->mpi_top) { mpi_wrap(MPI_Cart_shift((mpi_world), 1, 1, &junk_rank, &dest_rank), (mpi_world), rc); for (int i = 0; i < width; ++i) grid->buf_top[i] = send_arr[idx(i, height_, height)]; mpi_wrap(MPI_Isend(grid->buf_top, width, MPI_DOUBLE, dest_rank, 0, (mpi_world), &request), (mpi_world), rc); mpi_wrap(MPI_Request_free(&request), (mpi_world), rc); } } void sync_recv_guests(struct Grid grid) { MPI_Comm* mpi_world = grid->mpi_world; int rc, src_rank, junk_rank, height = grid->height, width = grid->width; // receiving buffers are the same no matter what if (grid->mpi_left) { mpi_wrap(MPI_Cart_shift((mpi_world), 0, -1, &junk_rank, &src_rank), (mpi_world), rc); mpi_wrap(MPI_Recv(grid->guest_left, height, MPI_DOUBLE, src_rank, 0, (mpi_world), MPI_STATUS_IGNORE), (mpi_world), rc); } if (grid->mpi_right) { mpi_wrap(MPI_Cart_shift((mpi_world), 0, 1, &junk_rank, &src_rank), (mpi_world), rc); mpi_wrap(MPI_Recv(grid->guest_right, height, MPI_DOUBLE, src_rank, 0, (mpi_world), MPI_STATUS_IGNORE), (mpi_world), rc); } if (grid->mpi_bot) { mpi_wrap(MPI_Cart_shift((mpi_world), 1, -1, &junk_rank, &src_rank), (mpi_world), rc); mpi_wrap(MPI_Recv(grid->guest_bot, width, MPI_DOUBLE, src_rank, 0, (mpi_world), MPI_STATUS_IGNORE), (mpi_world), rc); } if (grid->mpi_top) { mpi_wrap(MPI_Cart_shift((mpi_world), 1, 1, &junk_rank, &src_rank), (mpi_world), rc); mpi_wrap(MPI_Recv(grid->guest_top, width, MPI_DOUBLE, src_rank, 0, (mpi_world), MPI_STATUS_IGNORE), (mpi_world), rc); } } void step_up(struct Grid* grid, double diff) { common_vars; double error = 0; #pragma omp parallel for reduction(+:error) for (int i = 0; i < width; ++i) for (int j = 0; j < height; ++j) { int base_idx = idx(i, j, height); double sub_error = diff * grid->resid[base_idx]; grid->inter[base_idx] = grid->inter[base_idx] - sub_error; error += sub_error * sub_error * (((i > 0) && (i < width_)) ? 1 : 0.5) * (((j > 0) && (j < height_)) ? 1 : 0.5); } grid->error = error; }
yolov2_forward_network_quantized.c	#include "additionally.h" // some definitions from: im2col.h, blas.h, list.h, utils.h, activations.h, tree.h, layer.h, network.h // softmax_layer.h, reorg_layer.h, route_layer.h, region_layer.h, maxpool_layer.h, convolutional_layer.h #define GEMMCONV #define W_MAX_VAL (256/2 - 1) // 7-bit (1-bit sign) #define I_MAX_VAL (256/2 - 1) // 7-bit (1-bit sign) #define R_MAX_VAL (256256/2 - 1) // 31-bit (1-bit sign) #define R_MULT (32) // 4 - 32 / // from: box.h typedef struct { float x, y, w, h; } box; / int max_abs(int src, int max_val) { if (abs(src) > abs(max_val)) src = (src > 0) ? max_val : -max_val; return src; } short int max_abs_short(short int src, short int max_val) { if (abs(src) > abs(max_val)) src = (src > 0) ? max_val : -max_val; return src; } int get_distribution(float arr_ptr, int arr_size, int number_of_ranges, float start_range) { //const int number_of_ranges = 32; //const float start_range = 1.F / 65536; int count = calloc(number_of_ranges, sizeof(int)); float min_val = 10000, max_val = 0; int i, j; for (i = 0; i < arr_size; ++i) { float w = arr_ptr[i]; float cur_range = start_range; for (j = 0; j < number_of_ranges; ++j) { if (fabs(cur_range) <= w && w < fabs(cur_range * 2)) count[j]++;// , printf("found \n"); cur_range = 2; //printf("%f, ", w); } } return count; } float get_multiplier(float arr_ptr, int arr_size, int bits_length) { const int number_of_ranges = 32; const float start_range = 1.F / 65536; int i, j; int count = get_distribution(arr_ptr, arr_size, number_of_ranges, start_range); int max_count_range = 0; int index_max_count = 0; for (j = 0; j < number_of_ranges; ++j) { int counter = 0; for (i = j; i < (j + bits_length) && i < number_of_ranges; ++i) { counter += count[i]; //counter += log2(count[i]); } if (max_count_range < counter) { max_count_range = counter; index_max_count = j; } } //index_max_count = index_max_count + 2; // optimal shift multipler float multiplier = 1 / (start_range powf(2., (float) index_max_count)); //printf(" max_count_range = %d, index_max_count = %d, multiplier = %g \n", // max_count_range, index_max_count, multiplier); free(count); return multiplier; } #ifdef OPENCV #include <opencv2/core/fast_math.hpp> #include "opencv2/highgui/highgui_c.h" #include "opencv2/core/core_c.h" #include "opencv2/core/version.hpp" #define CV_RGB(r, g, b) cvScalar( (b), (g), (r), 0 ) void draw_distribution(float arr_ptr, int arr_size, char name) { int img_w = 1200, img_h = 800; const int number_of_ranges = 32; const float start_range = 1.F / 65536; //int count = calloc(number_of_ranges, sizeof(int)); //float min_val = 100, max_val = 0; int i, j; int count = get_distribution(arr_ptr, arr_size, number_of_ranges, start_range); float multiplier = get_multiplier(arr_ptr, arr_size, 8); int max_count_range = 0; for (j = 0; j < number_of_ranges; ++j) { count[j] = log2(count[j]); if (max_count_range < count[j]) max_count_range = count[j]; } cvNamedWindow("Distribution", CV_WINDOW_NORMAL); cvResizeWindow("Distribution", img_w, img_h); IplImage img = cvCreateImage(cvSize(img_w, img_h), IPL_DEPTH_8U, 3); if (max_count_range > 0) { for (j = 0; j < number_of_ranges; ++j) { //printf("count[j] = %d, max_count_range = %d, img_w = %d, img_h = %d, j = %d, number_of_ranges = %d \n", // count[j], max_count_range, img_w, img_h, j, number_of_ranges); CvPoint pt1, pt2; pt1.x = jimg_w / number_of_ranges; pt2.x = (j + 1)img_w / number_of_ranges; pt1.y = img_h; pt2.y = img_h - img_hcount[j] / max_count_range; //printf("pt1.x = %d, pt1.y = %d, pt2.x = %d, pt2.y = %d \n", pt1.x, pt1.y, pt2.x, pt2.y); //if(pt2.y < pt1.y) cvRectangle(img, pt1, pt2, CV_RGB(128, 64, 32), CV_FILLED, 8, 0); cvRectangle(img, pt1, pt2, CV_RGB(32, 32, 32), 1, 8, 0); } } int index_multiplier = log2(1 / (multiplierstart_range)); int x_coord_multiplier = index_multiplierimg_w / number_of_ranges; cvLine(img, cvPoint(x_coord_multiplier, 0), cvPoint(x_coord_multiplier, img_h), CV_RGB(255, 32, 32), 1, 8, 0); char buff[256]; //sprintf(buff, "[%g - %g]", min_val, max_val); sprintf(buff, "optimal multiplier = %g", multiplier); //printf("[%g - %g]", min_val, max_val); CvFont font; cvInitFont(&font, CV_FONT_HERSHEY_COMPLEX, 1, 1, 0, 2, 8); cvPutText(img, buff, cvPoint(100, 50), &font, CV_RGB(32, 64, 128)); if (name) cvPutText(img, name, cvPoint(0, 20), &font, CV_RGB(32, 64, 128)); float cur_range = start_range; cvInitFont(&font, CV_FONT_HERSHEY_COMPLEX, 0.5, 0.5, 0, 1, 8); for (j = 0; j < number_of_ranges; ++j) { CvPoint pt_text = cvPoint(jimg_w / number_of_ranges, img_h - 50); int lg = log2(cur_range); sprintf(buff, "%d", lg); cvPutText(img, buff, pt_text, &font, CV_RGB(32, 64, 128)); cur_range = 2; } cvPutText(img, "X and Y are log2", cvPoint(img_w / 2 - 100, img_h - 10), &font, CV_RGB(32, 64, 128)); cvShowImage("Distribution", img); cvWaitKey(0); free(count); } #endif // OPENCV // im2col.c int8_t im2col_get_pixel_int8(int8_t im, int height, int width, int channels, int row, int col, int channel, int pad) { row -= pad; col -= pad; if (row < 0 \|\| col < 0 \|\| row >= height \|\| col >= width) return 0; return im[col + width (row + height * channel)]; } // im2col.c //From Berkeley Vision's Caffe! //https://github.com/BVLC/caffe/blob/master/LICENSE void im2col_cpu_int8(int8_t data_im, int channels, int height, int width, int ksize, int stride, int pad, int8_t data_col) { int c, h, w; int height_col = (height + 2 * pad - ksize) / stride + 1; int width_col = (width + 2 * pad - ksize) / stride + 1; int channels_col = channels * ksize * ksize; for (c = 0; c < channels_col; ++c) { int w_offset = c % ksize; int h_offset = (c / ksize) % ksize; int c_im = c / ksize / ksize; for (h = 0; h < height_col; ++h) { for (w = 0; w < width_col; ++w) { int im_row = h_offset + h * stride; int im_col = w_offset + w * stride; int col_index = (c * height_col + h) * width_col + w; data_col[col_index] = im2col_get_pixel_int8(data_im, height, width, channels, im_row, im_col, c_im, pad); } } } } // Use to enable AVX or SSE41 //#define AVX // 1.35 sec (0.8 FPS) 2.3x - GCC -mavx -mavx2 -mfma -ffp-contract=fast //#define SSE41 // 1.55 sec (0.7 FPS) 2x // default 3.10 sec (0.3 FPS) #if defined(AVX) \|\| defined(SSE41) #ifdef _WIN64 #include <intrin.h> #else #include <x86intrin.h> #endif #include <ammintrin.h> #include <immintrin.h> #include <smmintrin.h> #include <emmintrin.h> // https://software.intel.com/sites/landingpage/IntrinsicsGuide/#text=broad&expand=561 #endif // AVX or SSE41 #if defined(AVX) __m256i _mm256_div_epi16(const __m256i va, const int b) { __m256i vb = _mm256_set1_epi16(32768 / b); return _mm256_mulhrs_epi16(va, vb); } #define INTERMEDIATE_MULT 15 // 8 or 15 #define FINAL_MULT (R_MULT / INTERMEDIATE_MULT) // 0.89 sec void gemm_nn_int8_int16_conv16(int M, int N, int K, int8_t ALPHA, int8_t A, int lda, int8_t B, int ldb, int16_t C, int ldc) { __m256i res; __m256i a, b, d; __m128i tmp128; __m256i div256 = _mm256_set1_epi16(INTERMEDIATE_MULT); int16_t c_tmp = calloc(N, sizeof(int16_t)); int i, j, k; for (i = 0; i < M; ++i) { for (k = 0; k < K; ++k) { register int16_t A_PART = ALPHAA[ilda + k]; a = _mm256_set1_epi16(A_PART); for (j = 0; j < N - 32; j += 32) { int index = kldb + j; d = _mm256_loadu_si256((__m256i)&B[index]); tmp128 = _mm256_extractf128_si256(d, 0);// get low 128 bit b = _mm256_cvtepi8_epi16(tmp128); // int8 -> int16 b = _mm256_mullo_epi16(a, b); // B = A * B b = _mm256_div_epi16(b, INTERMEDIATE_MULT); // B = (A * B) / INTERMEDIATE_MULL res = _mm256_loadu_si256(&c_tmp[j]); // load temp C res = _mm256_add_epi16(b, res); // (AB) + C _mm256_storeu_si256(&c_tmp[j], res); // store temp C tmp128 = _mm256_extractf128_si256(d, 1);// get high 128 bit b = _mm256_cvtepi8_epi16(tmp128); // int8 -> int16 (for low 8 bytes) b = _mm256_mullo_epi16(a, b); // B = A B b = _mm256_div_epi16(b, INTERMEDIATE_MULT); // B = (A * B) / INTERMEDIATE_MULL res = _mm256_loadu_si256(&c_tmp[j + 16]); // Load next temp C res = _mm256_add_epi16(b, res); // (AB) + C _mm256_storeu_si256(&c_tmp[j + 16], res); // store temp C //c_tmp[j] += A_PARTB[kldb + j]; //C[ildc + j] += max_abs(A_PARTB[kldb + j] / (INTERMEDIATE_MULL), (256 * 128 - 1)); } int prev_end = (N % 32 == 0) ? (N - 32) : (N / 32) * 32; for (j = prev_end; j < N; ++j) { c_tmp[j] += A_PARTB[kldb + j] / (INTERMEDIATE_MULT); } } for (j = 0; j < N; ++j) { C[ildc + j] += (c_tmp[j] / FINAL_MULT); c_tmp[j] = 0; } } free(c_tmp); } // 1.15 sec void gemm_nn_int8_int16(int M, int N, int K, int8_t ALPHA, int8_t A, int lda, int8_t B, int ldb, int16_t C, int ldc) { __m256i multyplied_i32, res; __m256i a, b, d; __m128i tmp128; int32_t c_tmp = calloc(N, sizeof(int32_t)); int i, j, k; for (i = 0; i < M; ++i) { for (k = 0; k < K; ++k) { register int16_t A_PART = ALPHAA[ilda + k]; a = _mm256_set1_epi16(A_PART); for (j = 0; j < N - 32; j += 32) { int index = kldb + j; d = _mm256_loadu_si256((__m256i)&B[index]); tmp128 = _mm256_extractf128_si256(d, 0);// get low 128 bit b = _mm256_cvtepi8_epi16(tmp128); // int8 -> int16 b = _mm256_mullo_epi16(a, b); // B = A B tmp128 = _mm256_extractf128_si256(b, 0); // get low 128 bit multyplied_i32 = _mm256_cvtepi16_epi32(tmp128); // int16 -> int32 res = _mm256_loadu_si256(&c_tmp[j]); // load temp C res = _mm256_add_epi32(multyplied_i32, res);// (AB) + C _mm256_storeu_si256(&c_tmp[j], res); // store temp C tmp128 = _mm256_extractf128_si256(b, 1); // get high 128 bit multyplied_i32 = _mm256_cvtepi16_epi32(tmp128); // int16 -> int32 res = _mm256_loadu_si256(&c_tmp[j + 8]); // Load next temp C res = _mm256_add_epi32(multyplied_i32, res);// (AB) + C _mm256_storeu_si256(&c_tmp[j + 8], res); // store temp C tmp128 = _mm256_extractf128_si256(d, 1);// get high 128 bit b = _mm256_cvtepi8_epi16(tmp128); // int8 -> int16 (for low 8 bytes) b = _mm256_mullo_epi16(a, b); // B = A * B tmp128 = _mm256_extractf128_si256(b, 0); // get low 128 bit multyplied_i32 = _mm256_cvtepi16_epi32(tmp128); // int16 -> int32 res = _mm256_loadu_si256(&c_tmp[j + 16]); // Load next temp C res = _mm256_add_epi32(multyplied_i32, res);// (AB) + C _mm256_storeu_si256(&c_tmp[j + 16], res); // store temp C tmp128 = _mm256_extractf128_si256(b, 1); // get high 128 bit multyplied_i32 = _mm256_cvtepi16_epi32(tmp128); // int16 -> int32 res = _mm256_loadu_si256(&c_tmp[j + 24]); // Load next temp C res = _mm256_add_epi32(multyplied_i32, res);// (AB) + C _mm256_storeu_si256(&c_tmp[j + 24], res); // store temp C //c_tmp[j] += A_PARTB[kldb + j]; //C[ildc + j] += max_abs(A_PARTB[kldb + j] / (32), (256 128 - 1)); } int prev_end = (N % 32 == 0) ? (N - 32) : (N / 32) * 32; for (j = prev_end; j < N; ++j) { c_tmp[j] += A_PARTB[kldb + j]; } } for (j = 0; j < N; ++j) { C[ildc + j] += max_abs(c_tmp[j] / (R_MULT), (256 128 - 1)); c_tmp[j] = 0; } //for (j = 0; j < N; ++j) C[ildc + j] += c_tmp[j] / (R_MULT); } free(c_tmp); } #elif defined(SSE41) // 1.3 sec void gemm_nn_int8_int16(int M, int N, int K, int8_t ALPHA, int8_t A, int lda, int8_t B, int ldb, int16_t C, int ldc) { __m128i multyplied_i32, res; __m128i a, b, d; //c = _mm_set1_epi16(32); int32_t c_tmp = calloc(N, sizeof(int32_t)); int i, j, k; for (i = 0; i < M; ++i) { for (k = 0; k < K; ++k) { register int16_t A_PART = ALPHAA[ilda + k]; a = _mm_set1_epi16(A_PART); for (j = 0; j < N - 16; j += 16) { int index = kldb + j; d = _mm_loadu_si128((__m128i)&B[index]); b = _mm_cvtepi8_epi16(d); // int8 -> int16 b = _mm_mullo_epi16(a, b); // B = A B multyplied_i32 = _mm_cvtepi16_epi32(b); // int16 -> int32 res = _mm_loadu_si128(&c_tmp[j]); // load temp C res = _mm_add_epi32(multyplied_i32, res);// (AB) + C _mm_store_si128(&c_tmp[j], res); // store temp C b = _mm_srli_si128(b, 8); // Shift Right -> 8 bytes multyplied_i32 = _mm_cvtepi16_epi32(b); // int16 -> int32 res = _mm_loadu_si128(&c_tmp[j + 4]); // Load next temp C res = _mm_add_epi32(multyplied_i32, res);// (AB) + C _mm_store_si128(&c_tmp[j + 4], res); // store temp C d = _mm_srli_si128(d, 8); // Shift Right -> 8 bytes b = _mm_cvtepi8_epi16(d); // int8 -> int16 (for low 8 bytes) b = _mm_mullo_epi16(a, b); // B = A * B multyplied_i32 = _mm_cvtepi16_epi32(b); // int16 -> int32 res = _mm_loadu_si128(&c_tmp[j + 8]); // Load next temp C res = _mm_add_epi32(multyplied_i32, res);// (AB) + C _mm_store_si128(&c_tmp[j + 8], res); // store temp C b = _mm_srli_si128(b, 8); // Shift Right -> 8 bytes multyplied_i32 = _mm_cvtepi16_epi32(b); // int16 -> int32 res = _mm_loadu_si128(&c_tmp[j + 12]); // Load next temp C res = _mm_add_epi32(multyplied_i32, res);// (AB) + C _mm_store_si128(&c_tmp[j + 12], res); // store temp C //c_tmp[j] += A_PARTB[kldb + j]; //C[ildc + j] += max_abs(A_PARTB[kldb + j] / (32), (256 128 - 1)); } int prev_end = (N % 16 == 0) ? (N - 16) : (N / 16) * 16; for (j = prev_end; j < N; ++j) { c_tmp[j] += A_PARTB[kldb + j]; } } for (j = 0; j < N; ++j) { C[ildc + j] += max_abs(c_tmp[j] / (R_MULT), (256 128 - 1)); c_tmp[j] = 0; } //for (j = 0; j < N; ++j) C[ildc + j] += c_tmp[j] / (R_MULT); } free(c_tmp); } void gemm_nn_int8_int16_conv16(int M, int N, int K, int8_t ALPHA, int8_t A, int lda, int8_t B, int ldb, int16_t C, int ldc) { printf(" gemm_nn_int8_int16_conv16() isn't implemented for SSE4.1 \n"); } #else // 2.9 sec void gemm_nn_int8_int16(int M, int N, int K, int8_t ALPHA, int8_t A, int lda, int8_t B, int ldb, int16_t C, int ldc) { int32_t c_tmp = calloc(N, sizeof(int32_t)); int i, j, k; for (i = 0; i < M; ++i) { for (k = 0; k < K; ++k) { register int16_t A_PART = ALPHA * A[i * lda + k]; //#pragma simd parallel for for (j = 0; j < N; ++j) { c_tmp[j] += A_PART * B[k * ldb + j]; //C[ildc + j] += max_abs(A_PARTB[kldb + j] / (R_MULT), (256 128 - 1)); } } for (j = 0; j < N; ++j) { C[i * ldc + j] += max_abs(c_tmp[j] / (R_MULT), (256 * 128 - 1)); c_tmp[j] = 0; } } free(c_tmp); } void gemm_nn_int8_int32(int M, int N, int K, int8_t ALPHA, int8_t A, int lda, int8_t B, int ldb, int32_t C, int ldc) { int32_t c_tmp = calloc(N, sizeof(int32_t)); int i, j, k; for (i = 0; i < M; ++i) { for (k = 0; k < K; ++k) { register int16_t A_PART = ALPHA * A[i * lda + k]; //#pragma simd parallel for for (j = 0; j < N; ++j) { c_tmp[j] += A_PART * B[k * ldb + j]; //C[ildc + j] += max_abs(A_PARTB[kldb + j] / (R_MULT), (256 128 - 1)); } } for (j = 0; j < N; ++j) { C[i * ldc + j] += max_abs(c_tmp[j] / (R_MULT), (256 * 128 - 1)); c_tmp[j] = 0; } } free(c_tmp); } void gemm_nn_int8_int16_conv16(int M, int N, int K, int8_t ALPHA, int8_t A, int lda, int8_t B, int ldb, int16_t C, int ldc) { printf(" gemm_nn_int8_int16_conv16() isn't implemented \n"); } #endif // SSE41 or AVX void forward_convolutional_layer_q(layer l, network_state state) { int out_h = (l.h + 2 l.pad - l.size) / l.stride + 1; // output_height=input_height for stride=1 and pad=1 int out_w = (l.w + 2 * l.pad - l.size) / l.stride + 1; // output_width=input_width for stride=1 and pad=1 int i, f, j; int const out_size = out_h * out_w; size_t const weights_size = l.size * l.size * l.c * l.n; // fill zero (ALPHA) //for (i = 0; i < l.outputs; ++i) l.output[i] = 0; // l.n - number of filters on this layer // l.c - channels of input-array // l.h - height of input-array // l.w - width of input-array // l.size - width and height of filters (the same size for all filters) //draw_distribution(l.weights, weights_size, "weights"); //draw_distribution(state.input, l.inputs, "input"); //typedef int32_t conv_t; // l.output typedef int16_t conv_t; // l.output conv_t output_q = calloc(l.outputs, sizeof(conv_t)); state.input_int8 = (int ) calloc(l.inputs, sizeof(int)); int z; for (z = 0; z < l.inputs; ++z) { //int16_t src = lround(state.input[k] * net.layers[0].input_quant_multipler); int16_t src = state.input[z] * l.input_quant_multipler; state.input_int8[z] = max_abs(src, I_MAX_VAL); } //////////////////////////////////// // cudnnConvolutionBiasActivationForward() // y = act ( alpha1 * conv(x) + alpha2 * z + bias ) // int8 = activation( float * conv(int8) + float * int8 + float ) // int8 = activation( conv(input_int8) + bias_float ) // X_INT8x4 or X_INT8 // https://docs.nvidia.com/deeplearning/sdk/cudnn-developer-guide/index.html#cudnnConvolutionBiasActivationForward /////////////////////////////////// // 1. Convolution !!! int fil; // cuDNN: y = conv(x) int m = l.n; int k = l.size * l.size * l.c; int n = out_h * out_w; int8_t a = l.weights_int8; int8_t b = (int8_t ) state.workspace; conv_t c = output_q; // int16_t // convolution as GEMM (as part of BLAS) //for (i = 0; i < l.batch; ++i) { im2col_cpu_int8(state.input_int8, l.c, l.h, l.w, l.size, l.stride, l.pad, b); // here //gemm_nn_int8_int16(m, n, k, 1, a, k, b, n, c, n); // single-thread gemm int t; // multi-thread gemm #pragma omp parallel for for (t = 0; t < m; ++t) { gemm_nn_int8_int16(1, n, k, 1, a + t * k, k, b, n, c + t * n, n); //gemm_nn_int8_int16_conv16(1, n, k, 1, a + tk, k, b, n, c + tn, n); //gemm_nn_int8_int32(1, n, k, 1, a + tk, k, b, n, c + tn, n); // conv_t should be int32_t } //} free(state.input_int8); float ALPHA1 = R_MULT / (l.input_quant_multipler * l.weights_quant_multipler); // cuDNN: y = alpha1 * conv(x) for (i = 0; i < l.outputs; ++i) { l.output[i] = output_q[i] * ALPHA1; // cuDNN: alpha1 } //for (fil = 0; fil < l.n; ++fil) { // for (j = 0; j < out_size; ++j) { // l.output[filout_size + j] = l.output[filout_size + j] * ALPHA1; // } //} // cuDNN: y = alpha1 * conv(x) + bias for (fil = 0; fil < l.n; ++fil) { for (j = 0; j < out_size; ++j) { l.output[fil * out_size + j] += l.biases[fil]; } } //draw_distribution(l.output, l.outputs, "output"); // cuDNN: y = act ( alpha1 * conv(x) + bias ) // bias is always FLOAT if (l.activation == LEAKY) { for (i = 0; i < l.n * out_size; ++i) { l.output[i] = (l.output[i] > 0) ? l.output[i] : l.output[i] / 10; //leaky_activate(l.output[i]); } } free(output_q); } // 4 layers in 1: convolution, batch-normalization, BIAS and activation void forward_convolutional_layer_q_old(layer l, network_state state, int return_float) { int out_h = (l.h + 2 * l.pad - l.size) / l.stride + 1; // output_height=input_height for stride=1 and pad=1 int out_w = (l.w + 2 * l.pad - l.size) / l.stride + 1; // output_width=input_width for stride=1 and pad=1 int i, f, j; int const out_size = out_h * out_w; size_t const weights_size = l.size * l.size * l.c * l.n; // fill zero (ALPHA) //for (i = 0; i < l.outputs; ++i) l.output[i] = 0; // l.n - number of filters on this layer // l.c - channels of input-array // l.h - height of input-array // l.w - width of input-array // l.size - width and height of filters (the same size for all filters) //draw_distribution(l.weights, weights_size, NULL); //draw_distribution(state.input, l.inputs, NULL); typedef int16_t conv_t; // l.output conv_t output_q = calloc(l.outputs, sizeof(conv_t)); //////////////////////////////////// // cudnnConvolutionBiasActivationForward() // y = act ( alpha1 conv(x) + alpha2 * z + bias ) // int8 = activation( float * conv(int8) + float * int8 + float ) // int8 = activation( conv(input_int8) + bias_float ) // X_INT8x4 or X_INT8 // https://docs.nvidia.com/deeplearning/sdk/cudnn-developer-guide/index.html#cudnnConvolutionBiasActivationForward /////////////////////////////////// // 1. Convolution !!! #ifndef GEMMCONV int fil; // filter index #pragma omp parallel for // "omp parallel for" - automatic parallelization of loop by using OpenMP for (fil = 0; fil < l.n; ++fil) { int chan, y, x, f_y, f_x; // channel index for (chan = 0; chan < l.c; ++chan) // input - y for (y = 0; y < l.h; ++y) // input - x for (x = 0; x < l.w; ++x) { int const output_index = fill.wl.h + yl.w + x; int const weights_pre_index = fill.cl.sizel.size + chanl.sizel.size; int const input_pre_index = chanl.wl.h; //float sum = 0; //int16_t sum = 0; int32_t sum = 0; //conv_t sum = 0; // filter - y for (f_y = 0; f_y < l.size; ++f_y) { int input_y = y + f_y - l.pad; // filter - x for (f_x = 0; f_x < l.size; ++f_x) { int input_x = x + f_x - l.pad; if (input_y < 0 \|\| input_x < 0 \|\| input_y >= l.h \|\| input_x >= l.w) continue; int input_index = input_pre_index + input_yl.w + input_x; int weights_index = weights_pre_index + f_yl.size + f_x; //sum += state.input[input_index] * l.weights[weights_index]; // int16 += int8 * int8; sum += (int32_t)state.input_int8[input_index] * (int32_t)l.weights_int8[weights_index]; } } // l.output[filters][width][height] += // state.input[channels][width][height] * // l.weights[filters][channels][filter_width][filter_height]; //output_q[output_index] += max_abs(sum, R_MAX_VAL); output_q[output_index] += max_abs(sum / R_MULT, R_MAX_VAL); //output_q[output_index] += sum / R_MULT; //if (fabs(output_q[output_index]) > 65535) printf(" fabs(output_q[output_index]) > 65535 \n"); } } #else int fil; // cuDNN: y = conv(x) int m = l.n; int k = l.size * l.size * l.c; int n = out_h * out_w; int8_t a = l.weights_int8; int8_t b = (int8_t ) state.workspace; conv_t c = output_q; // int16_t // convolution as GEMM (as part of BLAS) //for (i = 0; i < l.batch; ++i) { im2col_cpu_int8(state.input_int8, l.c, l.h, l.w, l.size, l.stride, l.pad, b); // here //gemm_nn_int8_int16(m, n, k, 1, a, k, b, n, c, n); // single-thread gemm int t; // multi-thread gemm #pragma omp parallel for for (t = 0; t < m; ++t) { gemm_nn_int8_int16(1, n, k, 1, a + t * k, k, b, n, c + t * n, n); //gemm_nn_int8_int16_conv16(1, n, k, 1, a + tk, k, b, n, c + tn, n); //gemm_nn_int8_int32(1, n, k, 1, a + tk, k, b, n, c + tn, n); conv_t should be int32_t } //} #endif // cuDNN: y = alpha1 * conv(x) //for (i = 0; i < l.outputs; ++i) { // output_q[i] = output_q[i] * l.output_multipler; // cuDNN: alpha1 //} for (fil = 0; fil < l.n; ++fil) { for (j = 0; j < out_size; ++j) { output_q[fil * out_size + j] = output_q[fil * out_size + j] * l.output_multipler; } } // cuDNN: y = alpha1 * conv(x) + bias for (fil = 0; fil < l.n; ++fil) { for (j = 0; j < out_size; ++j) { output_q[fil * out_size + j] += l.biases_quant[fil]; } } //for (i = 0; i < l.inputs; ++i) state.input[i] = state.input_int8[i]; //char buff[1024]; //sprintf(buff, "inputs - filters %d", l.n); //draw_distribution(state.input, l.inputs, buff); //for (i = 0; i < l.outputs; ++i) l.output[i] = (float)output_q[i]; //draw_distribution(l.output, l.outputs, "output"); // cuDNN: y = act ( alpha1 * conv(x) + bias ) // bias is always FLOAT if (l.activation == LEAKY) { for (i = 0; i < l.n * out_size; ++i) { output_q[i] = (output_q[i] > 0) ? output_q[i] : output_q[i] / 10; //leaky_activate(l.output[i]); } } // cuDNN: y = act ( alpha1 * conv(x) + alpha2 * z + bias ), where: alpha2=0, z=NULL if (return_float) { // y - FLOAT, x,w - X_INT8 / X_INT8x4 for (i = 0; i < l.outputs; ++i) { l.output[i] = (float) output_q[i] / 16.F; // /8 // float32 // 15.769 } } else { // y - X_INT8 / X_INT8x4, x,w - X_INT8 / X_INT8x4 for (i = 0; i < l.outputs; ++i) { l.output_int8[i] = max_abs(output_q[i], I_MAX_VAL); // int8 } } free(output_q); } #define MIN_INT8 -128 // MAX pooling layer void forward_maxpool_layer_q(const layer l, network_state state) { int b, i, j, k, m, n; int w_offset = -l.pad; int h_offset = -l.pad; int h = l.out_h; int w = l.out_w; int c = l.c; // batch index for (b = 0; b < l.batch; ++b) { // channel index for (k = 0; k < c; ++k) { // y - input for (i = 0; i < h; ++i) { // x - input for (j = 0; j < w; ++j) { int out_index = j + w * (i + h * (k + c * b)); int8_t max = MIN_INT8; int max_i = -1; // pooling x-index for (n = 0; n < l.size; ++n) { // pooling y-index for (m = 0; m < l.size; ++m) { int cur_h = h_offset + i * l.stride + n; int cur_w = w_offset + j * l.stride + m; int index = cur_w + l.w * (cur_h + l.h * (k + b * l.c)); int valid = (cur_h >= 0 && cur_h < l.h && cur_w >= 0 && cur_w < l.w); int8_t val = (valid != 0) ? state.input_int8[index] : MIN_INT8; max_i = (val > max) ? index : max_i; // get max index max = (val > max) ? val : max; // get max value } } //l.output[out_index] = max; // store max value l.output_int8[out_index] = max; // store max value l.indexes[out_index] = max_i; // store max index } } } } } // Route layer - just copy 1 or more layers into the current layer void forward_route_layer_q(const layer l, network_state state) { int i, j; int offset = 0; // number of merged layers for (i = 0; i < l.n; ++i) { int index = l.input_layers[i]; // source layer index //float input = state.net.layers[index].output; // source layer output ptr int8_t input = state.net.layers[index].output_int8; // source layer output ptr int input_size = l.input_sizes[i]; // source layer size // batch index for (j = 0; j < l.batch; ++j) { memcpy(l.output_int8 + offset + j * l.outputs, input + j * input_size, input_size * sizeof(int8_t)); } offset += input_size; } } // Reorg layer - just change dimension sizes of the previous layer (some dimension sizes are increased by decreasing other) void forward_reorg_layer_q(const layer l, network_state state) { //float out = l.output; //float x = state.input; int8_t out = l.output_int8; int8_t x = state.input_int8; int out_w = l.out_w; int out_h = l.out_h; int out_c = l.out_c; int batch = l.batch; int stride = l.stride; int b, i, j, k; int in_c = out_c / (stride * stride); int out_w_X_stride = out_w * stride; int out_h_X_stride = out_h * stride; //printf("\n out_c = %d, out_w = %d, out_h = %d, stride = %d, forward = %d \n", out_c, out_w, out_h, stride, forward); //printf(" in_c = %d, in_w = %d, in_h = %d \n", in_c, out_wstride, out_hstride); // batch for (b = 0; b < batch; ++b) { // channel for (k = 0; k < out_c; ++k) { int c2 = k % in_c; int pre_out_index = out_h_X_stride * (c2 + in_c * b); int offset = k / in_c; int offset_mod_stride = offset % stride; int offset_div_stride = offset / stride; // y for (j = 0; j < out_h; ++j) { int pre_in_index = out_w * (j + out_h * (k + out_c * b)); // x for (i = 0; i < out_w; ++i) { int in_index = i + pre_in_index; int w2 = i * stride + offset_mod_stride; int h2 = j * stride + offset_div_stride; int out_index = w2 + out_w_X_stride * (h2 + pre_out_index); out[in_index] = x[out_index]; } } } } } // ---- region layer ---- static void softmax_q(float input, int n, float temp, float output) { int i; float sum = 0; float largest = -FLT_MAX; for (i = 0; i < n; ++i) { if (input[i] > largest) largest = input[i]; } for (i = 0; i < n; ++i) { float e = expf(input[i] / temp - largest / temp); sum += e; output[i] = e; } for (i = 0; i < n; ++i) { output[i] /= sum; } } static void softmax_tree(float input, int batch, int inputs, float temp, tree hierarchy, float output) { int b; for (b = 0; b < batch; ++b) { int i; int count = 0; for (i = 0; i < hierarchy->groups; ++i) { int group_size = hierarchy->group_size[i]; softmax_q(input + b inputs + count, group_size, temp, output + b * inputs + count); count += group_size; } } } // --- // Region layer - just change places of array items, then do logistic_activate and softmax void forward_region_layer_q(const layer l, network_state state) { int i, b; int size = l.coords + l.classes + 1; // 4 Coords(x,y,w,h) + Classes + 1 Probability-t0 //printf("\n l.coords = %d \n", l.coords); memcpy(l.output, state.input, l.outputs * l.batch * sizeof(float)); //flatten(l.output, l.wl.h, sizel.n, l.batch, 1); // convert many channels to the one channel (depth=1) // (each grid cell will have a number of float-variables equal = to the initial number of channels) { float x = l.output; int layer_size = l.w l.h; // W x H - size of layer int layers = size * l.n; // number of channels (where l.n = number of anchors) int batch = l.batch; float swap = calloc(layer_size layers * batch, sizeof(float)); int i, c, b; // batch index for (b = 0; b < batch; ++b) { // channel index for (c = 0; c < layers; ++c) { // layer grid index for (i = 0; i < layer_size; ++i) { int i1 = b * layers * layer_size + c * layer_size + i; int i2 = b * layers * layer_size + i * layers + c; swap[i2] = x[i1]; } } } memcpy(x, swap, layer_size * layers * batch * sizeof(float)); free(swap); } // logistic activation only for: t0 (where is t0 = Probability * IoU(box, object)) for (b = 0; b < l.batch; ++b) { // for each item (x, y, anchor-index) for (i = 0; i < l.h * l.w * l.n; ++i) { int index = size * i + b * l.outputs; float x = l.output[index + 4]; l.output[index + 4] = 1.0F / (1.0F + expf(-x)); // logistic_activate_q(l.output[index + 4]); } } if (l.softmax_tree) { // Yolo 9000 for (b = 0; b < l.batch; ++b) { for (i = 0; i < l.h * l.w * l.n; ++i) { int index = size * i + b * l.outputs; softmax_tree(l.output + index + 5, 1, 0, 1, l.softmax_tree, l.output + index + 5); } } } else if (l.softmax) { // Yolo v2 // softmax activation only for Classes probability for (b = 0; b < l.batch; ++b) { // for each item (x, y, anchor-index) //#pragma omp parallel for for (i = 0; i < l.h * l.w * l.n; ++i) { int index = size * i + b * l.outputs; softmax_q(l.output + index + 5, l.classes, 1, l.output + index + 5); } } } } void yolov2_forward_network_q(network net, network_state state) { state.workspace = net.workspace; int i, k; for (i = 0; i < net.n; ++i) { state.index = i; layer l = net.layers[i]; if (l.type == CONVOLUTIONAL) { if (i >= 1 && l.activation != LINEAR) forward_convolutional_layer_q(l, state); else forward_convolutional_layer_cpu(l, state); printf("\n %d - CONVOLUTIONAL \t\t l.size = %d \n", i, l.size); } else if (l.type == MAXPOOL) { forward_maxpool_layer_cpu(l, state); //printf("\n MAXPOOL \t\t l.size = %d \n", l.size); } else if (l.type == ROUTE) { forward_route_layer_cpu(l, state); //printf("\n ROUTE \t\t\t l.n = %d \n", l.n); } else if (l.type == REORG) { forward_reorg_layer_cpu(l, state); //printf("\n REORG \n"); } else if (l.type == UPSAMPLE) { forward_upsample_layer_cpu(l, state); //printf("\n UPSAMPLE \n"); } else if (l.type == SHORTCUT) { forward_shortcut_layer_cpu(l, state); //printf("\n SHORTCUT \n"); } else if (l.type == YOLO) { forward_yolo_layer_cpu(l, state); //printf("\n YOLO \n"); } else if (l.type == REGION) { forward_region_layer_cpu(l, state); //printf("\n REGION \n"); } else { printf("\n layer: %d \n", l.type); } state.input = l.output; //state.input_int8 = l.output_int8; /* if (i == 0) { //draw_distribution(state.input, l.outputs, NULL); int k; for (k = 0; k < l.out_wl.out_hl.out_c; ++k) { int16_t src = state.input[k] * 3.88677;// net.layers[2].input_quant_multipler; state.input_int8[k] = max_abs(src, I_MAX_VAL); //printf(" %d, ", src); } } / } } void yolov2_forward_network_q_old(network net, network_state state) { state.workspace = net.workspace; int i, k; for (i = 0; i < net.n; ++i) { state.index = i; layer l = net.layers[i]; if (l.type == CONVOLUTIONAL) { int return_float = (net.layers[i + 1].activation == LINEAR); // if next layer has LINEAR activation if (i >= 1 && l.activation != LINEAR) forward_convolutional_layer_q_old(l, state, return_float); else forward_convolutional_layer_cpu(l, state); printf("\n %d - CONVOLUTIONAL \t\t l.size = %d \n", i, l.size); } else if (l.type == MAXPOOL) { forward_maxpool_layer_q(l, state); //printf("\n MAXPOOL \t\t l.size = %d \n", l.size); } else if (l.type == ROUTE) { forward_route_layer_q(l, state); //printf("\n ROUTE \t\t\t l.n = %d \n", l.n); } else if (l.type == REORG) { forward_reorg_layer_q(l, state); //printf("\n REORG \n"); } /* else if (l.type == UPSAMPLE) { forward_upsample_layer_cpu(l, state); //printf("\n UPSAMPLE \n"); } else if (l.type == SHORTCUT) { forward_shortcut_layer_cpu(l, state); //printf("\n SHORTCUT \n"); } else if (l.type == YOLO) { forward_yolo_layer_cpu(l, state); //printf("\n YOLO \n"); } / else if (l.type == REGION) { forward_region_layer_q(l, state); //printf("\n REGION \n"); } else { printf("\n layer: %d \n", l.type); } state.input = l.output; state.input_int8 = l.output_int8; if (i == 0) { //draw_distribution(state.input, l.outputs, NULL); int k; for (k = 0; k < l.out_w l.out_h * l.out_c; ++k) { int16_t src = state.input[k] * 3.88677;// net.layers[2].input_quant_multipler; state.input_int8[k] = max_abs(src, I_MAX_VAL); //printf(" %d, ", src); } } } } // detect on CPU float network_predict_quantized(network net, float input) { network_state state; state.net = net; state.index = 0; state.input = input; //state.input_int8 = calloc(net.wnet.hnet.c, sizeof(int8_t)); state.truth = 0; state.train = 0; state.delta = 0; // int k; for (k = 0; k < net.wnet.hnet.c; ++k) { //int16_t src = lround(state.input[k] * net.layers[0].input_quant_multipler); int16_t src = state.input[k] * net.layers[0].input_quant_multipler; state.input_int8[k] = max_abs(src, I_MAX_VAL); } / yolov2_forward_network_q(net, state); // network on CPU //float out = get_network_output(net); int i; for (i = net.n - 1; i > 0; --i) if (net.layers[i].type != COST) break; //free(state.input_int8); return net.layers[i].output; } // detect on CPU float network_predict_quantized_old(network net, float input) { network_state state; state.net = net; state.index = 0; state.input = input; state.input_int8 = calloc(net.w * net.h * net.c, sizeof(int8_t)); state.truth = 0; state.train = 0; state.delta = 0; int k; for (k = 0; k < net.w * net.h * net.c; ++k) { //int16_t src = lround(state.input[k] * net.layers[0].input_quant_multipler); int16_t src = state.input[k] * net.layers[0].input_quant_multipler; state.input_int8[k] = max_abs(src, I_MAX_VAL); } yolov2_forward_network_q_old(net, state); // network on CPU //float out = get_network_output(net); int i; for (i = net.n - 1; i > 0; --i) if (net.layers[i].type != COST) break; free(state.input_int8); return net.layers[i].output; } // -------------------- // x - last conv-layer output // biases - anchors from cfg-file // n - number of anchors from cfg-file box get_region_box_q(float x, float biases, int n, int index, int i, int j, int w, int h) { box b; b.x = (i + logistic_activate(x[index + 0])) / w; // (col + 1./(1. + exp(-x))) / width_last_layer b.y = (j + logistic_activate(x[index + 1])) / h; // (row + 1./(1. + exp(-x))) / height_last_layer b.w = expf(x[index + 2]) biases[2 * n] / w; // exp(x) * anchor_w / width_last_layer b.h = expf(x[index + 3]) * biases[2 * n + 1] / h; // exp(x) * anchor_h / height_last_layer return b; } // get prediction boxes void get_region_boxes_q(layer l, int w, int h, float thresh, float *probs, box boxes, int only_objectness, int map) { int i, j, n; float predictions = l.output; // grid index for (i = 0; i < l.w * l.h; ++i) { int row = i / l.w; int col = i % l.w; // anchor index for (n = 0; n < l.n; ++n) { int index = i * l.n + n; // index for each grid-cell & anchor int p_index = index * (l.classes + 5) + 4; float scale = predictions[p_index]; // scale = t0 = Probability * IoU(box, object) if (l.classfix == -1 && scale < .5) scale = 0; // if(t0 < 0.5) t0 = 0; int box_index = index * (l.classes + 5); boxes[index] = get_region_box_q(predictions, l.biases, n, box_index, col, row, l.w, l.h); boxes[index].x = w; boxes[index].y = h; boxes[index].w = w; boxes[index].h = h; int class_index = index * (l.classes + 5) + 5; // Yolo 9000 or Yolo v2 if (l.softmax_tree) { // Yolo 9000 hierarchy_predictions(predictions + class_index, l.classes, l.softmax_tree, 0); int found = 0; if (map) { for (j = 0; j < 200; ++j) { float prob = scale * predictions[class_index + map[j]]; probs[index][j] = (prob > thresh) ? prob : 0; } } else { for (j = l.classes - 1; j >= 0; --j) { if (!found && predictions[class_index + j] > .5) { found = 1; } else { predictions[class_index + j] = 0; } float prob = predictions[class_index + j]; probs[index][j] = (scale > thresh) ? prob : 0; } } } else { // Yolo v2 for (j = 0; j < l.classes; ++j) { float prob = scale * predictions[class_index + j]; // prob = IoU(box, object) = t0 * class-probability probs[index][j] = (prob > thresh) ? prob : 0; // if (IoU < threshold) IoU = 0; } } if (only_objectness) { probs[index][0] = scale; } } } } float entropy_calibration(float src_arr, const size_t size, const float bin_width, const int max_bin) { //const float bin_width = 1.0 / 4096;// 1.0F / 64.0F; //const int max_bin = 20482;// 2048; const int max_global_val = max_bin * bin_width; // 1024 // 32 float m_array = (float ) calloc(max_bin, sizeof(float)); float H_histogram = (float ) calloc(max_bin, sizeof(float)); float P_array = (float ) calloc(max_bin, sizeof(float)); float Q_array = (float ) calloc(max_bin, sizeof(float)); float quant_Q_array = (float ) calloc(128, sizeof(float)); // 128 for INT8 uint64_t quant_Q_array_count = (uint64_t ) calloc(128, sizeof(uint64_t)); // 128 for INT8 int i, j; { //uint64_t outliers = 0; const int last_bin = max_bin - 1; for (j = 0; j <= last_bin; ++j) P_array[j] = 0; for (j = 0; j < size; ++j) { int bin_num = lround(fabs(src_arr[j]) / bin_width); int bin_num_saturated = (bin_num >= last_bin) ? last_bin : bin_num; H_histogram[bin_num_saturated]++; //if (bin_num > last_bin) outliers++; //else H_histogram[bin_num]++; } } for (i = 128; i < max_bin; ++i) { // [1/64; 1024] // [1/64; 32] //if (i > max_bin) printf(" i > max_bin = %d, ", i); //printf(" %d \r", i); // calculate bin histogram uint64_t outliers = 0; const int last_bin = i - 1; for (j = 0; j <= last_bin; ++j) P_array[j] = 0; /for (j = 0; j < size; ++j) { int bin_num = lround(fabs(src_arr[j]) / bin_width); //int bin_num_saturated = (bin_num >= last_bin) ? last_bin : bin_num; if (bin_num > last_bin) outliers++; else P_array[bin_num]++; }/ for (j = 0; j < max_bin; ++j) { if (j <= last_bin) P_array[j] = H_histogram[j]; else outliers += H_histogram[j]; } // quantinization P-i-bins to Q-128-bins const float quant_expand_width = i / 128.0F; for (j = 0; j < 128; ++j) quant_Q_array[j] = 0, quant_Q_array_count[j] = 0; for (j = 0; j < i; ++j) { int quant_bin = lround(j / quant_expand_width); if (quant_bin > 127) quant_bin = 127; // printf(" quant_bin > 127 = %d \n", quant_bin); quant_Q_array[quant_bin] += P_array[j]; if (P_array[j] != 0) quant_Q_array_count[quant_bin]++; } // expand 128-bins to i-bins for (j = 0; j < i; ++j) Q_array[j] = 0; for (j = 0; j < i; ++j) { int quant_bin = lround(j / quant_expand_width); if (quant_bin > 127) quant_bin = 127;// printf(" quant_bin > 127 = %d \n", quant_bin); //Q_array[j] = llround(quant_Q_array[quant_bin] / quant_expand_width); if (P_array[j] != 0) // preserve empty bins from original P Q_array[j] = quant_Q_array[quant_bin] / quant_Q_array_count[quant_bin]; //printf(" quant_bin = %d, Q[j] = %f = q_Q %f / q_w %f, P = %f \n", quant_bin, Q_array[j], quant_Q_array[quant_bin], quant_expand_width, P_array[j]); } P_array[last_bin] += outliers; // saturation // P /= SUM(P); Q /= SUM(Q); float sum_P = 0, sum_Q = 0, quant_sum_Q = 0; for (j = 0; j < 128; ++j) quant_sum_Q += quant_Q_array[j]; for (j = 0; j < i; ++j) { sum_P += P_array[j]; sum_Q += Q_array[j]; //printf(" P_array = %f, Q_array = %f \n", P_array[j], Q_array[j]); } for (j = 0; j < i; ++j) { P_array[j] /= sum_P; Q_array[j] /= sum_Q; } // KL_divergence(P, Q); for (j = 0; j < i; ++j) { m_array[i] += P_array[j] * (log((P_array[j] + FLT_MIN) / (Q_array[j] + FLT_MIN))); //printf(" p = %f, q = %f, p/q = %f, log(p/q) = %f, m = %f \n", P_array[j], Q_array[j], P_array[j] / Q_array[j], log((P_array[j] + FLT_MIN) / (Q_array[j] + FLT_MIN)), m_array[i]); } //printf("\n i = %d, size = %zu, sum_P = %f, sum_Q = %f, q_sum_Q = %f, q_e_width = %f, m = %f \n", i, size, sum_P, sum_Q, quant_sum_Q, quant_expand_width, m_array[i]); //getchar(); } float m_index = 128, min_m = FLT_MAX; for (i = 128; i < max_bin; ++i) { if (m_array[i] < min_m) { min_m = m_array[i]; m_index = i; } } float threshold = (m_index + 0.5) * bin_width; float multiplier = 127 / threshold; printf(" mult = %g, threshold = %g, min_m = %g, m_index = %g \n", multiplier, threshold, min_m, m_index); free(H_histogram); free(P_array); free(Q_array); free(quant_Q_array); free(quant_Q_array_count); free(m_array); //getchar(); return multiplier; } // Quantinization and get multiplers for convolutional weights for quantinization void quantinization_and_get_multipliers(network net) { // ----------- entropy_calibration(,, 1.0 / 16, 4096); - FULL ---------------------- //float input_mult[] = { 256, 4,32,64,32,32,32,32,32,64,64,64,64,64,128,64,128,128,64,128,64,128,128 }; // divided 4 - full works int counter = 0; //const int input_mult_size = sizeof(input_mult) / sizeof(float); int j; for (j = 0; j < net.n; ++j) { layer l = &net.layers[j]; if (l->type == CONVOLUTIONAL) { size_t const weights_size = l->size l->size * l->c * l->n; size_t const filter_size = l->size * l->size * l->c; int i, k, fil; // get optimal multipliers - for Weights //float weights_multiplier = (float )calloc(l->n, sizeof(float)); //l->output_multipler = (float )calloc(l->n, sizeof(float)); //float weights_multiplier_single = entropy_calibration(l->weights, weights_size, 1.0 / (2048), (2048)); //float weights_multiplier_single = entropy_calibration(l->weights, weights_size, 1.0 / 4096, 4096) / 2; //if (j == 0) weights_multiplier_single = entropy_calibration(l->weights, weights_size, 1.0 / 2, 2048); float old_weight_mult = get_multiplier(l->weights, weights_size, 8) / 4; // good [2 - 8], best 4 float weights_multiplier_single = old_weight_mult; //float old_weight_mult = get_multiplier(l->weights, weights_size, 7) / 4; printf(" old_weight_mult = %f, weights_multiplier_single = %f \n\n", old_weight_mult, weights_multiplier_single); //weights_multiplier_single = old_weight_mult; l->weights_quant_multipler = weights_multiplier_single; for (fil = 0; fil < l->n; ++fil) { for (i = 0; i < filter_size; ++i) { float w = l->weights[fil filter_size + i] * l->weights_quant_multipler;// [fil]; l->weights_int8[fil * filter_size + i] = max_abs(w, W_MAX_VAL); //l->weights_int8[filfilter_size + i] = max_abs(lround(w), W_MAX_VAL); } } if (counter >= net.input_calibration_size) { printf("\n Warning: input_calibration= in the cfg-file has less values %d than convolutional layers %d \n", net.input_calibration_size, counter); } //l->input_quant_multipler = 40;//(counter < net.input_calibration_size) ? net.input_calibration[counter] : 16; // best 40 l->input_quant_multipler = (counter < net.input_calibration_size) ? net.input_calibration[counter] : 40; ++counter; //float current_input_mult = 40;//(counter < net.input_calibration_size) ? net.input_calibration[counter] : 16; float current_input_mult = (counter < net.input_calibration_size) ? net.input_calibration[counter] : 40; for (fil = 0; fil < l->n; ++fil) { if (counter == 1) l->output_multipler = current_input_mult / (l->weights_quant_multipler l->input_quant_multipler / R_MULT); if (counter == 2) l->output_multipler = current_input_mult / (l->weights_quant_multipler * l->input_quant_multipler / R_MULT); else if (counter >= 2) l->output_multipler = current_input_mult / (l->weights_quant_multipler * l->input_quant_multipler / R_MULT); } // quantinization Biases for (fil = 0; fil < l->n; ++fil) { // calculate optimal multipliers - for Biases float biases_multipler = (l->output_multipler * l->weights_quant_multipler * l->input_quant_multipler / R_MULT); l->biases_quant[fil] = l->biases[fil] * biases_multipler; } printf(" Multiplers: weights %g, input %g, output %g \n", l->weights_quant_multipler, l->input_quant_multipler, l->output_multipler); } else { printf(" Skip layer: %d \n", l->type); } } #ifdef GPU // init weights and cuDNN for quantized IINT8x4 init_gpu_int8x4(net); #endif //GPU }
effect.c	/* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % EEEEE FFFFF FFFFF EEEEE CCCC TTTTT % % E F F E C T % % EEE FFF FFF EEE C T % % E F F E C T % % EEEEE F F EEEEE CCCC T % % % % % % MagickCore Image Effects Methods % % % % Software Design % % Cristy % % October 1996 % % % % % % Copyright 1999-2019 ImageMagick Studio LLC, a non-profit organization % % dedicated to making software imaging solutions freely available. % % % % You may not use this file except in compliance with the License. You may % % obtain a copy of the License at % % % % https://imagemagick.org/script/license.php % % % % Unless required by applicable law or agreed to in writing, software % % distributed under the License is distributed on an "AS IS" BASIS, % % WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. % % See the License for the specific language governing permissions and % % limitations under the License. % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % / / Include declarations. / #include "magick/studio.h" #include "magick/accelerate-private.h" #include "magick/blob.h" #include "magick/cache-view.h" #include "magick/color.h" #include "magick/color-private.h" #include "magick/colorspace.h" #include "magick/constitute.h" #include "magick/decorate.h" #include "magick/distort.h" #include "magick/draw.h" #include "magick/enhance.h" #include "magick/exception.h" #include "magick/exception-private.h" #include "magick/effect.h" #include "magick/fx.h" #include "magick/gem.h" #include "magick/geometry.h" #include "magick/image-private.h" #include "magick/list.h" #include "magick/log.h" #include "magick/matrix.h" #include "magick/memory_.h" #include "magick/memory-private.h" #include "magick/monitor.h" #include "magick/monitor-private.h" #include "magick/montage.h" #include "magick/morphology.h" #include "magick/morphology-private.h" #include "magick/opencl-private.h" #include "magick/paint.h" #include "magick/pixel-accessor.h" #include "magick/pixel-private.h" #include "magick/property.h" #include "magick/quantize.h" #include "magick/quantum.h" #include "magick/random_.h" #include "magick/random-private.h" #include "magick/resample.h" #include "magick/resample-private.h" #include "magick/resize.h" #include "magick/resource_.h" #include "magick/segment.h" #include "magick/shear.h" #include "magick/signature-private.h" #include "magick/statistic.h" #include "magick/string_.h" #include "magick/thread-private.h" #include "magick/transform.h" #include "magick/threshold.h" #ifdef MAGICKCORE_CLPERFMARKER #include "CLPerfMarker.h" #endif / %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % A d a p t i v e B l u r I m a g e % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % AdaptiveBlurImage() adaptively blurs the image by blurring less % intensely near image edges and more intensely far from edges. We blur the % image with a Gaussian operator of the given radius and standard deviation % (sigma). For reasonable results, radius should be larger than sigma. Use a % radius of 0 and AdaptiveBlurImage() selects a suitable radius for you. % % The format of the AdaptiveBlurImage method is: % % Image AdaptiveBlurImage(const Image image,const double radius, % const double sigma,ExceptionInfo exception) % Image AdaptiveBlurImageChannel(const Image image, % const ChannelType channel,double radius,const double sigma, % ExceptionInfo exception) % % A description of each parameter follows: % % o image: the image. % % o channel: the channel type. % % o radius: the radius of the Gaussian, in pixels, not counting the center % pixel. % % o sigma: the standard deviation of the Laplacian, in pixels. % % o exception: return any errors or warnings in this structure. % / MagickExport Image AdaptiveBlurImage(const Image image,const double radius, const double sigma,ExceptionInfo exception) { Image blur_image; blur_image=AdaptiveBlurImageChannel(image,DefaultChannels,radius,sigma, exception); return(blur_image); } MagickExport Image AdaptiveBlurImageChannel(const Image image, const ChannelType channel,const double radius,const double sigma, ExceptionInfo exception) { #define AdaptiveBlurImageTag "Convolve/Image" #define MagickSigma (fabs(sigma) < MagickEpsilon ? MagickEpsilon : sigma) CacheView blur_view, edge_view, image_view; double kernel, normalize; Image blur_image, edge_image, gaussian_image; MagickBooleanType status; MagickOffsetType progress; MagickPixelPacket bias; register ssize_t i; size_t width; ssize_t j, k, u, v, y; assert(image != (const Image ) NULL); assert(image->signature == MagickCoreSignature); if (image->debug != MagickFalse) (void) LogMagickEvent(TraceEvent,GetMagickModule(),"%s",image->filename); assert(exception != (ExceptionInfo ) NULL); assert(exception->signature == MagickCoreSignature); blur_image=CloneImage(image,0,0,MagickTrue,exception); if (blur_image == (Image ) NULL) return((Image ) NULL); if (fabs(sigma) <= MagickEpsilon) return(blur_image); if (SetImageStorageClass(blur_image,DirectClass) == MagickFalse) { InheritException(exception,&blur_image->exception); blur_image=DestroyImage(blur_image); return((Image ) NULL); } / Edge detect the image brighness channel, level, blur, and level again. / edge_image=EdgeImage(image,radius,exception); if (edge_image == (Image ) NULL) { blur_image=DestroyImage(blur_image); return((Image ) NULL); } (void) AutoLevelImage(edge_image); gaussian_image=BlurImage(edge_image,radius,sigma,exception); if (gaussian_image != (Image ) NULL) { edge_image=DestroyImage(edge_image); edge_image=gaussian_image; } (void) AutoLevelImage(edge_image); /* Create a set of kernels from maximum (radius,sigma) to minimum. / width=GetOptimalKernelWidth2D(radius,sigma); kernel=(double ) MagickAssumeAligned(AcquireAlignedMemory((size_t) width, sizeof(kernel))); if (kernel == (double *) NULL) { edge_image=DestroyImage(edge_image); blur_image=DestroyImage(blur_image); ThrowImageException(ResourceLimitError,"MemoryAllocationFailed"); } (void) memset(kernel,0,(size_t) widthsizeof(kernel)); for (i=0; i < (ssize_t) width; i+=2) { kernel[i]=(double ) MagickAssumeAligned(AcquireAlignedMemory((size_t) (width-i),(width-i)sizeof(kernel))); if (kernel[i] == (double ) NULL) break; normalize=0.0; j=(ssize_t) (width-i-1)/2; k=0; for (v=(-j); v <= j; v++) { for (u=(-j); u <= j; u++) { kernel[i][k]=(double) (exp(-((double) uu+vv)/(2.0MagickSigma MagickSigma))/(2.0MagickPIMagickSigmaMagickSigma)); normalize+=kernel[i][k]; k++; } } kernel[i][(k-1)/2]+=(1.0-normalize); if (sigma < MagickEpsilon) kernel[i][(k-1)/2]=1.0; } if (i < (ssize_t) width) { for (i-=2; i >= 0; i-=2) kernel[i]=(double ) RelinquishAlignedMemory(kernel[i]); kernel=(double *) RelinquishAlignedMemory(kernel); edge_image=DestroyImage(edge_image); blur_image=DestroyImage(blur_image); ThrowImageException(ResourceLimitError,"MemoryAllocationFailed"); } / Adaptively blur image. / status=MagickTrue; progress=0; GetMagickPixelPacket(image,&bias); SetMagickPixelPacketBias(image,&bias); image_view=AcquireVirtualCacheView(image,exception); edge_view=AcquireVirtualCacheView(edge_image,exception); blur_view=AcquireAuthenticCacheView(blur_image,exception); #if defined(MAGICKCORE_OPENMP_SUPPORT) #pragma omp parallel for schedule(static) shared(progress,status) \ magick_number_threads(image,blur_image,blur_image->rows,1) #endif for (y=0; y < (ssize_t) blur_image->rows; y++) { register const IndexPacket magick_restrict indexes; register const PixelPacket magick_restrict p, magick_restrict r; register IndexPacket magick_restrict blur_indexes; register PixelPacket magick_restrict q; register ssize_t x; if (status == MagickFalse) continue; r=GetCacheViewVirtualPixels(edge_view,0,y,edge_image->columns,1,exception); q=QueueCacheViewAuthenticPixels(blur_view,0,y,blur_image->columns,1, exception); if ((r == (const PixelPacket ) NULL) \|\| (q == (PixelPacket ) NULL)) { status=MagickFalse; continue; } blur_indexes=GetCacheViewAuthenticIndexQueue(blur_view); for (x=0; x < (ssize_t) blur_image->columns; x++) { double alpha, gamma; DoublePixelPacket pixel; register const double magick_restrict k; register ssize_t i, u, v; gamma=0.0; i=(ssize_t) ceil((double) widthQuantumScale* GetPixelIntensity(edge_image,r)-0.5); if (i < 0) i=0; else if (i > (ssize_t) width) i=(ssize_t) width; if ((i & 0x01) != 0) i--; p=GetCacheViewVirtualPixels(image_view,x-((ssize_t) (width-i)/2L),y- (ssize_t) ((width-i)/2L),width-i,width-i,exception); if (p == (const PixelPacket ) NULL) break; indexes=GetCacheViewVirtualIndexQueue(image_view); pixel.red=bias.red; pixel.green=bias.green; pixel.blue=bias.blue; pixel.opacity=bias.opacity; pixel.index=bias.index; k=kernel[i]; for (v=0; v < (ssize_t) (width-i); v++) { for (u=0; u < (ssize_t) (width-i); u++) { alpha=1.0; if (((channel & OpacityChannel) != 0) && (image->matte != MagickFalse)) alpha=(MagickRealType) (QuantumScaleGetPixelAlpha(p)); if ((channel & RedChannel) != 0) pixel.red+=(k)alphaGetPixelRed(p); if ((channel & GreenChannel) != 0) pixel.green+=(k)alphaGetPixelGreen(p); if ((channel & BlueChannel) != 0) pixel.blue+=(k)alphaGetPixelBlue(p); if ((channel & OpacityChannel) != 0) pixel.opacity+=(k)GetPixelOpacity(p); if (((channel & IndexChannel) != 0) && (image->colorspace == CMYKColorspace)) pixel.index+=(k)alphaGetPixelIndex(indexes+x+(width-i)v+u); gamma+=(k)alpha; k++; p++; } } gamma=PerceptibleReciprocal(gamma); if ((channel & RedChannel) != 0) SetPixelRed(q,ClampToQuantum(gammapixel.red)); if ((channel & GreenChannel) != 0) SetPixelGreen(q,ClampToQuantum(gammapixel.green)); if ((channel & BlueChannel) != 0) SetPixelBlue(q,ClampToQuantum(gammapixel.blue)); if ((channel & OpacityChannel) != 0) SetPixelOpacity(q,ClampToQuantum(pixel.opacity)); if (((channel & IndexChannel) != 0) && (image->colorspace == CMYKColorspace)) SetPixelIndex(blur_indexes+x,ClampToQuantum(gammapixel.index)); q++; r++; } if (SyncCacheViewAuthenticPixels(blur_view,exception) == MagickFalse) status=MagickFalse; if (image->progress_monitor != (MagickProgressMonitor) NULL) { MagickBooleanType proceed; #if defined(MAGICKCORE_OPENMP_SUPPORT) #pragma omp atomic #endif progress++; proceed=SetImageProgress(image,AdaptiveBlurImageTag,progress, image->rows); if (proceed == MagickFalse) status=MagickFalse; } } blur_image->type=image->type; blur_view=DestroyCacheView(blur_view); edge_view=DestroyCacheView(edge_view); image_view=DestroyCacheView(image_view); edge_image=DestroyImage(edge_image); for (i=0; i < (ssize_t) width; i+=2) kernel[i]=(double ) RelinquishAlignedMemory(kernel[i]); kernel=(double *) RelinquishAlignedMemory(kernel); if (status == MagickFalse) blur_image=DestroyImage(blur_image); return(blur_image); } / %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % A d a p t i v e S h a r p e n I m a g e % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % AdaptiveSharpenImage() adaptively sharpens the image by sharpening more % intensely near image edges and less intensely far from edges. We sharpen the % image with a Gaussian operator of the given radius and standard deviation % (sigma). For reasonable results, radius should be larger than sigma. Use a % radius of 0 and AdaptiveSharpenImage() selects a suitable radius for you. % % The format of the AdaptiveSharpenImage method is: % % Image AdaptiveSharpenImage(const Image image,const double radius, % const double sigma,ExceptionInfo exception) % Image AdaptiveSharpenImageChannel(const Image image, % const ChannelType channel,double radius,const double sigma, % ExceptionInfo exception) % % A description of each parameter follows: % % o image: the image. % % o channel: the channel type. % % o radius: the radius of the Gaussian, in pixels, not counting the center % pixel. % % o sigma: the standard deviation of the Laplacian, in pixels. % % o exception: return any errors or warnings in this structure. % / MagickExport Image AdaptiveSharpenImage(const Image image,const double radius, const double sigma,ExceptionInfo exception) { Image sharp_image; sharp_image=AdaptiveSharpenImageChannel(image,DefaultChannels,radius,sigma, exception); return(sharp_image); } MagickExport Image AdaptiveSharpenImageChannel(const Image image, const ChannelType channel,const double radius,const double sigma, ExceptionInfo exception) { #define AdaptiveSharpenImageTag "Convolve/Image" #define MagickSigma (fabs(sigma) < MagickEpsilon ? MagickEpsilon : sigma) CacheView sharp_view, edge_view, image_view; double kernel, normalize; Image sharp_image, edge_image, gaussian_image; MagickBooleanType status; MagickOffsetType progress; MagickPixelPacket bias; register ssize_t i; size_t width; ssize_t j, k, u, v, y; assert(image != (const Image ) NULL); assert(image->signature == MagickCoreSignature); if (image->debug != MagickFalse) (void) LogMagickEvent(TraceEvent,GetMagickModule(),"%s",image->filename); assert(exception != (ExceptionInfo ) NULL); assert(exception->signature == MagickCoreSignature); sharp_image=CloneImage(image,0,0,MagickTrue,exception); if (sharp_image == (Image ) NULL) return((Image ) NULL); if (fabs(sigma) <= MagickEpsilon) return(sharp_image); if (SetImageStorageClass(sharp_image,DirectClass) == MagickFalse) { InheritException(exception,&sharp_image->exception); sharp_image=DestroyImage(sharp_image); return((Image ) NULL); } / Edge detect the image brighness channel, level, sharp, and level again. / edge_image=EdgeImage(image,radius,exception); if (edge_image == (Image ) NULL) { sharp_image=DestroyImage(sharp_image); return((Image ) NULL); } (void) AutoLevelImage(edge_image); gaussian_image=BlurImage(edge_image,radius,sigma,exception); if (gaussian_image != (Image ) NULL) { edge_image=DestroyImage(edge_image); edge_image=gaussian_image; } (void) AutoLevelImage(edge_image); /* Create a set of kernels from maximum (radius,sigma) to minimum. / width=GetOptimalKernelWidth2D(radius,sigma); kernel=(double ) MagickAssumeAligned(AcquireAlignedMemory((size_t) width, sizeof(kernel))); if (kernel == (double *) NULL) { edge_image=DestroyImage(edge_image); sharp_image=DestroyImage(sharp_image); ThrowImageException(ResourceLimitError,"MemoryAllocationFailed"); } (void) memset(kernel,0,(size_t) widthsizeof(kernel)); for (i=0; i < (ssize_t) width; i+=2) { kernel[i]=(double ) MagickAssumeAligned(AcquireAlignedMemory((size_t) (width-i),(width-i)sizeof(kernel))); if (kernel[i] == (double ) NULL) break; normalize=0.0; j=(ssize_t) (width-i-1)/2; k=0; for (v=(-j); v <= j; v++) { for (u=(-j); u <= j; u++) { kernel[i][k]=(double) (-exp(-((double) uu+vv)/(2.0MagickSigma MagickSigma))/(2.0MagickPIMagickSigmaMagickSigma)); normalize+=kernel[i][k]; k++; } } kernel[i][(k-1)/2]=(double) ((-2.0)normalize); if (sigma < MagickEpsilon) kernel[i][(k-1)/2]=1.0; } if (i < (ssize_t) width) { for (i-=2; i >= 0; i-=2) kernel[i]=(double ) RelinquishAlignedMemory(kernel[i]); kernel=(double ) RelinquishAlignedMemory(kernel); edge_image=DestroyImage(edge_image); sharp_image=DestroyImage(sharp_image); ThrowImageException(ResourceLimitError,"MemoryAllocationFailed"); } / Adaptively sharpen image. / status=MagickTrue; progress=0; GetMagickPixelPacket(image,&bias); SetMagickPixelPacketBias(image,&bias); image_view=AcquireVirtualCacheView(image,exception); edge_view=AcquireVirtualCacheView(edge_image,exception); sharp_view=AcquireAuthenticCacheView(sharp_image,exception); #if defined(MAGICKCORE_OPENMP_SUPPORT) #pragma omp parallel for schedule(static) shared(progress,status) \ magick_number_threads(image,sharp_image,sharp_image->rows,1) #endif for (y=0; y < (ssize_t) sharp_image->rows; y++) { register const IndexPacket magick_restrict indexes; register const PixelPacket magick_restrict p, magick_restrict r; register IndexPacket magick_restrict sharp_indexes; register PixelPacket magick_restrict q; register ssize_t x; if (status == MagickFalse) continue; r=GetCacheViewVirtualPixels(edge_view,0,y,edge_image->columns,1,exception); q=QueueCacheViewAuthenticPixels(sharp_view,0,y,sharp_image->columns,1, exception); if ((r == (const PixelPacket ) NULL) \|\| (q == (PixelPacket ) NULL)) { status=MagickFalse; continue; } sharp_indexes=GetCacheViewAuthenticIndexQueue(sharp_view); for (x=0; x < (ssize_t) sharp_image->columns; x++) { double alpha, gamma; DoublePixelPacket pixel; register const double magick_restrict k; register ssize_t i, u, v; gamma=0.0; i=(ssize_t) ceil((double) width(1.0-QuantumScale* GetPixelIntensity(edge_image,r))-0.5); if (i < 0) i=0; else if (i > (ssize_t) width) i=(ssize_t) width; if ((i & 0x01) != 0) i--; p=GetCacheViewVirtualPixels(image_view,x-((ssize_t) (width-i)/2L),y- (ssize_t) ((width-i)/2L),width-i,width-i,exception); if (p == (const PixelPacket ) NULL) break; indexes=GetCacheViewVirtualIndexQueue(image_view); k=kernel[i]; pixel.red=bias.red; pixel.green=bias.green; pixel.blue=bias.blue; pixel.opacity=bias.opacity; pixel.index=bias.index; for (v=0; v < (ssize_t) (width-i); v++) { for (u=0; u < (ssize_t) (width-i); u++) { alpha=1.0; if (((channel & OpacityChannel) != 0) && (image->matte != MagickFalse)) alpha=(MagickRealType) (QuantumScaleGetPixelAlpha(p)); if ((channel & RedChannel) != 0) pixel.red+=(k)alphaGetPixelRed(p); if ((channel & GreenChannel) != 0) pixel.green+=(k)alphaGetPixelGreen(p); if ((channel & BlueChannel) != 0) pixel.blue+=(k)alphaGetPixelBlue(p); if ((channel & OpacityChannel) != 0) pixel.opacity+=(k)GetPixelOpacity(p); if (((channel & IndexChannel) != 0) && (image->colorspace == CMYKColorspace)) pixel.index+=(k)alphaGetPixelIndex(indexes+x+(width-i)v+u); gamma+=(k)alpha; k++; p++; } } gamma=PerceptibleReciprocal(gamma); if ((channel & RedChannel) != 0) SetPixelRed(q,ClampToQuantum(gammapixel.red)); if ((channel & GreenChannel) != 0) SetPixelGreen(q,ClampToQuantum(gammapixel.green)); if ((channel & BlueChannel) != 0) SetPixelBlue(q,ClampToQuantum(gammapixel.blue)); if ((channel & OpacityChannel) != 0) SetPixelOpacity(q,ClampToQuantum(pixel.opacity)); if (((channel & IndexChannel) != 0) && (image->colorspace == CMYKColorspace)) SetPixelIndex(sharp_indexes+x,ClampToQuantum(gammapixel.index)); q++; r++; } if (SyncCacheViewAuthenticPixels(sharp_view,exception) == MagickFalse) status=MagickFalse; if (image->progress_monitor != (MagickProgressMonitor) NULL) { MagickBooleanType proceed; #if defined(MAGICKCORE_OPENMP_SUPPORT) #pragma omp atomic #endif progress++; proceed=SetImageProgress(image,AdaptiveSharpenImageTag,progress, image->rows); if (proceed == MagickFalse) status=MagickFalse; } } sharp_image->type=image->type; sharp_view=DestroyCacheView(sharp_view); edge_view=DestroyCacheView(edge_view); image_view=DestroyCacheView(image_view); edge_image=DestroyImage(edge_image); for (i=0; i < (ssize_t) width; i+=2) kernel[i]=(double ) RelinquishAlignedMemory(kernel[i]); kernel=(double *) RelinquishAlignedMemory(kernel); if (status == MagickFalse) sharp_image=DestroyImage(sharp_image); return(sharp_image); } / %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % B l u r I m a g e % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % BlurImage() blurs an image. We convolve the image with a Gaussian operator % of the given radius and standard deviation (sigma). For reasonable results, % the radius should be larger than sigma. Use a radius of 0 and BlurImage() % selects a suitable radius for you. % % The format of the BlurImage method is: % % Image BlurImage(const Image image,const double radius, % const double sigma,ExceptionInfo exception) % Image BlurImageChannel(const Image image,const ChannelType channel, % const double radius,const double sigma,ExceptionInfo exception) % % A description of each parameter follows: % % o image: the image. % % o channel: the channel type. % % o radius: the radius of the Gaussian, in pixels, not counting the center % pixel. % % o sigma: the standard deviation of the Gaussian, in pixels. % % o exception: return any errors or warnings in this structure. % / MagickExport Image BlurImage(const Image image,const double radius, const double sigma,ExceptionInfo exception) { Image blur_image; blur_image=BlurImageChannel(image,DefaultChannels,radius,sigma,exception); return(blur_image); } MagickExport Image BlurImageChannel(const Image image, const ChannelType channel,const double radius,const double sigma, ExceptionInfo exception) { char geometry[MaxTextExtent]; KernelInfo kernel_info; Image blur_image = NULL; assert(image != (const Image ) NULL); assert(image->signature == MagickCoreSignature); if (image->debug != MagickFalse) (void) LogMagickEvent(TraceEvent,GetMagickModule(),"%s",image->filename); assert(exception != (ExceptionInfo ) NULL); assert(exception->signature == MagickCoreSignature); #if defined(MAGICKCORE_OPENCL_SUPPORT) blur_image=AccelerateBlurImage(image,channel,radius,sigma,exception); if (blur_image != (Image ) NULL) return(blur_image); #endif (void) FormatLocaleString(geometry,MaxTextExtent, "blur:%.20gx%.20g;blur:%.20gx%.20g+90",radius,sigma,radius,sigma); kernel_info=AcquireKernelInfo(geometry); if (kernel_info == (KernelInfo ) NULL) ThrowImageException(ResourceLimitError,"MemoryAllocationFailed"); blur_image=MorphologyImageChannel(image,channel,ConvolveMorphology,1, kernel_info,exception); kernel_info=DestroyKernelInfo(kernel_info); return(blur_image); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % C o n v o l v e I m a g e % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % ConvolveImage() applies a custom convolution kernel to the image. % % The format of the ConvolveImage method is: % % Image ConvolveImage(const Image image,const size_t order, % const double kernel,ExceptionInfo exception) % Image ConvolveImageChannel(const Image image,const ChannelType channel, % const size_t order,const double kernel,ExceptionInfo exception) % % A description of each parameter follows: % % o image: the image. % % o channel: the channel type. % % o order: the number of columns and rows in the filter kernel. % % o kernel: An array of double representing the convolution kernel. % % o exception: return any errors or warnings in this structure. % / MagickExport Image ConvolveImage(const Image image,const size_t order, const double kernel,ExceptionInfo exception) { Image convolve_image; #ifdef MAGICKCORE_CLPERFMARKER clBeginPerfMarkerAMD(__FUNCTION__,""); #endif convolve_image=ConvolveImageChannel(image,DefaultChannels,order,kernel, exception); #ifdef MAGICKCORE_CLPERFMARKER clEndPerfMarkerAMD(); #endif return(convolve_image); } MagickExport Image ConvolveImageChannel(const Image image, const ChannelType channel,const size_t order,const double kernel, ExceptionInfo exception) { Image convolve_image; KernelInfo kernel_info; register ssize_t i; kernel_info=AcquireKernelInfo((const char ) NULL); if (kernel_info == (KernelInfo ) NULL) ThrowImageException(ResourceLimitError,"MemoryAllocationFailed"); kernel_info->width=order; kernel_info->height=order; kernel_info->x=(ssize_t) (order-1)/2; kernel_info->y=(ssize_t) (order-1)/2; kernel_info->signature=MagickCoreSignature; kernel_info->values=(double ) MagickAssumeAligned(AcquireAlignedMemory( kernel_info->width,kernel_info->widthsizeof(kernel_info->values))); if (kernel_info->values == (double ) NULL) { kernel_info=DestroyKernelInfo(kernel_info); ThrowImageException(ResourceLimitError,"MemoryAllocationFailed"); } for (i=0; i < (ssize_t) (orderorder); i++) kernel_info->values[i]=kernel[i]; convolve_image=(Image ) NULL; #if defined(MAGICKCORE_OPENCL_SUPPORT) convolve_image=AccelerateConvolveImageChannel(image,channel,kernel_info, exception); #endif if (convolve_image == (Image ) NULL) convolve_image=MorphologyImageChannel(image,channel,ConvolveMorphology,1, kernel_info,exception); kernel_info=DestroyKernelInfo(kernel_info); return(convolve_image); } / %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % D e s p e c k l e I m a g e % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % DespeckleImage() reduces the speckle noise in an image while perserving the % edges of the original image. A speckle removing filter uses a complementary % hulling technique (raising pixels that are darker than their surrounding % neighbors, then complementarily lowering pixels that are brighter than their % surrounding neighbors) to reduce the speckle index of that image (reference % Crimmins speckle removal). % % The format of the DespeckleImage method is: % % Image DespeckleImage(const Image image,ExceptionInfo exception) % % A description of each parameter follows: % % o image: the image. % % o exception: return any errors or warnings in this structure. % / static void Hull(const Image image,const ssize_t x_offset, const ssize_t y_offset,const size_t columns,const size_t rows, const int polarity,Quantum magick_restrict f,Quantum magick_restrict g) { register Quantum p, q, r, s; ssize_t y; assert(f != (Quantum ) NULL); assert(g != (Quantum ) NULL); p=f+(columns+2); q=g+(columns+2); r=p+(y_offset(columns+2)+x_offset); #if defined(MAGICKCORE_OPENMP_SUPPORT) #pragma omp parallel for schedule(static) \ magick_number_threads(image,image,rows,1) #endif for (y=0; y < (ssize_t) rows; y++) { register ssize_t i, x; SignedQuantum v; i=(2y+1)+ycolumns; if (polarity > 0) for (x=0; x < (ssize_t) columns; x++) { v=(SignedQuantum) p[i]; if ((SignedQuantum) r[i] >= (v+ScaleCharToQuantum(2))) v+=ScaleCharToQuantum(1); q[i]=(Quantum) v; i++; } else for (x=0; x < (ssize_t) columns; x++) { v=(SignedQuantum) p[i]; if ((SignedQuantum) r[i] <= (v-ScaleCharToQuantum(2))) v-=ScaleCharToQuantum(1); q[i]=(Quantum) v; i++; } } p=f+(columns+2); q=g+(columns+2); r=q+(y_offset(columns+2)+x_offset); s=q-(y_offset(columns+2)+x_offset); #if defined(MAGICKCORE_OPENMP_SUPPORT) #pragma omp parallel for schedule(static) \ magick_number_threads(image,image,rows,1) #endif for (y=0; y < (ssize_t) rows; y++) { register ssize_t i, x; SignedQuantum v; i=(2y+1)+ycolumns; if (polarity > 0) for (x=0; x < (ssize_t) columns; x++) { v=(SignedQuantum) q[i]; if (((SignedQuantum) s[i] >= (v+ScaleCharToQuantum(2))) && ((SignedQuantum) r[i] > v)) v+=ScaleCharToQuantum(1); p[i]=(Quantum) v; i++; } else for (x=0; x < (ssize_t) columns; x++) { v=(SignedQuantum) q[i]; if (((SignedQuantum) s[i] <= (v-ScaleCharToQuantum(2))) && ((SignedQuantum) r[i] < v)) v-=ScaleCharToQuantum(1); p[i]=(Quantum) v; i++; } } } MagickExport Image DespeckleImage(const Image image,ExceptionInfo exception) { #define DespeckleImageTag "Despeckle/Image" CacheView despeckle_view, image_view; Image despeckle_image; MagickBooleanType status; MemoryInfo buffer_info, pixel_info; register ssize_t i; Quantum magick_restrict buffer, magick_restrict pixels; size_t length, number_channels; static const ssize_t X[4] = {0, 1, 1,-1}, Y[4] = {1, 0, 1, 1}; /* Allocate despeckled image. / assert(image != (const Image ) NULL); assert(image->signature == MagickCoreSignature); if (image->debug != MagickFalse) (void) LogMagickEvent(TraceEvent,GetMagickModule(),"%s",image->filename); assert(exception != (ExceptionInfo ) NULL); assert(exception->signature == MagickCoreSignature); #if defined(MAGICKCORE_OPENCL_SUPPORT) despeckle_image=AccelerateDespeckleImage(image, exception); if (despeckle_image != (Image ) NULL) return(despeckle_image); #endif despeckle_image=CloneImage(image,0,0,MagickTrue,exception); if (despeckle_image == (Image ) NULL) return((Image ) NULL); if (SetImageStorageClass(despeckle_image,DirectClass) == MagickFalse) { InheritException(exception,&despeckle_image->exception); despeckle_image=DestroyImage(despeckle_image); return((Image ) NULL); } / Allocate image buffer. / length=(size_t) ((image->columns+2)(image->rows+2)); pixel_info=AcquireVirtualMemory(length,sizeof(pixels)); buffer_info=AcquireVirtualMemory(length,sizeof(buffer)); if ((pixel_info == (MemoryInfo ) NULL) \|\| (buffer_info == (MemoryInfo ) NULL)) { if (buffer_info != (MemoryInfo ) NULL) buffer_info=RelinquishVirtualMemory(buffer_info); if (pixel_info != (MemoryInfo ) NULL) pixel_info=RelinquishVirtualMemory(pixel_info); despeckle_image=DestroyImage(despeckle_image); ThrowImageException(ResourceLimitError,"MemoryAllocationFailed"); } pixels=(Quantum ) GetVirtualMemoryBlob(pixel_info); buffer=(Quantum ) GetVirtualMemoryBlob(buffer_info); /* Reduce speckle in the image. / status=MagickTrue; number_channels=(size_t) (image->colorspace == CMYKColorspace ? 5 : 4); image_view=AcquireVirtualCacheView(image,exception); despeckle_view=AcquireAuthenticCacheView(despeckle_image,exception); for (i=0; i < (ssize_t) number_channels; i++) { register ssize_t k, x; ssize_t j, y; if (status == MagickFalse) continue; if ((image->matte == MagickFalse) && (i == 3)) continue; (void) memset(pixels,0,lengthsizeof(pixels)); j=(ssize_t) image->columns+2; for (y=0; y < (ssize_t) image->rows; y++) { register const IndexPacket magick_restrict indexes; register const PixelPacket magick_restrict p; p=GetCacheViewVirtualPixels(image_view,0,y,image->columns,1,exception); if (p == (const PixelPacket ) NULL) break; indexes=GetCacheViewVirtualIndexQueue(image_view); j++; for (x=0; x < (ssize_t) image->columns; x++) { switch (i) { case 0: pixels[j]=GetPixelRed(p); break; case 1: pixels[j]=GetPixelGreen(p); break; case 2: pixels[j]=GetPixelBlue(p); break; case 3: pixels[j]=GetPixelOpacity(p); break; case 4: pixels[j]=GetPixelBlack(indexes+x); break; default: break; } p++; j++; } j++; } (void) memset(buffer,0,lengthsizeof(buffer)); for (k=0; k < 4; k++) { Hull(image,X[k],Y[k],image->columns,image->rows,1,pixels,buffer); Hull(image,-X[k],-Y[k],image->columns,image->rows,1,pixels,buffer); Hull(image,-X[k],-Y[k],image->columns,image->rows,-1,pixels,buffer); Hull(image,X[k],Y[k],image->columns,image->rows,-1,pixels,buffer); } j=(ssize_t) image->columns+2; for (y=0; y < (ssize_t) image->rows; y++) { MagickBooleanType sync; register IndexPacket magick_restrict indexes; register PixelPacket magick_restrict q; q=GetCacheViewAuthenticPixels(despeckle_view,0,y,despeckle_image->columns, 1,exception); if (q == (PixelPacket ) NULL) break; indexes=GetCacheViewAuthenticIndexQueue(despeckle_view); j++; for (x=0; x < (ssize_t) image->columns; x++) { switch (i) { case 0: SetPixelRed(q,pixels[j]); break; case 1: SetPixelGreen(q,pixels[j]); break; case 2: SetPixelBlue(q,pixels[j]); break; case 3: SetPixelOpacity(q,pixels[j]); break; case 4: SetPixelIndex(indexes+x,pixels[j]); break; default: break; } q++; j++; } sync=SyncCacheViewAuthenticPixels(despeckle_view,exception); if (sync == MagickFalse) { status=MagickFalse; break; } j++; } if (image->progress_monitor != (MagickProgressMonitor) NULL) { MagickBooleanType proceed; proceed=SetImageProgress(image,DespeckleImageTag,(MagickOffsetType) i, number_channels); if (proceed == MagickFalse) status=MagickFalse; } } despeckle_view=DestroyCacheView(despeckle_view); image_view=DestroyCacheView(image_view); buffer_info=RelinquishVirtualMemory(buffer_info); pixel_info=RelinquishVirtualMemory(pixel_info); despeckle_image->type=image->type; if (status == MagickFalse) despeckle_image=DestroyImage(despeckle_image); return(despeckle_image); } / %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % E d g e I m a g e % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % EdgeImage() finds edges in an image. Radius defines the radius of the % convolution filter. Use a radius of 0 and EdgeImage() selects a suitable % radius for you. % % The format of the EdgeImage method is: % % Image EdgeImage(const Image image,const double radius, % ExceptionInfo exception) % % A description of each parameter follows: % % o image: the image. % % o radius: the radius of the pixel neighborhood. % % o exception: return any errors or warnings in this structure. % / MagickExport Image EdgeImage(const Image image,const double radius, ExceptionInfo exception) { Image edge_image; KernelInfo kernel_info; register ssize_t i; size_t width; assert(image != (const Image ) NULL); assert(image->signature == MagickCoreSignature); if (image->debug != MagickFalse) (void) LogMagickEvent(TraceEvent,GetMagickModule(),"%s",image->filename); assert(exception != (ExceptionInfo ) NULL); assert(exception->signature == MagickCoreSignature); width=GetOptimalKernelWidth1D(radius,0.5); kernel_info=AcquireKernelInfo((const char ) NULL); if (kernel_info == (KernelInfo ) NULL) ThrowImageException(ResourceLimitError,"MemoryAllocationFailed"); (void) memset(kernel_info,0,sizeof(kernel_info)); kernel_info->width=width; kernel_info->height=width; kernel_info->x=(ssize_t) (kernel_info->width-1)/2; kernel_info->y=(ssize_t) (kernel_info->height-1)/2; kernel_info->signature=MagickCoreSignature; kernel_info->values=(double ) MagickAssumeAligned(AcquireAlignedMemory( kernel_info->width,kernel_info->heightsizeof(kernel_info->values))); if (kernel_info->values == (double ) NULL) { kernel_info=DestroyKernelInfo(kernel_info); ThrowImageException(ResourceLimitError,"MemoryAllocationFailed"); } for (i=0; i < (ssize_t) (kernel_info->widthkernel_info->height); i++) kernel_info->values[i]=(-1.0); kernel_info->values[i/2]=(double) kernel_info->widthkernel_info->height-1.0; edge_image=(Image ) NULL; #if defined(MAGICKCORE_OPENCL_SUPPORT) edge_image=AccelerateConvolveImageChannel(image,DefaultChannels,kernel_info, exception); #endif if (edge_image == (Image ) NULL) edge_image=MorphologyImageChannel(image,DefaultChannels,ConvolveMorphology, 1,kernel_info,exception); kernel_info=DestroyKernelInfo(kernel_info); return(edge_image); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % E m b o s s I m a g e % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % EmbossImage() returns a grayscale image with a three-dimensional effect. % We convolve the image with a Gaussian operator of the given radius and % standard deviation (sigma). For reasonable results, radius should be % larger than sigma. Use a radius of 0 and Emboss() selects a suitable % radius for you. % % The format of the EmbossImage method is: % % Image EmbossImage(const Image image,const double radius, % const double sigma,ExceptionInfo exception) % % A description of each parameter follows: % % o image: the image. % % o radius: the radius of the pixel neighborhood. % % o sigma: the standard deviation of the Gaussian, in pixels. % % o exception: return any errors or warnings in this structure. % / MagickExport Image EmbossImage(const Image image,const double radius, const double sigma,ExceptionInfo exception) { double gamma, normalize; Image emboss_image; KernelInfo kernel_info; register ssize_t i; size_t width; ssize_t j, k, u, v; assert(image != (const Image ) NULL); assert(image->signature == MagickCoreSignature); if (image->debug != MagickFalse) (void) LogMagickEvent(TraceEvent,GetMagickModule(),"%s",image->filename); assert(exception != (ExceptionInfo ) NULL); assert(exception->signature == MagickCoreSignature); width=GetOptimalKernelWidth1D(radius,sigma); kernel_info=AcquireKernelInfo((const char ) NULL); if (kernel_info == (KernelInfo ) NULL) ThrowImageException(ResourceLimitError,"MemoryAllocationFailed"); kernel_info->width=width; kernel_info->height=width; kernel_info->x=(ssize_t) (width-1)/2; kernel_info->y=(ssize_t) (width-1)/2; kernel_info->values=(double ) MagickAssumeAligned(AcquireAlignedMemory( kernel_info->width,kernel_info->widthsizeof(kernel_info->values))); if (kernel_info->values == (double ) NULL) { kernel_info=DestroyKernelInfo(kernel_info); ThrowImageException(ResourceLimitError,"MemoryAllocationFailed"); } j=(ssize_t) (kernel_info->width-1)/2; k=j; i=0; for (v=(-j); v <= j; v++) { for (u=(-j); u <= j; u++) { kernel_info->values[i]=(double) (((u < 0) \|\| (v < 0) ? -8.0 : 8.0)exp(-((double) uu+vv)/(2.0MagickSigmaMagickSigma))/ (2.0MagickPIMagickSigmaMagickSigma)); if (u != k) kernel_info->values[i]=0.0; i++; } k--; } normalize=0.0; for (i=0; i < (ssize_t) (kernel_info->widthkernel_info->height); i++) normalize+=kernel_info->values[i]; gamma=PerceptibleReciprocal(normalize); for (i=0; i < (ssize_t) (kernel_info->widthkernel_info->height); i++) kernel_info->values[i]=gamma; emboss_image=(Image ) NULL; #if defined(MAGICKCORE_OPENCL_SUPPORT) emboss_image=AccelerateConvolveImageChannel(image,DefaultChannels,kernel_info, exception); #endif if (emboss_image == (Image ) NULL) emboss_image=MorphologyImageChannel(image,DefaultChannels, ConvolveMorphology,1,kernel_info,exception); kernel_info=DestroyKernelInfo(kernel_info); if (emboss_image != (Image ) NULL) (void) EqualizeImageChannel(emboss_image,(ChannelType) (AllChannels &~ SyncChannels)); return(emboss_image); } / %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % F i l t e r I m a g e % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % FilterImage() applies a custom convolution kernel to the image. % % The format of the FilterImage method is: % % Image FilterImage(const Image image,const KernelInfo kernel, % ExceptionInfo exception) % Image FilterImageChannel(const Image image,const ChannelType channel, % const KernelInfo kernel,ExceptionInfo exception) % % A description of each parameter follows: % % o image: the image. % % o channel: the channel type. % % o kernel: the filtering kernel. % % o exception: return any errors or warnings in this structure. % / MagickExport Image FilterImage(const Image image,const KernelInfo kernel, ExceptionInfo exception) { Image filter_image; filter_image=FilterImageChannel(image,DefaultChannels,kernel,exception); return(filter_image); } MagickExport Image FilterImageChannel(const Image image, const ChannelType channel,const KernelInfo kernel,ExceptionInfo exception) { #define FilterImageTag "Filter/Image" CacheView filter_view, image_view; Image filter_image; MagickBooleanType status; MagickOffsetType progress; MagickPixelPacket bias; MagickRealType filter_kernel; register ssize_t i; ssize_t y; #ifdef MAGICKCORE_CLPERFMARKER clBeginPerfMarkerAMD(__FUNCTION__,""); #endif /* Initialize filter image attributes. / assert(image != (Image ) NULL); assert(image->signature == MagickCoreSignature); if (image->debug != MagickFalse) (void) LogMagickEvent(TraceEvent,GetMagickModule(),"%s",image->filename); assert(exception != (ExceptionInfo ) NULL); assert(exception->signature == MagickCoreSignature); if ((kernel->width % 2) == 0) ThrowImageException(OptionError,"KernelWidthMustBeAnOddNumber"); if (image->debug != MagickFalse) { char format[MaxTextExtent], message; register const double k; ssize_t u, v; (void) LogMagickEvent(TransformEvent,GetMagickModule(), " FilterImage with %.20gx%.20g kernel:",(double) kernel->width,(double) kernel->height); message=AcquireString(""); k=kernel->values; for (v=0; v < (ssize_t) kernel->height; v++) { message='\0'; (void) FormatLocaleString(format,MaxTextExtent,"%.20g: ",(double) v); (void) ConcatenateString(&message,format); for (u=0; u < (ssize_t) kernel->width; u++) { (void) FormatLocaleString(format,MaxTextExtent,"%g ",k++); (void) ConcatenateString(&message,format); } (void) LogMagickEvent(TransformEvent,GetMagickModule(),"%s",message); } message=DestroyString(message); } #if defined(MAGICKCORE_OPENCL_SUPPORT) filter_image=AccelerateConvolveImageChannel(image,channel,kernel,exception); if (filter_image != (Image ) NULL) { #ifdef MAGICKCORE_CLPERFMARKER clEndPerfMarkerAMD(); #endif return(filter_image); } #endif filter_image=CloneImage(image,0,0,MagickTrue,exception); if (filter_image == (Image ) NULL) return((Image ) NULL); if (SetImageStorageClass(filter_image,DirectClass) == MagickFalse) { InheritException(exception,&filter_image->exception); filter_image=DestroyImage(filter_image); return((Image ) NULL); } / Normalize kernel. / filter_kernel=(MagickRealType ) MagickAssumeAligned(AcquireAlignedMemory( kernel->width,kernel->heightsizeof(filter_kernel))); if (filter_kernel == (MagickRealType ) NULL) { filter_image=DestroyImage(filter_image); ThrowImageException(ResourceLimitError,"MemoryAllocationFailed"); } for (i=0; i < (ssize_t) (kernel->widthkernel->height); i++) filter_kernel[i]=(MagickRealType) kernel->values[i]; /* Filter image. / status=MagickTrue; progress=0; GetMagickPixelPacket(image,&bias); SetMagickPixelPacketBias(image,&bias); image_view=AcquireVirtualCacheView(image,exception); filter_view=AcquireAuthenticCacheView(filter_image,exception); #if defined(MAGICKCORE_OPENMP_SUPPORT) #pragma omp parallel for schedule(static) shared(progress,status) \ magick_number_threads(image,filter_image,image->rows,1) #endif for (y=0; y < (ssize_t) image->rows; y++) { MagickBooleanType sync; register const IndexPacket magick_restrict indexes; register const PixelPacket magick_restrict p; register IndexPacket magick_restrict filter_indexes; register PixelPacket magick_restrict q; register ssize_t x; if (status == MagickFalse) continue; p=GetCacheViewVirtualPixels(image_view,-((ssize_t) (kernel->width-1)/2L),y- (ssize_t) ((kernel->height-1)/2L),image->columns+kernel->width, kernel->height,exception); q=GetCacheViewAuthenticPixels(filter_view,0,y,filter_image->columns,1, exception); if ((p == (const PixelPacket ) NULL) \|\| (q == (PixelPacket ) NULL)) { status=MagickFalse; continue; } indexes=GetCacheViewVirtualIndexQueue(image_view); filter_indexes=GetCacheViewAuthenticIndexQueue(filter_view); for (x=0; x < (ssize_t) image->columns; x++) { DoublePixelPacket pixel; register const MagickRealType magick_restrict k; register const PixelPacket magick_restrict kernel_pixels; register ssize_t u; ssize_t v; pixel.red=bias.red; pixel.green=bias.green; pixel.blue=bias.blue; pixel.opacity=bias.opacity; pixel.index=bias.index; k=filter_kernel; kernel_pixels=p; if (((channel & OpacityChannel) == 0) \|\| (image->matte == MagickFalse)) { for (v=0; v < (ssize_t) kernel->width; v++) { for (u=0; u < (ssize_t) kernel->height; u++) { pixel.red+=(k)kernel_pixels[u].red; pixel.green+=(k)kernel_pixels[u].green; pixel.blue+=(k)kernel_pixels[u].blue; k++; } kernel_pixels+=image->columns+kernel->width; } if ((channel & RedChannel) != 0) SetPixelRed(q,ClampToQuantum(pixel.red)); if ((channel & GreenChannel) != 0) SetPixelGreen(q,ClampToQuantum(pixel.green)); if ((channel & BlueChannel) != 0) SetPixelBlue(q,ClampToQuantum(pixel.blue)); if ((channel & OpacityChannel) != 0) { k=filter_kernel; kernel_pixels=p; for (v=0; v < (ssize_t) kernel->width; v++) { for (u=0; u < (ssize_t) kernel->height; u++) { pixel.opacity+=(k)kernel_pixels[u].opacity; k++; } kernel_pixels+=image->columns+kernel->width; } SetPixelOpacity(q,ClampToQuantum(pixel.opacity)); } if (((channel & IndexChannel) != 0) && (image->colorspace == CMYKColorspace)) { register const IndexPacket magick_restrict kernel_indexes; k=filter_kernel; kernel_indexes=indexes; for (v=0; v < (ssize_t) kernel->width; v++) { for (u=0; u < (ssize_t) kernel->height; u++) { pixel.index+=(k)GetPixelIndex(kernel_indexes+u); k++; } kernel_indexes+=image->columns+kernel->width; } SetPixelIndex(filter_indexes+x,ClampToQuantum(pixel.index)); } } else { double alpha, gamma; gamma=0.0; for (v=0; v < (ssize_t) kernel->width; v++) { for (u=0; u < (ssize_t) kernel->height; u++) { alpha=(MagickRealType) (QuantumScale(QuantumRange- GetPixelOpacity(kernel_pixels+u))); pixel.red+=(k)alphaGetPixelRed(kernel_pixels+u); pixel.green+=(k)alphaGetPixelGreen(kernel_pixels+u); pixel.blue+=(k)alphaGetPixelBlue(kernel_pixels+u); gamma+=(k)alpha; k++; } kernel_pixels+=image->columns+kernel->width; } gamma=PerceptibleReciprocal(gamma); if ((channel & RedChannel) != 0) SetPixelRed(q,ClampToQuantum(gammapixel.red)); if ((channel & GreenChannel) != 0) SetPixelGreen(q,ClampToQuantum(gammapixel.green)); if ((channel & BlueChannel) != 0) SetPixelBlue(q,ClampToQuantum(gammapixel.blue)); if ((channel & OpacityChannel) != 0) { k=filter_kernel; kernel_pixels=p; for (v=0; v < (ssize_t) kernel->width; v++) { for (u=0; u < (ssize_t) kernel->height; u++) { pixel.opacity+=(k)GetPixelOpacity(kernel_pixels+u); k++; } kernel_pixels+=image->columns+kernel->width; } SetPixelOpacity(q,ClampToQuantum(pixel.opacity)); } if (((channel & IndexChannel) != 0) && (image->colorspace == CMYKColorspace)) { register const IndexPacket magick_restrict kernel_indexes; k=filter_kernel; kernel_pixels=p; kernel_indexes=indexes; for (v=0; v < (ssize_t) kernel->width; v++) { for (u=0; u < (ssize_t) kernel->height; u++) { alpha=(MagickRealType) (QuantumScale(QuantumRange- kernel_pixels[u].opacity)); pixel.index+=(k)alphaGetPixelIndex(kernel_indexes+u); k++; } kernel_pixels+=image->columns+kernel->width; kernel_indexes+=image->columns+kernel->width; } SetPixelIndex(filter_indexes+x,ClampToQuantum(gammapixel.index)); } } indexes++; p++; q++; } sync=SyncCacheViewAuthenticPixels(filter_view,exception); if (sync == MagickFalse) status=MagickFalse; if (image->progress_monitor != (MagickProgressMonitor) NULL) { MagickBooleanType proceed; #if defined(MAGICKCORE_OPENMP_SUPPORT) #pragma omp atomic #endif progress++; proceed=SetImageProgress(image,FilterImageTag,progress,image->rows); if (proceed == MagickFalse) status=MagickFalse; } } filter_image->type=image->type; filter_view=DestroyCacheView(filter_view); image_view=DestroyCacheView(image_view); filter_kernel=(MagickRealType ) RelinquishAlignedMemory(filter_kernel); if (status == MagickFalse) filter_image=DestroyImage(filter_image); #ifdef MAGICKCORE_CLPERFMARKER clEndPerfMarkerAMD(); #endif return(filter_image); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % G a u s s i a n B l u r I m a g e % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % GaussianBlurImage() blurs an image. We convolve the image with a % Gaussian operator of the given radius and standard deviation (sigma). % For reasonable results, the radius should be larger than sigma. Use a % radius of 0 and GaussianBlurImage() selects a suitable radius for you % % The format of the GaussianBlurImage method is: % % Image GaussianBlurImage(const Image image,onst double radius, % const double sigma,ExceptionInfo exception) % Image GaussianBlurImageChannel(const Image image, % const ChannelType channel,const double radius,const double sigma, % ExceptionInfo exception) % % A description of each parameter follows: % % o image: the image. % % o channel: the channel type. % % o radius: the radius of the Gaussian, in pixels, not counting the center % pixel. % % o sigma: the standard deviation of the Gaussian, in pixels. % % o exception: return any errors or warnings in this structure. % / MagickExport Image GaussianBlurImage(const Image image,const double radius, const double sigma,ExceptionInfo exception) { Image blur_image; blur_image=GaussianBlurImageChannel(image,DefaultChannels,radius,sigma, exception); return(blur_image); } MagickExport Image GaussianBlurImageChannel(const Image image, const ChannelType channel,const double radius,const double sigma, ExceptionInfo exception) { char geometry[MaxTextExtent]; KernelInfo kernel_info; Image blur_image; assert(image != (const Image ) NULL); assert(image->signature == MagickCoreSignature); if (image->debug != MagickFalse) (void) LogMagickEvent(TraceEvent,GetMagickModule(),"%s",image->filename); assert(exception != (ExceptionInfo ) NULL); assert(exception->signature == MagickCoreSignature); (void) FormatLocaleString(geometry,MaxTextExtent,"gaussian:%.20gx%.20g", radius,sigma); kernel_info=AcquireKernelInfo(geometry); if (kernel_info == (KernelInfo ) NULL) ThrowImageException(ResourceLimitError,"MemoryAllocationFailed"); blur_image=(Image ) NULL; #if defined(MAGICKCORE_OPENCL_SUPPORT) blur_image=AccelerateConvolveImageChannel(image,channel,kernel_info, exception); #endif if (blur_image == (Image ) NULL) blur_image=MorphologyImageChannel(image,channel,ConvolveMorphology,1, kernel_info,exception); kernel_info=DestroyKernelInfo(kernel_info); return(blur_image); } / %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % M o t i o n B l u r I m a g e % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % MotionBlurImage() simulates motion blur. We convolve the image with a % Gaussian operator of the given radius and standard deviation (sigma). % For reasonable results, radius should be larger than sigma. Use a % radius of 0 and MotionBlurImage() selects a suitable radius for you. % Angle gives the angle of the blurring motion. % % Andrew Protano contributed this effect. % % The format of the MotionBlurImage method is: % % Image MotionBlurImage(const Image image,const double radius, % const double sigma,const double angle,ExceptionInfo exception) % Image MotionBlurImageChannel(const Image image,const ChannelType channel, % const double radius,const double sigma,const double angle, % ExceptionInfo exception) % % A description of each parameter follows: % % o image: the image. % % o channel: the channel type. % % o radius: the radius of the Gaussian, in pixels, not counting the center % pixel. % % o sigma: the standard deviation of the Gaussian, in pixels. % % o angle: Apply the effect along this angle. % % o exception: return any errors or warnings in this structure. % / static double GetMotionBlurKernel(const size_t width,const double sigma) { double kernel, normalize; register ssize_t i; / Generate a 1-D convolution kernel. / (void) LogMagickEvent(TraceEvent,GetMagickModule(),"..."); kernel=(double ) MagickAssumeAligned(AcquireAlignedMemory((size_t) width, sizeof(kernel))); if (kernel == (double ) NULL) return(kernel); normalize=0.0; for (i=0; i < (ssize_t) width; i++) { kernel[i]=(double) (exp((-((double) ii)/(double) (2.0MagickSigma* MagickSigma)))/(MagickSQ2PIMagickSigma)); normalize+=kernel[i]; } for (i=0; i < (ssize_t) width; i++) kernel[i]/=normalize; return(kernel); } MagickExport Image MotionBlurImage(const Image image,const double radius, const double sigma,const double angle,ExceptionInfo exception) { Image motion_blur; motion_blur=MotionBlurImageChannel(image,DefaultChannels,radius,sigma,angle, exception); return(motion_blur); } MagickExport Image MotionBlurImageChannel(const Image image, const ChannelType channel,const double radius,const double sigma, const double angle,ExceptionInfo exception) { #define BlurImageTag "Blur/Image" CacheView blur_view, image_view; double kernel; Image blur_image; MagickBooleanType status; MagickOffsetType progress; MagickPixelPacket bias; OffsetInfo offset; PointInfo point; register ssize_t i; size_t width; ssize_t y; assert(image != (Image ) NULL); assert(image->signature == MagickCoreSignature); if (image->debug != MagickFalse) (void) LogMagickEvent(TraceEvent,GetMagickModule(),"%s",image->filename); assert(exception != (ExceptionInfo ) NULL); width=GetOptimalKernelWidth1D(radius,sigma); kernel=GetMotionBlurKernel(width,sigma); if (kernel == (double ) NULL) ThrowImageException(ResourceLimitError,"MemoryAllocationFailed"); offset=(OffsetInfo ) AcquireQuantumMemory(width,sizeof(offset)); if (offset == (OffsetInfo ) NULL) { kernel=(double ) RelinquishAlignedMemory(kernel); ThrowImageException(ResourceLimitError,"MemoryAllocationFailed"); } point.x=(double) widthsin(DegreesToRadians(angle)); point.y=(double) widthcos(DegreesToRadians(angle)); for (i=0; i < (ssize_t) width; i++) { offset[i].x=(ssize_t) ceil((double) (ipoint.y)/hypot(point.x,point.y)-0.5); offset[i].y=(ssize_t) ceil((double) (ipoint.x)/hypot(point.x,point.y)-0.5); } /* Motion blur image. / #if defined(MAGICKCORE_OPENCL_SUPPORT) blur_image=AccelerateMotionBlurImage(image,channel,kernel,width,offset, exception); if (blur_image != (Image ) NULL) return blur_image; #endif blur_image=CloneImage(image,0,0,MagickTrue,exception); if (blur_image == (Image ) NULL) { kernel=(double ) RelinquishAlignedMemory(kernel); offset=(OffsetInfo ) RelinquishMagickMemory(offset); return((Image ) NULL); } if (SetImageStorageClass(blur_image,DirectClass) == MagickFalse) { kernel=(double ) RelinquishAlignedMemory(kernel); offset=(OffsetInfo ) RelinquishMagickMemory(offset); InheritException(exception,&blur_image->exception); blur_image=DestroyImage(blur_image); return((Image ) NULL); } status=MagickTrue; progress=0; GetMagickPixelPacket(image,&bias); image_view=AcquireVirtualCacheView(image,exception); blur_view=AcquireAuthenticCacheView(blur_image,exception); #if defined(MAGICKCORE_OPENMP_SUPPORT) #pragma omp parallel for schedule(static) shared(progress,status) \ magick_number_threads(image,blur_image,image->rows,1) #endif for (y=0; y < (ssize_t) image->rows; y++) { register IndexPacket magick_restrict blur_indexes; register PixelPacket magick_restrict q; register ssize_t x; if (status == MagickFalse) continue; q=GetCacheViewAuthenticPixels(blur_view,0,y,blur_image->columns,1, exception); if (q == (PixelPacket ) NULL) { status=MagickFalse; continue; } blur_indexes=GetCacheViewAuthenticIndexQueue(blur_view); for (x=0; x < (ssize_t) image->columns; x++) { MagickPixelPacket qixel; PixelPacket pixel; register const IndexPacket magick_restrict indexes; register double magick_restrict k; register ssize_t i; k=kernel; qixel=bias; if (((channel & OpacityChannel) == 0) \|\| (image->matte == MagickFalse)) { for (i=0; i < (ssize_t) width; i++) { (void) GetOneCacheViewVirtualPixel(image_view,x+offset[i].x,y+ offset[i].y,&pixel,exception); qixel.red+=(k)pixel.red; qixel.green+=(k)pixel.green; qixel.blue+=(k)pixel.blue; qixel.opacity+=(k)pixel.opacity; if (image->colorspace == CMYKColorspace) { indexes=GetCacheViewVirtualIndexQueue(image_view); qixel.index+=(k)(indexes); } k++; } if ((channel & RedChannel) != 0) SetPixelRed(q,ClampToQuantum(qixel.red)); if ((channel & GreenChannel) != 0) SetPixelGreen(q,ClampToQuantum(qixel.green)); if ((channel & BlueChannel) != 0) SetPixelBlue(q,ClampToQuantum(qixel.blue)); if ((channel & OpacityChannel) != 0) SetPixelOpacity(q,ClampToQuantum(qixel.opacity)); if (((channel & IndexChannel) != 0) && (image->colorspace == CMYKColorspace)) SetPixelIndex(blur_indexes+x,ClampToQuantum(qixel.index)); } else { double alpha, gamma; alpha=0.0; gamma=0.0; for (i=0; i < (ssize_t) width; i++) { (void) GetOneCacheViewVirtualPixel(image_view,x+offset[i].x,y+ offset[i].y,&pixel,exception); alpha=(MagickRealType) (QuantumScaleGetPixelAlpha(&pixel)); qixel.red+=(k)alphapixel.red; qixel.green+=(k)alphapixel.green; qixel.blue+=(k)alphapixel.blue; qixel.opacity+=(k)pixel.opacity; if (image->colorspace == CMYKColorspace) { indexes=GetCacheViewVirtualIndexQueue(image_view); qixel.index+=(k)alphaGetPixelIndex(indexes); } gamma+=(k)alpha; k++; } gamma=PerceptibleReciprocal(gamma); if ((channel & RedChannel) != 0) SetPixelRed(q,ClampToQuantum(gammaqixel.red)); if ((channel & GreenChannel) != 0) SetPixelGreen(q,ClampToQuantum(gammaqixel.green)); if ((channel & BlueChannel) != 0) SetPixelBlue(q,ClampToQuantum(gammaqixel.blue)); if ((channel & OpacityChannel) != 0) SetPixelOpacity(q,ClampToQuantum(qixel.opacity)); if (((channel & IndexChannel) != 0) && (image->colorspace == CMYKColorspace)) SetPixelIndex(blur_indexes+x,ClampToQuantum(gammaqixel.index)); } q++; } if (SyncCacheViewAuthenticPixels(blur_view,exception) == MagickFalse) status=MagickFalse; if (image->progress_monitor != (MagickProgressMonitor) NULL) { MagickBooleanType proceed; #if defined(MAGICKCORE_OPENMP_SUPPORT) #pragma omp atomic #endif progress++; proceed=SetImageProgress(image,BlurImageTag,progress,image->rows); if (proceed == MagickFalse) status=MagickFalse; } } blur_view=DestroyCacheView(blur_view); image_view=DestroyCacheView(image_view); kernel=(double ) RelinquishAlignedMemory(kernel); offset=(OffsetInfo ) RelinquishMagickMemory(offset); if (status == MagickFalse) blur_image=DestroyImage(blur_image); return(blur_image); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % K u w a h a r a I m a g e % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % KuwaharaImage() is an edge preserving noise reduction filter. % % The format of the KuwaharaImage method is: % % Image KuwaharaImage(const Image image,const double width, % const double sigma,ExceptionInfo exception) % Image KuwaharaImageChannel(const Image image,const ChannelType channel, % const double width,const double sigma,ExceptionInfo exception) % % A description of each parameter follows: % % o image: the image. % % o channel: the channel type. % % o radius: the square window radius. % % o sigma: the standard deviation of the Gaussian, in pixels. % % o exception: return any errors or warnings in this structure. % / MagickExport Image KuwaharaImage(const Image image,const double radius, const double sigma,ExceptionInfo exception) { Image kuwahara_image; kuwahara_image=KuwaharaImageChannel(image,DefaultChannels,radius,sigma, exception); return(kuwahara_image); } MagickExport Image KuwaharaImageChannel(const Image image, const ChannelType channel,const double radius,const double sigma, ExceptionInfo exception) { #define KuwaharaImageTag "Kiwahara/Image" CacheView image_view, kuwahara_view; Image gaussian_image, kuwahara_image; MagickBooleanType status; MagickOffsetType progress; size_t width; ssize_t y; /* Initialize Kuwahara image attributes. / assert(image != (Image ) NULL); assert(image->signature == MagickCoreSignature); if (image->debug != MagickFalse) (void) LogMagickEvent(TraceEvent,GetMagickModule(),"%s",image->filename); assert(exception != (ExceptionInfo ) NULL); assert(exception->signature == MagickCoreSignature); (void) channel; width=(size_t) radius+1; gaussian_image=BlurImage(image,radius,sigma,exception); if (gaussian_image == (Image ) NULL) return((Image ) NULL); kuwahara_image=CloneImage(image,0,0,MagickTrue,exception); if (kuwahara_image == (Image ) NULL) { gaussian_image=DestroyImage(gaussian_image); return((Image ) NULL); } if (SetImageStorageClass(kuwahara_image,DirectClass) == MagickFalse) { InheritException(exception,&kuwahara_image->exception); gaussian_image=DestroyImage(gaussian_image); kuwahara_image=DestroyImage(kuwahara_image); return((Image ) NULL); } /* Edge preserving noise reduction filter. / status=MagickTrue; progress=0; image_view=AcquireVirtualCacheView(gaussian_image,exception); kuwahara_view=AcquireAuthenticCacheView(kuwahara_image,exception); #if defined(MAGICKCORE_OPENMP_SUPPORT) #pragma omp parallel for schedule(static) shared(progress,status) \ magick_number_threads(image,kuwahara_image,kuwahara_image->rows,1) #endif for (y=0; y < (ssize_t) kuwahara_image->rows; y++) { register IndexPacket magick_restrict kuwahara_indexes; register PixelPacket magick_restrict q; register ssize_t x; if (status == MagickFalse) continue; q=QueueCacheViewAuthenticPixels(kuwahara_view,0,y,kuwahara_image->columns,1, exception); if (q == (PixelPacket ) NULL) { status=MagickFalse; continue; } kuwahara_indexes=GetCacheViewAuthenticIndexQueue(kuwahara_view); for (x=0; x < (ssize_t) kuwahara_image->columns; x++) { double min_variance; MagickPixelPacket pixel; RectangleInfo quadrant, target; register ssize_t i; min_variance=MagickMaximumValue; SetGeometry(gaussian_image,&target); quadrant.width=width; quadrant.height=width; for (i=0; i < 4; i++) { const PixelPacket magick_restrict p; double variance; MagickPixelPacket mean; register const PixelPacket magick_restrict k; register ssize_t n; quadrant.x=x; quadrant.y=y; switch (i) { case 0: { quadrant.x=x-(ssize_t) (width-1); quadrant.y=y-(ssize_t) (width-1); break; } case 1: { quadrant.y=y-(ssize_t) (width-1); break; } case 2: { quadrant.x=x-(ssize_t) (width-1); break; } default: break; } p=GetCacheViewVirtualPixels(image_view,quadrant.x,quadrant.y, quadrant.width,quadrant.height,exception); if (p == (const PixelPacket ) NULL) break; GetMagickPixelPacket(image,&mean); k=p; for (n=0; n < (ssize_t) (widthwidth); n++) { mean.red+=(double) k->red; mean.green+=(double) k->green; mean.blue+=(double) k->blue; k++; } mean.red/=(double) (widthwidth); mean.green/=(double) (widthwidth); mean.blue/=(double) (widthwidth); k=p; variance=0.0; for (n=0; n < (ssize_t) (widthwidth); n++) { double luma; luma=GetPixelLuma(image,k); variance+=(luma-MagickPixelLuma(&mean))(luma-MagickPixelLuma(&mean)); k++; } if (variance < min_variance) { min_variance=variance; target=quadrant; } } if (i < 4) { status=MagickFalse; break; } status=InterpolateMagickPixelPacket(gaussian_image,image_view, UndefinedInterpolatePixel,(double) target.x+target.width/2.0, (double) target.y+target.height/2.0,&pixel,exception); if (status == MagickFalse) break; SetPixelPacket(kuwahara_image,&pixel,q,kuwahara_indexes+x); q++; } if (SyncCacheViewAuthenticPixels(kuwahara_view,exception) == MagickFalse) status=MagickFalse; if (image->progress_monitor != (MagickProgressMonitor) NULL) { MagickBooleanType proceed; #if defined(MAGICKCORE_OPENMP_SUPPORT) #pragma omp atomic #endif progress++; proceed=SetImageProgress(image,KuwaharaImageTag,progress,image->rows); if (proceed == MagickFalse) status=MagickFalse; } } kuwahara_view=DestroyCacheView(kuwahara_view); image_view=DestroyCacheView(image_view); gaussian_image=DestroyImage(gaussian_image); if (status == MagickFalse) kuwahara_image=DestroyImage(kuwahara_image); return(kuwahara_image); } / %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % L o c a l C o n t r a s t I m a g e % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % LocalContrastImage() attempts to increase the appearance of large-scale % light-dark transitions. Local contrast enhancement works similarly to % sharpening with an unsharp mask, however the mask is instead created using % an image with a greater blur distance. % % The format of the LocalContrastImage method is: % % Image LocalContrastImage(const Image image, const double radius, % const double strength, ExceptionInfo exception) % % A description of each parameter follows: % % o image: the image. % % o radius: the radius of the Gaussian blur, in percentage with 100% % resulting in a blur radius of 20% of largest dimension. % % o strength: the strength of the blur mask in percentage. % % o exception: return any errors or warnings in this structure. % / MagickExport Image LocalContrastImage(const Image image,const double radius, const double strength,ExceptionInfo exception) { #define LocalContrastImageTag "LocalContrast/Image" CacheView image_view, contrast_view; float interImage, scanLinePixels, totalWeight; Image contrast_image; MagickBooleanType status; MemoryInfo scanLinePixels_info, interImage_info; ssize_t scanLineSize, width; /* Initialize contrast image attributes. / assert(image != (const Image ) NULL); assert(image->signature == MagickCoreSignature); if (image->debug != MagickFalse) (void) LogMagickEvent(TraceEvent,GetMagickModule(),"%s",image->filename); assert(exception != (ExceptionInfo ) NULL); assert(exception->signature == MagickCoreSignature); #if defined(MAGICKCORE_OPENCL_SUPPORT) contrast_image=AccelerateLocalContrastImage(image,radius,strength,exception); if (contrast_image != (Image ) NULL) return(contrast_image); #endif contrast_image=CloneImage(image,0,0,MagickTrue,exception); if (contrast_image == (Image ) NULL) return((Image ) NULL); if (SetImageStorageClass(contrast_image,DirectClass) == MagickFalse) { InheritException(exception,&contrast_image->exception); contrast_image=DestroyImage(contrast_image); return((Image ) NULL); } image_view=AcquireVirtualCacheView(image,exception); contrast_view=AcquireAuthenticCacheView(contrast_image,exception); scanLineSize=(ssize_t) MagickMax(image->columns,image->rows); width=(ssize_t) scanLineSize0.002ffabs(radius); scanLineSize+=(2width); scanLinePixels_info=AcquireVirtualMemory(GetOpenMPMaximumThreads()* scanLineSize,sizeof(scanLinePixels)); if (scanLinePixels_info == (MemoryInfo ) NULL) { contrast_view=DestroyCacheView(contrast_view); image_view=DestroyCacheView(image_view); contrast_image=DestroyImage(contrast_image); ThrowImageException(ResourceLimitError,"MemoryAllocationFailed"); } scanLinePixels=(float ) GetVirtualMemoryBlob(scanLinePixels_info); / Create intermediate buffer. / interImage_info=AcquireVirtualMemory(image->rows(image->columns+(2width)), sizeof(interImage)); if (interImage_info == (MemoryInfo ) NULL) { scanLinePixels_info=RelinquishVirtualMemory(scanLinePixels_info); contrast_view=DestroyCacheView(contrast_view); image_view=DestroyCacheView(image_view); contrast_image=DestroyImage(contrast_image); ThrowImageException(ResourceLimitError,"MemoryAllocationFailed"); } interImage=(float ) GetVirtualMemoryBlob(interImage_info); totalWeight=(width+1)(width+1); / Vertical pass. / status=MagickTrue; { ssize_t x; #if defined(MAGICKCORE_OPENMP_SUPPORT) #pragma omp parallel for schedule(static) \ magick_number_threads(image,image,image->columns,1) #endif for (x=0; x < (ssize_t) image->columns; x++) { const int id = GetOpenMPThreadId(); const PixelPacket magick_restrict p; float out, pix, pixels; register ssize_t y; ssize_t i; if (status == MagickFalse) continue; pixels=scanLinePixels; pixels+=idscanLineSize; pix=pixels; p=GetCacheViewVirtualPixels(image_view,x,-width,1,image->rows+(2width), exception); if (p == (const PixelPacket ) NULL) { status=MagickFalse; continue; } for (y=0; y < (ssize_t) image->rows+(2width); y++) { pix++=(float)GetPixelLuma(image,p); p++; } out=interImage+x+width; for (y=0; y < (ssize_t) image->rows; y++) { float sum, weight; weight=1.0f; sum=0; pix=pixels+y; for (i=0; i < width; i++) { sum+=weight(pix++); weight+=1.0f; } for (i=width+1; i < (2width); i++) { sum+=weight(pix++); weight-=1.0f; } / write to output / out=sum/totalWeight; /* mirror into padding / if (x <= width && x != 0) (out-(x2))=out; if ((x > (ssize_t) image->columns-width-2) && (x != (ssize_t) image->columns-1)) (out+((image->columns-x-1)2))=out; out+=image->columns+(width2); } } } /* Horizontal pass. / { ssize_t y; #if defined(MAGICKCORE_OPENMP_SUPPORT) #pragma omp parallel for schedule(static) \ magick_number_threads(image,image,image->rows,1) #endif for (y=0; y < (ssize_t) image->rows; y++) { const int id = GetOpenMPThreadId(); const PixelPacket magick_restrict p; float pix, pixels; register PixelPacket magick_restrict q; register ssize_t x; ssize_t i; if (status == MagickFalse) continue; pixels=scanLinePixels; pixels+=idscanLineSize; p=GetCacheViewVirtualPixels(image_view,0,y,image->columns,1, exception); q=GetCacheViewAuthenticPixels(contrast_view,0,y,image->columns,1, exception); if ((p == (const PixelPacket ) NULL) \|\| (q == (PixelPacket ) NULL)) { status=MagickFalse; continue; } memcpy(pixels,interImage+(y(image->columns+(2width))),(image->columns+ (2width))sizeof(float)); for (x=0; x < (ssize_t) image->columns; x++) { float mult, srcVal, sum, weight; weight=1.0f; sum=0; pix=pixels+x; for (i=0; i < width; i++) { sum+=weight(pix++); weight+=1.0f; } for (i=width+1; i < (2width); i++) { sum+=weight(pix++); weight-=1.0f; } / Apply and write / srcVal=(float) GetPixelLuma(image,p); mult=(srcVal-(sum/totalWeight))(strength/100.0f); mult=(srcVal+mult)/srcVal; SetPixelRed(q,ClampToQuantum(GetPixelRed(p)mult)); SetPixelGreen(q,ClampToQuantum(GetPixelGreen(p)mult)); SetPixelBlue(q,ClampToQuantum(GetPixelBlue(p)mult)); p++; q++; } if (SyncCacheViewAuthenticPixels(contrast_view,exception) == MagickFalse) status=MagickFalse; } } scanLinePixels_info=RelinquishVirtualMemory(scanLinePixels_info); interImage_info=RelinquishVirtualMemory(interImage_info); contrast_view=DestroyCacheView(contrast_view); image_view=DestroyCacheView(image_view); if (status == MagickFalse) contrast_image=DestroyImage(contrast_image); return(contrast_image); } / %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % P r e v i e w I m a g e % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % PreviewImage() tiles 9 thumbnails of the specified image with an image % processing operation applied with varying parameters. This may be helpful % pin-pointing an appropriate parameter for a particular image processing % operation. % % The format of the PreviewImages method is: % % Image PreviewImages(const Image image,const PreviewType preview, % ExceptionInfo exception) % % A description of each parameter follows: % % o image: the image. % % o preview: the image processing operation. % % o exception: return any errors or warnings in this structure. % / MagickExport Image PreviewImage(const Image image,const PreviewType preview, ExceptionInfo exception) { #define NumberTiles 9 #define PreviewImageTag "Preview/Image" #define DefaultPreviewGeometry "204x204+10+10" char factor[MaxTextExtent], label[MaxTextExtent]; double degrees, gamma, percentage, radius, sigma, threshold; Image images, montage_image, preview_image, thumbnail; ImageInfo preview_info; MagickBooleanType proceed; MontageInfo montage_info; QuantizeInfo quantize_info; RectangleInfo geometry; register ssize_t i, x; size_t colors; ssize_t y; / Open output image file. / assert(image != (Image ) NULL); assert(image->signature == MagickCoreSignature); if (image->debug != MagickFalse) (void) LogMagickEvent(TraceEvent,GetMagickModule(),"%s",image->filename); colors=2; degrees=0.0; gamma=(-0.2f); preview_info=AcquireImageInfo(); SetGeometry(image,&geometry); (void) ParseMetaGeometry(DefaultPreviewGeometry,&geometry.x,&geometry.y, &geometry.width,&geometry.height); images=NewImageList(); percentage=12.5; GetQuantizeInfo(&quantize_info); radius=0.0; sigma=1.0; threshold=0.0; x=0; y=0; for (i=0; i < NumberTiles; i++) { thumbnail=ThumbnailImage(image,geometry.width,geometry.height,exception); if (thumbnail == (Image ) NULL) break; (void) SetImageProgressMonitor(thumbnail,(MagickProgressMonitor) NULL, (void ) NULL); (void) SetImageProperty(thumbnail,"label",DefaultTileLabel); if (i == (NumberTiles/2)) { (void) QueryColorDatabase("#dfdfdf",&thumbnail->matte_color,exception); AppendImageToList(&images,thumbnail); continue; } switch (preview) { case RotatePreview: { degrees+=45.0; preview_image=RotateImage(thumbnail,degrees,exception); (void) FormatLocaleString(label,MaxTextExtent,"rotate %g",degrees); break; } case ShearPreview: { degrees+=5.0; preview_image=ShearImage(thumbnail,degrees,degrees,exception); (void) FormatLocaleString(label,MaxTextExtent,"shear %gx%g", degrees,2.0degrees); break; } case RollPreview: { x=(ssize_t) ((i+1)thumbnail->columns)/NumberTiles; y=(ssize_t) ((i+1)thumbnail->rows)/NumberTiles; preview_image=RollImage(thumbnail,x,y,exception); (void) FormatLocaleString(label,MaxTextExtent,"roll %+.20gx%+.20g", (double) x,(double) y); break; } case HuePreview: { preview_image=CloneImage(thumbnail,0,0,MagickTrue,exception); if (preview_image == (Image ) NULL) break; (void) FormatLocaleString(factor,MaxTextExtent,"100,100,%g", 2.0percentage); (void) ModulateImage(preview_image,factor); (void) FormatLocaleString(label,MaxTextExtent,"modulate %s",factor); break; } case SaturationPreview: { preview_image=CloneImage(thumbnail,0,0,MagickTrue,exception); if (preview_image == (Image ) NULL) break; (void) FormatLocaleString(factor,MaxTextExtent,"100,%g",2.0percentage); (void) ModulateImage(preview_image,factor); (void) FormatLocaleString(label,MaxTextExtent,"modulate %s",factor); break; } case BrightnessPreview: { preview_image=CloneImage(thumbnail,0,0,MagickTrue,exception); if (preview_image == (Image ) NULL) break; (void) FormatLocaleString(factor,MaxTextExtent,"%g",2.0percentage); (void) ModulateImage(preview_image,factor); (void) FormatLocaleString(label,MaxTextExtent,"modulate %s",factor); break; } case GammaPreview: default: { preview_image=CloneImage(thumbnail,0,0,MagickTrue,exception); if (preview_image == (Image ) NULL) break; gamma+=0.4f; (void) GammaImageChannel(preview_image,DefaultChannels,gamma); (void) FormatLocaleString(label,MaxTextExtent,"gamma %g",gamma); break; } case SpiffPreview: { preview_image=CloneImage(thumbnail,0,0,MagickTrue,exception); if (preview_image != (Image ) NULL) for (x=0; x < i; x++) (void) ContrastImage(preview_image,MagickTrue); (void) FormatLocaleString(label,MaxTextExtent,"contrast (%.20g)", (double) i+1); break; } case DullPreview: { preview_image=CloneImage(thumbnail,0,0,MagickTrue,exception); if (preview_image == (Image ) NULL) break; for (x=0; x < i; x++) (void) ContrastImage(preview_image,MagickFalse); (void) FormatLocaleString(label,MaxTextExtent,"+contrast (%.20g)", (double) i+1); break; } case GrayscalePreview: { preview_image=CloneImage(thumbnail,0,0,MagickTrue,exception); if (preview_image == (Image ) NULL) break; colors<<=1; quantize_info.number_colors=colors; quantize_info.colorspace=GRAYColorspace; (void) QuantizeImage(&quantize_info,preview_image); (void) FormatLocaleString(label,MaxTextExtent, "-colorspace gray -colors %.20g",(double) colors); break; } case QuantizePreview: { preview_image=CloneImage(thumbnail,0,0,MagickTrue,exception); if (preview_image == (Image ) NULL) break; colors<<=1; quantize_info.number_colors=colors; (void) QuantizeImage(&quantize_info,preview_image); (void) FormatLocaleString(label,MaxTextExtent,"colors %.20g",(double) colors); break; } case DespecklePreview: { for (x=0; x < (i-1); x++) { preview_image=DespeckleImage(thumbnail,exception); if (preview_image == (Image ) NULL) break; thumbnail=DestroyImage(thumbnail); thumbnail=preview_image; } preview_image=DespeckleImage(thumbnail,exception); if (preview_image == (Image ) NULL) break; (void) FormatLocaleString(label,MaxTextExtent,"despeckle (%.20g)", (double) i+1); break; } case ReduceNoisePreview: { preview_image=StatisticImage(thumbnail,NonpeakStatistic,(size_t) radius, (size_t) radius,exception); (void) FormatLocaleString(label,MaxTextExtent,"noise %g",radius); break; } case AddNoisePreview: { switch ((int) i) { case 0: { (void) CopyMagickString(factor,"uniform",MaxTextExtent); break; } case 1: { (void) CopyMagickString(factor,"gaussian",MaxTextExtent); break; } case 2: { (void) CopyMagickString(factor,"multiplicative",MaxTextExtent); break; } case 3: { (void) CopyMagickString(factor,"impulse",MaxTextExtent); break; } case 5: { (void) CopyMagickString(factor,"laplacian",MaxTextExtent); break; } case 6: { (void) CopyMagickString(factor,"poisson",MaxTextExtent); break; } default: { (void) CopyMagickString(thumbnail->magick,"NULL",MaxTextExtent); break; } } preview_image=StatisticImage(thumbnail,NonpeakStatistic,(size_t) i, (size_t) i,exception); (void) FormatLocaleString(label,MaxTextExtent,"+noise %s",factor); break; } case SharpenPreview: { preview_image=SharpenImage(thumbnail,radius,sigma,exception); (void) FormatLocaleString(label,MaxTextExtent,"sharpen %gx%g", radius,sigma); break; } case BlurPreview: { preview_image=BlurImage(thumbnail,radius,sigma,exception); (void) FormatLocaleString(label,MaxTextExtent,"blur %gx%g",radius, sigma); break; } case ThresholdPreview: { preview_image=CloneImage(thumbnail,0,0,MagickTrue,exception); if (preview_image == (Image ) NULL) break; (void) BilevelImage(thumbnail, (double) (percentage((MagickRealType) QuantumRange+1.0))/100.0); (void) FormatLocaleString(label,MaxTextExtent,"threshold %g", (double) (percentage((MagickRealType) QuantumRange+1.0))/100.0); break; } case EdgeDetectPreview: { preview_image=EdgeImage(thumbnail,radius,exception); (void) FormatLocaleString(label,MaxTextExtent,"edge %g",radius); break; } case SpreadPreview: { preview_image=SpreadImage(thumbnail,radius,exception); (void) FormatLocaleString(label,MaxTextExtent,"spread %g", radius+0.5); break; } case SolarizePreview: { preview_image=CloneImage(thumbnail,0,0,MagickTrue,exception); if (preview_image == (Image ) NULL) break; (void) SolarizeImage(preview_image,(double) QuantumRange* percentage/100.0); (void) FormatLocaleString(label,MaxTextExtent,"solarize %g", (QuantumRangepercentage)/100.0); break; } case ShadePreview: { degrees+=10.0; preview_image=ShadeImage(thumbnail,MagickTrue,degrees,degrees, exception); (void) FormatLocaleString(label,MaxTextExtent,"shade %gx%g", degrees,degrees); break; } case RaisePreview: { preview_image=CloneImage(thumbnail,0,0,MagickTrue,exception); if (preview_image == (Image ) NULL) break; geometry.width=(size_t) (2i+2); geometry.height=(size_t) (2i+2); geometry.x=(i-1)/2; geometry.y=(i-1)/2; (void) RaiseImage(preview_image,&geometry,MagickTrue); (void) FormatLocaleString(label,MaxTextExtent, "raise %.20gx%.20g%+.20g%+.20g",(double) geometry.width,(double) geometry.height,(double) geometry.x,(double) geometry.y); break; } case SegmentPreview: { preview_image=CloneImage(thumbnail,0,0,MagickTrue,exception); if (preview_image == (Image ) NULL) break; threshold+=0.4f; (void) SegmentImage(preview_image,sRGBColorspace,MagickFalse,threshold, threshold); (void) FormatLocaleString(label,MaxTextExtent,"segment %gx%g", threshold,threshold); break; } case SwirlPreview: { preview_image=SwirlImage(thumbnail,degrees,exception); (void) FormatLocaleString(label,MaxTextExtent,"swirl %g",degrees); degrees+=45.0; break; } case ImplodePreview: { degrees+=0.1f; preview_image=ImplodeImage(thumbnail,degrees,exception); (void) FormatLocaleString(label,MaxTextExtent,"implode %g",degrees); break; } case WavePreview: { degrees+=5.0f; preview_image=WaveImage(thumbnail,0.5degrees,2.0degrees,exception); (void) FormatLocaleString(label,MaxTextExtent,"wave %gx%g", 0.5degrees,2.0degrees); break; } case OilPaintPreview: { preview_image=OilPaintImage(thumbnail,(double) radius,exception); (void) FormatLocaleString(label,MaxTextExtent,"paint %g",radius); break; } case CharcoalDrawingPreview: { preview_image=CharcoalImage(thumbnail,(double) radius,(double) sigma, exception); (void) FormatLocaleString(label,MaxTextExtent,"charcoal %gx%g", radius,sigma); break; } case JPEGPreview: { char filename[MaxTextExtent]; int file; MagickBooleanType status; preview_image=CloneImage(thumbnail,0,0,MagickTrue,exception); if (preview_image == (Image ) NULL) break; preview_info->quality=(size_t) percentage; (void) FormatLocaleString(factor,MaxTextExtent,"%.20g",(double) preview_info->quality); file=AcquireUniqueFileResource(filename); if (file != -1) file=close(file)-1; (void) FormatLocaleString(preview_image->filename,MaxTextExtent, "jpeg:%s",filename); status=WriteImage(preview_info,preview_image); if (status != MagickFalse) { Image quality_image; (void) CopyMagickString(preview_info->filename, preview_image->filename,MaxTextExtent); quality_image=ReadImage(preview_info,exception); if (quality_image != (Image ) NULL) { preview_image=DestroyImage(preview_image); preview_image=quality_image; } } (void) RelinquishUniqueFileResource(preview_image->filename); if ((GetBlobSize(preview_image)/1024) >= 1024) (void) FormatLocaleString(label,MaxTextExtent,"quality %s\n%gmb ", factor,(double) ((MagickOffsetType) GetBlobSize(preview_image))/ 1024.0/1024.0); else if (GetBlobSize(preview_image) >= 1024) (void) FormatLocaleString(label,MaxTextExtent, "quality %s\n%gkb ",factor,(double) ((MagickOffsetType) GetBlobSize(preview_image))/1024.0); else (void) FormatLocaleString(label,MaxTextExtent,"quality %s\n%.20gb ", factor,(double) ((MagickOffsetType) GetBlobSize(thumbnail))); break; } } thumbnail=DestroyImage(thumbnail); percentage+=12.5; radius+=0.5; sigma+=0.25; if (preview_image == (Image ) NULL) break; (void) DeleteImageProperty(preview_image,"label"); (void) SetImageProperty(preview_image,"label",label); AppendImageToList(&images,preview_image); proceed=SetImageProgress(image,PreviewImageTag,(MagickOffsetType) i, NumberTiles); if (proceed == MagickFalse) break; } if (images == (Image ) NULL) { preview_info=DestroyImageInfo(preview_info); return((Image ) NULL); } / Create the montage. / montage_info=CloneMontageInfo(preview_info,(MontageInfo ) NULL); (void) CopyMagickString(montage_info->filename,image->filename,MaxTextExtent); montage_info->shadow=MagickTrue; (void) CloneString(&montage_info->tile,"3x3"); (void) CloneString(&montage_info->geometry,DefaultPreviewGeometry); (void) CloneString(&montage_info->frame,DefaultTileFrame); montage_image=MontageImages(images,montage_info,exception); montage_info=DestroyMontageInfo(montage_info); images=DestroyImageList(images); if (montage_image == (Image ) NULL) ThrowImageException(ResourceLimitError,"MemoryAllocationFailed"); if (montage_image->montage != (char ) NULL) { /* Free image directory. / montage_image->montage=(char ) RelinquishMagickMemory( montage_image->montage); if (image->directory != (char ) NULL) montage_image->directory=(char ) RelinquishMagickMemory( montage_image->directory); } preview_info=DestroyImageInfo(preview_info); return(montage_image); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % R o t a t i o n a l B l u r I m a g e % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % RotationalBlurImage() applies a rotational blur to the image. % % Andrew Protano contributed this effect. % % The format of the RotationalBlurImage method is: % % Image RotationalBlurImage(const Image image,const double angle, % ExceptionInfo exception) % Image RotationalBlurImageChannel(const Image image, % const ChannelType channel,const double angle,ExceptionInfo exception) % % A description of each parameter follows: % % o image: the image. % % o channel: the channel type. % % o angle: the angle of the rotational blur. % % o exception: return any errors or warnings in this structure. % / MagickExport Image RotationalBlurImage(const Image image,const double angle, ExceptionInfo exception) { Image blur_image; blur_image=RotationalBlurImageChannel(image,DefaultChannels,angle,exception); return(blur_image); } MagickExport Image RotationalBlurImageChannel(const Image image, const ChannelType channel,const double angle,ExceptionInfo exception) { CacheView blur_view, image_view; Image blur_image; MagickBooleanType status; MagickOffsetType progress; MagickPixelPacket bias; MagickRealType blur_radius, cos_theta, offset, sin_theta, theta; PointInfo blur_center; register ssize_t i; size_t n; ssize_t y; / Allocate blur image. / assert(image != (Image ) NULL); assert(image->signature == MagickCoreSignature); if (image->debug != MagickFalse) (void) LogMagickEvent(TraceEvent,GetMagickModule(),"%s",image->filename); assert(exception != (ExceptionInfo ) NULL); assert(exception->signature == MagickCoreSignature); #if defined(MAGICKCORE_OPENCL_SUPPORT) blur_image=AccelerateRadialBlurImage(image,channel,angle,exception); if (blur_image != (Image ) NULL) return(blur_image); #endif blur_image=CloneImage(image,0,0,MagickTrue,exception); if (blur_image == (Image ) NULL) return((Image ) NULL); if (SetImageStorageClass(blur_image,DirectClass) == MagickFalse) { InheritException(exception,&blur_image->exception); blur_image=DestroyImage(blur_image); return((Image ) NULL); } blur_center.x=(double) (image->columns-1)/2.0; blur_center.y=(double) (image->rows-1)/2.0; blur_radius=hypot(blur_center.x,blur_center.y); n=(size_t) fabs(4.0DegreesToRadians(angle)sqrt((double) blur_radius)+2UL); theta=DegreesToRadians(angle)/(MagickRealType) (n-1); cos_theta=(MagickRealType ) AcquireQuantumMemory((size_t) n, sizeof(cos_theta)); sin_theta=(MagickRealType ) AcquireQuantumMemory((size_t) n, sizeof(sin_theta)); if ((cos_theta == (MagickRealType ) NULL) \|\| (sin_theta == (MagickRealType ) NULL)) { if (cos_theta != (double ) NULL) cos_theta=(double ) RelinquishMagickMemory(cos_theta); if (sin_theta != (double ) NULL) sin_theta=(double ) RelinquishMagickMemory(sin_theta); blur_image=DestroyImage(blur_image); ThrowImageException(ResourceLimitError,"MemoryAllocationFailed"); } offset=theta(MagickRealType) (n-1)/2.0; for (i=0; i < (ssize_t) n; i++) { cos_theta[i]=cos((double) (thetai-offset)); sin_theta[i]=sin((double) (thetai-offset)); } /* Radial blur image. / status=MagickTrue; progress=0; GetMagickPixelPacket(image,&bias); image_view=AcquireVirtualCacheView(image,exception); blur_view=AcquireAuthenticCacheView(blur_image,exception); #if defined(MAGICKCORE_OPENMP_SUPPORT) #pragma omp parallel for schedule(static) shared(progress,status) \ magick_number_threads(image,blur_image,blur_image->rows,1) #endif for (y=0; y < (ssize_t) blur_image->rows; y++) { register const IndexPacket magick_restrict indexes; register IndexPacket magick_restrict blur_indexes; register PixelPacket magick_restrict q; register ssize_t x; if (status == MagickFalse) continue; q=GetCacheViewAuthenticPixels(blur_view,0,y,blur_image->columns,1, exception); if (q == (PixelPacket ) NULL) { status=MagickFalse; continue; } blur_indexes=GetCacheViewAuthenticIndexQueue(blur_view); for (x=0; x < (ssize_t) blur_image->columns; x++) { MagickPixelPacket qixel; MagickRealType normalize, radius; PixelPacket pixel; PointInfo center; register ssize_t i; size_t step; center.x=(double) x-blur_center.x; center.y=(double) y-blur_center.y; radius=hypot((double) center.x,center.y); if (radius == 0) step=1; else { step=(size_t) (blur_radius/radius); if (step == 0) step=1; else if (step >= n) step=n-1; } normalize=0.0; qixel=bias; if (((channel & OpacityChannel) == 0) \|\| (image->matte == MagickFalse)) { for (i=0; i < (ssize_t) n; i+=(ssize_t) step) { (void) GetOneCacheViewVirtualPixel(image_view,(ssize_t) (blur_center.x+center.xcos_theta[i]-center.ysin_theta[i]+0.5), (ssize_t) (blur_center.y+center.xsin_theta[i]+center.y* cos_theta[i]+0.5),&pixel,exception); qixel.red+=pixel.red; qixel.green+=pixel.green; qixel.blue+=pixel.blue; qixel.opacity+=pixel.opacity; if (image->colorspace == CMYKColorspace) { indexes=GetCacheViewVirtualIndexQueue(image_view); qixel.index+=(indexes); } normalize+=1.0; } normalize=PerceptibleReciprocal(normalize); if ((channel & RedChannel) != 0) SetPixelRed(q,ClampToQuantum(normalizeqixel.red)); if ((channel & GreenChannel) != 0) SetPixelGreen(q,ClampToQuantum(normalizeqixel.green)); if ((channel & BlueChannel) != 0) SetPixelBlue(q,ClampToQuantum(normalizeqixel.blue)); if ((channel & OpacityChannel) != 0) SetPixelOpacity(q,ClampToQuantum(normalizeqixel.opacity)); if (((channel & IndexChannel) != 0) && (image->colorspace == CMYKColorspace)) SetPixelIndex(blur_indexes+x,ClampToQuantum(normalizeqixel.index)); } else { double alpha, gamma; alpha=1.0; gamma=0.0; for (i=0; i < (ssize_t) n; i+=(ssize_t) step) { (void) GetOneCacheViewVirtualPixel(image_view,(ssize_t) (blur_center.x+center.xcos_theta[i]-center.ysin_theta[i]+0.5), (ssize_t) (blur_center.y+center.xsin_theta[i]+center.y cos_theta[i]+0.5),&pixel,exception); alpha=(MagickRealType) (QuantumScaleGetPixelAlpha(&pixel)); qixel.red+=alphapixel.red; qixel.green+=alphapixel.green; qixel.blue+=alphapixel.blue; qixel.opacity+=pixel.opacity; if (image->colorspace == CMYKColorspace) { indexes=GetCacheViewVirtualIndexQueue(image_view); qixel.index+=alpha(indexes); } gamma+=alpha; normalize+=1.0; } gamma=PerceptibleReciprocal(gamma); normalize=PerceptibleReciprocal(normalize); if ((channel & RedChannel) != 0) SetPixelRed(q,ClampToQuantum(gammaqixel.red)); if ((channel & GreenChannel) != 0) SetPixelGreen(q,ClampToQuantum(gammaqixel.green)); if ((channel & BlueChannel) != 0) SetPixelBlue(q,ClampToQuantum(gammaqixel.blue)); if ((channel & OpacityChannel) != 0) SetPixelOpacity(q,ClampToQuantum(normalizeqixel.opacity)); if (((channel & IndexChannel) != 0) && (image->colorspace == CMYKColorspace)) SetPixelIndex(blur_indexes+x,ClampToQuantum(gammaqixel.index)); } q++; } if (SyncCacheViewAuthenticPixels(blur_view,exception) == MagickFalse) status=MagickFalse; if (image->progress_monitor != (MagickProgressMonitor) NULL) { MagickBooleanType proceed; #if defined(MAGICKCORE_OPENMP_SUPPORT) #pragma omp atomic #endif progress++; proceed=SetImageProgress(image,BlurImageTag,progress,image->rows); if (proceed == MagickFalse) status=MagickFalse; } } blur_view=DestroyCacheView(blur_view); image_view=DestroyCacheView(image_view); cos_theta=(MagickRealType ) RelinquishMagickMemory(cos_theta); sin_theta=(MagickRealType ) RelinquishMagickMemory(sin_theta); if (status == MagickFalse) blur_image=DestroyImage(blur_image); return(blur_image); } / %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % S e l e c t i v e B l u r I m a g e % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % SelectiveBlurImage() selectively blur pixels within a contrast threshold. % It is similar to the unsharpen mask that sharpens everything with contrast % above a certain threshold. % % The format of the SelectiveBlurImage method is: % % Image SelectiveBlurImage(const Image image,const double radius, % const double sigma,const double threshold,ExceptionInfo exception) % Image SelectiveBlurImageChannel(const Image image, % const ChannelType channel,const double radius,const double sigma, % const double threshold,ExceptionInfo exception) % % A description of each parameter follows: % % o image: the image. % % o channel: the channel type. % % o radius: the radius of the Gaussian, in pixels, not counting the center % pixel. % % o sigma: the standard deviation of the Gaussian, in pixels. % % o threshold: only pixels within this contrast threshold are included % in the blur operation. % % o exception: return any errors or warnings in this structure. % / MagickExport Image SelectiveBlurImage(const Image image,const double radius, const double sigma,const double threshold,ExceptionInfo exception) { Image blur_image; blur_image=SelectiveBlurImageChannel(image,DefaultChannels,radius,sigma, threshold,exception); return(blur_image); } MagickExport Image SelectiveBlurImageChannel(const Image image, const ChannelType channel,const double radius,const double sigma, const double threshold,ExceptionInfo exception) { #define SelectiveBlurImageTag "SelectiveBlur/Image" CacheView blur_view, image_view, luminance_view; double kernel; Image blur_image, luminance_image; MagickBooleanType status; MagickOffsetType progress; MagickPixelPacket bias; register ssize_t i; size_t width; ssize_t center, j, u, v, y; /* Initialize blur image attributes. / assert(image != (Image ) NULL); assert(image->signature == MagickCoreSignature); if (image->debug != MagickFalse) (void) LogMagickEvent(TraceEvent,GetMagickModule(),"%s",image->filename); assert(exception != (ExceptionInfo ) NULL); assert(exception->signature == MagickCoreSignature); width=GetOptimalKernelWidth1D(radius,sigma); kernel=(double ) MagickAssumeAligned(AcquireAlignedMemory((size_t) width, widthsizeof(kernel))); if (kernel == (double ) NULL) ThrowImageException(ResourceLimitError,"MemoryAllocationFailed"); j=(ssize_t) (width-1)/2; i=0; for (v=(-j); v <= j; v++) { for (u=(-j); u <= j; u++) kernel[i++]=(double) (exp(-((double) uu+vv)/(2.0MagickSigma* MagickSigma))/(2.0MagickPIMagickSigmaMagickSigma)); } if (image->debug != MagickFalse) { char format[MaxTextExtent], message; register const double k; ssize_t u, v; (void) LogMagickEvent(TransformEvent,GetMagickModule(), " SelectiveBlurImage with %.20gx%.20g kernel:",(double) width,(double) width); message=AcquireString(""); k=kernel; for (v=0; v < (ssize_t) width; v++) { message='\0'; (void) FormatLocaleString(format,MaxTextExtent,"%.20g: ",(double) v); (void) ConcatenateString(&message,format); for (u=0; u < (ssize_t) width; u++) { (void) FormatLocaleString(format,MaxTextExtent,"%+f ",k++); (void) ConcatenateString(&message,format); } (void) LogMagickEvent(TransformEvent,GetMagickModule(),"%s",message); } message=DestroyString(message); } blur_image=CloneImage(image,0,0,MagickTrue,exception); if (blur_image == (Image ) NULL) { kernel=(double ) RelinquishAlignedMemory(kernel); return((Image ) NULL); } if (SetImageStorageClass(blur_image,DirectClass) == MagickFalse) { kernel=(double ) RelinquishAlignedMemory(kernel); InheritException(exception,&blur_image->exception); blur_image=DestroyImage(blur_image); return((Image ) NULL); } luminance_image=CloneImage(image,0,0,MagickTrue,exception); if (luminance_image == (Image ) NULL) { kernel=(double ) RelinquishAlignedMemory(kernel); blur_image=DestroyImage(blur_image); return((Image ) NULL); } status=TransformImageColorspace(luminance_image,GRAYColorspace); if (status == MagickFalse) { InheritException(exception,&luminance_image->exception); kernel=(double ) RelinquishAlignedMemory(kernel); blur_image=DestroyImage(blur_image); luminance_image=DestroyImage(luminance_image); return((Image ) NULL); } / Threshold blur image. / status=MagickTrue; progress=0; center=(ssize_t) ((image->columns+width)((width-1)/2L)+((width-1)/2L)); GetMagickPixelPacket(image,&bias); SetMagickPixelPacketBias(image,&bias); image_view=AcquireVirtualCacheView(image,exception); luminance_view=AcquireVirtualCacheView(luminance_image,exception); blur_view=AcquireAuthenticCacheView(blur_image,exception); #if defined(MAGICKCORE_OPENMP_SUPPORT) #pragma omp parallel for schedule(static) shared(progress,status) \ magick_number_threads(image,blur_image,image->rows,1) #endif for (y=0; y < (ssize_t) image->rows; y++) { double gamma; MagickBooleanType sync; register const IndexPacket magick_restrict indexes; register const PixelPacket magick_restrict l, magick_restrict p; register IndexPacket magick_restrict blur_indexes; register PixelPacket magick_restrict q; register ssize_t x; if (status == MagickFalse) continue; p=GetCacheViewVirtualPixels(image_view,-((ssize_t) (width-1)/2L),y-(ssize_t) ((width-1)/2L),image->columns+width,width,exception); l=GetCacheViewVirtualPixels(luminance_view,-((ssize_t) (width-1)/2L),y- (ssize_t) ((width-1)/2L),luminance_image->columns+width,width,exception); q=GetCacheViewAuthenticPixels(blur_view,0,y,blur_image->columns,1, exception); if ((p == (const PixelPacket ) NULL) \|\| (l == (const PixelPacket ) NULL) \|\| (q == (PixelPacket ) NULL)) { status=MagickFalse; continue; } indexes=GetCacheViewVirtualIndexQueue(image_view); blur_indexes=GetCacheViewAuthenticIndexQueue(blur_view); for (x=0; x < (ssize_t) image->columns; x++) { double contrast; DoublePixelPacket pixel; MagickRealType intensity; register const double magick_restrict k; register ssize_t u; ssize_t j, v; pixel.red=bias.red; pixel.green=bias.green; pixel.blue=bias.blue; pixel.opacity=bias.opacity; pixel.index=bias.index; k=kernel; intensity=GetPixelIntensity(image,p+center); gamma=0.0; j=0; if (((channel & OpacityChannel) == 0) \|\| (image->matte == MagickFalse)) { for (v=0; v < (ssize_t) width; v++) { for (u=0; u < (ssize_t) width; u++) { contrast=GetPixelIntensity(luminance_image,l+u+j)-intensity; if (fabs(contrast) < threshold) { pixel.red+=(k)GetPixelRed(p+u+j); pixel.green+=(k)GetPixelGreen(p+u+j); pixel.blue+=(k)GetPixelBlue(p+u+j); gamma+=(k); } k++; } j+=(ssize_t) (image->columns+width); } if (gamma != 0.0) { gamma=PerceptibleReciprocal(gamma); if ((channel & RedChannel) != 0) SetPixelRed(q,ClampToQuantum(gammapixel.red)); if ((channel & GreenChannel) != 0) SetPixelGreen(q,ClampToQuantum(gammapixel.green)); if ((channel & BlueChannel) != 0) SetPixelBlue(q,ClampToQuantum(gammapixel.blue)); } if ((channel & OpacityChannel) != 0) { gamma=0.0; j=0; for (v=0; v < (ssize_t) width; v++) { for (u=0; u < (ssize_t) width; u++) { contrast=GetPixelIntensity(luminance_image,l+u+j)-intensity; if (fabs(contrast) < threshold) { pixel.opacity+=(k)(p+u+j)->opacity; gamma+=(k); } k++; } j+=(ssize_t) (image->columns+width); } gamma=PerceptibleReciprocal(gamma); SetPixelOpacity(q,ClampToQuantum(gammapixel.opacity)); } if (((channel & IndexChannel) != 0) && (image->colorspace == CMYKColorspace)) { gamma=0.0; j=0; for (v=0; v < (ssize_t) width; v++) { for (u=0; u < (ssize_t) width; u++) { contrast=GetPixelIntensity(luminance_image,l+u+j)-intensity; if (fabs(contrast) < threshold) { pixel.index+=(k)GetPixelIndex(indexes+x+u+j); gamma+=(k); } k++; } j+=(ssize_t) (image->columns+width); } gamma=PerceptibleReciprocal(gamma); SetPixelIndex(blur_indexes+x,ClampToQuantum(gammapixel.index)); } } else { MagickRealType alpha; for (v=0; v < (ssize_t) width; v++) { for (u=0; u < (ssize_t) width; u++) { contrast=GetPixelIntensity(luminance_image,l+u+j)-intensity; if (fabs(contrast) < threshold) { alpha=(MagickRealType) (QuantumScaleGetPixelAlpha(p+u+j)); pixel.red+=(k)alphaGetPixelRed(p+u+j); pixel.green+=(k)alphaGetPixelGreen(p+u+j); pixel.blue+=(k)alphaGetPixelBlue(p+u+j); pixel.opacity+=(k)GetPixelOpacity(p+u+j); gamma+=(k)alpha; } k++; } j+=(ssize_t) (image->columns+width); } if (gamma != 0.0) { gamma=PerceptibleReciprocal(gamma); if ((channel & RedChannel) != 0) SetPixelRed(q,ClampToQuantum(gammapixel.red)); if ((channel & GreenChannel) != 0) SetPixelGreen(q,ClampToQuantum(gammapixel.green)); if ((channel & BlueChannel) != 0) SetPixelBlue(q,ClampToQuantum(gammapixel.blue)); } if ((channel & OpacityChannel) != 0) { j=0; for (v=0; v < (ssize_t) width; v++) { for (u=0; u < (ssize_t) width; u++) { contrast=GetPixelIntensity(luminance_image,l+u+j)-intensity; if (fabs(contrast) < threshold) pixel.opacity+=(k)GetPixelOpacity(p+u+j); k++; } j+=(ssize_t) (image->columns+width); } SetPixelOpacity(q,ClampToQuantum(pixel.opacity)); } if (((channel & IndexChannel) != 0) && (image->colorspace == CMYKColorspace)) { gamma=0.0; j=0; for (v=0; v < (ssize_t) width; v++) { for (u=0; u < (ssize_t) width; u++) { contrast=GetPixelIntensity(luminance_image,l+u+j)-intensity; if (fabs(contrast) < threshold) { alpha=(MagickRealType) (QuantumScale* GetPixelAlpha(p+u+j)); pixel.index+=(k)alphaGetPixelIndex(indexes+x+u+j); gamma+=(k); } k++; } j+=(ssize_t) (image->columns+width); } gamma=PerceptibleReciprocal(gamma); SetPixelIndex(blur_indexes+x,ClampToQuantum(gammapixel.index)); } } p++; l++; q++; } sync=SyncCacheViewAuthenticPixels(blur_view,exception); if (sync == MagickFalse) status=MagickFalse; if (image->progress_monitor != (MagickProgressMonitor) NULL) { MagickBooleanType proceed; #if defined(MAGICKCORE_OPENMP_SUPPORT) #pragma omp atomic #endif progress++; proceed=SetImageProgress(image,SelectiveBlurImageTag,progress, image->rows); if (proceed == MagickFalse) status=MagickFalse; } } blur_image->type=image->type; blur_view=DestroyCacheView(blur_view); luminance_view=DestroyCacheView(luminance_view); image_view=DestroyCacheView(image_view); luminance_image=DestroyImage(luminance_image); kernel=(double ) RelinquishAlignedMemory(kernel); if (status == MagickFalse) blur_image=DestroyImage(blur_image); return(blur_image); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % S h a d e I m a g e % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % ShadeImage() shines a distant light on an image to create a % three-dimensional effect. You control the positioning of the light with % azimuth and elevation; azimuth is measured in degrees off the x axis % and elevation is measured in pixels above the Z axis. % % The format of the ShadeImage method is: % % Image ShadeImage(const Image image,const MagickBooleanType gray, % const double azimuth,const double elevation,ExceptionInfo exception) % % A description of each parameter follows: % % o image: the image. % % o gray: A value other than zero shades the intensity of each pixel. % % o azimuth, elevation: Define the light source direction. % % o exception: return any errors or warnings in this structure. % / MagickExport Image ShadeImage(const Image image,const MagickBooleanType gray, const double azimuth,const double elevation,ExceptionInfo exception) { #define ShadeImageTag "Shade/Image" CacheView image_view, shade_view; Image linear_image, shade_image; MagickBooleanType status; MagickOffsetType progress; PrimaryInfo light; ssize_t y; / Initialize shaded image attributes. / assert(image != (const Image ) NULL); assert(image->signature == MagickCoreSignature); if (image->debug != MagickFalse) (void) LogMagickEvent(TraceEvent,GetMagickModule(),"%s",image->filename); assert(exception != (ExceptionInfo ) NULL); assert(exception->signature == MagickCoreSignature); linear_image=CloneImage(image,0,0,MagickTrue,exception); shade_image=CloneImage(image,0,0,MagickTrue,exception); if ((linear_image == (Image ) NULL) \|\| (shade_image == (Image ) NULL)) { if (linear_image != (Image ) NULL) linear_image=DestroyImage(linear_image); if (shade_image != (Image ) NULL) shade_image=DestroyImage(shade_image); return((Image ) NULL); } if (SetImageStorageClass(shade_image,DirectClass) == MagickFalse) { InheritException(exception,&shade_image->exception); linear_image=DestroyImage(linear_image); shade_image=DestroyImage(shade_image); return((Image ) NULL); } / Compute the light vector. / light.x=(double) QuantumRangecos(DegreesToRadians(azimuth))* cos(DegreesToRadians(elevation)); light.y=(double) QuantumRangesin(DegreesToRadians(azimuth)) cos(DegreesToRadians(elevation)); light.z=(double) QuantumRangesin(DegreesToRadians(elevation)); / Shade image. / status=MagickTrue; progress=0; image_view=AcquireVirtualCacheView(linear_image,exception); shade_view=AcquireAuthenticCacheView(shade_image,exception); #if defined(MAGICKCORE_OPENMP_SUPPORT) #pragma omp parallel for schedule(static) shared(progress,status) \ magick_number_threads(linear_image,shade_image,linear_image->rows,1) #endif for (y=0; y < (ssize_t) linear_image->rows; y++) { MagickRealType distance, normal_distance, shade; PrimaryInfo normal; register const PixelPacket magick_restrict p, magick_restrict s0, magick_restrict s1, magick_restrict s2; register PixelPacket magick_restrict q; register ssize_t x; if (status == MagickFalse) continue; p=GetCacheViewVirtualPixels(image_view,-1,y-1,linear_image->columns+2,3, exception); q=QueueCacheViewAuthenticPixels(shade_view,0,y,shade_image->columns,1, exception); if ((p == (PixelPacket ) NULL) \|\| (q == (PixelPacket ) NULL)) { status=MagickFalse; continue; } /* Shade this row of pixels. / normal.z=2.0(double) QuantumRange; /* constant Z of surface normal / for (x=0; x < (ssize_t) linear_image->columns; x++) { / Determine the surface normal and compute shading. / s0=p+1; s1=s0+image->columns+2; s2=s1+image->columns+2; normal.x=(double) (GetPixelIntensity(linear_image,s0-1)+ GetPixelIntensity(linear_image,s1-1)+ GetPixelIntensity(linear_image,s2-1)- GetPixelIntensity(linear_image,s0+1)- GetPixelIntensity(linear_image,s1+1)- GetPixelIntensity(linear_image,s2+1)); normal.y=(double) (GetPixelIntensity(linear_image,s2-1)+ GetPixelIntensity(linear_image,s2)+ GetPixelIntensity(linear_image,s2+1)- GetPixelIntensity(linear_image,s0-1)- GetPixelIntensity(linear_image,s0)- GetPixelIntensity(linear_image,s0+1)); if ((fabs(normal.x) <= MagickEpsilon) && (fabs(normal.y) <= MagickEpsilon)) shade=light.z; else { shade=0.0; distance=normal.xlight.x+normal.ylight.y+normal.zlight.z; if (distance > MagickEpsilon) { normal_distance=normal.xnormal.x+normal.ynormal.y+normal.z* normal.z; if (normal_distance > (MagickEpsilonMagickEpsilon)) shade=distance/sqrt((double) normal_distance); } } if (gray != MagickFalse) { SetPixelRed(q,shade); SetPixelGreen(q,shade); SetPixelBlue(q,shade); } else { SetPixelRed(q,ClampToQuantum(QuantumScaleshadeGetPixelRed(s1))); SetPixelGreen(q,ClampToQuantum(QuantumScaleshadeGetPixelGreen(s1))); SetPixelBlue(q,ClampToQuantum(QuantumScaleshadeGetPixelBlue(s1))); } q->opacity=s1->opacity; p++; q++; } if (SyncCacheViewAuthenticPixels(shade_view,exception) == MagickFalse) status=MagickFalse; if (image->progress_monitor != (MagickProgressMonitor) NULL) { MagickBooleanType proceed; #if defined(MAGICKCORE_OPENMP_SUPPORT) #pragma omp atomic #endif progress++; proceed=SetImageProgress(image,ShadeImageTag,progress,image->rows); if (proceed == MagickFalse) status=MagickFalse; } } shade_view=DestroyCacheView(shade_view); image_view=DestroyCacheView(image_view); linear_image=DestroyImage(linear_image); if (status == MagickFalse) shade_image=DestroyImage(shade_image); return(shade_image); } / %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % S h a r p e n I m a g e % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % SharpenImage() sharpens the image. We convolve the image with a Gaussian % operator of the given radius and standard deviation (sigma). For % reasonable results, radius should be larger than sigma. Use a radius of 0 % and SharpenImage() selects a suitable radius for you. % % Using a separable kernel would be faster, but the negative weights cancel % out on the corners of the kernel producing often undesirable ringing in the % filtered result; this can be avoided by using a 2D gaussian shaped image % sharpening kernel instead. % % The format of the SharpenImage method is: % % Image SharpenImage(const Image image,const double radius, % const double sigma,ExceptionInfo exception) % Image SharpenImageChannel(const Image image,const ChannelType channel, % const double radius,const double sigma,ExceptionInfo exception) % % A description of each parameter follows: % % o image: the image. % % o channel: the channel type. % % o radius: the radius of the Gaussian, in pixels, not counting the center % pixel. % % o sigma: the standard deviation of the Laplacian, in pixels. % % o exception: return any errors or warnings in this structure. % / MagickExport Image SharpenImage(const Image image,const double radius, const double sigma,ExceptionInfo exception) { Image sharp_image; sharp_image=SharpenImageChannel(image,DefaultChannels,radius,sigma,exception); return(sharp_image); } MagickExport Image SharpenImageChannel(const Image image, const ChannelType channel,const double radius,const double sigma, ExceptionInfo exception) { double gamma, normalize; Image sharp_image; KernelInfo kernel_info; register ssize_t i; size_t width; ssize_t j, u, v; assert(image != (const Image ) NULL); assert(image->signature == MagickCoreSignature); if (image->debug != MagickFalse) (void) LogMagickEvent(TraceEvent,GetMagickModule(),"%s",image->filename); assert(exception != (ExceptionInfo ) NULL); assert(exception->signature == MagickCoreSignature); width=GetOptimalKernelWidth2D(radius,sigma); kernel_info=AcquireKernelInfo((const char ) NULL); if (kernel_info == (KernelInfo ) NULL) ThrowImageException(ResourceLimitError,"MemoryAllocationFailed"); (void) memset(kernel_info,0,sizeof(kernel_info)); kernel_info->width=width; kernel_info->height=width; kernel_info->x=(ssize_t) (width-1)/2; kernel_info->y=(ssize_t) (width-1)/2; kernel_info->signature=MagickCoreSignature; kernel_info->values=(double ) MagickAssumeAligned(AcquireAlignedMemory( kernel_info->width,kernel_info->heightsizeof(kernel_info->values))); if (kernel_info->values == (double ) NULL) { kernel_info=DestroyKernelInfo(kernel_info); ThrowImageException(ResourceLimitError,"MemoryAllocationFailed"); } normalize=0.0; j=(ssize_t) (kernel_info->width-1)/2; i=0; for (v=(-j); v <= j; v++) { for (u=(-j); u <= j; u++) { kernel_info->values[i]=(double) (-exp(-((double) uu+vv)/(2.0 MagickSigmaMagickSigma))/(2.0MagickPIMagickSigmaMagickSigma)); normalize+=kernel_info->values[i]; i++; } } kernel_info->values[i/2]=(double) ((-2.0)normalize); normalize=0.0; for (i=0; i < (ssize_t) (kernel_info->widthkernel_info->height); i++) normalize+=kernel_info->values[i]; gamma=PerceptibleReciprocal(normalize); for (i=0; i < (ssize_t) (kernel_info->widthkernel_info->height); i++) kernel_info->values[i]=gamma; sharp_image=MorphologyImageChannel(image,channel,ConvolveMorphology,1, kernel_info,exception); kernel_info=DestroyKernelInfo(kernel_info); return(sharp_image); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % S p r e a d I m a g e % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % SpreadImage() is a special effects method that randomly displaces each % pixel in a block defined by the radius parameter. % % The format of the SpreadImage method is: % % Image SpreadImage(const Image image,const double radius, % ExceptionInfo exception) % % A description of each parameter follows: % % o image: the image. % % o radius: Choose a random pixel in a neighborhood of this extent. % % o exception: return any errors or warnings in this structure. % / MagickExport Image SpreadImage(const Image image,const double radius, ExceptionInfo exception) { #define SpreadImageTag "Spread/Image" CacheView image_view, spread_view; Image spread_image; MagickBooleanType status; MagickOffsetType progress; MagickPixelPacket bias; RandomInfo *magick_restrict random_info; size_t width; ssize_t y; #if defined(MAGICKCORE_OPENMP_SUPPORT) unsigned long key; #endif / Initialize spread image attributes. / assert(image != (Image ) NULL); assert(image->signature == MagickCoreSignature); if (image->debug != MagickFalse) (void) LogMagickEvent(TraceEvent,GetMagickModule(),"%s",image->filename); assert(exception != (ExceptionInfo ) NULL); assert(exception->signature == MagickCoreSignature); spread_image=CloneImage(image,0,0,MagickTrue,exception); if (spread_image == (Image ) NULL) return((Image ) NULL); if (SetImageStorageClass(spread_image,DirectClass) == MagickFalse) { InheritException(exception,&spread_image->exception); spread_image=DestroyImage(spread_image); return((Image ) NULL); } /* Spread image. / status=MagickTrue; progress=0; GetMagickPixelPacket(spread_image,&bias); width=GetOptimalKernelWidth1D(radius,0.5); random_info=AcquireRandomInfoThreadSet(); image_view=AcquireVirtualCacheView(image,exception); spread_view=AcquireAuthenticCacheView(spread_image,exception); #if defined(MAGICKCORE_OPENMP_SUPPORT) key=GetRandomSecretKey(random_info[0]); #pragma omp parallel for schedule(static) shared(progress,status) \ magick_number_threads(image,spread_image,spread_image->rows,key == ~0UL) #endif for (y=0; y < (ssize_t) spread_image->rows; y++) { const int id = GetOpenMPThreadId(); MagickPixelPacket pixel; register IndexPacket magick_restrict indexes; register PixelPacket magick_restrict q; register ssize_t x; if (status == MagickFalse) continue; q=QueueCacheViewAuthenticPixels(spread_view,0,y,spread_image->columns,1, exception); if (q == (PixelPacket ) NULL) { status=MagickFalse; continue; } indexes=GetCacheViewAuthenticIndexQueue(spread_view); pixel=bias; for (x=0; x < (ssize_t) spread_image->columns; x++) { PointInfo point; point.x=GetPseudoRandomValue(random_info[id]); point.y=GetPseudoRandomValue(random_info[id]); status=InterpolateMagickPixelPacket(image,image_view,image->interpolate, (double) x+width(point.x-0.5),(double) y+width(point.y-0.5),&pixel, exception); if (status == MagickFalse) break; SetPixelPacket(spread_image,&pixel,q,indexes+x); q++; } if (SyncCacheViewAuthenticPixels(spread_view,exception) == MagickFalse) status=MagickFalse; if (image->progress_monitor != (MagickProgressMonitor) NULL) { MagickBooleanType proceed; #if defined(MAGICKCORE_OPENMP_SUPPORT) #pragma omp atomic #endif progress++; proceed=SetImageProgress(image,SpreadImageTag,progress,image->rows); if (proceed == MagickFalse) status=MagickFalse; } } spread_view=DestroyCacheView(spread_view); image_view=DestroyCacheView(image_view); random_info=DestroyRandomInfoThreadSet(random_info); if (status == MagickFalse) spread_image=DestroyImage(spread_image); return(spread_image); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % U n s h a r p M a s k I m a g e % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % UnsharpMaskImage() sharpens one or more image channels. We convolve the % image with a Gaussian operator of the given radius and standard deviation % (sigma). For reasonable results, radius should be larger than sigma. Use a % radius of 0 and UnsharpMaskImage() selects a suitable radius for you. % % The format of the UnsharpMaskImage method is: % % Image UnsharpMaskImage(const Image image,const double radius, % const double sigma,const double amount,const double threshold, % ExceptionInfo exception) % Image UnsharpMaskImageChannel(const Image image, % const ChannelType channel,const double radius,const double sigma, % const double gain,const double threshold,ExceptionInfo exception) % % A description of each parameter follows: % % o image: the image. % % o channel: the channel type. % % o radius: the radius of the Gaussian, in pixels, not counting the center % pixel. % % o sigma: the standard deviation of the Gaussian, in pixels. % % o gain: the percentage of the difference between the original and the % blur image that is added back into the original. % % o threshold: the threshold in pixels needed to apply the diffence gain. % % o exception: return any errors or warnings in this structure. % / MagickExport Image UnsharpMaskImage(const Image image,const double radius, const double sigma,const double gain,const double threshold, ExceptionInfo exception) { Image sharp_image; sharp_image=UnsharpMaskImageChannel(image,DefaultChannels,radius,sigma,gain, threshold,exception); return(sharp_image); } MagickExport Image UnsharpMaskImageChannel(const Image image, const ChannelType channel,const double radius,const double sigma, const double gain,const double threshold,ExceptionInfo exception) { #define SharpenImageTag "Sharpen/Image" CacheView image_view, unsharp_view; Image unsharp_image; MagickBooleanType status; MagickOffsetType progress; MagickPixelPacket bias; MagickRealType quantum_threshold; ssize_t y; assert(image != (const Image ) NULL); assert(image->signature == MagickCoreSignature); if (image->debug != MagickFalse) (void) LogMagickEvent(TraceEvent,GetMagickModule(),"%s",image->filename); assert(exception != (ExceptionInfo ) NULL); #if defined(MAGICKCORE_OPENCL_SUPPORT) unsharp_image=AccelerateUnsharpMaskImage(image,channel,radius,sigma,gain, threshold,exception); if (unsharp_image != (Image ) NULL) return(unsharp_image); #endif unsharp_image=BlurImageChannel(image,(ChannelType) (channel &~ SyncChannels), radius,sigma,exception); if (unsharp_image == (Image ) NULL) return((Image ) NULL); quantum_threshold=(MagickRealType) QuantumRangethreshold; / Unsharp-mask image. / status=MagickTrue; progress=0; GetMagickPixelPacket(image,&bias); image_view=AcquireVirtualCacheView(image,exception); unsharp_view=AcquireAuthenticCacheView(unsharp_image,exception); #if defined(MAGICKCORE_OPENMP_SUPPORT) #pragma omp parallel for schedule(static) shared(progress,status) \ magick_number_threads(image,unsharp_image,image->rows,1) #endif for (y=0; y < (ssize_t) image->rows; y++) { DoublePixelPacket pixel; register const IndexPacket magick_restrict indexes; register const PixelPacket magick_restrict p; register IndexPacket magick_restrict unsharp_indexes; register PixelPacket magick_restrict q; register ssize_t x; if (status == MagickFalse) continue; p=GetCacheViewVirtualPixels(image_view,0,y,image->columns,1,exception); q=GetCacheViewAuthenticPixels(unsharp_view,0,y,unsharp_image->columns,1, exception); if ((p == (const PixelPacket ) NULL) \|\| (q == (PixelPacket ) NULL)) { status=MagickFalse; continue; } indexes=GetCacheViewVirtualIndexQueue(image_view); unsharp_indexes=GetCacheViewAuthenticIndexQueue(unsharp_view); pixel.red=bias.red; pixel.green=bias.green; pixel.blue=bias.blue; pixel.opacity=bias.opacity; pixel.index=bias.index; for (x=0; x < (ssize_t) image->columns; x++) { if ((channel & RedChannel) != 0) { pixel.red=GetPixelRed(p)-(MagickRealType) GetPixelRed(q); if (fabs(2.0pixel.red) < quantum_threshold) pixel.red=(MagickRealType) GetPixelRed(p); else pixel.red=(MagickRealType) GetPixelRed(p)+(pixel.redgain); SetPixelRed(q,ClampToQuantum(pixel.red)); } if ((channel & GreenChannel) != 0) { pixel.green=GetPixelGreen(p)-(MagickRealType) q->green; if (fabs(2.0pixel.green) < quantum_threshold) pixel.green=(MagickRealType) GetPixelGreen(p); else pixel.green=(MagickRealType) GetPixelGreen(p)+(pixel.greengain); SetPixelGreen(q,ClampToQuantum(pixel.green)); } if ((channel & BlueChannel) != 0) { pixel.blue=GetPixelBlue(p)-(MagickRealType) q->blue; if (fabs(2.0pixel.blue) < quantum_threshold) pixel.blue=(MagickRealType) GetPixelBlue(p); else pixel.blue=(MagickRealType) GetPixelBlue(p)+(pixel.bluegain); SetPixelBlue(q,ClampToQuantum(pixel.blue)); } if ((channel & OpacityChannel) != 0) { pixel.opacity=GetPixelOpacity(p)-(MagickRealType) q->opacity; if (fabs(2.0pixel.opacity) < quantum_threshold) pixel.opacity=(MagickRealType) GetPixelOpacity(p); else pixel.opacity=GetPixelOpacity(p)+(pixel.opacitygain); SetPixelOpacity(q,ClampToQuantum(pixel.opacity)); } if (((channel & IndexChannel) != 0) && (image->colorspace == CMYKColorspace)) { pixel.index=GetPixelIndex(indexes+x)-(MagickRealType) GetPixelIndex(unsharp_indexes+x); if (fabs(2.0pixel.index) < quantum_threshold) pixel.index=(MagickRealType) GetPixelIndex(indexes+x); else pixel.index=(MagickRealType) GetPixelIndex(indexes+x)+ (pixel.index*gain); SetPixelIndex(unsharp_indexes+x,ClampToQuantum(pixel.index)); } p++; q++; } if (SyncCacheViewAuthenticPixels(unsharp_view,exception) == MagickFalse) status=MagickFalse; if (image->progress_monitor != (MagickProgressMonitor) NULL) { MagickBooleanType proceed; #if defined(MAGICKCORE_OPENMP_SUPPORT) #pragma omp atomic #endif progress++; proceed=SetImageProgress(image,SharpenImageTag,progress,image->rows); if (proceed == MagickFalse) status=MagickFalse; } } unsharp_image->type=image->type; unsharp_view=DestroyCacheView(unsharp_view); image_view=DestroyCacheView(image_view); if (status == MagickFalse) unsharp_image=DestroyImage(unsharp_image); return(unsharp_image); }
fill_int2e.c	/* Copyright 2014-2018 The PySCF Developers. All Rights Reserved. Licensed under the Apache License, Version 2.0 (the "License"); you may not use this file except in compliance with the License. You may obtain a copy of the License at http://www.apache.org/licenses/LICENSE-2.0 Unless required by applicable law or agreed to in writing, software distributed under the License is distributed on an "AS IS" BASIS, WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. See the License for the specific language governing permissions and limitations under the License. * * Author: Qiming Sun <osirpt.sun@gmail.com> / #include <stdlib.h> #include <math.h> #include "config.h" #include "cint.h" #define MAX(I,J) ((I) > (J) ? (I) : (J)) #define MIN(I,J) ((I) < (J) ? (I) : (J)) int GTOmax_shell_dim(int ao_loc, int shls_slice, int ncenter) { int i; int i0 = shls_slice[0]; int i1 = shls_slice[1]; int di = 0; for (i = 1; i < ncenter; i++) { i0 = MIN(i0, shls_slice[i2 ]); i1 = MAX(i1, shls_slice[i2+1]); } for (i = i0; i < i1; i++) { di = MAX(di, ao_loc[i+1]-ao_loc[i]); } return di; } int GTOmax_cache_size(int (intor)(), int shls_slice, int ncenter, int atm, int natm, int bas, int nbas, double env) { int i, n; int i0 = shls_slice[0]; int i1 = shls_slice[1]; for (i = 1; i < ncenter; i++) { i0 = MIN(i0, shls_slice[i2 ]); i1 = MAX(i1, shls_slice[i2+1]); } int shls[4]; int cache_size = 0; for (i = i0; i < i1; i++) { shls[0] = i; shls[1] = i; shls[2] = i; shls[3] = i; n = (intor)(NULL, NULL, shls, atm, natm, bas, nbas, env, NULL, NULL); cache_size = MAX(cache_size, n); } return cache_size; } / ************************************************* * 2e AO integrals in s4, s2ij, s2kl, s1 / void GTOnr2e_fill_s1(int (intor)(), int (fprescreen)(), double eri, double buf, int comp, int ishp, int jshp, int shls_slice, int ao_loc, CINTOpt cintopt, int atm, int natm, int bas, int nbas, double env) { int ish0 = shls_slice[0]; int ish1 = shls_slice[1]; int jsh0 = shls_slice[2]; int jsh1 = shls_slice[3]; int ksh0 = shls_slice[4]; int ksh1 = shls_slice[5]; int lsh0 = shls_slice[6]; int lsh1 = shls_slice[7]; int ni = ao_loc[ish1] - ao_loc[ish0]; int nj = ao_loc[jsh1] - ao_loc[jsh0]; int nk = ao_loc[ksh1] - ao_loc[ksh0]; int nl = ao_loc[lsh1] - ao_loc[lsh0]; size_t nij = ni nj; size_t nkl = nk * nl; size_t neri = nij * nkl; int ish = ishp + ish0; int jsh = jshp + jsh0; int i0 = ao_loc[ish] - ao_loc[ish0]; int j0 = ao_loc[jsh] - ao_loc[jsh0]; eri += nkl * (i0 * nj + j0); int di = ao_loc[ish+1] - ao_loc[ish]; int dj = ao_loc[jsh+1] - ao_loc[jsh]; int dij = di * dj; int k0, l0, dk, dl, dijk, dijkl; int i, j, k, l, icomp; int ksh, lsh; int shls[4]; double eri0, peri, buf0, pbuf, cache; shls[0] = ish; shls[1] = jsh; for (ksh = ksh0; ksh < ksh1; ksh++) { for (lsh = lsh0; lsh < lsh1; lsh++) { shls[2] = ksh; shls[3] = lsh; k0 = ao_loc[ksh] - ao_loc[ksh0]; l0 = ao_loc[lsh] - ao_loc[lsh0]; dk = ao_loc[ksh+1] - ao_loc[ksh]; dl = ao_loc[lsh+1] - ao_loc[lsh]; dijk = dij dk; dijkl = dijk * dl; cache = buf + dijkl * comp; if ((fprescreen)(shls, atm, bas, env) && (intor)(buf, NULL, shls, atm, natm, bas, nbas, env, cintopt, cache)) { eri0 = eri + k0nl+l0; buf0 = buf; for (icomp = 0; icomp < comp; icomp++) { for (i = 0; i < di; i++) { for (j = 0; j < dj; j++) { peri = eri0 + nkl(inj+j); for (k = 0; k < dk; k++) { for (pbuf = buf0 + kdij + jdi + i, l = 0; l < dl; l++) { peri[knl+l] = pbuf[ldijk]; } } } } buf0 += dijkl; eri0 += neri; } } else { eri0 = eri + k0nl+l0; for (icomp = 0; icomp < comp; icomp++) { for (i = 0; i < di; i++) { for (j = 0; j < dj; j++) { peri = eri0 + nkl(inj+j); for (k = 0; k < dk; k++) { for (l = 0; l < dl; l++) { peri[knl+l] = 0; } } } } eri0 += neri; } } } } } void GTOnr2e_fill_s2ij(int (intor)(), int (fprescreen)(), double eri, double buf, int comp, int ishp, int jshp, int shls_slice, int ao_loc, CINTOpt cintopt, int atm, int natm, int bas, int nbas, double env) { if (ishp < jshp) { return; } int ish0 = shls_slice[0]; int ish1 = shls_slice[1]; int jsh0 = shls_slice[2]; //int jsh1 = shls_slice[3]; int ksh0 = shls_slice[4]; int ksh1 = shls_slice[5]; int lsh0 = shls_slice[6]; int lsh1 = shls_slice[7]; int ni = ao_loc[ish1] - ao_loc[ish0]; //int nj = ao_loc[jsh1] - ao_loc[jsh0]; int nk = ao_loc[ksh1] - ao_loc[ksh0]; int nl = ao_loc[lsh1] - ao_loc[lsh0]; size_t nij = ni (ni+1) / 2; size_t nkl = nk * nl; size_t neri = nij * nkl; int ish = ishp + ish0; int jsh = jshp + jsh0; int i0 = ao_loc[ish] - ao_loc[ish0]; int j0 = ao_loc[jsh] - ao_loc[jsh0]; eri += nkl * (i0(i0+1)/2 + j0); int di = ao_loc[ish+1] - ao_loc[ish]; int dj = ao_loc[jsh+1] - ao_loc[jsh]; int dij = di dj; int k0, l0, dk, dl, dijk, dijkl; int i, j, k, l, icomp; int ksh, lsh; int shls[4]; double eri0, peri0, peri, buf0, pbuf, cache; shls[0] = ish; shls[1] = jsh; for (ksh = ksh0; ksh < ksh1; ksh++) { for (lsh = lsh0; lsh < lsh1; lsh++) { shls[2] = ksh; shls[3] = lsh; k0 = ao_loc[ksh] - ao_loc[ksh0]; l0 = ao_loc[lsh] - ao_loc[lsh0]; dk = ao_loc[ksh+1] - ao_loc[ksh]; dl = ao_loc[lsh+1] - ao_loc[lsh]; dijk = dij * dk; dijkl = dijk * dl; cache = buf + dijkl * comp; if ((fprescreen)(shls, atm, bas, env) && (intor)(buf, NULL, shls, atm, natm, bas, nbas, env, cintopt, cache)) { eri0 = eri + k0nl+l0; buf0 = buf; for (icomp = 0; icomp < comp; icomp++) { peri0 = eri0; if (ishp > jshp) { for (i = 0; i < di; i++, peri0+=nkl(i0+i)) { for (j = 0; j < dj; j++) { peri = peri0 + nklj; for (k = 0; k < dk; k++) { for (pbuf = buf0 + kdij + jdi + i, l = 0; l < dl; l++) { peri[knl+l] = pbuf[ldijk]; } } } } } else { for (i = 0; i < di; i++, peri0+=nkl(i0+i)) { for (j = 0; j <= i; j++) { peri = peri0 + nklj; for (k = 0; k < dk; k++) { for (pbuf = buf0 + kdij + jdi + i, l = 0; l < dl; l++) { peri[knl+l] = pbuf[ldijk]; } } } } } buf0 += dijkl; eri0 += neri; } } else { eri0 = eri + k0nl+l0; for (icomp = 0; icomp < comp; icomp++) { peri0 = eri0; if (ishp > jshp) { for (i = 0; i < di; i++, peri0+=nkl(i0+i)) { for (j = 0; j < dj; j++) { peri = peri0 + nklj; for (k = 0; k < dk; k++) { for (l = 0; l < dl; l++) { peri[knl+l] = 0; } } } } } else { for (i = 0; i < di; i++, peri0+=nkl(i0+i)) { for (j = 0; j <= i; j++) { peri = peri0 + nklj; for (k = 0; k < dk; k++) { for (l = 0; l < dl; l++) { peri[knl+l] = 0; } } } } } eri0 += neri; } } } } } void GTOnr2e_fill_s2kl(int (intor)(), int (fprescreen)(), double eri, double buf, int comp, int ishp, int jshp, int shls_slice, int ao_loc, CINTOpt cintopt, int atm, int natm, int bas, int nbas, double env) { int ish0 = shls_slice[0]; int ish1 = shls_slice[1]; int jsh0 = shls_slice[2]; int jsh1 = shls_slice[3]; int ksh0 = shls_slice[4]; int ksh1 = shls_slice[5]; int lsh0 = shls_slice[6]; //int lsh1 = shls_slice[7]; int ni = ao_loc[ish1] - ao_loc[ish0]; int nj = ao_loc[jsh1] - ao_loc[jsh0]; int nk = ao_loc[ksh1] - ao_loc[ksh0]; //int nl = ao_loc[lsh1] - ao_loc[lsh0]; size_t nij = ni * nj; size_t nkl = nk * (nk+1) / 2; size_t neri = nij * nkl; int ish = ishp + ish0; int jsh = jshp + jsh0; int i0 = ao_loc[ish] - ao_loc[ish0]; int j0 = ao_loc[jsh] - ao_loc[jsh0]; eri += nkl * (i0 * nj + j0); int di = ao_loc[ish+1] - ao_loc[ish]; int dj = ao_loc[jsh+1] - ao_loc[jsh]; int dij = di * dj; int k0, l0, dk, dl, dijk, dijkl; int i, j, k, l, icomp; int ksh, lsh, kshp, lshp; int shls[4]; double eri0, peri, buf0, pbuf, cache; shls[0] = ish; shls[1] = jsh; for (kshp = 0; kshp < ksh1-ksh0; kshp++) { for (lshp = 0; lshp <= kshp; lshp++) { ksh = kshp + ksh0; lsh = lshp + lsh0; shls[2] = ksh; shls[3] = lsh; k0 = ao_loc[ksh] - ao_loc[ksh0]; l0 = ao_loc[lsh] - ao_loc[lsh0]; dk = ao_loc[ksh+1] - ao_loc[ksh]; dl = ao_loc[lsh+1] - ao_loc[lsh]; dijk = dij dk; dijkl = dijk * dl; cache = buf + dijkl * comp; if ((fprescreen)(shls, atm, bas, env) && (intor)(buf, NULL, shls, atm, natm, bas, nbas, env, cintopt, cache)) { eri0 = eri + k0(k0+1)/2+l0; buf0 = buf; for (icomp = 0; icomp < comp; icomp++) { if (kshp > lshp) { for (i = 0; i < di; i++) { for (j = 0; j < dj; j++) { peri = eri0 + nkl(inj+j); for (k = 0; k < dk; k++, peri+=k0+k) { for (pbuf = buf0 + kdij + jdi + i, l = 0; l < dl; l++) { peri[l] = pbuf[ldijk]; } } } } } else { for (i = 0; i < di; i++) { for (j = 0; j < dj; j++) { peri = eri0 + nkl(inj+j); for (k = 0; k < dk; k++, peri+=k0+k) { for (pbuf = buf0 + kdij + jdi + i, l = 0; l <= k; l++) { peri[l] = pbuf[ldijk]; } } } } } buf0 += dijkl; eri0 += neri; } } else { eri0 = eri + k0(k0+1)/2+l0; for (icomp = 0; icomp < comp; icomp++) { if (kshp > lshp) { for (i = 0; i < di; i++) { for (j = 0; j < dj; j++) { peri = eri0 + nkl(inj+j); for (k = 0; k < dk; k++, peri+=k0+k) { for (l = 0; l < dl; l++) { peri[l] = 0; } } } } } else { for (i = 0; i < di; i++) { for (j = 0; j < dj; j++) { peri = eri0 + nkl(inj+j); for (k = 0; k < dk; k++, peri+=k0+k) { for (l = 0; l <= k; l++) { peri[l] = 0; } } } } } eri0 += neri; } } } } } void GTOnr2e_fill_s4(int (intor)(), int (fprescreen)(), double eri, double buf, int comp, int ishp, int jshp, int shls_slice, int ao_loc, CINTOpt cintopt, int atm, int natm, int bas, int nbas, double env) { if (ishp < jshp) { return; } int ish0 = shls_slice[0]; int ish1 = shls_slice[1]; int jsh0 = shls_slice[2]; //int jsh1 = shls_slice[3]; int ksh0 = shls_slice[4]; int ksh1 = shls_slice[5]; int lsh0 = shls_slice[6]; //int lsh1 = shls_slice[7]; int ni = ao_loc[ish1] - ao_loc[ish0]; //int nj = ao_loc[jsh1] - ao_loc[jsh0]; int nk = ao_loc[ksh1] - ao_loc[ksh0]; //int nl = ao_loc[lsh1] - ao_loc[lsh0]; size_t nij = ni * (ni+1) / 2; size_t nkl = nk * (nk+1) / 2; size_t neri = nij * nkl; int ish = ishp + ish0; int jsh = jshp + jsh0; int i0 = ao_loc[ish] - ao_loc[ish0]; int j0 = ao_loc[jsh] - ao_loc[jsh0]; eri += nkl * (i0(i0+1)/2 + j0); int di = ao_loc[ish+1] - ao_loc[ish]; int dj = ao_loc[jsh+1] - ao_loc[jsh]; int dij = di dj; int k0, l0, dk, dl, dijk, dijkl; int i, j, k, l, icomp; int ksh, lsh, kshp, lshp; int shls[4]; double eri0, peri0, peri, buf0, pbuf, cache; shls[0] = ish; shls[1] = jsh; for (kshp = 0; kshp < ksh1-ksh0; kshp++) { for (lshp = 0; lshp <= kshp; lshp++) { ksh = kshp + ksh0; lsh = lshp + lsh0; shls[2] = ksh; shls[3] = lsh; k0 = ao_loc[ksh] - ao_loc[ksh0]; l0 = ao_loc[lsh] - ao_loc[lsh0]; dk = ao_loc[ksh+1] - ao_loc[ksh]; dl = ao_loc[lsh+1] - ao_loc[lsh]; dijk = dij * dk; dijkl = dijk * dl; cache = buf + dijkl * comp; if ((fprescreen)(shls, atm, bas, env) && (intor)(buf, NULL, shls, atm, natm, bas, nbas, env, cintopt, cache)) { eri0 = eri + k0(k0+1)/2+l0; buf0 = buf; for (icomp = 0; icomp < comp; icomp++) { peri0 = eri0; if (kshp > lshp && ishp > jshp) { for (i = 0; i < di; i++, peri0+=nkl(i0+i)) { for (j = 0; j < dj; j++) { peri = peri0 + nklj; for (k = 0; k < dk; k++, peri+=k0+k) { for (pbuf = buf0 + kdij + jdi + i, l = 0; l < dl; l++) { peri[l] = pbuf[ldijk]; } } } } } else if (ish > jsh) { for (i = 0; i < di; i++, peri0+=nkl(i0+i)) { for (j = 0; j < dj; j++) { peri = peri0 + nklj; for (k = 0; k < dk; k++, peri+=k0+k) { for (pbuf = buf0 + kdij + jdi + i, l = 0; l <= k; l++) { peri[l] = pbuf[ldijk]; } } } } } else if (ksh > lsh) { for (i = 0; i < di; i++, peri0+=nkl(i0+i)) { for (j = 0; j <= i; j++) { peri = peri0 + nklj; for (k = 0; k < dk; k++, peri+=k0+k) { for (pbuf = buf0 + kdij + jdi + i, l = 0; l < dl; l++) { peri[l] = pbuf[ldijk]; } } } } } else { for (i = 0; i < di; i++, peri0+=nkl(i0+i)) { for (j = 0; j <= i; j++) { peri = peri0 + nklj; for (k = 0; k < dk; k++, peri+=k0+k) { for (pbuf = buf0 + kdij + jdi + i, l = 0; l <= k; l++) { peri[l] = pbuf[ldijk]; } } } } } buf0 += dijkl; eri0 += neri; } } else { eri0 = eri + k0(k0+1)/2+l0; buf0 = buf; for (icomp = 0; icomp < comp; icomp++) { peri0 = eri0; if (kshp > lshp && ishp > jshp) { for (i = 0; i < di; i++, peri0+=nkl(i0+i)) { for (j = 0; j < dj; j++) { peri = peri0 + nklj; for (k = 0; k < dk; k++, peri+=k0+k) { for (l = 0; l < dl; l++) { peri[l] = 0; } } } } } else if (ish > jsh) { for (i = 0; i < di; i++, peri0+=nkl(i0+i)) { for (j = 0; j < dj; j++) { peri = peri0 + nklj; for (k = 0; k < dk; k++, peri+=k0+k) { for (l = 0; l <= k; l++) { peri[l] = 0; } } } } } else if (ksh > lsh) { for (i = 0; i < di; i++, peri0+=nkl(i0+i)) { for (j = 0; j <= i; j++) { peri = peri0 + nklj; for (k = 0; k < dk; k++, peri+=k0+k) { for (l = 0; l < dl; l++) { peri[l] = 0; } } } } } else { for (i = 0; i < di; i++, peri0+=nkl(i0+i)) { for (j = 0; j <= i; j++) { peri = peri0 + nklj; for (k = 0; k < dk; k++, peri+=k0+k) { for (l = 0; l <= k; l++) { peri[l] = 0; } } } } } eri0 += neri; } } } } } static int no_prescreen() { return 1; } void GTOnr2e_fill_drv(int (intor)(), void (fill)(), int (fprescreen)(), double eri, int comp, int shls_slice, int ao_loc, CINTOpt cintopt, int atm, int natm, int bas, int nbas, double env) { if (fprescreen == NULL) { fprescreen = no_prescreen; } const int ish0 = shls_slice[0]; const int ish1 = shls_slice[1]; const int jsh0 = shls_slice[2]; const int jsh1 = shls_slice[3]; const int nish = ish1 - ish0; const int njsh = jsh1 - jsh0; const int di = GTOmax_shell_dim(ao_loc, shls_slice, 4); const int cache_size = GTOmax_cache_size(intor, shls_slice, 4, atm, natm, bas, nbas, env); #pragma omp parallel { int ij, i, j; double buf = malloc(sizeof(double) (didididicomp + cache_size)); #pragma omp for nowait schedule(dynamic) for (ij = 0; ij < nishnjsh; ij++) { i = ij / njsh; j = ij % njsh; (fill)(intor, fprescreen, eri, buf, comp, i, j, shls_slice, ao_loc, cintopt, atm, natm, bas, nbas, env); } free(buf); } }
Data.h	/***************************************************************************** * * Copyright (c) 2003-2020 by The University of Queensland * http://www.uq.edu.au * * Primary Business: Queensland, Australia * Licensed under the Apache License, version 2.0 * http://www.apache.org/licenses/LICENSE-2.0 * * Development until 2012 by Earth Systems Science Computational Center (ESSCC) * Development 2012-2013 by School of Earth Sciences * Development from 2014-2017 by Centre for Geoscience Computing (GeoComp) * Development from 2019 by School of Earth and Environmental Sciences *************************************************************************/ / \file Data.h / #ifndef __ESCRIPT_DATA_H__ #define __ESCRIPT_DATA_H__ #include "system_dep.h" #include "DataAbstract.h" #include "DataException.h" #include "DataTypes.h" #include "EsysMPI.h" #include "FunctionSpace.h" #include "DataVectorOps.h" #include <algorithm> #include <string> #include <sstream> #include <boost/python/object.hpp> #include <boost/python/tuple.hpp> #include <boost/math/special_functions/bessel.hpp> #ifndef ESCRIPT_MAX_DATA_RANK #define ESCRIPT_MAX_DATA_RANK 4 #endif namespace escript { // // Forward declaration for various implementations of Data. class DataConstant; class DataTagged; class DataExpanded; class DataLazy; /* \brief Data represents a collection of datapoints. Description: Internally, the datapoints are actually stored by a DataAbstract object. The specific instance of DataAbstract used may vary over the lifetime of the Data object. Some methods on this class return references (eg getShape()). These references should not be used after an operation which changes the underlying DataAbstract object. Doing so will lead to invalid memory access. This should not affect any methods exposed via boost::python. / class ESCRIPT_DLL_API Data { public: /* Constructors. / /* \brief Default constructor. Creates a DataEmpty object. / Data(); /* \brief Copy constructor. WARNING: Only performs a shallow copy. / Data(const Data& inData); /* \brief Constructor from another Data object. If "what" is different from the function space of inData the inData are tried to be interpolated to what, otherwise a shallow copy of inData is returned. / Data(const Data& inData, const FunctionSpace& what); /* \brief Copy Data from an existing vector / Data(const DataTypes::RealVectorType& value, const DataTypes::ShapeType& shape, const FunctionSpace& what, bool expanded); /* \brief Constructor which creates a Data with points having the specified shape. \param value - Input - Single real value applied to all Data. \param dataPointShape - Input - The shape of each data point. \param what - Input - A description of what this data represents. \param expanded - Input - Flag, if true fill the entire container with the given value. Otherwise a more efficient storage mechanism will be used. / Data(DataTypes::real_t value, const DataTypes::ShapeType& dataPointShape, const FunctionSpace& what, bool expanded); /* \brief Constructor which creates a Data with points having the specified shape. \param value - Input - Single complex value applied to all Data. \param dataPointShape - Input - The shape of each data point. \param what - Input - A description of what this data represents. \param expanded - Input - Flag, if true fill the entire container with the given value. Otherwise a more efficient storage mechanism will be used. / explicit Data(DataTypes::cplx_t value, const DataTypes::ShapeType& dataPointShape, const FunctionSpace& what, bool expanded); /* \brief Constructor which performs a deep copy of a region from another Data object. \param inData - Input - Input Data object. \param region - Input - Region to copy. / Data(const Data& inData, const DataTypes::RegionType& region); /* \brief Constructor which copies data from a wrapped array. \param w - Input - Input data. \param what - Input - A description of what this data represents. \param expanded - Input - Flag, if true fill the entire container with the value. Otherwise a more efficient storage mechanism will be used. / Data(const WrappedArray& w, const FunctionSpace& what, bool expanded); /* \brief Constructor which creates a DataConstant. Copies data from any object that can be treated like a python array/sequence. All other parameters are copied from other. \param value - Input - Input data. \param other - Input - contains all other parameters. / Data(const boost::python::object& value, const Data& other); /* This constructor subsumes a number of previous python ones. Data(const boost::python::object& value, const FunctionSpace& what=FunctionSpace(), bool expanded=false); Data(DataTypes::real_t value, const boost::python::tuple& shape=boost::python::make_tuple(), const FunctionSpace& what=FunctionSpace(), bool expanded=false); and a new Data(cplx_t value, const boost::python::tuple& shape=boost::python::make_tuple(), const FunctionSpace& what=FunctionSpace(), bool expanded=false); / Data(boost::python::object value, boost::python::object par1=boost::python::object(), boost::python::object par2=boost::python::object(), boost::python::object par3=boost::python::object()); /* \brief Create a Data using an existing DataAbstract. Warning: The new object assumes ownership of the pointer! Once you have passed the pointer, do not delete it. / explicit Data(DataAbstract underlyingdata); /** \brief Create a Data based on the supplied DataAbstract / explicit Data(DataAbstract_ptr underlyingdata); /* \brief Destructor / ~Data(); /* \brief Make this object a deep copy of "other". / void copy(const Data& other); /* \brief Return a pointer to a deep copy of this object. / Data copySelf() const; /* \brief produce a delayed evaluation version of this Data. / Data delay(); /* \brief convert the current data into lazy data. / void delaySelf(); /* Member access methods. / /* \brief switches on update protection / void setProtection(); /* \brief Returns true, if the data object is protected against update / bool isProtected() const; /* \brief Return the value of a data point as a python tuple. / const boost::python::object getValueOfDataPointAsTuple(int dataPointNo); /* \brief sets the values of a data-point from a python object on this process / void setValueOfDataPointToPyObject(int dataPointNo, const boost::python::object& py_object); /* \brief sets the values of a data-point from a array-like object on this process / void setValueOfDataPointToArray(int dataPointNo, const boost::python::object&); /* \brief sets the values of a data-point on this process / void setValueOfDataPoint(int dataPointNo, const DataTypes::real_t); void setValueOfDataPointC(int dataPointNo, const DataTypes::cplx_t); /* \brief Return a data point across all processors as a python tuple. / const boost::python::object getValueOfGlobalDataPointAsTuple(int procNo, int dataPointNo); /* \brief Set the value of a global data point / void setTupleForGlobalDataPoint(int id, int proc, boost::python::object); /* \brief Return the tag number associated with the given data-point. / int getTagNumber(int dpno); /* \brief Write the data as a string. For large amounts of data, a summary is printed. / std::string toString() const; /* \brief Whatever the current Data type make this into a DataExpanded. / void expand(); /* \brief If possible convert this Data to DataTagged. This will only allow Constant data to be converted to tagged. An attempt to convert Expanded data to tagged will throw an exception. / void tag(); /* \brief If this data is lazy, then convert it to ready data. What type of ready data depends on the expression. For example, Constant+Tagged==Tagged. / void resolve(); /* \brief returns return true if data contains NaN. \warning This is dependent on the ability to reliably detect NaNs on your compiler. See the nancheck function in LocalOps for details. / bool hasNaN(); /* \brief replaces all NaN values with value / void replaceNaN(DataTypes::real_t value); /* \brief replaces all NaN values with value / void replaceNaN(DataTypes::cplx_t value); /* \brief replaces all NaN values with value / void replaceNaNPython(boost::python::object obj); bool hasInf(); void replaceInf(DataTypes::real_t value); void replaceInf(DataTypes::cplx_t value); void replaceInfPython(boost::python::object obj); /* \brief Ensures data is ready for write access. This means that the data will be resolved if lazy and will be copied if shared with another Data object. \warning This method should only be called in single threaded sections of code. (It modifies m_data). Do not create any Data objects from this one between calling requireWrite and getSampleDataRW. Doing so might introduce additional sharing. / void requireWrite(); /* \brief Return true if this Data is expanded. \note To determine if a sample will contain separate values for each datapoint. Use actsExpanded instead. / bool isExpanded() const; /* \brief Return true if this Data is expanded or resolves to expanded. That is, if it has a separate value for each datapoint in the sample. / bool actsExpanded() const; /* \brief Return true if this Data is tagged. / bool isTagged() const; /* \brief Return true if this Data is constant. / bool isConstant() const; /* \brief Return true if this Data is lazy. / bool isLazy() const; /* \brief Return true if this data is ready. / bool isReady() const; /* \brief Return true if this Data holds an instance of DataEmpty. This is _not_ the same as asking if the object contains datapoints. / bool isEmpty() const; /* \brief True if components of this data are stored as complex / bool isComplex() const; /* \brief Return the function space. / inline const FunctionSpace& getFunctionSpace() const { return m_data->getFunctionSpace(); } /* \brief Returns the spatial locations of the data points. / inline escript::Data getXFromFunctionSpace() const { // This is exposed to Python as [Data object].getX() return m_data->getFunctionSpace().getX(); } /* \brief Return the domain. / inline // const AbstractDomain& const_Domain_ptr getDomain() const { return getFunctionSpace().getDomain(); } /* \brief Return the domain. TODO: For internal use only. This should be removed. / inline // const AbstractDomain& Domain_ptr getDomainPython() const { return getFunctionSpace().getDomainPython(); } /* \brief Return the rank of the point data. / inline unsigned int getDataPointRank() const { return m_data->getRank(); } /* \brief Return the number of data points / inline int getNumDataPoints() const { return getNumSamples() getNumDataPointsPerSample(); } /** \brief Return the number of samples. / inline int getNumSamples() const { return m_data->getNumSamples(); } /* \brief Return the number of data points per sample. / inline int getNumDataPointsPerSample() const { return m_data->getNumDPPSample(); } /* \brief Returns true if the number of data points per sample and the number of samples match the respective argument. DataEmpty always returns true. / inline bool numSamplesEqual(int numDataPointsPerSample, int numSamples) const { return (isEmpty() \|\| (numDataPointsPerSample==getNumDataPointsPerSample() && numSamples==getNumSamples())); } /* \brief Returns true if the shape matches the vector (dimensions[0],..., dimensions[rank-1]). DataEmpty always returns true. / inline bool isDataPointShapeEqual(int rank, const int dimensions) const { if (isEmpty()) return true; const DataTypes::ShapeType givenShape(&dimensions[0],&dimensions[rank]); return (getDataPointShape()==givenShape); } /** \brief Return the number of values in the shape for this object. / int getNoValues() const { return m_data->getNoValues(); } /* \brief dumps the object into a netCDF file / void dump(const std::string fileName) const; /* \brief returns the values of the object as a list of tuples (one for each datapoint). \param scalarastuple If true, scalar data will produce single valued tuples [(1,) (2,) ...] If false, the result is a list of scalars [1, 2, ...] / const boost::python::object toListOfTuples(bool scalarastuple=true); /* \brief Return the sample data for the given sample no. Please do not use this unless you NEED to access samples individually \param sampleNo - Input - the given sample no. \return pointer to the sample data. / const DataTypes::real_t getSampleDataRO(DataTypes::RealVectorType::size_type sampleNo, DataTypes::real_t dummy=0) const; const DataTypes::cplx_t* getSampleDataRO(DataTypes::CplxVectorType::size_type sampleNo, DataTypes::cplx_t dummy) const; /** \brief Return the sample data for the given sample no. Please do not use this unless you NEED to access samples individually \param sampleNo - Input - the given sample no. \return pointer to the sample data. / DataTypes::real_t getSampleDataRW(DataTypes::RealVectorType::size_type sampleNo, DataTypes::real_t dummy=0); DataTypes::cplx_t* getSampleDataRW(DataTypes::RealVectorType::size_type sampleNo, DataTypes::cplx_t dummy); /** \brief Return a pointer to the beginning of the underlying data \warning please avoid using this method since it by-passes possible lazy improvements. May be removed without notice. \return pointer to the data. / const DataTypes::real_t getDataRO(DataTypes::real_t dummy=0) const; const DataTypes::cplx_t* getDataRO(DataTypes::cplx_t dummy) const; /** \brief Return the sample data for the given tag. If an attempt is made to access data that isn't tagged an exception will be thrown. \param tag - Input - the tag key. / inline DataTypes::real_t getSampleDataByTag(int tag, DataTypes::real_t dummy=0) { return m_data->getSampleDataByTag(tag, dummy); } inline DataTypes::cplx_t* getSampleDataByTag(int tag, DataTypes::cplx_t dummy) { return m_data->getSampleDataByTag(tag, dummy); } /** \brief Return a reference into the DataVector which points to the specified data point. \param sampleNo - Input - \param dataPointNo - Input - / DataTypes::RealVectorType::const_reference getDataPointRO(int sampleNo, int dataPointNo); /* \brief Return a reference into the DataVector which points to the specified data point. \param sampleNo - Input - \param dataPointNo - Input - / DataTypes::RealVectorType::reference getDataPointRW(int sampleNo, int dataPointNo); /* \brief Return the offset for the given sample and point within the sample / inline DataTypes::RealVectorType::size_type getDataOffset(int sampleNo, int dataPointNo) { return m_data->getPointOffset(sampleNo,dataPointNo); } /* \brief Return a reference to the data point shape. / inline const DataTypes::ShapeType& getDataPointShape() const { return m_data->getShape(); } /* \brief Return the data point shape as a tuple of integers. / const boost::python::tuple getShapeTuple() const; /* \brief Returns the product of the data point shapes / long getShapeProduct() const; /* \brief Return the size of the data point. It is the product of the data point shape dimensions. / int getDataPointSize() const; /* \brief Return the number of doubles stored for this Data. / DataTypes::RealVectorType::size_type getLength() const; /* \brief Return true if this object contains no samples. This is not the same as isEmpty() / bool hasNoSamples() const { return m_data->getNumSamples()==0; } /* \brief Assign the given value to the tag assocciated with name. Implicitly converts this object to type DataTagged. Throws an exception if this object cannot be converted to a DataTagged object or name cannot be mapped onto a tag key. \param name - Input - name of tag. \param value - Input - Value to associate with given key. / void setTaggedValueByName(std::string name, const boost::python::object& value); /* \brief Assign the given value to the tag. Implicitly converts this object to type DataTagged if it is constant. \param tagKey - Input - Integer key. \param value - Input - Value to associate with given key. ==>* / void setTaggedValue(int tagKey, const boost::python::object& value); /* \brief Assign the given value to the tag. Implicitly converts this object to type DataTagged if it is constant. \param tagKey - Input - Integer key. \param pointshape - Input - The shape of the value parameter \param value - Input - Value to associate with given key. \param dataOffset - Input - Offset of the begining of the point within the value parameter / void setTaggedValueFromCPP(int tagKey, const DataTypes::ShapeType& pointshape, const DataTypes::RealVectorType& value, int dataOffset=0); void setTaggedValueFromCPP(int tagKey, const DataTypes::ShapeType& pointshape, const DataTypes::CplxVectorType& value, int dataOffset=0); /* \brief Copy other Data object into this Data object where mask is positive. / void copyWithMask(const Data& other, const Data& mask); /* Data object operation methods and operators. / /* \brief set all values to zero * / void setToZero(); /* \brief Interpolates this onto the given functionspace and returns the result as a Data object. * / Data interpolate(const FunctionSpace& functionspace) const; Data interpolateFromTable3D(const WrappedArray& table, DataTypes::real_t Amin, DataTypes::real_t Astep, DataTypes::real_t undef, Data& B, DataTypes::real_t Bmin, DataTypes::real_t Bstep, Data& C, DataTypes::real_t Cmin, DataTypes::real_t Cstep, bool check_boundaries); Data interpolateFromTable2D(const WrappedArray& table, DataTypes::real_t Amin, DataTypes::real_t Astep, DataTypes::real_t undef, Data& B, DataTypes::real_t Bmin, DataTypes::real_t Bstep,bool check_boundaries); Data interpolateFromTable1D(const WrappedArray& table, DataTypes::real_t Amin, DataTypes::real_t Astep, DataTypes::real_t undef,bool check_boundaries); Data interpolateFromTable3DP(boost::python::object table, DataTypes::real_t Amin, DataTypes::real_t Astep, Data& B, DataTypes::real_t Bmin, DataTypes::real_t Bstep, Data& C, DataTypes::real_t Cmin, DataTypes::real_t Cstep, DataTypes::real_t undef,bool check_boundaries); Data interpolateFromTable2DP(boost::python::object table, DataTypes::real_t Amin, DataTypes::real_t Astep, Data& B, DataTypes::real_t Bmin, DataTypes::real_t Bstep, DataTypes::real_t undef,bool check_boundaries); Data interpolateFromTable1DP(boost::python::object table, DataTypes::real_t Amin, DataTypes::real_t Astep, DataTypes::real_t undef,bool check_boundaries); Data nonuniforminterp(boost::python::object in, boost::python::object out, bool check_boundaries); Data nonuniformslope(boost::python::object in, boost::python::object out, bool check_boundaries); /* \brief Calculates the gradient of the data at the data points of functionspace. If functionspace is not present the function space of Function(getDomain()) is used. * / Data gradOn(const FunctionSpace& functionspace) const; Data grad() const; /* \brief Calculate the integral over the function space domain as a python tuple. / boost::python::object integrateToTuple_const() const; /* \brief Calculate the integral over the function space domain as a python tuple. / boost::python::object integrateToTuple(); /* \brief Returns 1./ Data object * / Data oneOver() const; /* \brief Return a Data with a 1 for +ive values and a 0 for 0 or -ive values. * / Data wherePositive() const; /* \brief Return a Data with a 1 for -ive values and a 0 for +ive or 0 values. * / Data whereNegative() const; /* \brief Return a Data with a 1 for +ive or 0 values and a 0 for -ive values. * / Data whereNonNegative() const; /* \brief Return a Data with a 1 for -ive or 0 values and a 0 for +ive values. * / Data whereNonPositive() const; /* \brief Return a Data with a 1 for 0 values and a 0 for +ive or -ive values. * / Data whereZero(DataTypes::real_t tol=0.0) const; /* \brief Return a Data with a 0 for 0 values and a 1 for +ive or -ive values. * / Data whereNonZero(DataTypes::real_t tol=0.0) const; /* \brief Return the maximum absolute value of this Data object. The method is not const because lazy data needs to be expanded before Lsup can be computed. The _const form can be used when the Data object is const, however this will only work for Data which is not Lazy. For Data which contain no samples (or tagged Data for which no tags in use have a value) zero is returned. / DataTypes::real_t Lsup(); DataTypes::real_t Lsup_const() const; /* \brief Return the maximum value of this Data object. The method is not const because lazy data needs to be expanded before sup can be computed. The _const form can be used when the Data object is const, however this will only work for Data which is not Lazy. For Data which contain no samples (or tagged Data for which no tags in use have a value) a large negative value is returned. / DataTypes::real_t sup(); DataTypes::real_t sup_const() const; /* \brief Return the minimum value of this Data object. The method is not const because lazy data needs to be expanded before inf can be computed. The _const form can be used when the Data object is const, however this will only work for Data which is not Lazy. For Data which contain no samples (or tagged Data for which no tags in use have a value) a large positive value is returned. / DataTypes::real_t inf(); DataTypes::real_t inf_const() const; /* \brief Return the absolute value of each data point of this Data object. * / Data abs() const; /* \brief Return the phase/arg/angular-part of complex values. * / Data phase() const; /* \brief Return the maximum value of each data point of this Data object. * / Data maxval() const; /* \brief Return the minimum value of each data point of this Data object. * / Data minval() const; /* \brief Return the (sample number, data-point number) of the data point with the minimum component value in this Data object. \note If you are working in python, please consider using Locator instead of manually manipulating process and point IDs. / const boost::python::tuple minGlobalDataPoint() const; /* \brief Return the (sample number, data-point number) of the data point with the minimum component value in this Data object. \note If you are working in python, please consider using Locator instead of manually manipulating process and point IDs. / const boost::python::tuple maxGlobalDataPoint() const; /* \brief Return the sign of each data point of this Data object. -1 for negative values, zero for zero values, 1 for positive values. * / Data sign() const; /* \brief Return the symmetric part of a matrix which is half the matrix plus its transpose. * / Data symmetric() const; /* \brief Return the antisymmetric part of a matrix which is half the matrix minus its transpose. * / Data antisymmetric() const; /* \brief Return the hermitian part of a matrix which is half the matrix plus its adjoint. * / Data hermitian() const; /* \brief Return the anti-hermitian part of a matrix which is half the matrix minus its hermitian. * / Data antihermitian() const; /* \brief Return the trace of a matrix * / Data trace(int axis_offset) const; /* \brief Transpose each data point of this Data object around the given axis. * / Data transpose(int axis_offset) const; /* \brief Return the eigenvalues of the symmetric part at each data point of this Data object in increasing values. Currently this function is restricted to rank 2, square shape, and dimension 3. * / Data eigenvalues() const; /* \brief Return the eigenvalues and corresponding eigenvcetors of the symmetric part at each data point of this Data object. the eigenvalues are ordered in increasing size where eigenvalues with relative difference less than tol are treated as equal. The eigenvectors are orthogonal, normalized and the sclaed such that the first non-zero entry is positive. Currently this function is restricted to rank 2, square shape, and dimension 3 * / const boost::python::tuple eigenvalues_and_eigenvectors(const DataTypes::real_t tol=1.e-12) const; /* \brief swaps the components axis0 and axis1 * / Data swapaxes(const int axis0, const int axis1) const; /* \brief Return the error function erf of each data point of this Data object. * / Data erf() const; /* \brief For complex values return the conjugate values. For non-complex data return a copy / Data conjugate() const; Data real() const; Data imag() const; /* \brief Return the sin of each data point of this Data object. * / Data sin() const; /* \brief Return the cos of each data point of this Data object. * / Data cos() const; /* \brief Bessel worker function. * / Data bessel(int order, DataTypes::real_t (besselfunc) (int,DataTypes::real_t) ); /** \brief Return the Bessel function of the first kind for each data point of this Data object. * / Data besselFirstKind(int order); /* \brief Return the Bessel function of the second kind for each data point of this Data object. * / Data besselSecondKind(int order); /* \brief Return the tan of each data point of this Data object. * / Data tan() const; /* \brief Return the asin of each data point of this Data object. * / Data asin() const; /* \brief Return the acos of each data point of this Data object. * / Data acos() const; /* \brief Return the atan of each data point of this Data object. * / Data atan() const; /* \brief Return the sinh of each data point of this Data object. * / Data sinh() const; /* \brief Return the cosh of each data point of this Data object. * / Data cosh() const; /* \brief Return the tanh of each data point of this Data object. * / Data tanh() const; /* \brief Return the asinh of each data point of this Data object. * / Data asinh() const; /* \brief Return the acosh of each data point of this Data object. * / Data acosh() const; /* \brief Return the atanh of each data point of this Data object. * / Data atanh() const; /* \brief Return the log to base 10 of each data point of this Data object. * / Data log10() const; /* \brief Return the natural log of each data point of this Data object. * / Data log() const; /* \brief Return the exponential function of each data point of this Data object. * / Data exp() const; /* \brief Return the square root of each data point of this Data object. * / Data sqrt() const; /* \brief Return the negation of each data point of this Data object. * / Data neg() const; /* \brief Return the identity of each data point of this Data object. Simply returns this object unmodified. * / Data pos() const; /* \brief Return the given power of each data point of this Data object. \param right Input - the power to raise the object to. * / Data powD(const Data& right) const; /* \brief Return the given power of each data point of this boost python object. \param right Input - the power to raise the object to. * / Data powO(const boost::python::object& right) const; /* \brief Return the given power of each data point of this boost python object. \param left Input - the bases * / Data rpowO(const boost::python::object& left) const; /* \brief Overloaded operator += \param right - Input - The right hand side. * / Data& operator+=(const Data& right); Data& operator+=(const boost::python::object& right); Data& operator=(const Data& other); /* \brief Overloaded operator -= \param right - Input - The right hand side. * / Data& operator-=(const Data& right); Data& operator-=(const boost::python::object& right); /* \brief Overloaded operator = \param right - Input - The right hand side. / Data& operator=(const Data& right); Data& operator=(const boost::python::object& right); /* \brief Overloaded operator /= \param right - Input - The right hand side. * / Data& operator/=(const Data& right); Data& operator/=(const boost::python::object& right); /* \brief Newer style division operator for python / Data truedivD(const Data& right); /* \brief Newer style division operator for python / Data truedivO(const boost::python::object& right); /* \brief Newer style division operator for python / Data rtruedivO(const boost::python::object& left); /* \brief wrapper for python add operation / boost::python::object __add__(const boost::python::object& right); /* \brief wrapper for python subtract operation / boost::python::object __sub__(const boost::python::object& right); /* \brief wrapper for python reverse subtract operation / boost::python::object __rsub__(const boost::python::object& right); /* \brief wrapper for python multiply operation / boost::python::object __mul__(const boost::python::object& right); /* \brief wrapper for python divide operation / boost::python::object __div__(const boost::python::object& right); /* \brief wrapper for python reverse divide operation / boost::python::object __rdiv__(const boost::python::object& right); /* \brief return inverse of matricies. / Data matrixInverse() const; /* \brief Returns true if this can be interpolated to functionspace. / bool probeInterpolation(const FunctionSpace& functionspace) const; /* Data object slicing methods. / /* \brief Returns a slice from this Data object. /description Implements the [] get operator in python. Calls getSlice. \param key - Input - python slice tuple specifying slice to return. / Data getItem(const boost::python::object& key) const; /* \brief Copies slice from value into this Data object. Implements the [] set operator in python. Calls setSlice. \param key - Input - python slice tuple specifying slice to copy from value. \param value - Input - Data object to copy from. / void setItemD(const boost::python::object& key, const Data& value); void setItemO(const boost::python::object& key, const boost::python::object& value); // These following public methods should be treated as private. /* \brief Perform the given unary operation on every element of every data point in this Data object. / template <class UnaryFunction> inline void unaryOp2(UnaryFunction operation); /* \brief Return a Data object containing the specified slice of this Data object. \param region - Input - Region to copy. * / Data getSlice(const DataTypes::RegionType& region) const; /* \brief Copy the specified slice from the given value into this Data object. \param value - Input - Data to copy from. \param region - Input - Region to copy. * / void setSlice(const Data& value, const DataTypes::RegionType& region); /* \brief print the data values to stdout. Used for debugging / void print(void); /* \brief return the MPI rank number of the local data MPI_COMM_WORLD is assumed and the result of MPI_Comm_size() is returned / int get_MPIRank(void) const; /* \brief return the MPI rank number of the local data MPI_COMM_WORLD is assumed and the result of MPI_Comm_rank() is returned / int get_MPISize(void) const; /* \brief return the MPI rank number of the local data MPI_COMM_WORLD is assumed and returned. / MPI_Comm get_MPIComm(void) const; /* \brief return the object produced by the factory, which is a DataConstant or DataExpanded TODO Ownership of this object should be explained in doco. / DataAbstract borrowData(void) const; DataAbstract_ptr borrowDataPtr(void) const; DataReady_ptr borrowReadyPtr(void) const; /** \brief Return a pointer to the beginning of the datapoint at the specified offset. TODO Eventually these should be inlined. \param i - position(offset) in the underlying datastructure / DataTypes::RealVectorType::const_reference getDataAtOffsetRO(DataTypes::RealVectorType::size_type i, DataTypes::real_t dummy); DataTypes::RealVectorType::reference getDataAtOffsetRW(DataTypes::RealVectorType::size_type i, DataTypes::real_t dummy); DataTypes::CplxVectorType::const_reference getDataAtOffsetRO(DataTypes::CplxVectorType::size_type i, DataTypes::cplx_t dummy); DataTypes::CplxVectorType::reference getDataAtOffsetRW(DataTypes::CplxVectorType::size_type i, DataTypes::cplx_t dummy); /* \brief Ensures that the Data is expanded and returns its underlying vector Does not check for exclusive write so do that before calling if sharing Is a posibility. \warning For domain implementors only. Using this function will avoid using optimisations like lazy evaluation. It is intended to allow quick initialisation of Data by domain; not as a bypass around escript's other mechanisms. / DataTypes::RealVectorType& getExpandedVectorReference(DataTypes::real_t dummy=0); DataTypes::CplxVectorType& getExpandedVectorReference(DataTypes::cplx_t dummy); /* * \brief For tagged Data returns the number of tags with values. * For non-tagged data will return 0 (even Data which has been expanded from tagged). / size_t getNumberOfTaggedValues() const; / * \brief make the data complex / void complicate(); protected: private: void init_from_data_and_fs(const Data& inData, const FunctionSpace& functionspace); template <typename S> void maskWorker(Data& other2, Data& mask2, S sentinel); template <class BinaryOp> DataTypes::real_t #ifdef ESYS_MPI lazyAlgWorker(DataTypes::real_t init, MPI_Op mpiop_type); #else lazyAlgWorker(DataTypes::real_t init); #endif DataTypes::real_t LsupWorker() const; DataTypes::real_t supWorker() const; DataTypes::real_t infWorker() const; template<typename Scalar> boost::python::object integrateWorker() const; void calc_minGlobalDataPoint(int& ProcNo, int& DataPointNo) const; void calc_maxGlobalDataPoint(int& ProcNo, int& DataPointNo) const; // For internal use in Data.cpp only! // other uses should call the main entry points and allow laziness Data minval_nonlazy() const; // For internal use in Data.cpp only! Data maxval_nonlazy() const; /* \brief Check this and the right operand are compatible. Throws an exception if they aren't. \param right - Input - The right hand side. / inline void operandCheck(const Data& right) const { return m_data->operandCheck((right.m_data.get())); } /* \brief Perform the specified reduction algorithm on every element of every data point in this Data object according to the given function and return the single value result. / template <class BinaryFunction> inline DataTypes::real_t reduction(BinaryFunction operation, DataTypes::real_t initial_value) const; /* \brief Reduce each data-point in this Data object using the given operation. Return a Data object with the same number of data-points, but with each data-point containing only one value - the result of the reduction operation on the corresponding data-point in this Data object / template <class BinaryFunction> inline Data dp_algorithm(BinaryFunction operation, DataTypes::real_t initial_value) const; /* \brief Convert the data type of the RHS to match this. \param right - Input - data type to match. / void typeMatchLeft(Data& right) const; /* \brief Convert the data type of this to match the RHS. \param right - Input - data type to match. / void typeMatchRight(const Data& right); /* \brief Construct a Data object of the appropriate type. / void initialise(const DataTypes::RealVectorType& value, const DataTypes::ShapeType& shape, const FunctionSpace& what, bool expanded); void initialise(const DataTypes::CplxVectorType& value, const DataTypes::ShapeType& shape, const FunctionSpace& what, bool expanded); void initialise(const WrappedArray& value, const FunctionSpace& what, bool expanded); void initialise(const DataTypes::real_t value, const DataTypes::ShapeType& shape, const FunctionSpace& what, bool expanded); void initialise(const DataTypes::cplx_t value, const DataTypes::ShapeType& shape, const FunctionSpace& what, bool expanded); // // flag to protect the data object against any update bool m_protected; bool m_lazy; // // pointer to the actual data object // boost::shared_ptr<DataAbstract> m_data; DataAbstract_ptr m_data; // If possible please use getReadyPtr instead. // But see warning below. const DataReady getReady() const { const DataReady* dr=dynamic_cast<const DataReady>(m_data.get()); ESYS_ASSERT(dr!=0, "error casting to DataReady."); return dr; } DataReady getReady() { DataReady* dr=dynamic_cast<DataReady>(m_data.get()); ESYS_ASSERT(dr!=0, "error casting to DataReady."); return dr; } // Be wary of using this for local operations since it (temporarily) increases reference count. // If you are just using this to call a method on DataReady instead of DataAbstract consider using // getReady() instead DataReady_ptr getReadyPtr() { DataReady_ptr dr=REFCOUNTNS::dynamic_pointer_cast<DataReady>(m_data); ESYS_ASSERT(dr.get()!=0, "error casting to DataReady."); return dr; } const_DataReady_ptr getReadyPtr() const { const_DataReady_ptr dr=REFCOUNTNS::dynamic_pointer_cast<const DataReady>(m_data); ESYS_ASSERT(dr.get()!=0, "error casting to DataReady."); return dr; } // In the isShared() method below: // A problem would occur if m_data (the address pointed to) were being modified // while the call m_data->is_shared is being executed. // // Q: So why do I think this code can be thread safe/correct? // A: We need to make some assumptions. // 1. We assume it is acceptable to return true under some conditions when we aren't shared. // 2. We assume that no constructions or assignments which will share previously unshared // will occur while this call is executing. This is consistent with the way Data:: and C are written. // // This means that the only transition we need to consider, is when a previously shared object is // not shared anymore. ie. the other objects have been destroyed or a deep copy has been made. // In those cases the m_shared flag changes to false after m_data has completed changing. // For any threads executing before the flag switches they will assume the object is still shared. bool isShared() const { #ifdef SLOWSHARECHECK return m_data->isShared(); // single threadsafe check for this #else return !m_data.unique(); #endif } void forceResolve() { if (isLazy()) { #ifdef _OPENMP if (omp_in_parallel()) { // Yes this is throwing an exception out of an omp thread which is forbidden. throw DataException("Please do not call forceResolve() in a parallel region."); } #endif resolve(); } } /* \brief if another object is sharing out member data make a copy to work with instead. This code should only be called from single threaded sections of code. / void exclusiveWrite() { #ifdef _OPENMP if (omp_in_parallel()) { throw DataException("Programming error. Please do not run exclusiveWrite() in multi-threaded sections."); } #endif forceResolve(); if (isShared()) { DataAbstract t=m_data->deepCopy(); set_m_data(DataAbstract_ptr(t)); } #ifdef EXWRITECHK m_data->exclusivewritecalled=true; #endif } /** \brief checks if caller can have exclusive write to the object / void checkExclusiveWrite() { if (isLazy() \|\| isShared()) { std::ostringstream oss; oss << "Programming error. ExclusiveWrite required - please call requireWrite() isLazy=" << isLazy() << " isShared()=" << isShared(); throw DataException(oss.str()); } } /* \brief Modify the data abstract hosted by this Data object For internal use only. Passing a pointer to null is permitted (do this in the destructor) \warning Only to be called in single threaded code or inside a single/critical section. This method needs to be atomic. / void set_m_data(DataAbstract_ptr p); void TensorSelfUpdateBinaryOperation(const Data& right, escript::ES_optype operation); friend class DataAbstract; // To allow calls to updateShareStatus friend class TestDomain; // so its getX will work quickly #ifdef IKNOWWHATIMDOING friend Data applyBinaryCFunction(boost::python::object cfunc, boost::python::tuple shape, escript::Data& d, escript::Data& e); #endif template <typename S> friend Data condEvalWorker(escript::Data& mask, escript::Data& trueval, escript::Data& falseval, S sentinel); friend ESCRIPT_DLL_API Data randomData(const boost::python::tuple& shape, const FunctionSpace& what, long seed, const boost::python::tuple& filter); }; #ifdef IKNOWWHATIMDOING Data applyBinaryCFunction(boost::python::object func, boost::python::tuple shape, escript::Data& d, escript::Data& e); #endif ESCRIPT_DLL_API Data condEval(escript::Data& mask, escript::Data& trueval, escript::Data& falseval); /* \brief Create a new Expanded Data object filled with pseudo-random data. / ESCRIPT_DLL_API Data randomData(const boost::python::tuple& shape, const FunctionSpace& what, long seed, const boost::python::tuple& filter); } // end namespace escript // No, this is not supposed to be at the top of the file // DataAbstact needs to be declared first, then DataReady needs to be fully declared // so that I can dynamic cast between them below. #include "DataReady.h" #include "DataLazy.h" #include "DataExpanded.h" #include "DataConstant.h" #include "DataTagged.h" namespace escript { inline DataTypes::real_t Data::getSampleDataRW(DataTypes::RealVectorType::size_type sampleNo, DataTypes::real_t dummy) { if (isLazy()) { throw DataException("Error, attempt to acquire RW access to lazy data. Please call requireWrite() first."); } #ifdef EXWRITECHK if (!getReady()->exclusivewritecalled) { throw DataException("Error, call to Data::getSampleDataRW without a preceeding call to requireWrite/exclusiveWrite."); } #endif return getReady()->getSampleDataRW(sampleNo, dummy); } inline DataTypes::cplx_t* Data::getSampleDataRW(DataTypes::CplxVectorType::size_type sampleNo, DataTypes::cplx_t dummy) { if (isLazy()) { throw DataException("Error, attempt to acquire RW access to lazy data. Please call requireWrite() first."); } #ifdef EXWRITECHK if (!getReady()->exclusivewritecalled) { throw DataException("Error, call to Data::getSampleDataRW without a preceeding call to requireWrite/exclusiveWrite."); } #endif return getReady()->getSampleDataRW(sampleNo, dummy); } inline const DataTypes::real_t* Data::getSampleDataRO(DataTypes::RealVectorType::size_type sampleNo,DataTypes::real_t dummy) const { DataLazy* l=dynamic_cast<DataLazy>(m_data.get()); if (l!=0) { size_t offset=0; const DataTypes::RealVectorType res=l->resolveSample(sampleNo,offset); return &((res)[offset]); } return getReady()->getSampleDataRO(sampleNo, dummy); } inline const DataTypes::cplx_t Data::getSampleDataRO(DataTypes::RealVectorType::size_type sampleNo, DataTypes::cplx_t dummy) const { DataLazy* l=dynamic_cast<DataLazy>(m_data.get()); if (l!=0) { throw DataException("Programming error: complex lazy objects are not supported."); } return getReady()->getSampleDataRO(sampleNo, dummy); } inline const DataTypes::real_t Data::getDataRO(DataTypes::real_t dummy) const { if (isLazy()) { throw DataException("Programmer error - getDataRO must not be called on Lazy Data."); } if (getNumSamples()==0) { return 0; } else { return &(getReady()->getTypedVectorRO(0)[0]); } } inline const DataTypes::cplx_t* Data::getDataRO(DataTypes::cplx_t dummy) const { if (isLazy()) { throw DataException("Programmer error - getDataRO must not be called on Lazy Data."); } if (getNumSamples()==0) { return 0; } else { return &(getReady()->getTypedVectorRO(dummy)[0]); } } /** Binary Data object operators. / inline DataTypes::real_t rpow(DataTypes::real_t x,DataTypes::real_t y) { return pow(y,x); } /* \brief Operator+ Takes two Data objects. / ESCRIPT_DLL_API Data operator+(const Data& left, const Data& right); /* \brief Operator- Takes two Data objects. / ESCRIPT_DLL_API Data operator-(const Data& left, const Data& right); /* \brief Operator* Takes two Data objects. / ESCRIPT_DLL_API Data operator(const Data& left, const Data& right); /** \brief Operator/ Takes two Data objects. / ESCRIPT_DLL_API Data operator/(const Data& left, const Data& right); /* \brief Operator+ Takes LHS Data object and RHS python::object. python::object must be convertable to Data type. / ESCRIPT_DLL_API Data operator+(const Data& left, const boost::python::object& right); /* \brief Operator- Takes LHS Data object and RHS python::object. python::object must be convertable to Data type. / ESCRIPT_DLL_API Data operator-(const Data& left, const boost::python::object& right); /* \brief Operator* Takes LHS Data object and RHS python::object. python::object must be convertable to Data type. / ESCRIPT_DLL_API Data operator(const Data& left, const boost::python::object& right); /** \brief Operator/ Takes LHS Data object and RHS python::object. python::object must be convertable to Data type. / ESCRIPT_DLL_API Data operator/(const Data& left, const boost::python::object& right); /* \brief Operator+ Takes LHS python::object and RHS Data object. python::object must be convertable to Data type. / ESCRIPT_DLL_API Data operator+(const boost::python::object& left, const Data& right); /* \brief Operator- Takes LHS python::object and RHS Data object. python::object must be convertable to Data type. / ESCRIPT_DLL_API Data operator-(const boost::python::object& left, const Data& right); /* \brief Operator* Takes LHS python::object and RHS Data object. python::object must be convertable to Data type. / ESCRIPT_DLL_API Data operator(const boost::python::object& left, const Data& right); /** \brief Operator/ Takes LHS python::object and RHS Data object. python::object must be convertable to Data type. / ESCRIPT_DLL_API Data operator/(const boost::python::object& left, const Data& right); /* \brief Output operator / ESCRIPT_DLL_API std::ostream& operator<<(std::ostream& o, const Data& data); /* \brief Compute a tensor product of two Data objects \param arg_0 - Input - Data object \param arg_1 - Input - Data object \param axis_offset - Input - axis offset \param transpose - Input - 0: transpose neither, 1: transpose arg0, 2: transpose arg1 / ESCRIPT_DLL_API Data C_GeneralTensorProduct(Data& arg_0, Data& arg_1, int axis_offset=0, int transpose=0); /* \brief Operator/ Takes RHS Data object. / inline Data Data::truedivD(const Data& right) { return this / right; } /** \brief Operator/ Takes RHS python::object. / inline Data Data::truedivO(const boost::python::object& right) { Data tmp(right, getFunctionSpace(), false); return truedivD(tmp); } /* \brief Operator/ Takes LHS python::object. / inline Data Data::rtruedivO(const boost::python::object& left) { Data tmp(left, getFunctionSpace(), false); return tmp.truedivD(this); } /** \brief Perform the given Data object reduction algorithm on this and return the result. Given operation combines each element of each data point, thus argument object (this) is a rank n Data object, and returned object is a scalar. Calls escript::algorithm. / template <class BinaryFunction> inline DataTypes::real_t Data::reduction(BinaryFunction operation, DataTypes::real_t initial_value) const { if (isExpanded()) { DataExpanded* leftC=dynamic_cast<DataExpanded>(m_data.get()); ESYS_ASSERT(leftC!=0, "Programming error - casting to DataExpanded."); DataExpanded& data=leftC; int i,j; int numDPPSample=data.getNumDPPSample(); int numSamples=data.getNumSamples(); DataTypes::real_t global_current_value=initial_value; DataTypes::real_t local_current_value; const auto& vec=data.getTypedVectorRO(typename BinaryFunction::first_argument_type(0)); const DataTypes::ShapeType& shape=data.getShape(); // calculate the reduction operation value for each data point // reducing the result for each data-point into the current_value variables #pragma omp parallel private(local_current_value) { local_current_value=initial_value; #pragma omp for private(i,j) schedule(static) for (i=0;i<numSamples;i++) { for (j=0;j<numDPPSample;j++) { local_current_value=operation(local_current_value,escript::reductionOpVector(vec,shape,data.getPointOffset(i,j),operation,initial_value)); } } #pragma omp critical global_current_value=operation(global_current_value,local_current_value); } return global_current_value; } else if (isTagged()) { DataTagged* leftC=dynamic_cast<DataTagged>(m_data.get()); ESYS_ASSERT(leftC!=0, "Programming error - casting to DataTagged."); DataTagged& data=leftC; DataTypes::real_t current_value=initial_value; const auto& vec=data.getTypedVectorRO(typename BinaryFunction::first_argument_type(0)); const DataTypes::ShapeType& shape=data.getShape(); const DataTagged::DataMapType& lookup=data.getTagLookup(); const std::list<int> used=data.getFunctionSpace().getListOfTagsSTL(); for (std::list<int>::const_iterator i=used.begin();i!=used.end();++i) { int tag=i; DataTagged::DataMapType::const_iterator it=lookup.find(tag); if ((tag==0) \|\| (it==lookup.end())) // check for the default tag { current_value=operation(current_value,escript::reductionOpVector(vec,shape,data.getDefaultOffset(),operation,initial_value)); } else { current_value=operation(current_value,escript::reductionOpVector(vec,shape,it->second,operation,initial_value)); } } return current_value; } else if (isConstant()) { DataConstant leftC=dynamic_cast<DataConstant>(m_data.get()); ESYS_ASSERT(leftC!=0, "Programming error - casting to DataConstant."); return escript::reductionOpVector(leftC->getTypedVectorRO(typename BinaryFunction::first_argument_type(0)),leftC->getShape(),0,operation,initial_value); } else if (isEmpty()) { throw DataException("Error - Operations (algorithm) not permitted on instances of DataEmpty."); } else if (isLazy()) { throw DataException("Error - Operations not permitted on instances of DataLazy."); } else { throw DataException("Error - Data encapsulates an unknown type."); } } /* \brief Perform the given data point reduction algorithm on data and return the result. Given operation combines each element within each data point into a scalar, thus argument object is a rank n Data object, and returned object is a rank 0 Data object. Calls escript::dp_algorithm. / template <class BinaryFunction> inline Data Data::dp_algorithm(BinaryFunction operation, DataTypes::real_t initial_value) const { if (isEmpty()) { throw DataException("Error - Operations (dp_algorithm) not permitted on instances of DataEmpty."); } else if (isExpanded()) { Data result(0,DataTypes::ShapeType(),getFunctionSpace(),isExpanded()); DataExpanded dataE=dynamic_cast<DataExpanded>(m_data.get()); DataExpanded resultE=dynamic_cast<DataExpanded>(result.m_data.get()); ESYS_ASSERT(dataE!=0, "Programming error - casting data to DataExpanded."); ESYS_ASSERT(resultE!=0, "Programming error - casting result to DataExpanded."); int i,j; int numSamples=dataE->getNumSamples(); int numDPPSample=dataE->getNumDPPSample(); // DataArrayView dataView=data.getPointDataView(); // DataArrayView resultView=result.getPointDataView(); const auto& dataVec=dataE->getTypedVectorRO(initial_value); const DataTypes::ShapeType& shape=dataE->getShape(); auto& resultVec=resultE->getTypedVectorRW(initial_value); // perform the operation on each data-point and assign // this to the corresponding element in result #pragma omp parallel for private(i,j) schedule(static) for (i=0;i<numSamples;i++) { for (j=0;j<numDPPSample;j++) { resultVec[resultE->getPointOffset(i,j)] = escript::reductionOpVector(dataVec, shape, dataE->getPointOffset(i,j),operation,initial_value); } } //escript::dp_algorithm(dataE,resultE,operation,initial_value); return result; } else if (isTagged()) { DataTagged dataT=dynamic_cast<DataTagged>(m_data.get()); ESYS_ASSERT(dataT!=0, "Programming error - casting data to DataTagged."); DataTypes::RealVectorType defval(1); defval[0]=0; DataTagged resultT=new DataTagged(getFunctionSpace(), DataTypes::scalarShape, defval, dataT); const DataTypes::ShapeType& shape=dataT->getShape(); const auto& vec=dataT->getTypedVectorRO(initial_value); const DataTagged::DataMapType& lookup=dataT->getTagLookup(); for (DataTagged::DataMapType::const_iterator i=lookup.begin(); i!=lookup.end(); i++) { resultT->getDataByTagRW(i->first,0) = escript::reductionOpVector(vec,shape,dataT->getOffsetForTag(i->first),operation,initial_value); } resultT->getTypedVectorRW(initial_value)[resultT->getDefaultOffset()] = escript::reductionOpVector(dataT->getTypedVectorRO(initial_value),dataT->getShape(),dataT->getDefaultOffset(),operation,initial_value); //escript::dp_algorithm(dataT,resultT,operation,initial_value); return Data(resultT); // note: the Data object now owns the resultT pointer } else if (isConstant()) { Data result(0,DataTypes::ShapeType(),getFunctionSpace(),isExpanded()); DataConstant* dataC=dynamic_cast<DataConstant>(m_data.get()); DataConstant resultC=dynamic_cast<DataConstant>(result.m_data.get()); ESYS_ASSERT(dataC!=0, "Programming error - casting data to DataConstant."); ESYS_ASSERT(resultC!=0, "Programming error - casting result to DataConstant."); DataConstant& data=dataC; resultC->getTypedVectorRW(initial_value)[0] = escript::reductionOpVector(data.getTypedVectorRO(initial_value),data.getShape(),0,operation,initial_value); //escript::dp_algorithm(dataC,resultC,operation,initial_value); return result; } else if (isLazy()) { throw DataException("Error - Operations not permitted on instances of DataLazy."); } else { throw DataException("Error - Data encapsulates an unknown type."); } } /** \brief Compute a tensor operation with two Data objects \param arg_0 - Input - Data object \param arg_1 - Input - Data object \param operation - Input - Binary op functor */ Data C_TensorBinaryOperation(Data const &arg_0, Data const &arg_1, ES_optype operation); Data C_TensorUnaryOperation(Data const &arg_0, escript::ES_optype operation, DataTypes::real_t tol=0); } // namespace escript #endif // __ESCRIPT_DATA_H__
sculpt.c	/* * $Id: sculpt.c 40597 2011-09-27 09:21:17Z nazgul $ * * *** BEGIN GPL LICENSE BLOCK *** * * This program is free software; you can redistribute it and/or * modify it under the terms of the GNU General Public License * as published by the Free Software Foundation; either version 2 * of the License, or (at your option) any later version. * * This program is distributed in the hope that it will be useful, * but WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the * GNU General Public License for more details. * * You should have received a copy of the GNU General Public License * along with this program; if not, write to the Free Software Foundation, * Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301, USA. * * The Original Code is Copyright (C) 2006 by Nicholas Bishop * All rights reserved. * * The Original Code is: all of this file. * * Contributor(s): Jason Wilkins, Tom Musgrove. * * *** END GPL LICENSE BLOCK *** * * Implements the Sculpt Mode tools * / /* \file blender/editors/sculpt_paint/sculpt.c * \ingroup edsculpt / #include "MEM_guardedalloc.h" #include "BLI_math.h" #include "BLI_blenlib.h" #include "BLI_utildefines.h" #include "BLI_dynstr.h" #include "BLI_ghash.h" #include "BLI_pbvh.h" #include "BLI_threads.h" #include "BLI_editVert.h" #include "BLI_rand.h" #include "DNA_meshdata_types.h" #include "DNA_node_types.h" #include "DNA_object_types.h" #include "DNA_scene_types.h" #include "DNA_brush_types.h" #include "BKE_brush.h" #include "BKE_cdderivedmesh.h" #include "BKE_context.h" #include "BKE_depsgraph.h" #include "BKE_key.h" #include "BKE_library.h" #include "BKE_mesh.h" #include "BKE_modifier.h" #include "BKE_multires.h" #include "BKE_paint.h" #include "BKE_report.h" #include "BKE_lattice.h" / for armature_deform_verts / #include "BKE_node.h" #include "BIF_glutil.h" #include "WM_api.h" #include "WM_types.h" #include "ED_sculpt.h" #include "ED_screen.h" #include "ED_view3d.h" #include "ED_util.h" / for crazyspace correction / #include "paint_intern.h" #include "sculpt_intern.h" #include "RNA_access.h" #include "RNA_define.h" #include "RE_render_ext.h" #include "GPU_buffers.h" #include <math.h> #include <stdlib.h> #include <string.h> #ifdef _OPENMP #include <omp.h> #endif void ED_sculpt_force_update(bContext C) { Object ob= CTX_data_active_object(C); if(ob && (ob->mode & OB_MODE_SCULPT)) multires_force_update(ob); } / Sculpt mode handles multires differently from regular meshes, but only if it's the last modifier on the stack and it is not on the first level / struct MultiresModifierData sculpt_multires_active(Scene scene, Object ob) { Mesh me= (Mesh)ob->data; ModifierData md; if(!CustomData_get_layer(&me->fdata, CD_MDISPS)) { / multires can't work without displacement layer / return NULL; } for(md= modifiers_getVirtualModifierList(ob); md; md= md->next) { if(md->type == eModifierType_Multires) { MultiresModifierData mmd= (MultiresModifierData)md; if(!modifier_isEnabled(scene, md, eModifierMode_Realtime)) continue; if(mmd->sculptlvl > 0) return mmd; else return NULL; } } return NULL; } / Check if there are any active modifiers in stack (used for flushing updates at enter/exit sculpt mode) / static int sculpt_has_active_modifiers(Scene scene, Object ob) { ModifierData md; md= modifiers_getVirtualModifierList(ob); /* exception for shape keys because we can edit those / for(; md; md= md->next) { if(modifier_isEnabled(scene, md, eModifierMode_Realtime)) return 1; } return 0; } / Checks if there are any supported deformation modifiers active / static int sculpt_modifiers_active(Scene scene, Sculpt sd, Object ob) { ModifierData md; Mesh me= (Mesh)ob->data; MultiresModifierData mmd= sculpt_multires_active(scene, ob); if(mmd) return 0; /* non-locked shape keys could be handled in the same way as deformed mesh / if((ob->shapeflag&OB_SHAPE_LOCK)==0 && me->key && ob->shapenr) return 1; md= modifiers_getVirtualModifierList(ob); / exception for shape keys because we can edit those / for(; md; md= md->next) { ModifierTypeInfo mti = modifierType_getInfo(md->type); if(!modifier_isEnabled(scene, md, eModifierMode_Realtime)) continue; if(md->type==eModifierType_ShapeKey) continue; if(mti->type==eModifierTypeType_OnlyDeform) return 1; else if((sd->flags & SCULPT_ONLY_DEFORM)==0) return 1; } return 0; } typedef enum StrokeFlags { CLIP_X = 1, CLIP_Y = 2, CLIP_Z = 4 } StrokeFlags; /* Cache stroke properties. Used because RNA property lookup isn't particularly fast. For descriptions of these settings, check the operator properties. / typedef struct StrokeCache { / Invariants / float initial_radius; float scale[3]; int flag; float clip_tolerance[3]; float initial_mouse[2]; / Variants / float radius; float radius_squared; //float traced_location[3]; float true_location[3]; float location[3]; float pen_flip; float invert; float pressure; float mouse[2]; float bstrength; float tex_mouse[2]; / The rest is temporary storage that isn't saved as a property / int first_time; / Beginning of stroke may do some things special / bglMats mats; /* Clean this up! / ViewContext vc; Brush brush; float (face_norms)[3]; /* Copy of the mesh faces' normals / float special_rotation; / Texture rotation (radians) for anchored and rake modes / int pixel_radius, previous_pixel_radius; float grab_delta[3], grab_delta_symmetry[3]; float old_grab_location[3], orig_grab_location[3]; int symmetry; / Symmetry index between 0 and 7 bit combo 0 is Brush only; 1 is X mirror; 2 is Y mirror; 3 is XY; 4 is Z; 5 is XZ; 6 is YZ; 7 is XYZ / int mirror_symmetry_pass; / the symmetry pass we are currently on between 0 and 7/ float true_view_normal[3]; float view_normal[3]; float last_area_normal[3]; float last_center[3]; int radial_symmetry_pass; float symm_rot_mat[4][4]; float symm_rot_mat_inv[4][4]; float last_rake[2]; / Last location of updating rake rotation / int original; float vertex_rotation; char saved_active_brush_name[24]; int alt_smooth; float plane_trim_squared; rcti previous_r; / previous redraw rectangle / } StrokeCache; / BVH Tree / / Get a screen-space rectangle of the modified area / static int sculpt_get_redraw_rect(ARegion ar, RegionView3D rv3d, Object ob, rcti rect) { PBVH pbvh= ob->sculpt->pbvh; float bb_min[3], bb_max[3], pmat[4][4]; int i, j, k; ED_view3d_ob_project_mat_get(rv3d, ob, pmat); if(!pbvh) return 0; BLI_pbvh_redraw_BB(pbvh, bb_min, bb_max); rect->xmin = rect->ymin = INT_MAX; rect->xmax = rect->ymax = INT_MIN; if(bb_min[0] > bb_max[0] \|\| bb_min[1] > bb_max[1] \|\| bb_min[2] > bb_max[2]) return 0; for(i = 0; i < 2; ++i) { for(j = 0; j < 2; ++j) { for(k = 0; k < 2; ++k) { float vec[3], proj[2]; vec[0] = i ? bb_min[0] : bb_max[0]; vec[1] = j ? bb_min[1] : bb_max[1]; vec[2] = k ? bb_min[2] : bb_max[2]; ED_view3d_project_float(ar, vec, proj, pmat); rect->xmin = MIN2(rect->xmin, proj[0]); rect->xmax = MAX2(rect->xmax, proj[0]); rect->ymin = MIN2(rect->ymin, proj[1]); rect->ymax = MAX2(rect->ymax, proj[1]); } } } if (rect->xmin < rect->xmax && rect->ymin < rect->ymax) { /* expand redraw rect with redraw rect from previous step to prevent partial-redraw issues caused by fast strokes. This is needed here (not in sculpt_flush_update) as it was before because redraw rectangle should be the same in both of optimized PBVH draw function and 3d view redraw (if not -- some mesh parts could disapper from screen (sergey) / SculptSession ss = ob->sculpt; if (ss->cache) { if (!BLI_rcti_is_empty(&ss->cache->previous_r)) BLI_union_rcti(rect, &ss->cache->previous_r); } return 1; } return 0; } void sculpt_get_redraw_planes(float planes[4][4], ARegion ar, RegionView3D rv3d, Object ob) { PBVH pbvh= ob->sculpt->pbvh; BoundBox bb; bglMats mats; rcti rect; memset(&bb, 0, sizeof(BoundBox)); view3d_get_transformation(ar, rv3d, ob, &mats); sculpt_get_redraw_rect(ar, rv3d,ob, &rect); #if 1 /* use some extra space just in case / rect.xmin -= 2; rect.xmax += 2; rect.ymin -= 2; rect.ymax += 2; #else / it was doing this before, allows to redraw a smaller part of the screen but also gives artifaces .. / rect.xmin += 2; rect.xmax -= 2; rect.ymin += 2; rect.ymax -= 2; #endif ED_view3d_calc_clipping(&bb, planes, &mats, &rect); mul_m4_fl(planes, -1.0f); / clear redraw flag from nodes / if(pbvh) BLI_pbvh_update(pbvh, PBVH_UpdateRedraw, NULL); } /********************* Brush Testing ****************/ typedef struct SculptBrushTest { float radius_squared; float location[3]; float dist; } SculptBrushTest; static void sculpt_brush_test_init(SculptSession ss, SculptBrushTest test) { test->radius_squared= ss->cache->radius_squared; copy_v3_v3(test->location, ss->cache->location); test->dist= 0.0f; / just for initialize / } static int sculpt_brush_test(SculptBrushTest test, float co[3]) { float distsq = len_squared_v3v3(co, test->location); if(distsq <= test->radius_squared) { test->dist = sqrt(distsq); return 1; } else { return 0; } } static int sculpt_brush_test_sq(SculptBrushTest test, float co[3]) { float distsq = len_squared_v3v3(co, test->location); if(distsq <= test->radius_squared) { test->dist = distsq; return 1; } else { return 0; } } static int sculpt_brush_test_fast(SculptBrushTest test, float co[3]) { return len_squared_v3v3(co, test->location) <= test->radius_squared; } static int sculpt_brush_test_cube(SculptBrushTest test, float co[3], float local[4][4]) { static const float side = 0.70710678118654752440084436210485; // sqrt(.5); float local_co[3]; mul_v3_m4v3(local_co, local, co); local_co[0] = fabs(local_co[0]); local_co[1] = fabs(local_co[1]); local_co[2] = fabs(local_co[2]); if (local_co[0] <= side && local_co[1] <= side && local_co[2] <= side) { test->dist = MAX3(local_co[0], local_co[1], local_co[2]) / side; return 1; } else { return 0; } } static float frontface(Brush brush, float sculpt_normal[3], short no[3], float fno[3]) { if (brush->flag & BRUSH_FRONTFACE) { float dot; if (no) { float tmp[3]; normal_short_to_float_v3(tmp, no); dot= dot_v3v3(tmp, sculpt_normal); } else { dot= dot_v3v3(fno, sculpt_normal); } return dot > 0 ? dot : 0; } else { return 1; } } #if 0 static int sculpt_brush_test_cyl(SculptBrushTest test, float co[3], float location[3], float an[3]) { if (sculpt_brush_test_fast(test, co)) { float t1[3], t2[3], t3[3], dist; sub_v3_v3v3(t1, location, co); sub_v3_v3v3(t2, x2, location); cross_v3_v3v3(t3, an, t1); dist = len_v3(t3)/len_v3(t2); test->dist = dist; return 1; } return 0; } #endif / ===== Sculpting ===== * / static float overlapped_curve(Brush br, float x) { int i; const int n = 100 / br->spacing; const float h = br->spacing / 50.0f; const float x0 = x-1; float sum; sum = 0; for (i= 0; i < n; i++) { float xx; xx = fabs(x0 + ih); if (xx < 1.0f) sum += brush_curve_strength(br, xx, 1); } return sum; } static float integrate_overlap(Brush br) { int i; int m= 10; float g = 1.0f/m; float max; max= 0; for(i= 0; i < m; i++) { float overlap= overlapped_curve(br, ig); if (overlap > max) max = overlap; } return max; } / Uses symm to selectively flip any axis of a coordinate. / static void flip_coord(float out[3], float in[3], const char symm) { if(symm & SCULPT_SYMM_X) out[0]= -in[0]; else out[0]= in[0]; if(symm & SCULPT_SYMM_Y) out[1]= -in[1]; else out[1]= in[1]; if(symm & SCULPT_SYMM_Z) out[2]= -in[2]; else out[2]= in[2]; } static float calc_overlap(StrokeCache cache, const char symm, const char axis, const float angle) { float mirror[3]; float distsq; //flip_coord(mirror, cache->traced_location, symm); flip_coord(mirror, cache->true_location, symm); if(axis != 0) { float mat[4][4]= MAT4_UNITY; rotate_m4(mat, axis, angle); mul_m4_v3(mat, mirror); } //distsq = len_squared_v3v3(mirror, cache->traced_location); distsq = len_squared_v3v3(mirror, cache->true_location); if (distsq <= 4.0f(cache->radius_squared)) return (2.0f(cache->radius) - sqrtf(distsq)) / (2.0f(cache->radius)); else return 0; } static float calc_radial_symmetry_feather(Sculpt sd, StrokeCache cache, const char symm, const char axis) { int i; float overlap; overlap = 0; for(i = 1; i < sd->radial_symm[axis-'X']; ++i) { const float angle = 2M_PIi/sd->radial_symm[axis-'X']; overlap += calc_overlap(cache, symm, axis, angle); } return overlap; } static float calc_symmetry_feather(Sculpt sd, StrokeCache* cache) { if (sd->flags & SCULPT_SYMMETRY_FEATHER) { float overlap; int symm = cache->symmetry; int i; overlap = 0; for (i = 0; i <= symm; i++) { if(i == 0 \|\| (symm & i && (symm != 5 \|\| i != 3) && (symm != 6 \|\| (i != 3 && i != 5)))) { overlap += calc_overlap(cache, i, 0, 0); overlap += calc_radial_symmetry_feather(sd, cache, i, 'X'); overlap += calc_radial_symmetry_feather(sd, cache, i, 'Y'); overlap += calc_radial_symmetry_feather(sd, cache, i, 'Z'); } } return 1/overlap; } else { return 1; } } /* Return modified brush strength. Includes the direction of the brush, positive values pull vertices, negative values push. Uses tablet pressure and a special multiplier found experimentally to scale the strength factor. / static float brush_strength(Sculpt sd, StrokeCache cache, float feather) { Brush brush = paint_brush(&sd->paint); /* Primary strength input; square it to make lower values more sensitive / const float root_alpha = brush_alpha(brush); float alpha = root_alpharoot_alpha; float dir = brush->flag & BRUSH_DIR_IN ? -1 : 1; float pressure = brush_use_alpha_pressure(brush) ? cache->pressure : 1; float pen_flip = cache->pen_flip ? -1 : 1; float invert = cache->invert ? -1 : 1; float accum = integrate_overlap(brush); float overlap = (brush->flag & BRUSH_SPACE_ATTEN && brush->flag & BRUSH_SPACE && !(brush->flag & BRUSH_ANCHORED)) && (brush->spacing < 100) ? 1.0f/accum : 1; // spacing is integer percentage of radius, divide by 50 to get normalized diameter float flip = dir * invert * pen_flip; switch(brush->sculpt_tool){ case SCULPT_TOOL_CLAY: case SCULPT_TOOL_CLAY_TUBES: case SCULPT_TOOL_DRAW: case SCULPT_TOOL_LAYER: return alpha * flip * pressure * overlap * feather; case SCULPT_TOOL_CREASE: case SCULPT_TOOL_BLOB: return alpha * flip * pressure * overlap * feather; case SCULPT_TOOL_INFLATE: if (flip > 0) { return 0.250f * alpha * flip * pressure * overlap * feather; } else { return 0.125f * alpha * flip * pressure * overlap * feather; } case SCULPT_TOOL_FILL: case SCULPT_TOOL_SCRAPE: case SCULPT_TOOL_FLATTEN: if (flip > 0) { overlap = (1+overlap) / 2; return alpha * flip * pressure * overlap * feather; } else { /* reduce strength for DEEPEN, PEAKS, and CONTRAST / return 0.5f alpha * flip * pressure * overlap * feather; } case SCULPT_TOOL_SMOOTH: return alpha * pressure * feather; case SCULPT_TOOL_PINCH: if (flip > 0) { return alpha * flip * pressure * overlap * feather; } else { return 0.25f * alpha * flip * pressure * overlap * feather; } case SCULPT_TOOL_NUDGE: overlap = (1+overlap) / 2; return alpha * pressure * overlap * feather; case SCULPT_TOOL_THUMB: return alphapressurefeather; case SCULPT_TOOL_SNAKE_HOOK: return feather; case SCULPT_TOOL_GRAB: case SCULPT_TOOL_ROTATE: return feather; default: return 0; } } /* Return a multiplier for brush strength on a particular vertex. / static float tex_strength(SculptSession ss, Brush br, float point, const float len) { MTex mtex = &br->mtex; float avg= 1; if(!mtex->tex) { avg= 1; } else if(mtex->brush_map_mode == MTEX_MAP_MODE_3D) { float jnk; / Get strength by feeding the vertex location directly into a texture / externtex(mtex, point, &avg, &jnk, &jnk, &jnk, &jnk, 0); } else if(ss->texcache) { float rotation = -mtex->rot; float x, y, point_2d[3]; float radius; / if the active area is being applied for symmetry, flip it across the symmetry axis and rotate it back to the orignal position in order to project it. This insures that the brush texture will be oriented correctly. / flip_coord(point_2d, point, ss->cache->mirror_symmetry_pass); if (ss->cache->radial_symmetry_pass) mul_m4_v3(ss->cache->symm_rot_mat_inv, point_2d); projectf(ss->cache->mats, point_2d, point_2d); / if fixed mode, keep coordinates relative to mouse / if(mtex->brush_map_mode == MTEX_MAP_MODE_FIXED) { rotation += ss->cache->special_rotation; point_2d[0] -= ss->cache->tex_mouse[0]; point_2d[1] -= ss->cache->tex_mouse[1]; radius = ss->cache->pixel_radius; // use pressure adjusted size for fixed mode x = point_2d[0]; y = point_2d[1]; } else / else (mtex->brush_map_mode == MTEX_MAP_MODE_TILED), leave the coordinates relative to the screen / { radius = brush_size(br); // use unadjusted size for tiled mode x = point_2d[0] - ss->cache->vc->ar->winrct.xmin; y = point_2d[1] - ss->cache->vc->ar->winrct.ymin; } x /= ss->cache->vc->ar->winx; y /= ss->cache->vc->ar->winy; if (mtex->brush_map_mode == MTEX_MAP_MODE_TILED) { x -= 0.5f; y -= 0.5f; } x = ss->cache->vc->ar->winx / radius; y = ss->cache->vc->ar->winy / radius; / it is probably worth optimizing for those cases where the texture is not rotated by skipping the calls to atan2, sqrtf, sin, and cos. / if (rotation > 0.001f \|\| rotation < -0.001f) { const float angle = atan2f(y, x) + rotation; const float flen = sqrtf(xx + yy); x = flen cosf(angle); y = flen * sinf(angle); } x = br->mtex.size[0]; y = br->mtex.size[1]; x += br->mtex.ofs[0]; y += br->mtex.ofs[1]; avg = paint_get_tex_pixel(br, x, y); } avg += br->texture_sample_bias; avg = brush_curve_strength(br, len, ss->cache->radius); / Falloff curve / return avg; } typedef struct { Sculpt sd; SculptSession ss; float radius_squared; int original; } SculptSearchSphereData; / Test AABB against sphere / static int sculpt_search_sphere_cb(PBVHNode node, void data_v) { SculptSearchSphereData data = data_v; float center = data->ss->cache->location, nearest[3]; float t[3], bb_min[3], bb_max[3]; int i; if(data->original) BLI_pbvh_node_get_original_BB(node, bb_min, bb_max); else BLI_pbvh_node_get_BB(node, bb_min, bb_max); for(i = 0; i < 3; ++i) { if(bb_min[i] > center[i]) nearest[i] = bb_min[i]; else if(bb_max[i] < center[i]) nearest[i] = bb_max[i]; else nearest[i] = center[i]; } sub_v3_v3v3(t, center, nearest); return dot_v3v3(t, t) < data->radius_squared; } / Handles clipping against a mirror modifier and SCULPT_LOCK axis flags / static void sculpt_clip(Sculpt sd, SculptSession ss, float co, const float val[3]) { int i; for(i=0; i<3; ++i) { if(sd->flags & (SCULPT_LOCK_X << i)) continue; if((ss->cache->flag & (CLIP_X << i)) && (fabsf(co[i]) <= ss->cache->clip_tolerance[i])) co[i]= 0.0f; else co[i]= val[i]; } } static void add_norm_if(float view_vec[3], float out[3], float out_flip[3], float fno[3]) { if((dot_v3v3(view_vec, fno)) > 0) { add_v3_v3(out, fno); } else { add_v3_v3(out_flip, fno); /* out_flip is used when out is {0,0,0} / } } static void calc_area_normal(Sculpt sd, Object ob, float an[3], PBVHNode nodes, int totnode) { SculptSession ss = ob->sculpt; int n; float out_flip[3] = {0.0f, 0.0f, 0.0f}; (void)sd; /* unused w/o openmp / zero_v3(an); #pragma omp parallel for schedule(guided) if (sd->flags & SCULPT_USE_OPENMP) for(n=0; n<totnode; n++) { PBVHVertexIter vd; SculptBrushTest test; SculptUndoNode unode; float private_an[3] = {0.0f, 0.0f, 0.0f}; float private_out_flip[3] = {0.0f, 0.0f, 0.0f}; unode = sculpt_undo_push_node(ob, nodes[n]); sculpt_brush_test_init(ss, &test); if(ss->cache->original) { BLI_pbvh_vertex_iter_begin(ss->pbvh, nodes[n], vd, PBVH_ITER_UNIQUE) { if(sculpt_brush_test_fast(&test, unode->co[vd.i])) { float fno[3]; normal_short_to_float_v3(fno, unode->no[vd.i]); add_norm_if(ss->cache->view_normal, private_an, private_out_flip, fno); } } BLI_pbvh_vertex_iter_end; } else { BLI_pbvh_vertex_iter_begin(ss->pbvh, nodes[n], vd, PBVH_ITER_UNIQUE) { if(sculpt_brush_test_fast(&test, vd.co)) { if(vd.no) { float fno[3]; normal_short_to_float_v3(fno, vd.no); add_norm_if(ss->cache->view_normal, private_an, private_out_flip, fno); } else { add_norm_if(ss->cache->view_normal, private_an, private_out_flip, vd.fno); } } } BLI_pbvh_vertex_iter_end; } #pragma omp critical { add_v3_v3(an, private_an); add_v3_v3(out_flip, private_out_flip); } } if (is_zero_v3(an)) copy_v3_v3(an, out_flip); normalize_v3(an); } /* This initializes the faces to be moved for this sculpt for draw/layer/flatten; then it finds average normal for all active vertices - note that this is called once for each mirroring direction / static void calc_sculpt_normal(Sculpt sd, Object ob, float an[3], PBVHNode nodes, int totnode) { SculptSession ss = ob->sculpt; Brush brush = paint_brush(&sd->paint); if (ss->cache->mirror_symmetry_pass == 0 && ss->cache->radial_symmetry_pass == 0 && (ss->cache->first_time \|\| !(brush->flag & BRUSH_ORIGINAL_NORMAL))) { switch (brush->sculpt_plane) { case SCULPT_DISP_DIR_VIEW: ED_view3d_global_to_vector(ss->cache->vc->rv3d, ss->cache->vc->rv3d->twmat[3], an); break; case SCULPT_DISP_DIR_X: an[1] = 0.0; an[2] = 0.0; an[0] = 1.0; break; case SCULPT_DISP_DIR_Y: an[0] = 0.0; an[2] = 0.0; an[1] = 1.0; break; case SCULPT_DISP_DIR_Z: an[0] = 0.0; an[1] = 0.0; an[2] = 1.0; break; case SCULPT_DISP_DIR_AREA: calc_area_normal(sd, ob, an, nodes, totnode); default: break; } copy_v3_v3(ss->cache->last_area_normal, an); } else { copy_v3_v3(an, ss->cache->last_area_normal); flip_coord(an, an, ss->cache->mirror_symmetry_pass); mul_m4_v3(ss->cache->symm_rot_mat, an); } } / For the smooth brush, uses the neighboring vertices around vert to calculate a smoothed location for vert. Skips corner vertices (used by only one polygon.) / static void neighbor_average(SculptSession ss, float avg[3], const unsigned vert) { int i, skip= -1, total=0; IndexNode node= ss->fmap[vert].first; char ncount= BLI_countlist(&ss->fmap[vert]); MFace f; avg[0] = avg[1] = avg[2] = 0; /* Don't modify corner vertices / if(ncount==1) { if(ss->deform_cos) copy_v3_v3(avg, ss->deform_cos[vert]); else copy_v3_v3(avg, ss->mvert[vert].co); return; } while(node){ f= &ss->mface[node->index]; if(f->v4) { skip= (f->v1==vert?2: f->v2==vert?3: f->v3==vert?0: f->v4==vert?1:-1); } for(i=0; i<(f->v4?4:3); ++i) { if(i != skip && (ncount!=2 \|\| BLI_countlist(&ss->fmap[(&f->v1)[i]]) <= 2)) { if(ss->deform_cos) add_v3_v3(avg, ss->deform_cos[(&f->v1)[i]]); else add_v3_v3(avg, ss->mvert[(&f->v1)[i]].co); ++total; } } node= node->next; } if(total>0) mul_v3_fl(avg, 1.0f / total); else { if(ss->deform_cos) copy_v3_v3(avg, ss->deform_cos[vert]); else copy_v3_v3(avg, ss->mvert[vert].co); } } static void do_mesh_smooth_brush(Sculpt sd, SculptSession ss, PBVHNode node, float bstrength) { Brush brush = paint_brush(&sd->paint); PBVHVertexIter vd; SculptBrushTest test; CLAMP(bstrength, 0.0f, 1.0f); sculpt_brush_test_init(ss, &test); BLI_pbvh_vertex_iter_begin(ss->pbvh, node, vd, PBVH_ITER_UNIQUE) { if(sculpt_brush_test(&test, vd.co)) { const float fade = bstrengthtex_strength(ss, brush, vd.co, test.dist)frontface(brush, ss->cache->view_normal, vd.no, vd.fno); float avg[3], val[3]; neighbor_average(ss, avg, vd.vert_indices[vd.i]); sub_v3_v3v3(val, avg, vd.co); mul_v3_fl(val, fade); add_v3_v3(val, vd.co); sculpt_clip(sd, ss, vd.co, val); if(vd.mvert) vd.mvert->flag \|= ME_VERT_PBVH_UPDATE; } } BLI_pbvh_vertex_iter_end; } static void do_multires_smooth_brush(Sculpt sd, SculptSession ss, PBVHNode node, float bstrength) { Brush brush = paint_brush(&sd->paint); SculptBrushTest test; DMGridData griddata, data; DMGridAdjacency gridadj, adj; float (tmpgrid)[3], (tmprow)[3]; int v1, v2, v3, v4; int grid_indices, totgrid, gridsize, i, x, y; sculpt_brush_test_init(ss, &test); CLAMP(bstrength, 0.0f, 1.0f); BLI_pbvh_node_get_grids(ss->pbvh, node, &grid_indices, &totgrid, NULL, &gridsize, &griddata, &gridadj); #pragma omp critical { tmpgrid= MEM_mallocN(sizeof(float)3gridsizegridsize, "tmpgrid"); tmprow= MEM_mallocN(sizeof(float)3gridsize, "tmprow"); } for(i = 0; i < totgrid; ++i) { data = griddata[grid_indices[i]]; adj = &gridadj[grid_indices[i]]; memset(tmpgrid, 0, sizeof(float)3gridsizegridsize); for (y= 0; y < gridsize-1; y++) { float tmp[3]; v1 = ygridsize; add_v3_v3v3(tmprow[0], data[v1].co, data[v1+gridsize].co); for (x= 0; x < gridsize-1; x++) { v1 = x + ygridsize; v2 = v1 + 1; v3 = v1 + gridsize; v4 = v3 + 1; add_v3_v3v3(tmprow[x+1], data[v2].co, data[v4].co); add_v3_v3v3(tmp, tmprow[x+1], tmprow[x]); add_v3_v3(tmpgrid[v1], tmp); add_v3_v3(tmpgrid[v2], tmp); add_v3_v3(tmpgrid[v3], tmp); add_v3_v3(tmpgrid[v4], tmp); } } / blend with existing coordinates / for(y = 0; y < gridsize; ++y) { for(x = 0; x < gridsize; ++x) { float co; float fno; int index; if(x == 0 && adj->index[0] == -1) continue; if(x == gridsize - 1 && adj->index[2] == -1) continue; if(y == 0 && adj->index[3] == -1) continue; if(y == gridsize - 1 && adj->index[1] == -1) continue; index = x + ygridsize; co= data[index].co; fno= data[index].no; if(sculpt_brush_test(&test, co)) { const float fade = bstrengthtex_strength(ss, brush, co, test.dist)frontface(brush, ss->cache->view_normal, NULL, fno); float avg, val[3]; float n; avg = tmpgrid[x + ygridsize]; n = 1/16.0f; if(x == 0 \|\| x == gridsize - 1) n = 2; if(y == 0 \|\| y == gridsize - 1) n = 2; mul_v3_fl(avg, n); sub_v3_v3v3(val, avg, co); mul_v3_fl(val, fade); add_v3_v3(val, co); sculpt_clip(sd, ss, co, val); } } } } #pragma omp critical { MEM_freeN(tmpgrid); MEM_freeN(tmprow); } } static void smooth(Sculpt sd, Object ob, PBVHNode *nodes, int totnode, float bstrength) { SculptSession ss = ob->sculpt; const int max_iterations = 4; const float fract = 1.0f/max_iterations; int iteration, n, count; float last; CLAMP(bstrength, 0, 1); count = (int)(bstrengthmax_iterations); last = max_iterations(bstrength - countfract); for(iteration = 0; iteration <= count; ++iteration) { #pragma omp parallel for schedule(guided) if (sd->flags & SCULPT_USE_OPENMP) for(n=0; n<totnode; n++) { if(ss->multires) { do_multires_smooth_brush(sd, ss, nodes[n], iteration != count ? 1.0f : last); } else if(ss->fmap) do_mesh_smooth_brush(sd, ss, nodes[n], iteration != count ? 1.0f : last); } if(ss->multires) multires_stitch_grids(ob); } } static void do_smooth_brush(Sculpt sd, Object ob, PBVHNode nodes, int totnode) { SculptSession ss = ob->sculpt; smooth(sd, ob, nodes, totnode, ss->cache->bstrength); } static void do_draw_brush(Sculpt sd, Object ob, PBVHNode *nodes, int totnode) { SculptSession ss = ob->sculpt; Brush brush = paint_brush(&sd->paint); float offset[3], area_normal[3]; float bstrength= ss->cache->bstrength; int n; calc_sculpt_normal(sd, ob, area_normal, nodes, totnode); / offset with as much as possible factored in already / mul_v3_v3fl(offset, area_normal, ss->cache->radius); mul_v3_v3(offset, ss->cache->scale); mul_v3_fl(offset, bstrength); / threaded loop over nodes / #pragma omp parallel for schedule(guided) if (sd->flags & SCULPT_USE_OPENMP) for(n=0; n<totnode; n++) { PBVHVertexIter vd; SculptBrushTest test; float (proxy)[3]; proxy= BLI_pbvh_node_add_proxy(ss->pbvh, nodes[n])->co; sculpt_brush_test_init(ss, &test); BLI_pbvh_vertex_iter_begin(ss->pbvh, nodes[n], vd, PBVH_ITER_UNIQUE) { if (sculpt_brush_test(&test, vd.co)) { //if(sculpt_brush_test_cyl(&test, vd.co, ss->cache->location, area_normal)) { /* offset vertex / float fade = tex_strength(ss, brush, vd.co, test.dist)frontface(brush, area_normal, vd.no, vd.fno); mul_v3_v3fl(proxy[vd.i], offset, fade); if(vd.mvert) vd.mvert->flag \|= ME_VERT_PBVH_UPDATE; } } BLI_pbvh_vertex_iter_end; } } static void do_crease_brush(Sculpt sd, Object ob, PBVHNode *nodes, int totnode) { SculptSession ss = ob->sculpt; Brush brush = paint_brush(&sd->paint); float offset[3], area_normal[3]; float bstrength= ss->cache->bstrength; float flippedbstrength, crease_correction; int n; calc_sculpt_normal(sd, ob, area_normal, nodes, totnode); / offset with as much as possible factored in already / mul_v3_v3fl(offset, area_normal, ss->cache->radius); mul_v3_v3(offset, ss->cache->scale); mul_v3_fl(offset, bstrength); / we divide out the squared alpha and multiply by the squared crease to give us the pinch strength / if(brush_alpha(brush) > 0.0f) crease_correction = brush->crease_pinch_factorbrush->crease_pinch_factor/(brush_alpha(brush)brush_alpha(brush)); else crease_correction = brush->crease_pinch_factorbrush->crease_pinch_factor; /* we always want crease to pinch or blob to relax even when draw is negative / flippedbstrength = (bstrength < 0) ? -crease_correctionbstrength : crease_correctionbstrength; if(brush->sculpt_tool == SCULPT_TOOL_BLOB) flippedbstrength = -1.0f; /* threaded loop over nodes / #pragma omp parallel for schedule(guided) if (sd->flags & SCULPT_USE_OPENMP) for(n=0; n<totnode; n++) { PBVHVertexIter vd; SculptBrushTest test; float (proxy)[3]; proxy= BLI_pbvh_node_add_proxy(ss->pbvh, nodes[n])->co; sculpt_brush_test_init(ss, &test); BLI_pbvh_vertex_iter_begin(ss->pbvh, nodes[n], vd, PBVH_ITER_UNIQUE) { if(sculpt_brush_test(&test, vd.co)) { /* offset vertex / const float fade = tex_strength(ss, brush, vd.co, test.dist)frontface(brush, area_normal, vd.no, vd.fno); float val1[3]; float val2[3]; /* first we pinch / sub_v3_v3v3(val1, test.location, vd.co); //mul_v3_v3(val1, ss->cache->scale); mul_v3_fl(val1, fadeflippedbstrength); /* then we draw / mul_v3_v3fl(val2, offset, fade); add_v3_v3v3(proxy[vd.i], val1, val2); if(vd.mvert) vd.mvert->flag \|= ME_VERT_PBVH_UPDATE; } } BLI_pbvh_vertex_iter_end; } } static void do_pinch_brush(Sculpt sd, Object ob, PBVHNode nodes, int totnode) { SculptSession ss = ob->sculpt; Brush brush = paint_brush(&sd->paint); float bstrength= ss->cache->bstrength; int n; #pragma omp parallel for schedule(guided) if (sd->flags & SCULPT_USE_OPENMP) for(n=0; n<totnode; n++) { PBVHVertexIter vd; SculptBrushTest test; float (proxy)[3]; proxy= BLI_pbvh_node_add_proxy(ss->pbvh, nodes[n])->co; sculpt_brush_test_init(ss, &test); BLI_pbvh_vertex_iter_begin(ss->pbvh, nodes[n], vd, PBVH_ITER_UNIQUE) { if(sculpt_brush_test(&test, vd.co)) { float fade = bstrengthtex_strength(ss, brush, vd.co, test.dist)frontface(brush, ss->cache->view_normal, vd.no, vd.fno); float val[3]; sub_v3_v3v3(val, test.location, vd.co); mul_v3_v3fl(proxy[vd.i], val, fade); if(vd.mvert) vd.mvert->flag \|= ME_VERT_PBVH_UPDATE; } } BLI_pbvh_vertex_iter_end; } } static void do_grab_brush(Sculpt sd, Object ob, PBVHNode *nodes, int totnode) { SculptSession ss = ob->sculpt; Brush brush= paint_brush(&sd->paint); float bstrength= ss->cache->bstrength; float grab_delta[3], an[3]; int n; float len; if (brush->normal_weight > 0 \|\| brush->flag & BRUSH_FRONTFACE) { int cache= 1; / grab brush requires to test on original data / SWAP(int, ss->cache->original, cache); calc_sculpt_normal(sd, ob, an, nodes, totnode); SWAP(int, ss->cache->original, cache); } copy_v3_v3(grab_delta, ss->cache->grab_delta_symmetry); len = len_v3(grab_delta); if (brush->normal_weight > 0) { mul_v3_fl(an, lenbrush->normal_weight); mul_v3_fl(grab_delta, 1.0f - brush->normal_weight); add_v3_v3(grab_delta, an); } #pragma omp parallel for schedule(guided) if (sd->flags & SCULPT_USE_OPENMP) for(n=0; n<totnode; n++) { PBVHVertexIter vd; SculptUndoNode* unode; SculptBrushTest test; float (origco)[3]; short (origno)[3]; float (proxy)[3]; unode= sculpt_undo_push_node(ob, nodes[n]); origco= unode->co; origno= unode->no; proxy= BLI_pbvh_node_add_proxy(ss->pbvh, nodes[n])->co; sculpt_brush_test_init(ss, &test); BLI_pbvh_vertex_iter_begin(ss->pbvh, nodes[n], vd, PBVH_ITER_UNIQUE) { if(sculpt_brush_test(&test, origco[vd.i])) { const float fade = bstrengthtex_strength(ss, brush, origco[vd.i], test.dist)frontface(brush, an, origno[vd.i], NULL); mul_v3_v3fl(proxy[vd.i], grab_delta, fade); if(vd.mvert) vd.mvert->flag \|= ME_VERT_PBVH_UPDATE; } } BLI_pbvh_vertex_iter_end; } } static void do_nudge_brush(Sculpt sd, Object ob, PBVHNode nodes, int totnode) { SculptSession ss = ob->sculpt; Brush brush = paint_brush(&sd->paint); float bstrength = ss->cache->bstrength; float grab_delta[3]; int n; float an[3]; float tmp[3], cono[3]; copy_v3_v3(grab_delta, ss->cache->grab_delta_symmetry); calc_sculpt_normal(sd, ob, an, nodes, totnode); cross_v3_v3v3(tmp, an, grab_delta); cross_v3_v3v3(cono, tmp, an); #pragma omp parallel for schedule(guided) if (sd->flags & SCULPT_USE_OPENMP) for(n = 0; n < totnode; n++) { PBVHVertexIter vd; SculptBrushTest test; float (proxy)[3]; proxy= BLI_pbvh_node_add_proxy(ss->pbvh, nodes[n])->co; sculpt_brush_test_init(ss, &test); BLI_pbvh_vertex_iter_begin(ss->pbvh, nodes[n], vd, PBVH_ITER_UNIQUE) { if(sculpt_brush_test(&test, vd.co)) { const float fade = bstrengthtex_strength(ss, brush, vd.co, test.dist)frontface(brush, an, vd.no, vd.fno); mul_v3_v3fl(proxy[vd.i], cono, fade); if(vd.mvert) vd.mvert->flag \|= ME_VERT_PBVH_UPDATE; } } BLI_pbvh_vertex_iter_end; } } static void do_snake_hook_brush(Sculpt sd, Object ob, PBVHNode *nodes, int totnode) { SculptSession ss = ob->sculpt; Brush brush = paint_brush(&sd->paint); float bstrength = ss->cache->bstrength; float grab_delta[3], an[3]; int n; float len; if (brush->normal_weight > 0 \|\| brush->flag & BRUSH_FRONTFACE) calc_sculpt_normal(sd, ob, an, nodes, totnode); copy_v3_v3(grab_delta, ss->cache->grab_delta_symmetry); len = len_v3(grab_delta); if (bstrength < 0) negate_v3(grab_delta); if (brush->normal_weight > 0) { mul_v3_fl(an, lenbrush->normal_weight); mul_v3_fl(grab_delta, 1.0f - brush->normal_weight); add_v3_v3(grab_delta, an); } #pragma omp parallel for schedule(guided) if (sd->flags & SCULPT_USE_OPENMP) for(n = 0; n < totnode; n++) { PBVHVertexIter vd; SculptBrushTest test; float (proxy)[3]; proxy= BLI_pbvh_node_add_proxy(ss->pbvh, nodes[n])->co; sculpt_brush_test_init(ss, &test); BLI_pbvh_vertex_iter_begin(ss->pbvh, nodes[n], vd, PBVH_ITER_UNIQUE) { if(sculpt_brush_test(&test, vd.co)) { const float fade = bstrengthtex_strength(ss, brush, vd.co, test.dist)frontface(brush, an, vd.no, vd.fno); mul_v3_v3fl(proxy[vd.i], grab_delta, fade); if(vd.mvert) vd.mvert->flag \|= ME_VERT_PBVH_UPDATE; } } BLI_pbvh_vertex_iter_end; } } static void do_thumb_brush(Sculpt sd, Object ob, PBVHNode nodes, int totnode) { SculptSession ss = ob->sculpt; Brush brush = paint_brush(&sd->paint); float bstrength = ss->cache->bstrength; float grab_delta[3]; int n; float an[3]; float tmp[3], cono[3]; copy_v3_v3(grab_delta, ss->cache->grab_delta_symmetry); calc_sculpt_normal(sd, ob, an, nodes, totnode); cross_v3_v3v3(tmp, an, grab_delta); cross_v3_v3v3(cono, tmp, an); #pragma omp parallel for schedule(guided) if (sd->flags & SCULPT_USE_OPENMP) for(n = 0; n < totnode; n++) { PBVHVertexIter vd; SculptUndoNode unode; SculptBrushTest test; float (origco)[3]; short (origno)[3]; float (proxy)[3]; unode= sculpt_undo_push_node(ob, nodes[n]); origco= unode->co; origno= unode->no; proxy= BLI_pbvh_node_add_proxy(ss->pbvh, nodes[n])->co; sculpt_brush_test_init(ss, &test); BLI_pbvh_vertex_iter_begin(ss->pbvh, nodes[n], vd, PBVH_ITER_UNIQUE) { if(sculpt_brush_test(&test, origco[vd.i])) { const float fade = bstrengthtex_strength(ss, brush, origco[vd.i], test.dist)frontface(brush, an, origno[vd.i], NULL); mul_v3_v3fl(proxy[vd.i], cono, fade); if(vd.mvert) vd.mvert->flag \|= ME_VERT_PBVH_UPDATE; } } BLI_pbvh_vertex_iter_end; } } static void do_rotate_brush(Sculpt sd, Object ob, PBVHNode nodes, int totnode) { SculptSession ss = ob->sculpt; Brush brush= paint_brush(&sd->paint); float bstrength= ss->cache->bstrength; float an[3]; int n; float m[3][3]; static const int flip[8] = { 1, -1, -1, 1, -1, 1, 1, -1 }; float angle = ss->cache->vertex_rotation flip[ss->cache->mirror_symmetry_pass]; calc_sculpt_normal(sd, ob, an, nodes, totnode); axis_angle_to_mat3(m, an, angle); #pragma omp parallel for schedule(guided) if (sd->flags & SCULPT_USE_OPENMP) for(n=0; n<totnode; n++) { PBVHVertexIter vd; SculptUndoNode* unode; SculptBrushTest test; float (origco)[3]; short (origno)[3]; float (proxy)[3]; unode= sculpt_undo_push_node(ob, nodes[n]); origco= unode->co; origno= unode->no; proxy= BLI_pbvh_node_add_proxy(ss->pbvh, nodes[n])->co; sculpt_brush_test_init(ss, &test); BLI_pbvh_vertex_iter_begin(ss->pbvh, nodes[n], vd, PBVH_ITER_UNIQUE) { if(sculpt_brush_test(&test, origco[vd.i])) { const float fade = bstrengthtex_strength(ss, brush, origco[vd.i], test.dist)frontface(brush, an, origno[vd.i], NULL); mul_v3_m3v3(proxy[vd.i], m, origco[vd.i]); sub_v3_v3(proxy[vd.i], origco[vd.i]); mul_v3_fl(proxy[vd.i], fade); if(vd.mvert) vd.mvert->flag \|= ME_VERT_PBVH_UPDATE; } } BLI_pbvh_vertex_iter_end; } } static void do_layer_brush(Sculpt sd, Object ob, PBVHNode nodes, int totnode) { SculptSession ss = ob->sculpt; Brush brush = paint_brush(&sd->paint); float bstrength= ss->cache->bstrength; float area_normal[3], offset[3]; float lim= brush->height; int n; if(bstrength < 0) lim = -lim; calc_sculpt_normal(sd, ob, area_normal, nodes, totnode); mul_v3_v3v3(offset, ss->cache->scale, area_normal); #pragma omp parallel for schedule(guided) if (sd->flags & SCULPT_USE_OPENMP) for(n=0; n<totnode; n++) { PBVHVertexIter vd; SculptBrushTest test; SculptUndoNode unode; float (origco)[3], layer_disp; //float (proxy)[3]; // XXX layer brush needs conversion to proxy but its more complicated //proxy= BLI_pbvh_node_add_proxy(ss->pbvh, nodes[n])->co; unode= sculpt_undo_push_node(ob, nodes[n]); origco=unode->co; if(!unode->layer_disp) { #pragma omp critical unode->layer_disp= MEM_callocN(sizeof(float)unode->totvert, "layer disp"); } layer_disp= unode->layer_disp; sculpt_brush_test_init(ss, &test); BLI_pbvh_vertex_iter_begin(ss->pbvh, nodes[n], vd, PBVH_ITER_UNIQUE) { if(sculpt_brush_test(&test, origco[vd.i])) { const float fade = bstrengthtex_strength(ss, brush, vd.co, test.dist)frontface(brush, area_normal, vd.no, vd.fno); float disp= &layer_disp[vd.i]; float val[3]; disp+= fade; /* Don't let the displacement go past the limit / if((lim < 0 && disp < lim) \|\| (lim >= 0 && disp > lim)) disp = lim; mul_v3_v3fl(val, offset, disp); if(ss->layer_co && (brush->flag & BRUSH_PERSISTENT)) { int index= vd.vert_indices[vd.i]; / persistent base / add_v3_v3(val, ss->layer_co[index]); } else { add_v3_v3(val, origco[vd.i]); } sculpt_clip(sd, ss, vd.co, val); if(vd.mvert) vd.mvert->flag \|= ME_VERT_PBVH_UPDATE; } } BLI_pbvh_vertex_iter_end; } } static void do_inflate_brush(Sculpt sd, Object ob, PBVHNode nodes, int totnode) { SculptSession ss = ob->sculpt; Brush brush = paint_brush(&sd->paint); float bstrength= ss->cache->bstrength; int n; #pragma omp parallel for schedule(guided) if (sd->flags & SCULPT_USE_OPENMP) for(n=0; n<totnode; n++) { PBVHVertexIter vd; SculptBrushTest test; float (proxy)[3]; proxy= BLI_pbvh_node_add_proxy(ss->pbvh, nodes[n])->co; sculpt_brush_test_init(ss, &test); BLI_pbvh_vertex_iter_begin(ss->pbvh, nodes[n], vd, PBVH_ITER_UNIQUE) { if(sculpt_brush_test(&test, vd.co)) { const float fade = bstrengthtex_strength(ss, brush, vd.co, test.dist)frontface(brush, ss->cache->view_normal, vd.no, vd.fno); float val[3]; if(vd.fno) copy_v3_v3(val, vd.fno); else normal_short_to_float_v3(val, vd.no); mul_v3_fl(val, fade * ss->cache->radius); mul_v3_v3v3(proxy[vd.i], val, ss->cache->scale); if(vd.mvert) vd.mvert->flag \|= ME_VERT_PBVH_UPDATE; } } BLI_pbvh_vertex_iter_end; } } static void calc_flatten_center(Sculpt sd, Object ob, PBVHNode *nodes, int totnode, float fc[3]) { SculptSession ss = ob->sculpt; int n; float count = 0; (void)sd; /* unused w/o openmp / zero_v3(fc); #pragma omp parallel for schedule(guided) if (sd->flags & SCULPT_USE_OPENMP) for(n=0; n<totnode; n++) { PBVHVertexIter vd; SculptBrushTest test; SculptUndoNode unode; float private_fc[3] = {0.0f, 0.0f, 0.0f}; int private_count = 0; unode = sculpt_undo_push_node(ob, nodes[n]); sculpt_brush_test_init(ss, &test); if(ss->cache->original) { BLI_pbvh_vertex_iter_begin(ss->pbvh, nodes[n], vd, PBVH_ITER_UNIQUE) { if(sculpt_brush_test_fast(&test, unode->co[vd.i])) { add_v3_v3(private_fc, vd.co); private_count++; } } BLI_pbvh_vertex_iter_end; } else { BLI_pbvh_vertex_iter_begin(ss->pbvh, nodes[n], vd, PBVH_ITER_UNIQUE) { if(sculpt_brush_test_fast(&test, vd.co)) { add_v3_v3(private_fc, vd.co); private_count++; } } BLI_pbvh_vertex_iter_end; } #pragma omp critical { add_v3_v3(fc, private_fc); count += private_count; } } mul_v3_fl(fc, 1.0f / count); } /* this calculates flatten center and area normal together, amortizing the memory bandwidth and loop overhead to calculate both at the same time / static void calc_area_normal_and_flatten_center(Sculpt sd, Object ob, PBVHNode nodes, int totnode, float an[3], float fc[3]) { SculptSession ss = ob->sculpt; int n; // an float out_flip[3] = {0.0f, 0.0f, 0.0f}; // fc float count = 0; (void)sd; /* unused w/o openmp / // an zero_v3(an); // fc zero_v3(fc); #pragma omp parallel for schedule(guided) if (sd->flags & SCULPT_USE_OPENMP) for(n=0; n<totnode; n++) { PBVHVertexIter vd; SculptBrushTest test; SculptUndoNode unode; float private_an[3] = {0.0f, 0.0f, 0.0f}; float private_out_flip[3] = {0.0f, 0.0f, 0.0f}; float private_fc[3] = {0.0f, 0.0f, 0.0f}; int private_count = 0; unode = sculpt_undo_push_node(ob, nodes[n]); sculpt_brush_test_init(ss, &test); if(ss->cache->original) { BLI_pbvh_vertex_iter_begin(ss->pbvh, nodes[n], vd, PBVH_ITER_UNIQUE) { if(sculpt_brush_test_fast(&test, unode->co[vd.i])) { // an float fno[3]; normal_short_to_float_v3(fno, unode->no[vd.i]); add_norm_if(ss->cache->view_normal, private_an, private_out_flip, fno); // fc add_v3_v3(private_fc, vd.co); private_count++; } } BLI_pbvh_vertex_iter_end; } else { BLI_pbvh_vertex_iter_begin(ss->pbvh, nodes[n], vd, PBVH_ITER_UNIQUE) { if(sculpt_brush_test_fast(&test, vd.co)) { // an if(vd.no) { float fno[3]; normal_short_to_float_v3(fno, vd.no); add_norm_if(ss->cache->view_normal, private_an, private_out_flip, fno); } else { add_norm_if(ss->cache->view_normal, private_an, private_out_flip, vd.fno); } // fc add_v3_v3(private_fc, vd.co); private_count++; } } BLI_pbvh_vertex_iter_end; } #pragma omp critical { // an add_v3_v3(an, private_an); add_v3_v3(out_flip, private_out_flip); // fc add_v3_v3(fc, private_fc); count += private_count; } } // an if (is_zero_v3(an)) copy_v3_v3(an, out_flip); normalize_v3(an); // fc if (count != 0) { mul_v3_fl(fc, 1.0f / count); } else { zero_v3(fc); } } static void calc_sculpt_plane(Sculpt sd, Object ob, PBVHNode *nodes, int totnode, float an[3], float fc[3]) { SculptSession ss = ob->sculpt; Brush brush = paint_brush(&sd->paint); if (ss->cache->mirror_symmetry_pass == 0 && ss->cache->radial_symmetry_pass == 0 && (ss->cache->first_time \|\| !(brush->flag & BRUSH_ORIGINAL_NORMAL))) { switch (brush->sculpt_plane) { case SCULPT_DISP_DIR_VIEW: ED_view3d_global_to_vector(ss->cache->vc->rv3d, ss->cache->vc->rv3d->twmat[3], an); break; case SCULPT_DISP_DIR_X: an[1] = 0.0; an[2] = 0.0; an[0] = 1.0; break; case SCULPT_DISP_DIR_Y: an[0] = 0.0; an[2] = 0.0; an[1] = 1.0; break; case SCULPT_DISP_DIR_Z: an[0] = 0.0; an[1] = 0.0; an[2] = 1.0; break; case SCULPT_DISP_DIR_AREA: calc_area_normal_and_flatten_center(sd, ob, nodes, totnode, an, fc); default: break; } // fc / flatten center has not been calculated yet if we are not using the area normal / if (brush->sculpt_plane != SCULPT_DISP_DIR_AREA) calc_flatten_center(sd, ob, nodes, totnode, fc); // an copy_v3_v3(ss->cache->last_area_normal, an); // fc copy_v3_v3(ss->cache->last_center, fc); } else { // an copy_v3_v3(an, ss->cache->last_area_normal); // fc copy_v3_v3(fc, ss->cache->last_center); // an flip_coord(an, an, ss->cache->mirror_symmetry_pass); // fc flip_coord(fc, fc, ss->cache->mirror_symmetry_pass); // an mul_m4_v3(ss->cache->symm_rot_mat, an); // fc mul_m4_v3(ss->cache->symm_rot_mat, fc); } } / Projects a point onto a plane along the plane's normal / static void point_plane_project(float intr[3], float co[3], float plane_normal[3], float plane_center[3]) { sub_v3_v3v3(intr, co, plane_center); mul_v3_v3fl(intr, plane_normal, dot_v3v3(plane_normal, intr)); sub_v3_v3v3(intr, co, intr); } static int plane_trim(StrokeCache cache, Brush brush, float val[3]) { return !(brush->flag & BRUSH_PLANE_TRIM) \|\| (dot_v3v3(val, val) <= cache->radius_squaredcache->plane_trim_squared); } static int plane_point_side_flip(float co[3], float plane_normal[3], float plane_center[3], int flip) { float delta[3]; float d; sub_v3_v3v3(delta, co, plane_center); d = dot_v3v3(plane_normal, delta); if (flip) d = -d; return d <= 0.0f; } static int plane_point_side(float co[3], float plane_normal[3], float plane_center[3]) { float delta[3]; sub_v3_v3v3(delta, co, plane_center); return dot_v3v3(plane_normal, delta) <= 0.0f; } static float get_offset(Sculpt sd, SculptSession ss) { Brush* brush = paint_brush(&sd->paint); float rv = brush->plane_offset; if (brush->flag & BRUSH_OFFSET_PRESSURE) { rv = ss->cache->pressure; } return rv; } static void do_flatten_brush(Sculpt sd, Object ob, PBVHNode nodes, int totnode) { SculptSession ss = ob->sculpt; Brush brush = paint_brush(&sd->paint); float bstrength = ss->cache->bstrength; const float radius = ss->cache->radius; float an[3]; float fc[3]; float offset = get_offset(sd, ss); float displace; int n; float temp[3]; calc_sculpt_plane(sd, ob, nodes, totnode, an, fc); displace = radiusoffset; mul_v3_v3v3(temp, an, ss->cache->scale); mul_v3_fl(temp, displace); add_v3_v3(fc, temp); #pragma omp parallel for schedule(guided) if (sd->flags & SCULPT_USE_OPENMP) for(n = 0; n < totnode; n++) { PBVHVertexIter vd; SculptBrushTest test; float (proxy)[3]; proxy= BLI_pbvh_node_add_proxy(ss->pbvh, nodes[n])->co; sculpt_brush_test_init(ss, &test); BLI_pbvh_vertex_iter_begin(ss->pbvh, nodes[n], vd, PBVH_ITER_UNIQUE) { if (sculpt_brush_test_sq(&test, vd.co)) { float intr[3]; float val[3]; point_plane_project(intr, vd.co, an, fc); sub_v3_v3v3(val, intr, vd.co); if (plane_trim(ss->cache, brush, val)) { const float fade = bstrengthtex_strength(ss, brush, vd.co, sqrt(test.dist))frontface(brush, an, vd.no, vd.fno); mul_v3_v3fl(proxy[vd.i], val, fade); if(vd.mvert) vd.mvert->flag \|= ME_VERT_PBVH_UPDATE; } } } BLI_pbvh_vertex_iter_end; } } static void do_clay_brush(Sculpt sd, Object ob, PBVHNode nodes, int totnode) { SculptSession ss = ob->sculpt; Brush brush = paint_brush(&sd->paint); float bstrength = ss->cache->bstrength; float radius = ss->cache->radius; float offset = get_offset(sd, ss); float displace; float an[3]; // area normal float fc[3]; // flatten center int n; float temp[3]; //float p[3]; int flip; calc_sculpt_plane(sd, ob, nodes, totnode, an, fc); flip = bstrength < 0; if (flip) { bstrength = -bstrength; radius = -radius; } displace = radius (0.25f+offset); mul_v3_v3v3(temp, an, ss->cache->scale); mul_v3_fl(temp, displace); add_v3_v3(fc, temp); //add_v3_v3v3(p, ss->cache->location, an); #pragma omp parallel for schedule(guided) if (sd->flags & SCULPT_USE_OPENMP) for (n = 0; n < totnode; n++) { PBVHVertexIter vd; SculptBrushTest test; float (proxy)[3]; proxy= BLI_pbvh_node_add_proxy(ss->pbvh, nodes[n])->co; sculpt_brush_test_init(ss, &test); BLI_pbvh_vertex_iter_begin(ss->pbvh, nodes[n], vd, PBVH_ITER_UNIQUE) { if (sculpt_brush_test_sq(&test, vd.co)) { if (plane_point_side_flip(vd.co, an, fc, flip)) { //if (sculpt_brush_test_cyl(&test, vd.co, ss->cache->location, p)) { float intr[3]; float val[3]; point_plane_project(intr, vd.co, an, fc); sub_v3_v3v3(val, intr, vd.co); if (plane_trim(ss->cache, brush, val)) { const float fade = bstrengthtex_strength(ss, brush, vd.co, sqrt(test.dist))frontface(brush, an, vd.no, vd.fno); mul_v3_v3fl(proxy[vd.i], val, fade); if(vd.mvert) vd.mvert->flag \|= ME_VERT_PBVH_UPDATE; } } } } BLI_pbvh_vertex_iter_end; } } static void do_clay_tubes_brush(Sculpt sd, Object ob, PBVHNode nodes, int totnode) { SculptSession ss = ob->sculpt; Brush brush = paint_brush(&sd->paint); float bstrength = ss->cache->bstrength; float radius = ss->cache->radius; float offset = get_offset(sd, ss); float displace; float sn[3]; // sculpt normal float an[3]; // area normal float fc[3]; // flatten center int n; float temp[3]; float mat[4][4]; float scale[4][4]; float tmat[4][4]; int flip; calc_sculpt_plane(sd, ob, nodes, totnode, sn, fc); if (brush->sculpt_plane != SCULPT_DISP_DIR_AREA \|\| (brush->flag & BRUSH_ORIGINAL_NORMAL)) calc_area_normal(sd, ob, an, nodes, totnode); else copy_v3_v3(an, sn); if (ss->cache->first_time) return; // delay the first daub because grab delta is not setup flip = bstrength < 0; if (flip) { bstrength = -bstrength; radius = -radius; } displace = radius (0.25f+offset); mul_v3_v3v3(temp, sn, ss->cache->scale); mul_v3_fl(temp, displace); add_v3_v3(fc, temp); cross_v3_v3v3(mat[0], an, ss->cache->grab_delta_symmetry); mat[0][3] = 0; cross_v3_v3v3(mat[1], an, mat[0]); mat[1][3] = 0; copy_v3_v3(mat[2], an); mat[2][3] = 0; copy_v3_v3(mat[3], ss->cache->location); mat[3][3] = 1; normalize_m4(mat); scale_m4_fl(scale, ss->cache->radius); mul_m4_m4m4(tmat, scale, mat); invert_m4_m4(mat, tmat); #pragma omp parallel for schedule(guided) if (sd->flags & SCULPT_USE_OPENMP) for (n = 0; n < totnode; n++) { PBVHVertexIter vd; SculptBrushTest test; float (proxy)[3]; proxy= BLI_pbvh_node_add_proxy(ss->pbvh, nodes[n])->co; sculpt_brush_test_init(ss, &test); BLI_pbvh_vertex_iter_begin(ss->pbvh, nodes[n], vd, PBVH_ITER_UNIQUE) { if (sculpt_brush_test_cube(&test, vd.co, mat)) { if (plane_point_side_flip(vd.co, sn, fc, flip)) { float intr[3]; float val[3]; point_plane_project(intr, vd.co, sn, fc); sub_v3_v3v3(val, intr, vd.co); if (plane_trim(ss->cache, brush, val)) { const float fade = bstrengthtex_strength(ss, brush, vd.co, ss->cache->radiustest.dist)frontface(brush, an, vd.no, vd.fno); mul_v3_v3fl(proxy[vd.i], val, fade); if(vd.mvert) vd.mvert->flag \|= ME_VERT_PBVH_UPDATE; } } } } BLI_pbvh_vertex_iter_end; } } static void do_fill_brush(Sculpt sd, Object ob, PBVHNode *nodes, int totnode) { SculptSession ss = ob->sculpt; Brush brush = paint_brush(&sd->paint); float bstrength = ss->cache->bstrength; const float radius = ss->cache->radius; float an[3]; float fc[3]; float offset = get_offset(sd, ss); float displace; int n; float temp[3]; calc_sculpt_plane(sd, ob, nodes, totnode, an, fc); displace = radiusoffset; mul_v3_v3v3(temp, an, ss->cache->scale); mul_v3_fl(temp, displace); add_v3_v3(fc, temp); #pragma omp parallel for schedule(guided) if (sd->flags & SCULPT_USE_OPENMP) for (n = 0; n < totnode; n++) { PBVHVertexIter vd; SculptBrushTest test; float (proxy)[3]; proxy= BLI_pbvh_node_add_proxy(ss->pbvh, nodes[n])->co; sculpt_brush_test_init(ss, &test); BLI_pbvh_vertex_iter_begin(ss->pbvh, nodes[n], vd, PBVH_ITER_UNIQUE) { if (sculpt_brush_test_sq(&test, vd.co)) { if (plane_point_side(vd.co, an, fc)) { float intr[3]; float val[3]; point_plane_project(intr, vd.co, an, fc); sub_v3_v3v3(val, intr, vd.co); if (plane_trim(ss->cache, brush, val)) { const float fade = bstrengthtex_strength(ss, brush, vd.co, sqrt(test.dist))frontface(brush, an, vd.no, vd.fno); mul_v3_v3fl(proxy[vd.i], val, fade); if(vd.mvert) vd.mvert->flag \|= ME_VERT_PBVH_UPDATE; } } } } BLI_pbvh_vertex_iter_end; } } static void do_scrape_brush(Sculpt sd, Object ob, PBVHNode nodes, int totnode) { SculptSession ss = ob->sculpt; Brush brush = paint_brush(&sd->paint); float bstrength = ss->cache->bstrength; const float radius = ss->cache->radius; float an[3]; float fc[3]; float offset = get_offset(sd, ss); float displace; int n; float temp[3]; calc_sculpt_plane(sd, ob, nodes, totnode, an, fc); displace = -radiusoffset; mul_v3_v3v3(temp, an, ss->cache->scale); mul_v3_fl(temp, displace); add_v3_v3(fc, temp); #pragma omp parallel for schedule(guided) if (sd->flags & SCULPT_USE_OPENMP) for (n = 0; n < totnode; n++) { PBVHVertexIter vd; SculptBrushTest test; float (proxy)[3]; proxy= BLI_pbvh_node_add_proxy(ss->pbvh, nodes[n])->co; sculpt_brush_test_init(ss, &test); BLI_pbvh_vertex_iter_begin(ss->pbvh, nodes[n], vd, PBVH_ITER_UNIQUE) { if (sculpt_brush_test_sq(&test, vd.co)) { if (!plane_point_side(vd.co, an, fc)) { float intr[3]; float val[3]; point_plane_project(intr, vd.co, an, fc); sub_v3_v3v3(val, intr, vd.co); if (plane_trim(ss->cache, brush, val)) { const float fade = bstrengthtex_strength(ss, brush, vd.co, sqrt(test.dist))frontface(brush, an, vd.no, vd.fno); mul_v3_v3fl(proxy[vd.i], val, fade); if(vd.mvert) vd.mvert->flag \|= ME_VERT_PBVH_UPDATE; } } } } BLI_pbvh_vertex_iter_end; } } void sculpt_vertcos_to_key(Object ob, KeyBlock kb, float (vertCos)[3]) { Mesh me= (Mesh)ob->data; float (ofs)[3]= NULL; int a, is_basis= 0; KeyBlock currkey; /* for relative keys editing of base should update other keys / if (me->key->type == KEY_RELATIVE) for (currkey = me->key->block.first; currkey; currkey= currkey->next) if(ob->shapenr-1 == currkey->relative) { is_basis= 1; break; } if (is_basis) { ofs= key_to_vertcos(ob, kb); / calculate key coord offsets (from previous location) / for (a= 0; a < me->totvert; a++) VECSUB(ofs[a], vertCos[a], ofs[a]); / apply offsets on other keys / currkey = me->key->block.first; while (currkey) { int apply_offset = ((currkey != kb) && (ob->shapenr-1 == currkey->relative)); if (apply_offset) offset_to_key(ob, currkey, ofs); currkey= currkey->next; } MEM_freeN(ofs); } / modifying of basis key should update mesh / if (kb == me->key->refkey) { MVert mvert= me->mvert; for (a= 0; a < me->totvert; a++, mvert++) VECCOPY(mvert->co, vertCos[a]); mesh_calc_normals(me->mvert, me->totvert, me->mface, me->totface, NULL); } /* apply new coords on active key block / vertcos_to_key(ob, kb, vertCos); } static void do_brush_action(Sculpt sd, Object ob, Brush brush) { SculptSession ss = ob->sculpt; SculptSearchSphereData data; PBVHNode nodes = NULL; int n, totnode; / Build a list of all nodes that are potentially within the brush's area of influence / data.ss = ss; data.sd = sd; data.radius_squared = ss->cache->radius_squared; data.original = ELEM4(brush->sculpt_tool, SCULPT_TOOL_GRAB, SCULPT_TOOL_ROTATE, SCULPT_TOOL_THUMB, SCULPT_TOOL_LAYER); BLI_pbvh_search_gather(ss->pbvh, sculpt_search_sphere_cb, &data, &nodes, &totnode); / Only act if some verts are inside the brush area / if (totnode) { #pragma omp parallel for schedule(guided) if (sd->flags & SCULPT_USE_OPENMP) for (n= 0; n < totnode; n++) { sculpt_undo_push_node(ob, nodes[n]); BLI_pbvh_node_mark_update(nodes[n]); } / Apply one type of brush action / switch(brush->sculpt_tool){ case SCULPT_TOOL_DRAW: do_draw_brush(sd, ob, nodes, totnode); break; case SCULPT_TOOL_SMOOTH: do_smooth_brush(sd, ob, nodes, totnode); break; case SCULPT_TOOL_CREASE: do_crease_brush(sd, ob, nodes, totnode); break; case SCULPT_TOOL_BLOB: do_crease_brush(sd, ob, nodes, totnode); break; case SCULPT_TOOL_PINCH: do_pinch_brush(sd, ob, nodes, totnode); break; case SCULPT_TOOL_INFLATE: do_inflate_brush(sd, ob, nodes, totnode); break; case SCULPT_TOOL_GRAB: do_grab_brush(sd, ob, nodes, totnode); break; case SCULPT_TOOL_ROTATE: do_rotate_brush(sd, ob, nodes, totnode); break; case SCULPT_TOOL_SNAKE_HOOK: do_snake_hook_brush(sd, ob, nodes, totnode); break; case SCULPT_TOOL_NUDGE: do_nudge_brush(sd, ob, nodes, totnode); break; case SCULPT_TOOL_THUMB: do_thumb_brush(sd, ob, nodes, totnode); break; case SCULPT_TOOL_LAYER: do_layer_brush(sd, ob, nodes, totnode); break; case SCULPT_TOOL_FLATTEN: do_flatten_brush(sd, ob, nodes, totnode); break; case SCULPT_TOOL_CLAY: do_clay_brush(sd, ob, nodes, totnode); break; case SCULPT_TOOL_CLAY_TUBES: do_clay_tubes_brush(sd, ob, nodes, totnode); break; case SCULPT_TOOL_FILL: do_fill_brush(sd, ob, nodes, totnode); break; case SCULPT_TOOL_SCRAPE: do_scrape_brush(sd, ob, nodes, totnode); break; } if (brush->sculpt_tool != SCULPT_TOOL_SMOOTH && brush->autosmooth_factor > 0) { if (brush->flag & BRUSH_INVERSE_SMOOTH_PRESSURE) { smooth(sd, ob, nodes, totnode, brush->autosmooth_factor(1-ss->cache->pressure)); } else { smooth(sd, ob, nodes, totnode, brush->autosmooth_factor); } } MEM_freeN(nodes); } } /* flush displacement from deformed PBVH vertex to original mesh / static void sculpt_flush_pbvhvert_deform(Object ob, PBVHVertexIter vd) { SculptSession ss = ob->sculpt; Mesh me= ob->data; float disp[3], newco[3]; int index= vd->vert_indices[vd->i]; sub_v3_v3v3(disp, vd->co, ss->deform_cos[index]); mul_m3_v3(ss->deform_imats[index], disp); add_v3_v3v3(newco, disp, ss->orig_cos[index]); copy_v3_v3(ss->deform_cos[index], vd->co); copy_v3_v3(ss->orig_cos[index], newco); if(!ss->kb) copy_v3_v3(me->mvert[index].co, newco); } static void sculpt_combine_proxies(Sculpt sd, Object ob) { SculptSession ss = ob->sculpt; Brush brush= paint_brush(&sd->paint); PBVHNode* nodes; int totnode, n; BLI_pbvh_gather_proxies(ss->pbvh, &nodes, &totnode); if(!ELEM(brush->sculpt_tool, SCULPT_TOOL_SMOOTH, SCULPT_TOOL_LAYER)) { /* these brushes start from original coordinates / const int use_orco = (ELEM3(brush->sculpt_tool, SCULPT_TOOL_GRAB, SCULPT_TOOL_ROTATE, SCULPT_TOOL_THUMB)); #pragma omp parallel for schedule(guided) if (sd->flags & SCULPT_USE_OPENMP) for (n= 0; n < totnode; n++) { PBVHVertexIter vd; PBVHProxyNode proxies; int proxy_count; float (orco)[3]; if(use_orco) orco= sculpt_undo_push_node(ob, nodes[n])->co; BLI_pbvh_node_get_proxies(nodes[n], &proxies, &proxy_count); BLI_pbvh_vertex_iter_begin(ss->pbvh, nodes[n], vd, PBVH_ITER_UNIQUE) { float val[3]; int p; if(use_orco) copy_v3_v3(val, orco[vd.i]); else copy_v3_v3(val, vd.co); for (p= 0; p < proxy_count; p++) add_v3_v3(val, proxies[p].co[vd.i]); sculpt_clip(sd, ss, vd.co, val); if(ss->modifiers_active) sculpt_flush_pbvhvert_deform(ob, &vd); } BLI_pbvh_vertex_iter_end; BLI_pbvh_node_free_proxies(nodes[n]); } } if (nodes) MEM_freeN(nodes); } / copy the modified vertices from bvh to the active key / static void sculpt_update_keyblock(Object ob) { SculptSession ss = ob->sculpt; float (vertCos)[3]; /* Keyblock update happens after hadning deformation caused by modifiers, so ss->orig_cos would be updated with new stroke / if(ss->orig_cos) vertCos = ss->orig_cos; else vertCos = BLI_pbvh_get_vertCos(ss->pbvh); if (vertCos) { sculpt_vertcos_to_key(ob, ss->kb, vertCos); if(vertCos != ss->orig_cos) MEM_freeN(vertCos); } } / flush displacement from deformed PBVH to original layer / static void sculpt_flush_stroke_deform(Sculpt sd, Object ob) { SculptSession ss = ob->sculpt; Brush brush= paint_brush(&sd->paint); if(ELEM(brush->sculpt_tool, SCULPT_TOOL_SMOOTH, SCULPT_TOOL_LAYER)) { / this brushes aren't using proxies, so sculpt_combine_proxies() wouldn't propagate needed deformation to original base / int n, totnode; Mesh me= (Mesh)ob->data; PBVHNode* nodes; float (vertCos)[3]= NULL; if(ss->kb) vertCos= MEM_callocN(sizeof(vertCos)me->totvert, "flushStrokeDeofrm keyVerts"); BLI_pbvh_search_gather(ss->pbvh, NULL, NULL, &nodes, &totnode); #pragma omp parallel for schedule(guided) if (sd->flags & SCULPT_USE_OPENMP) for (n= 0; n < totnode; n++) { PBVHVertexIter vd; BLI_pbvh_vertex_iter_begin(ss->pbvh, nodes[n], vd, PBVH_ITER_UNIQUE) { sculpt_flush_pbvhvert_deform(ob, &vd); if(vertCos) { int index= vd.vert_indices[vd.i]; copy_v3_v3(vertCos[index], ss->orig_cos[index]); } } BLI_pbvh_vertex_iter_end; } if(vertCos) { sculpt_vertcos_to_key(ob, ss->kb, vertCos); MEM_freeN(vertCos); } MEM_freeN(nodes); / Modifiers could depend on mesh normals, so we should update them/ Note, then if sculpting happens on locked key, normals should be re-calculated after applying coords from keyblock on base mesh / mesh_calc_normals(me->mvert, me->totvert, me->mface, me->totface, NULL); } else if (ss->kb) sculpt_update_keyblock(ob); } //static int max_overlap_count(Sculpt sd) //{ // int count[3]; // int i, j; // // for (i= 0; i < 3; i++) { // count[i] = sd->radial_symm[i]; // // for (j= 0; j < 3; j++) { // if (i != j && sd->flags & (SCULPT_SYMM_X<<i)) // count[i] = 2; // } // } // // return MAX3(count[0], count[1], count[2]); //} / Flip all the editdata across the axis/axes specified by symm. Used to calculate multiple modifications to the mesh when symmetry is enabled. / static void calc_brushdata_symm(Sculpt sd, StrokeCache cache, const char symm, const char axis, const float angle, const float UNUSED(feather)) { (void)sd; / unused / flip_coord(cache->location, cache->true_location, symm); flip_coord(cache->grab_delta_symmetry, cache->grab_delta, symm); flip_coord(cache->view_normal, cache->true_view_normal, symm); // XXX This reduces the length of the grab delta if it approaches the line of symmetry // XXX However, a different approach appears to be needed //if (sd->flags & SCULPT_SYMMETRY_FEATHER) { // float frac = 1.0f/max_overlap_count(sd); // float reduce = (feather-frac)/(1-frac); // printf("feather: %f frac: %f reduce: %f\n", feather, frac, reduce); // if (frac < 1) // mul_v3_fl(cache->grab_delta_symmetry, reduce); //} unit_m4(cache->symm_rot_mat); unit_m4(cache->symm_rot_mat_inv); if(axis) { / expects XYZ / rotate_m4(cache->symm_rot_mat, axis, angle); rotate_m4(cache->symm_rot_mat_inv, axis, -angle); } mul_m4_v3(cache->symm_rot_mat, cache->location); mul_m4_v3(cache->symm_rot_mat, cache->grab_delta_symmetry); } static void do_radial_symmetry(Sculpt sd, Object ob, Brush brush, const char symm, const int axis, const float feather) { SculptSession ss = ob->sculpt; int i; for(i = 1; i < sd->radial_symm[axis-'X']; ++i) { const float angle = 2M_PIi/sd->radial_symm[axis-'X']; ss->cache->radial_symmetry_pass= i; calc_brushdata_symm(sd, ss->cache, symm, axis, angle, feather); do_brush_action(sd, ob, brush); } } / noise texture gives different values for the same input coord; this can tear a multires mesh during sculpting so do a stitch in this case / static void sculpt_fix_noise_tear(Sculpt sd, Object ob) { SculptSession ss = ob->sculpt; Brush brush = paint_brush(&sd->paint); MTex mtex = &brush->mtex; if(ss->multires && mtex->tex && mtex->tex->type == TEX_NOISE) multires_stitch_grids(ob); } static void do_symmetrical_brush_actions(Sculpt sd, Object ob) { Brush brush = paint_brush(&sd->paint); SculptSession ss = ob->sculpt; StrokeCache cache = ss->cache; const char symm = sd->flags & 7; int i; float feather = calc_symmetry_feather(sd, ss->cache); cache->bstrength= brush_strength(sd, cache, feather); cache->symmetry= symm; / symm is a bit combination of XYZ - 1 is mirror X; 2 is Y; 3 is XY; 4 is Z; 5 is XZ; 6 is YZ; 7 is XYZ / for(i = 0; i <= symm; ++i) { if(i == 0 \|\| (symm & i && (symm != 5 \|\| i != 3) && (symm != 6 \|\| (i != 3 && i != 5)))) { cache->mirror_symmetry_pass= i; cache->radial_symmetry_pass= 0; calc_brushdata_symm(sd, cache, i, 0, 0, feather); do_brush_action(sd, ob, brush); do_radial_symmetry(sd, ob, brush, i, 'X', feather); do_radial_symmetry(sd, ob, brush, i, 'Y', feather); do_radial_symmetry(sd, ob, brush, i, 'Z', feather); } } sculpt_combine_proxies(sd, ob); / hack to fix noise texture tearing mesh / sculpt_fix_noise_tear(sd, ob); if (ss->modifiers_active) sculpt_flush_stroke_deform(sd, ob); cache->first_time= 0; } static void sculpt_update_tex(Sculpt sd, SculptSession ss) { Brush brush = paint_brush(&sd->paint); const int radius= brush_size(brush); if(ss->texcache) { MEM_freeN(ss->texcache); ss->texcache= NULL; } /* Need to allocate a bigger buffer for bigger brush size / ss->texcache_side = 2radius; if(!ss->texcache \|\| ss->texcache_side > ss->texcache_actual) { ss->texcache = brush_gen_texture_cache(brush, radius); ss->texcache_actual = ss->texcache_side; } } void sculpt_update_mesh_elements(Scene scene, Sculpt sd, Object ob, int need_fmap) { DerivedMesh dm = mesh_get_derived_final(scene, ob, CD_MASK_BAREMESH); SculptSession ss = ob->sculpt; MultiresModifierData mmd= sculpt_multires_active(scene, ob); ss->modifiers_active= sculpt_modifiers_active(scene, sd, ob); if(!mmd) ss->kb= ob_get_keyblock(ob); else ss->kb= NULL; if(mmd) { ss->multires = mmd; ss->totvert = dm->getNumVerts(dm); ss->totface = dm->getNumFaces(dm); ss->mvert= NULL; ss->mface= NULL; ss->face_normals= NULL; } else { Mesh me = get_mesh(ob); ss->totvert = me->totvert; ss->totface = me->totface; ss->mvert = me->mvert; ss->mface = me->mface; ss->face_normals = NULL; ss->multires = NULL; } ss->pbvh = dm->getPBVH(ob, dm); ss->fmap = (need_fmap && dm->getFaceMap)? dm->getFaceMap(ob, dm): NULL; if(ss->modifiers_active) { if(!ss->orig_cos) { int a; free_sculptsession_deformMats(ss); if(ss->kb) ss->orig_cos = key_to_vertcos(ob, ss->kb); else ss->orig_cos = mesh_getVertexCos(ob->data, NULL); crazyspace_build_sculpt(scene, ob, &ss->deform_imats, &ss->deform_cos); BLI_pbvh_apply_vertCos(ss->pbvh, ss->deform_cos); for(a = 0; a < ((Mesh)ob->data)->totvert; ++a) invert_m3(ss->deform_imats[a]); } } else free_sculptsession_deformMats(ss); /* if pbvh is deformed, key block is already applied to it / if (ss->kb && !BLI_pbvh_isDeformed(ss->pbvh)) { float (vertCos)[3]= key_to_vertcos(ob, ss->kb); if (vertCos) { /* apply shape keys coordinates to PBVH / BLI_pbvh_apply_vertCos(ss->pbvh, vertCos); MEM_freeN(vertCos); } } } static int sculpt_mode_poll(bContext C) { Object ob = CTX_data_active_object(C); return ob && ob->mode & OB_MODE_SCULPT; } int sculpt_poll(bContext C) { return sculpt_mode_poll(C) && paint_poll(C); } static const char sculpt_tool_name(Sculpt sd) { Brush brush = paint_brush(&sd->paint); switch(brush->sculpt_tool) { case SCULPT_TOOL_DRAW: return "Draw Brush"; break; case SCULPT_TOOL_SMOOTH: return "Smooth Brush"; break; case SCULPT_TOOL_CREASE: return "Crease Brush"; break; case SCULPT_TOOL_BLOB: return "Blob Brush"; break; case SCULPT_TOOL_PINCH: return "Pinch Brush"; break; case SCULPT_TOOL_INFLATE: return "Inflate Brush"; break; case SCULPT_TOOL_GRAB: return "Grab Brush"; break; case SCULPT_TOOL_NUDGE: return "Nudge Brush"; break; case SCULPT_TOOL_THUMB: return "Thumb Brush"; break; case SCULPT_TOOL_LAYER: return "Layer Brush"; break; case SCULPT_TOOL_FLATTEN: return "Flatten Brush"; break; case SCULPT_TOOL_CLAY: return "Clay Brush"; break; case SCULPT_TOOL_CLAY_TUBES: return "Clay Tubes Brush"; break; case SCULPT_TOOL_FILL: return "Fill Brush"; break; case SCULPT_TOOL_SCRAPE: return "Scrape Brush"; break; default: return "Sculpting"; break; } } /* Operator for applying a stroke (various attributes including mouse path) using the current brush. */ static void sculpt_cache_free(StrokeCache cache) { if(cache->face_norms) MEM_freeN(cache->face_norms); if(cache->mats) MEM_freeN(cache->mats); MEM_freeN(cache); } /* Initialize mirror modifier clipping / static void sculpt_init_mirror_clipping(Object ob, SculptSession ss) { ModifierData md; int i; for(md= ob->modifiers.first; md; md= md->next) { if(md->type==eModifierType_Mirror && (md->mode & eModifierMode_Realtime)) { MirrorModifierData mmd = (MirrorModifierData)md; if(mmd->flag & MOD_MIR_CLIPPING) { /* check each axis for mirroring / for(i = 0; i < 3; ++i) { if(mmd->flag & (MOD_MIR_AXIS_X << i)) { / enable sculpt clipping / ss->cache->flag \|= CLIP_X << i; / update the clip tolerance / if(mmd->tolerance > ss->cache->clip_tolerance[i]) ss->cache->clip_tolerance[i] = mmd->tolerance; } } } } } } / Initialize the stroke cache invariants from operator properties / static void sculpt_update_cache_invariants(bContext C, Sculpt sd, SculptSession ss, wmOperator op, wmEvent event) { StrokeCache cache = MEM_callocN(sizeof(StrokeCache), "stroke cache"); Brush brush = paint_brush(&sd->paint); ViewContext vc = paint_stroke_view_context(op->customdata); Object ob= CTX_data_active_object(C); int i; int mode; ss->cache = cache; /* Set scaling adjustment / ss->cache->scale[0] = 1.0f / ob->size[0]; ss->cache->scale[1] = 1.0f / ob->size[1]; ss->cache->scale[2] = 1.0f / ob->size[2]; ss->cache->plane_trim_squared = brush->plane_trim brush->plane_trim; ss->cache->flag = 0; sculpt_init_mirror_clipping(ob, ss); /* Initial mouse location / if (event) { ss->cache->initial_mouse[0] = event->x; ss->cache->initial_mouse[1] = event->y; } else { ss->cache->initial_mouse[0] = 0; ss->cache->initial_mouse[1] = 0; } mode = RNA_enum_get(op->ptr, "mode"); cache->invert = mode == BRUSH_STROKE_INVERT; cache->alt_smooth = mode == BRUSH_STROKE_SMOOTH; / not very nice, but with current events system implementation we can't handle brush appearance inversion hotkey separately (sergey) / if(cache->invert) brush->flag \|= BRUSH_INVERTED; else brush->flag &= ~BRUSH_INVERTED; / Alt-Smooth / if (ss->cache->alt_smooth) { Paint p= &sd->paint; Brush br; BLI_strncpy(cache->saved_active_brush_name, brush->id.name+2, sizeof(cache->saved_active_brush_name)); br= (Brush )find_id("BR", "Smooth"); if(br) { paint_brush_set(p, br); brush = br; } } copy_v2_v2(cache->mouse, cache->initial_mouse); copy_v2_v2(cache->tex_mouse, cache->initial_mouse); /* Truly temporary data that isn't stored in properties / cache->vc = vc; cache->brush = brush; cache->mats = MEM_callocN(sizeof(bglMats), "sculpt bglMats"); view3d_get_transformation(vc->ar, vc->rv3d, vc->obact, cache->mats); ED_view3d_global_to_vector(cache->vc->rv3d, cache->vc->rv3d->twmat[3], cache->true_view_normal); / Initialize layer brush displacements and persistent coords / if(brush->sculpt_tool == SCULPT_TOOL_LAYER) { / not supported yet for multires / if(!ss->multires && !ss->layer_co && (brush->flag & BRUSH_PERSISTENT)) { if(!ss->layer_co) ss->layer_co= MEM_mallocN(sizeof(float) 3 * ss->totvert, "sculpt mesh vertices copy"); if(ss->deform_cos) memcpy(ss->layer_co, ss->deform_cos, ss->totvert); else { for(i = 0; i < ss->totvert; ++i) { copy_v3_v3(ss->layer_co[i], ss->mvert[i].co); } } } } /* Make copies of the mesh vertex locations and normals for some tools / if(brush->flag & BRUSH_ANCHORED) { if(ss->face_normals) { float fn = ss->face_normals; cache->face_norms= MEM_mallocN(sizeof(float) * 3 * ss->totface, "Sculpt face norms"); for(i = 0; i < ss->totface; ++i, fn += 3) copy_v3_v3(cache->face_norms[i], fn); } cache->original = 1; } if(ELEM8(brush->sculpt_tool, SCULPT_TOOL_DRAW, SCULPT_TOOL_CREASE, SCULPT_TOOL_BLOB, SCULPT_TOOL_LAYER, SCULPT_TOOL_INFLATE, SCULPT_TOOL_CLAY, SCULPT_TOOL_CLAY_TUBES, SCULPT_TOOL_ROTATE)) if(!(brush->flag & BRUSH_ACCUMULATE)) cache->original = 1; cache->special_rotation = (brush->flag & BRUSH_RAKE) ? sd->last_angle : 0; //cache->last_rake[0] = sd->last_x; //cache->last_rake[1] = sd->last_y; cache->first_time= 1; cache->vertex_rotation= 0; } static void sculpt_update_brush_delta(Sculpt sd, Object ob, Brush brush) { SculptSession ss = ob->sculpt; StrokeCache cache = ss->cache; int tool = brush->sculpt_tool; if(ELEM5(tool, SCULPT_TOOL_GRAB, SCULPT_TOOL_NUDGE, SCULPT_TOOL_CLAY_TUBES, SCULPT_TOOL_SNAKE_HOOK, SCULPT_TOOL_THUMB)) { float grab_location[3], imat[4][4], delta[3], loc[3]; if(cache->first_time) { copy_v3_v3(cache->orig_grab_location, cache->true_location); } else if(tool == SCULPT_TOOL_SNAKE_HOOK) add_v3_v3(cache->true_location, cache->grab_delta); / compute 3d coordinate at same z from original location + mouse / mul_v3_m4v3(loc, ob->obmat, cache->orig_grab_location); initgrabz(cache->vc->rv3d, loc[0], loc[1], loc[2]); ED_view3d_win_to_delta(cache->vc->ar, cache->mouse, grab_location); / compute delta to move verts by / if(!cache->first_time) { switch(tool) { case SCULPT_TOOL_GRAB: case SCULPT_TOOL_THUMB: sub_v3_v3v3(delta, grab_location, cache->old_grab_location); invert_m4_m4(imat, ob->obmat); mul_mat3_m4_v3(imat, delta); add_v3_v3(cache->grab_delta, delta); break; case SCULPT_TOOL_CLAY_TUBES: case SCULPT_TOOL_NUDGE: sub_v3_v3v3(cache->grab_delta, grab_location, cache->old_grab_location); invert_m4_m4(imat, ob->obmat); mul_mat3_m4_v3(imat, cache->grab_delta); break; case SCULPT_TOOL_SNAKE_HOOK: sub_v3_v3v3(cache->grab_delta, grab_location, cache->old_grab_location); invert_m4_m4(imat, ob->obmat); mul_mat3_m4_v3(imat, cache->grab_delta); break; } } else { zero_v3(cache->grab_delta); } copy_v3_v3(cache->old_grab_location, grab_location); if(tool == SCULPT_TOOL_GRAB) copy_v3_v3(sd->anchored_location, cache->true_location); else if(tool == SCULPT_TOOL_THUMB) copy_v3_v3(sd->anchored_location, cache->orig_grab_location); if(ELEM(tool, SCULPT_TOOL_GRAB, SCULPT_TOOL_THUMB)) { / location stays the same for finding vertices in brush radius / copy_v3_v3(cache->true_location, cache->orig_grab_location); sd->draw_anchored = 1; copy_v2_v2(sd->anchored_initial_mouse, cache->initial_mouse); sd->anchored_size = cache->pixel_radius; } } } / Initialize the stroke cache variants from operator properties / static void sculpt_update_cache_variants(bContext C, Sculpt sd, Object ob, struct PaintStroke stroke, PointerRNA ptr) { SculptSession ss = ob->sculpt; StrokeCache cache = ss->cache; Brush brush = paint_brush(&sd->paint); int dx, dy; //RNA_float_get_array(ptr, "location", cache->traced_location); if (cache->first_time \|\| !((brush->flag & BRUSH_ANCHORED)\|\| (brush->sculpt_tool == SCULPT_TOOL_SNAKE_HOOK)\|\| (brush->sculpt_tool == SCULPT_TOOL_ROTATE)) ) { RNA_float_get_array(ptr, "location", cache->true_location); } cache->pen_flip = RNA_boolean_get(ptr, "pen_flip"); RNA_float_get_array(ptr, "mouse", cache->mouse); / XXX: Use preassure value from first brush step for brushes which don't support strokes (grab, thumb). They depends on initial state and brush coord/pressure/etc. It's more an events design issue, which doesn't split coordinate/pressure/angle changing events. We should avoid this after events system re-design / if(paint_space_stroke_enabled(brush) \|\| cache->first_time) cache->pressure = RNA_float_get(ptr, "pressure"); / Truly temporary data that isn't stored in properties / sd->draw_pressure= 1; sd->pressure_value= cache->pressure; cache->previous_pixel_radius = cache->pixel_radius; cache->pixel_radius = brush_size(brush); if(cache->first_time) { if (!brush_use_locked_size(brush)) { cache->initial_radius= paint_calc_object_space_radius(cache->vc, cache->true_location, brush_size(brush)); brush_set_unprojected_radius(brush, cache->initial_radius); } else { cache->initial_radius= brush_unprojected_radius(brush); } } if(brush_use_size_pressure(brush)) { cache->pixel_radius = cache->pressure; cache->radius= cache->initial_radius * cache->pressure; } else cache->radius= cache->initial_radius; cache->radius_squared = cache->radiuscache->radius; if(!(brush->flag & BRUSH_ANCHORED \|\| ELEM4(brush->sculpt_tool, SCULPT_TOOL_GRAB, SCULPT_TOOL_SNAKE_HOOK, SCULPT_TOOL_THUMB, SCULPT_TOOL_ROTATE))) { copy_v2_v2(cache->tex_mouse, cache->mouse); if ( (brush->mtex.brush_map_mode == MTEX_MAP_MODE_FIXED) && (brush->flag & BRUSH_RANDOM_ROTATION) && !(brush->flag & BRUSH_RAKE)) { cache->special_rotation = 2.0f(float)M_PIBLI_frand(); } } if(brush->flag & BRUSH_ANCHORED) { int hit = 0; dx = cache->mouse[0] - cache->initial_mouse[0]; dy = cache->mouse[1] - cache->initial_mouse[1]; sd->anchored_size = cache->pixel_radius = sqrt(dxdx + dydy); cache->special_rotation = atan2(dx, dy) + M_PI; if (brush->flag & BRUSH_EDGE_TO_EDGE) { float halfway[2]; float out[3]; halfway[0] = (float)dx 0.5f + cache->initial_mouse[0]; halfway[1] = (float)dy * 0.5f + cache->initial_mouse[1]; if (sculpt_stroke_get_location(C, stroke, out, halfway)) { copy_v3_v3(sd->anchored_location, out); copy_v2_v2(sd->anchored_initial_mouse, halfway); copy_v2_v2(cache->tex_mouse, halfway); copy_v3_v3(cache->true_location, sd->anchored_location); sd->anchored_size /= 2.0f; cache->pixel_radius /= 2.0f; hit = 1; } } if (!hit) copy_v2_v2(sd->anchored_initial_mouse, cache->initial_mouse); cache->radius= paint_calc_object_space_radius(paint_stroke_view_context(stroke), cache->true_location, cache->pixel_radius); cache->radius_squared = cache->radiuscache->radius; copy_v3_v3(sd->anchored_location, cache->true_location); sd->draw_anchored = 1; } else if(brush->flag & BRUSH_RAKE) { const float u = 0.5f; const float v = 1 - u; const float r = 20; const float dx = cache->last_rake[0] - cache->mouse[0]; const float dy = cache->last_rake[1] - cache->mouse[1]; if (cache->first_time) { copy_v2_v2(cache->last_rake, cache->mouse); } else if (dxdx + dydy >= rr) { cache->special_rotation = atan2(dx, dy); cache->last_rake[0] = ucache->last_rake[0] + vcache->mouse[0]; cache->last_rake[1] = ucache->last_rake[1] + vcache->mouse[1]; } } sculpt_update_brush_delta(sd, ob, brush); if(brush->sculpt_tool == SCULPT_TOOL_ROTATE) { dx = cache->mouse[0] - cache->initial_mouse[0]; dy = cache->mouse[1] - cache->initial_mouse[1]; cache->vertex_rotation = -atan2(dx, dy); sd->draw_anchored = 1; copy_v2_v2(sd->anchored_initial_mouse, cache->initial_mouse); copy_v3_v3(sd->anchored_location, cache->true_location); sd->anchored_size = cache->pixel_radius; } sd->special_rotation = cache->special_rotation; } static void sculpt_stroke_modifiers_check(bContext C, Object ob) { SculptSession ss = ob->sculpt; if(ss->modifiers_active) { Sculpt sd = CTX_data_tool_settings(C)->sculpt; Brush brush = paint_brush(&sd->paint); sculpt_update_mesh_elements(CTX_data_scene(C), sd, ob, brush->sculpt_tool == SCULPT_TOOL_SMOOTH); } } typedef struct { SculptSession ss; float ray_start, ray_normal; int hit; float dist; int original; } SculptRaycastData; static void sculpt_raycast_cb(PBVHNode node, void data_v, float* tmin) { if (BLI_pbvh_node_get_tmin(node) < tmin) { SculptRaycastData srd = data_v; float (origco)[3]= NULL; if(srd->original && srd->ss->cache) { / intersect with coordinates from before we started stroke / SculptUndoNode unode= sculpt_undo_get_node(node); origco= (unode)? unode->co: NULL; } if (BLI_pbvh_node_raycast(srd->ss->pbvh, node, origco, srd->ray_start, srd->ray_normal, &srd->dist)) { srd->hit = 1; tmin = srd->dist; } } } / Do a raycast in the tree to find the 3d brush location (This allows us to ignore the GL depth buffer) Returns 0 if the ray doesn't hit the mesh, non-zero otherwise / int sculpt_stroke_get_location(bContext C, struct PaintStroke stroke, float out[3], float mouse[2]) { ViewContext vc = paint_stroke_view_context(stroke); Object ob = vc->obact; SculptSession ss= ob->sculpt; StrokeCache cache= ss->cache; float ray_start[3], ray_end[3], ray_normal[3], dist; float obimat[4][4]; float mval[2]; SculptRaycastData srd; mval[0] = mouse[0] - vc->ar->winrct.xmin; mval[1] = mouse[1] - vc->ar->winrct.ymin; sculpt_stroke_modifiers_check(C, ob); ED_view3d_win_to_segment_clip(vc->ar, vc->v3d, mval, ray_start, ray_end); invert_m4_m4(obimat, ob->obmat); mul_m4_v3(obimat, ray_start); mul_m4_v3(obimat, ray_end); sub_v3_v3v3(ray_normal, ray_end, ray_start); dist= normalize_v3(ray_normal); srd.ss = vc->obact->sculpt; srd.ray_start = ray_start; srd.ray_normal = ray_normal; srd.dist = dist; srd.hit = 0; srd.original = (cache)? cache->original: 0; BLI_pbvh_raycast(ss->pbvh, sculpt_raycast_cb, &srd, ray_start, ray_normal, srd.original); copy_v3_v3(out, ray_normal); mul_v3_fl(out, srd.dist); add_v3_v3(out, ray_start); return srd.hit; } static void sculpt_brush_init_tex(Sculpt sd, SculptSession ss) { Brush brush = paint_brush(&sd->paint); MTex mtex= &brush->mtex; / init mtex nodes / if(mtex->tex && mtex->tex->nodetree) ntreeTexBeginExecTree(mtex->tex->nodetree, 1); / has internal flag to detect it only does it once / / TODO: Shouldn't really have to do this at the start of every stroke, but sculpt would need some sort of notification when changes are made to the texture. / sculpt_update_tex(sd, ss); } static int sculpt_brush_stroke_init(bContext C, wmOperator op) { Scene scene= CTX_data_scene(C); Object ob= CTX_data_active_object(C); Sculpt sd = CTX_data_tool_settings(C)->sculpt; SculptSession ss = CTX_data_active_object(C)->sculpt; Brush brush = paint_brush(&sd->paint); int mode= RNA_enum_get(op->ptr, "mode"); int is_smooth= 0; view3d_operator_needs_opengl(C); sculpt_brush_init_tex(sd, ss); is_smooth\|= mode == BRUSH_STROKE_SMOOTH; is_smooth\|= brush->sculpt_tool == SCULPT_TOOL_SMOOTH; sculpt_update_mesh_elements(scene, sd, ob, is_smooth); return 1; } static void sculpt_restore_mesh(Sculpt sd, SculptSession ss) { Brush brush = paint_brush(&sd->paint); / Restore the mesh before continuing with anchored stroke / if((brush->flag & BRUSH_ANCHORED) \|\| (brush->sculpt_tool == SCULPT_TOOL_GRAB && brush_use_size_pressure(brush)) \|\| (brush->flag & BRUSH_RESTORE_MESH)) { StrokeCache cache = ss->cache; int i; PBVHNode *nodes; int n, totnode; BLI_pbvh_search_gather(ss->pbvh, NULL, NULL, &nodes, &totnode); #pragma omp parallel for schedule(guided) if (sd->flags & SCULPT_USE_OPENMP) for(n=0; n<totnode; n++) { SculptUndoNode unode; unode= sculpt_undo_get_node(nodes[n]); if(unode) { PBVHVertexIter vd; BLI_pbvh_vertex_iter_begin(ss->pbvh, nodes[n], vd, PBVH_ITER_UNIQUE) { copy_v3_v3(vd.co, unode->co[vd.i]); if(vd.no) copy_v3_v3_short(vd.no, unode->no[vd.i]); else normal_short_to_float_v3(vd.fno, unode->no[vd.i]); if(vd.mvert) vd.mvert->flag \|= ME_VERT_PBVH_UPDATE; } BLI_pbvh_vertex_iter_end; BLI_pbvh_node_mark_update(nodes[n]); } } if(ss->face_normals) { float fn = ss->face_normals; for(i = 0; i < ss->totface; ++i, fn += 3) copy_v3_v3(fn, cache->face_norms[i]); } if(nodes) MEM_freeN(nodes); } } static void sculpt_flush_update(bContext C) { Object ob = CTX_data_active_object(C); SculptSession ss = ob->sculpt; ARegion ar = CTX_wm_region(C); MultiresModifierData mmd = ss->multires; if(mmd) multires_mark_as_modified(ob); if(ob->derivedFinal) /* VBO no longer valid / GPU_drawobject_free(ob->derivedFinal); if(ss->modifiers_active) { DAG_id_tag_update(&ob->id, OB_RECALC_DATA); ED_region_tag_redraw(ar); } else { rcti r; BLI_pbvh_update(ss->pbvh, PBVH_UpdateBB, NULL); if (sculpt_get_redraw_rect(ar, CTX_wm_region_view3d(C), ob, &r)) { if (ss->cache) ss->cache->previous_r= r; r.xmin += ar->winrct.xmin + 1; r.xmax += ar->winrct.xmin - 1; r.ymin += ar->winrct.ymin + 1; r.ymax += ar->winrct.ymin - 1; ss->partial_redraw = 1; ED_region_tag_redraw_partial(ar, &r); } } } / Returns whether the mouse/stylus is over the mesh (1) or over the background (0) / static int over_mesh(bContext C, struct wmOperator op, float x, float y) { float mouse[2], co[3]; mouse[0] = x; mouse[1] = y; return sculpt_stroke_get_location(C, op->customdata, co, mouse); } static int sculpt_stroke_test_start(bContext C, struct wmOperator op, wmEvent event) { /* Don't start the stroke until mouse goes over the mesh. * note: event will only be null when re-executing the saved stroke. / if(event==NULL \|\| over_mesh(C, op, event->x, event->y)) { Object ob = CTX_data_active_object(C); SculptSession ss = ob->sculpt; Sculpt sd = CTX_data_tool_settings(C)->sculpt; ED_view3d_init_mats_rv3d(ob, CTX_wm_region_view3d(C)); sculpt_update_cache_invariants(C, sd, ss, op, event); sculpt_undo_push_begin(sculpt_tool_name(sd)); #ifdef _OPENMP /* If using OpenMP then create a number of threads two times the number of processor cores. Justification: Empirically I've found that two threads per processor gives higher throughput. / if (sd->flags & SCULPT_USE_OPENMP) { int num_procs; num_procs = omp_get_num_procs(); omp_set_num_threads(2num_procs); } #endif return 1; } else return 0; } static void sculpt_stroke_update_step(bContext C, struct PaintStroke stroke, PointerRNA itemptr) { Sculpt sd = CTX_data_tool_settings(C)->sculpt; Object ob = CTX_data_active_object(C); SculptSession ss = ob->sculpt; sculpt_stroke_modifiers_check(C, ob); sculpt_update_cache_variants(C, sd, ob, stroke, itemptr); sculpt_restore_mesh(sd, ss); do_symmetrical_brush_actions(sd, ob); /* Cleanup / sculpt_flush_update(C); } static void sculpt_brush_exit_tex(Sculpt sd) { Brush brush= paint_brush(&sd->paint); MTex mtex= &brush->mtex; if(mtex->tex && mtex->tex->nodetree) ntreeTexEndExecTree(mtex->tex->nodetree->execdata, 1); } static void sculpt_stroke_done(bContext C, struct PaintStroke UNUSED(stroke)) { Object ob= CTX_data_active_object(C); SculptSession ss = ob->sculpt; Sculpt sd = CTX_data_tool_settings(C)->sculpt; // reset values used to draw brush after completing the stroke sd->draw_anchored= 0; sd->draw_pressure= 0; sd->special_rotation= 0; / Finished / if(ss->cache) { Brush brush= paint_brush(&sd->paint); brush->flag &= ~BRUSH_INVERTED; sculpt_stroke_modifiers_check(C, ob); /* Alt-Smooth / if (ss->cache->alt_smooth) { Paint p= &sd->paint; brush= (Brush )find_id("BR", ss->cache->saved_active_brush_name); if(brush) { paint_brush_set(p, brush); } } sculpt_cache_free(ss->cache); ss->cache = NULL; sculpt_undo_push_end(); BLI_pbvh_update(ss->pbvh, PBVH_UpdateOriginalBB, NULL); / optimization: if there is locked key and active modifiers present in / / the stack, keyblock is updating at each step. otherwise we could update / / keyblock only when stroke is finished / if(ss->kb && !ss->modifiers_active) sculpt_update_keyblock(ob); ss->partial_redraw = 0; / try to avoid calling this, only for e.g. linked duplicates now / if(((Mesh)ob->data)->id.us > 1) DAG_id_tag_update(&ob->id, OB_RECALC_DATA); WM_event_add_notifier(C, NC_OBJECT\|ND_DRAW, ob); } sculpt_brush_exit_tex(sd); } static int sculpt_brush_stroke_invoke(bContext C, wmOperator op, wmEvent event) { struct PaintStroke stroke; int ignore_background_click; if(!sculpt_brush_stroke_init(C, op)) return OPERATOR_CANCELLED; stroke = paint_stroke_new(C, sculpt_stroke_get_location, sculpt_stroke_test_start, sculpt_stroke_update_step, sculpt_stroke_done, event->type); op->customdata = stroke; /* For tablet rotation / ignore_background_click = RNA_boolean_get(op->ptr, "ignore_background_click"); if(ignore_background_click && !over_mesh(C, op, event->x, event->y)) { paint_stroke_free(stroke); return OPERATOR_PASS_THROUGH; } / add modal handler / WM_event_add_modal_handler(C, op); op->type->modal(C, op, event); return OPERATOR_RUNNING_MODAL; } static int sculpt_brush_stroke_exec(bContext C, wmOperator op) { if(!sculpt_brush_stroke_init(C, op)) return OPERATOR_CANCELLED; op->customdata = paint_stroke_new(C, sculpt_stroke_get_location, sculpt_stroke_test_start, sculpt_stroke_update_step, sculpt_stroke_done, 0); / frees op->customdata / paint_stroke_exec(C, op); return OPERATOR_FINISHED; } static int sculpt_brush_stroke_cancel(bContext C, wmOperator op) { Object ob= CTX_data_active_object(C); SculptSession ss = ob->sculpt; Sculpt sd = CTX_data_tool_settings(C)->sculpt; paint_stroke_cancel(C, op); if(ss->cache) { sculpt_cache_free(ss->cache); ss->cache = NULL; } sculpt_brush_exit_tex(sd); return OPERATOR_CANCELLED; } static void SCULPT_OT_brush_stroke(wmOperatorType ot) { static EnumPropertyItem stroke_mode_items[] = { {BRUSH_STROKE_NORMAL, "NORMAL", 0, "Normal", "Apply brush normally"}, {BRUSH_STROKE_INVERT, "INVERT", 0, "Invert", "Invert action of brush for duration of stroke"}, {BRUSH_STROKE_SMOOTH, "SMOOTH", 0, "Smooth", "Switch brush to smooth mode for duration of stroke"}, {0} }; / identifiers / ot->name= "Sculpt Mode"; ot->idname= "SCULPT_OT_brush_stroke"; / api callbacks / ot->invoke= sculpt_brush_stroke_invoke; ot->modal= paint_stroke_modal; ot->exec= sculpt_brush_stroke_exec; ot->poll= sculpt_poll; ot->cancel= sculpt_brush_stroke_cancel; / flags (sculpt does own undo? (ton) / ot->flag= OPTYPE_BLOCKING; / properties / RNA_def_collection_runtime(ot->srna, "stroke", &RNA_OperatorStrokeElement, "Stroke", ""); RNA_def_enum(ot->srna, "mode", stroke_mode_items, BRUSH_STROKE_NORMAL, "Sculpt Stroke Mode", "Action taken when a sculpt stroke is made"); RNA_def_boolean(ot->srna, "ignore_background_click", 0, "Ignore Background Click", "Clicks on the background do not start the stroke"); } /* Reset the copy of the mesh that is being sculpted on (currently just for the layer brush) */ static int sculpt_set_persistent_base(bContext C, wmOperator UNUSED(op)) { SculptSession ss = CTX_data_active_object(C)->sculpt; if(ss) { if(ss->layer_co) MEM_freeN(ss->layer_co); ss->layer_co = NULL; } return OPERATOR_FINISHED; } static void SCULPT_OT_set_persistent_base(wmOperatorType ot) { / identifiers / ot->name= "Set Persistent Base"; ot->idname= "SCULPT_OT_set_persistent_base"; / api callbacks / ot->exec= sculpt_set_persistent_base; ot->poll= sculpt_mode_poll; ot->flag= OPTYPE_REGISTER\|OPTYPE_UNDO; } /* Toggle operator for turning sculpt mode on or off */ static void sculpt_init_session(Scene scene, Object ob) { ob->sculpt = MEM_callocN(sizeof(SculptSession), "sculpt session"); sculpt_update_mesh_elements(scene, scene->toolsettings->sculpt, ob, 0); } static int sculpt_toggle_mode(bContext C, wmOperator UNUSED(op)) { Scene scene = CTX_data_scene(C); ToolSettings ts = CTX_data_tool_settings(C); Object ob = CTX_data_active_object(C); MultiresModifierData mmd= sculpt_multires_active(scene, ob); int flush_recalc= 0; / multires in sculpt mode could have different from object mode subdivision level / flush_recalc \|= mmd && mmd->sculptlvl != mmd->lvl; / if object has got active modifiers, it's dm could be different in sculpt mode / flush_recalc \|= sculpt_has_active_modifiers(scene, ob); if(ob->mode & OB_MODE_SCULPT) { if(mmd) multires_force_update(ob); if(flush_recalc) DAG_id_tag_update(&ob->id, OB_RECALC_DATA); / Leave sculptmode / ob->mode &= ~OB_MODE_SCULPT; free_sculptsession(ob); } else { / Enter sculptmode / ob->mode \|= OB_MODE_SCULPT; if(flush_recalc) DAG_id_tag_update(&ob->id, OB_RECALC_DATA); / Create persistent sculpt mode data / if(!ts->sculpt) { ts->sculpt = MEM_callocN(sizeof(Sculpt), "sculpt mode data"); / Turn on X plane mirror symmetry by default / ts->sculpt->flags \|= SCULPT_SYMM_X; } / Create sculpt mode session data / if(ob->sculpt) free_sculptsession(ob); sculpt_init_session(scene, ob); paint_init(&ts->sculpt->paint, PAINT_CURSOR_SCULPT); paint_cursor_start(C, sculpt_poll); } WM_event_add_notifier(C, NC_SCENE\|ND_MODE, CTX_data_scene(C)); return OPERATOR_FINISHED; } static void SCULPT_OT_sculptmode_toggle(wmOperatorType ot) { /* identifiers / ot->name= "Sculpt Mode"; ot->idname= "SCULPT_OT_sculptmode_toggle"; / api callbacks */ ot->exec= sculpt_toggle_mode; ot->poll= ED_operator_object_active_editable_mesh; ot->flag= OPTYPE_REGISTER\|OPTYPE_UNDO; } void ED_operatortypes_sculpt(void) { WM_operatortype_append(SCULPT_OT_brush_stroke); WM_operatortype_append(SCULPT_OT_sculptmode_toggle); WM_operatortype_append(SCULPT_OT_set_persistent_base); }
mmap_spin.c	#include <sys/types.h> #include <sys/stat.h> #include <fcntl.h> #include <stdio.h> #include <stdlib.h> #include <sys/mman.h> #include <unistd.h> #include <string.h> int main() { size_t size = 8294400; int fd = open("/tmp/testmmap", O_RDWR \| O_CREAT, S_IRUSR \| S_IWUSR); ftruncate(fd, size + 64); char buf = (char)mmap(NULL, 64 + size, PROT_READ\|PROT_WRITE, MAP_SHARED, fd, 0); char src = (char)malloc(size); buf[0] = 1; for (size_t i = 0; i < size; i++) { src[i] = i; } for (int j = 0; j < 100; j++) { printf("send %d\n", j); #pragma omp parallel for for (size_t i = 0; i < size; i += size/4) { memcpy(buf+(i+64), src+i, size/4); } buf[0] = 0; } return 0; }
Network.h	/* * Network.h * * Created by Guido Novati on 30.10.18. * Copyright 2018 ETH Zurich. All rights reserved. * / #pragma once #include "Layers.h" struct Network { std::mt19937 gen; // Vector of layers, each defines a forward and bckward operation: std::vector<Layer> layers; // Vector of parameters of each layer (two vectors must have the same size) // Each Params contains the matrices of parameters needed by the corresp layer std::vector<Params> params; // Vector of grads for each parameter. By definition they have the same size std::vector<Params> grads; // Memory space where each layer can compute its output and gradient: std::vector<Activation> workspace; // Number of inputs to the network: int nInputs = 0; // Number of network outputs: int nOutputs = 0; Network(const int seed = 0) : gen(seed) {}; std::vector<std::vector<Real>> forward( // one vector of input for each element in the mini-batch: const std::vector<std::vector<Real>> I, // layer ID at which to start forward operation: const size_t layerStart = 0 // (zero means compute from input to output) ) { if(params.size()==0 \|\| grads.size()==0 \|\| layers.size()==0) { printf("Attempted to access uninitialized network. Aborting\n"); abort(); } // input is a minibatch of datapoints: one vector for each datapoint: const size_t batchSize = I.size(); // allocate workspaces where we can write output of each layer clearWorkspace(); workspace = allocateActivation(batchSize); // User can overwrite the output of any upper layer (marked by layerStart) // in order to see what happens if layer layerStart has a predefined output. // ( this allows visualizing PCA components! ) const int inputLayerSize = workspace[layerStart]->layersSize; //copy input onto output of input layer: #pragma omp parallel for schedule(static) for (size_t b=0; b<batchSize; b++) { assert(I[b].size() == (size_t) inputLayerSize ); // Input to the network is the output of input layer. // Respective workspace is a matrix of size [batchSize]x[nInputs] // Here we use row-major ordering: nInputs is the number of columns. Real const input_b = workspace[layerStart]->output + b * inputLayerSize; // copy from function argument to workspace: std::copy(I[b].begin(), I[b].end(), input_b); } // Start from layer after input. E.g. Input layer is 0. No need to backprop // input layer has it has no parameters. for (size_t j=layerStart+1; j<layers.size(); j++) layers[j]->forward(workspace, params); // copy output into vector of vectors: one vector for each element of batch std::vector<std::vector<Real>> O(batchSize, std::vector<Real>(nOutputs, 0)); #pragma omp parallel for schedule(static) for (size_t b=0; b<batchSize; b++) { assert(nOutputs == workspace.back()->layersSize); // network output is the output of last layer. // Respective workspace is a matrix of size [batchSize]x[nOutputs] // Here we use row-major ordering: nOutputs is the number of columns. Real* const output_b = workspace.back()->output + b * nOutputs; // copy from function argument to workspace: std::copy(output_b, output_b + nOutputs, O[b].begin()); } return O; } void bckward( // vector of size of mini-batch of gradients of error wrt to network output const std::vector<std::vector<Real>> E, // layer ID at which forward operation was started: const size_t layerStart=0 // (zero means compute from input to output) ) const { //this function assumes that we already called forward propagation if(params.size()==0 \|\| grads.size()==0 \|\| layers.size()==0) { printf("Attempted to access uninitialized network. Aborting\n"); abort(); } // input is a minibatch of datapoints: one vector for each datapoint: const size_t batchSize = E.size(); assert( (size_t) workspace.back()->batchSize == batchSize); // first, clear memory over which we'll write gradients: for(auto& p : workspace) p->clearErrors(); //copy input onto output of input layer: for (size_t b=0; b<batchSize; b++) { assert(E[b].size() == (size_t) nOutputs); // Write d Err / d Out onto last layer of the network. // Respective workspace is a matrix of size [batchSize]x[nOutputs] // Here we use row-major ordering: nOutputs is the number of columns. Real* const errors_b = workspace.back()->dError_dOutput + b * nOutputs; // copy from function argument to workspace: std::copy(E[b].begin(), E[b].end(), errors_b); } // Backprop starts at the last layer, which computes gradient of error wrt // to its parameters and gradient of error wrt to it's input. // Last layer to backprop is the one above input layer. Eg. if layerStart=0 // Then input layer was 0, which has no parametes and has no inputs to // backprp the error grad to, last layer to backprop is layer 1. for (size_t i = layers.size()-1; i >= layerStart + 1; i--) layers[i]->bckward(workspace, params, grads); } // Helper function for forward with batchsize = 1 std::vector<Real> forward(const std::vector<Real>I, const size_t layerStart=0) { std::vector<std::vector<Real>> vecI (1, I); std::vector<std::vector<Real>> vecO = forward(vecI, layerStart); return vecO[0]; } // Helper function for forward with batchsize = 1) void bckward(const std::vector<Real> E, const size_t layerStart = 0) const { std::vector<std::vector<Real>> vecE (1, E); bckward(vecE, layerStart); } void save() const { for(const auto &l : layers) l->save(params); } void restart() const { for(const auto &l : layers) l->restart(params); } ~Network() { for(auto& p : grads) _dispose_object(p); for(auto& p : params) _dispose_object(p); for(auto& p : layers) _dispose_object(p); for(auto& p : workspace) _dispose_object(p); } inline void clearWorkspace() { for(auto& p : workspace) _dispose_object(p); workspace.clear(); } // Function to loop over layers and allocate workspace for network operations: inline std::vector<Activation> allocateActivation(size_t batchSize) const { std::vector<Activation> ret(layers.size(), nullptr); for(size_t j=0; j<layers.size(); j++) ret[j] = layers[j]->allocateActivation(batchSize); return ret; } // Function to loop over layers and allocate memory space for parameter grads: inline std::vector<Params> allocateGrad() const { std::vector<Params> ret(layers.size(), nullptr); for(size_t j=0; j<layers.size(); j++) ret[j] = layers[j]->allocate_params(); return ret; } ////////////////////////////////////////////////////////////////////////////// /// Functions to build the network are defined in Network_buildFunctions.h /// ////////////////////////////////////////////////////////////////////////////// template<int size> void addInput(); template<int nInputs, int size> void addLinear(const std::string fname = std::string()); template<int size> void addTanh(); }; #include "Network_buildFunctions.h"
deconv_2d.h	// Copyright 2018 Xiaomi, Inc. All rights reserved. // // Licensed under the Apache License, Version 2.0 (the "License"); // you may not use this file except in compliance with the License. // You may obtain a copy of the License at // // http://www.apache.org/licenses/LICENSE-2.0 // // Unless required by applicable law or agreed to in writing, software // distributed under the License is distributed on an "AS IS" BASIS, // WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. // See the License for the specific language governing permissions and // limitations under the License. #ifndef MACE_KERNELS_DECONV_2D_H_ #define MACE_KERNELS_DECONV_2D_H_ #if defined(MACE_ENABLE_NEON) && defined(__aarch64__) #include <arm_neon.h> #endif #include <algorithm> #include <memory> #include <vector> #include "mace/core/future.h" #include "mace/core/tensor.h" #include "mace/kernels/activation.h" #include "mace/kernels/conv_pool_2d_util.h" #include "mace/utils/utils.h" #ifdef MACE_ENABLE_OPENCL #include "mace/core/runtime/opencl/cl2_header.h" #endif // MACE_ENABLE_OPENCL namespace mace { namespace kernels { namespace deconv { template<typename T> void Deconv2dNCHW(const T input, const T filter, const T bias, const index_t in_shape, const index_t out_shape, const index_t kernel_hw, const int strides, const int padding, float output) { #pragma omp parallel for collapse(4) for (index_t b = 0; b < out_shape[0]; ++b) { for (index_t oc = 0; oc < out_shape[1]; ++oc) { for (index_t oh = 0; oh < out_shape[2]; ++oh) { for (index_t ow = 0; ow < out_shape[3]; ++ow) { index_t filter_start_y, filter_start_x; index_t start_x = std::max<int>(0, ow + strides[1] -1 - padding[1]); index_t start_y = std::max<int>(0, oh + strides[0] -1 - padding[0]); start_x /= strides[1]; start_y /= strides[0]; filter_start_x = padding[1] + strides[1] start_x - ow; filter_start_y = padding[0] + strides[0] * start_y - oh; filter_start_x = kernel_hw[1] - 1 - filter_start_x; filter_start_y = kernel_hw[0] - 1 - filter_start_y; T out_value = 0; index_t out_pos = ((b * out_shape[1] + oc) * out_shape[2] + oh) * out_shape[3] + ow; for (index_t ic = 0; ic < in_shape[1]; ++ic) { for (index_t f_y = filter_start_y, ih = start_y; f_y >= 0 && ih < in_shape[2]; f_y -= strides[0], ++ih) { for (index_t f_x = filter_start_x, iw = start_x; f_x >= 0 && iw < in_shape[3]; f_x -= strides[1], ++iw) { index_t weight_pos = ((oc * in_shape[1] + ic) * kernel_hw[0] + f_y) * kernel_hw[1] + f_x; index_t in_pos = ((b * in_shape[1] + ic) * in_shape[2] + ih) * in_shape[3] + iw; out_value += input[in_pos] * filter[weight_pos]; } } } if (bias != nullptr) out_value += bias[oc]; output[out_pos] = out_value; } } } } } } // namespace deconv struct Deconv2dFunctorBase { Deconv2dFunctorBase(const int strides, const Padding &padding_type, const std::vector<int> &paddings, const std::vector<index_t> &output_shape, const ActivationType activation, const float relux_max_limit, const bool from_caffe) : strides_(strides), padding_type_(padding_type), paddings_(paddings), output_shape_(output_shape), activation_(activation), relux_max_limit_(relux_max_limit), from_caffe_(from_caffe) {} static void CalcDeconvOutputSize( const index_t input_shape, // NHWC const index_t filter_shape, // OIHW const int strides, index_t output_shape, const int padding_size, const bool isNCHW = false) { MACE_CHECK_NOTNULL(output_shape); MACE_CHECK_NOTNULL(padding_size); MACE_CHECK_NOTNULL(input_shape); MACE_CHECK_NOTNULL(filter_shape); MACE_CHECK_NOTNULL(strides); const index_t output_channel = filter_shape[0]; const index_t in_height = isNCHW ? input_shape[2] : input_shape[1]; const index_t in_width = isNCHW ? input_shape[3] : input_shape[2]; const index_t filter_h = filter_shape[2]; const index_t filter_w = filter_shape[3]; index_t out_height = (in_height - 1) * strides[0] + filter_h -padding_size[0]; index_t out_width = (in_width - 1) * strides[1] + filter_w -padding_size[1]; output_shape[0] = input_shape[0]; if (isNCHW) { output_shape[1] = output_channel; output_shape[2] = out_height; output_shape[3] = out_width; } else { output_shape[1] = out_height; output_shape[2] = out_width; output_shape[3] = output_channel; } } static void CalcDeconvPaddingAndInputSize( const index_t input_shape, // NHWC const index_t filter_shape, // OIHW const int strides, Padding padding, const index_t output_shape, int padding_size, const bool isNCHW = false) { MACE_CHECK_NOTNULL(output_shape); MACE_CHECK_NOTNULL(padding_size); MACE_CHECK_NOTNULL(input_shape); MACE_CHECK_NOTNULL(filter_shape); MACE_CHECK_NOTNULL(strides); const index_t in_height = isNCHW ? input_shape[2] : input_shape[1]; const index_t in_width = isNCHW ? input_shape[3] : input_shape[2]; const index_t out_height = isNCHW ? output_shape[2] : output_shape[1]; const index_t out_width = isNCHW ? output_shape[3] : output_shape[2]; const index_t extended_input_height = (in_height - 1) strides[0] + 1; const index_t extended_input_width = (in_width - 1) * strides[1] + 1; const index_t filter_h = filter_shape[2]; const index_t filter_w = filter_shape[3]; index_t expected_input_height = 0, expected_input_width = 0; switch (padding) { case VALID: expected_input_height = (out_height - filter_h + strides[0]) / strides[0]; expected_input_width = (out_width - filter_w + strides[1]) / strides[1]; break; case SAME: expected_input_height = (out_height + strides[0] - 1) / strides[0]; expected_input_width = (out_width + strides[1] - 1) / strides[1]; break; default: MACE_CHECK(false, "Unsupported padding type: ", padding); } MACE_CHECK(expected_input_height == in_height, expected_input_height, "!=", in_height); MACE_CHECK(expected_input_width == in_width, expected_input_width, "!=", in_width); const int p_h = static_cast<int>(out_height + filter_h - 1 - extended_input_height); const int p_w = static_cast<int>(out_width + filter_w - 1 - extended_input_width); padding_size[0] = std::max<int>(0, p_h); padding_size[1] = std::max<int>(0, p_w); } const int strides_; // [stride_h, stride_w] const Padding padding_type_; std::vector<int> paddings_; std::vector<index_t> output_shape_; const ActivationType activation_; const float relux_max_limit_; const bool from_caffe_; }; template <DeviceType D, typename T> struct Deconv2dFunctor : Deconv2dFunctorBase { Deconv2dFunctor(const int strides, const Padding &padding_type, const std::vector<int> &paddings, const std::vector<index_t> &output_shape, const ActivationType activation, const float relux_max_limit, const bool from_caffe) : Deconv2dFunctorBase(strides, padding_type, paddings, output_shape, activation, relux_max_limit, from_caffe) {} MaceStatus operator()(const Tensor input, // NCHW const Tensor filter, // OIHW const Tensor bias, const Tensor output_shape_tensor, Tensor output, StatsFuture future) { MACE_UNUSED(future); MACE_CHECK_NOTNULL(input); MACE_CHECK_NOTNULL(filter); MACE_CHECK_NOTNULL(output); if (!from_caffe_) { // tensorflow std::vector<index_t> output_shape(4); if (output_shape_.size() == 4) { output_shape[0] = output_shape_[0]; output_shape[1] = output_shape_[3]; output_shape[2] = output_shape_[1]; output_shape[3] = output_shape_[2]; } else { MACE_CHECK_NOTNULL(output_shape_tensor); MACE_CHECK(output_shape_tensor->size() == 4); Tensor::MappingGuard output_shape_mapper(output_shape_tensor); auto output_shape_data = output_shape_tensor->data<int32_t>(); output_shape = std::vector<index_t>(output_shape_data, output_shape_data + 4); } paddings_.clear(); paddings_ = std::vector<int>(2, 0); CalcDeconvPaddingAndInputSize( input->shape().data(), filter->shape().data(), strides_, padding_type_, output_shape.data(), paddings_.data(), true); MACE_RETURN_IF_ERROR(output->Resize(output_shape)); } else { // caffe output_shape_.clear(); output_shape_ = std::vector<index_t>(4, 0); CalcDeconvOutputSize(input->shape().data(), filter->shape().data(), strides_, output_shape_.data(), paddings_.data(), true); MACE_RETURN_IF_ERROR(output->Resize(output_shape_)); } index_t kernel_h = filter->dim(2); index_t kernel_w = filter->dim(3); const index_t in_shape = input->shape().data(); const index_t out_shape = output->shape().data(); const index_t kernel_hw[2] = {kernel_h, kernel_w}; MACE_CHECK(filter->dim(0) == out_shape[1], filter->dim(0), " != ", out_shape[1]); MACE_CHECK(filter->dim(1) == in_shape[1], filter->dim(1), " != ", in_shape[1]); MACE_CHECK(in_shape[0] == out_shape[0], "Input/Output batch size mismatch"); Tensor::MappingGuard input_mapper(input); Tensor::MappingGuard filter_mapper(filter); Tensor::MappingGuard bias_mapper(bias); Tensor::MappingGuard output_mapper(output); auto input_data = input->data<T>(); auto filter_data = filter->data<T>(); auto bias_data = bias == nullptr ? nullptr : bias->data<T>(); auto output_data = output->mutable_data<T>(); int padding[2]; padding[0] = (paddings_[0] + 1) >> 1; padding[1] = (paddings_[1] + 1) >> 1; deconv::Deconv2dNCHW(input_data, filter_data, bias_data, in_shape, out_shape, kernel_hw, strides_, padding, output_data); DoActivation(output_data, output_data, output->size(), activation_, relux_max_limit_); return MACE_SUCCESS; } }; #ifdef MACE_ENABLE_OPENCL template <typename T> struct Deconv2dFunctor<DeviceType::GPU, T> : Deconv2dFunctorBase { Deconv2dFunctor(const int strides, const Padding &padding_type, const std::vector<int> &paddings, const std::vector<index_t> &output_shape, const ActivationType activation, const float relux_max_limit, const bool from_caffe) : Deconv2dFunctorBase(strides, padding_type, paddings, output_shape, activation, relux_max_limit, from_caffe) {} MaceStatus operator()(const Tensor input, const Tensor filter, const Tensor bias, const Tensor output_shape_tensor, Tensor output, StatsFuture *future); cl::Kernel kernel_; uint32_t kwg_size_; std::unique_ptr<BufferBase> kernel_error_; std::vector<index_t> input_shape_; }; #endif // MACE_ENABLE_OPENCL } // namespace kernels } // namespace mace #endif // MACE_KERNELS_DECONV_2D_H_
dds.c	/* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % DDDD DDDD SSSSS % % D D D D SS % % D D D D SSS % % D D D D SS % % DDDD DDDD SSSSS % % % % % % Read/Write Microsoft Direct Draw Surface Image Format % % % % Software Design % % Bianca van Schaik % % March 2008 % % Dirk Lemstra % % September 2013 % % % % % % Copyright 1999-2021 ImageMagick Studio LLC, a non-profit organization % % dedicated to making software imaging solutions freely available. % % % % You may not use this file except in compliance with the License. You may % % obtain a copy of the License at % % % % https://imagemagick.org/script/license.php % % % % Unless required by applicable law or agreed to in writing, software % % distributed under the License is distributed on an "AS IS" BASIS, % % WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. % % See the License for the specific language governing permissions and % % limitations under the License. % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % / / Include declarations. / #include "MagickCore/studio.h" #include "MagickCore/attribute.h" #include "MagickCore/blob.h" #include "MagickCore/blob-private.h" #include "MagickCore/cache.h" #include "MagickCore/colorspace.h" #include "MagickCore/colorspace-private.h" #include "MagickCore/exception.h" #include "MagickCore/exception-private.h" #include "MagickCore/image.h" #include "MagickCore/image-private.h" #include "MagickCore/list.h" #include "MagickCore/log.h" #include "MagickCore/magick.h" #include "MagickCore/memory_.h" #include "MagickCore/monitor.h" #include "MagickCore/monitor-private.h" #include "MagickCore/option.h" #include "MagickCore/pixel-accessor.h" #include "MagickCore/profile.h" #include "MagickCore/quantum.h" #include "MagickCore/quantum-private.h" #include "MagickCore/resource_.h" #include "MagickCore/static.h" #include "MagickCore/string_.h" #include "MagickCore/string-private.h" #include "MagickCore/module.h" #include "MagickCore/transform.h" / Definitions / #define DDSD_CAPS 0x00000001 #define DDSD_HEIGHT 0x00000002 #define DDSD_WIDTH 0x00000004 #define DDSD_PITCH 0x00000008 #define DDSD_PIXELFORMAT 0x00001000 #define DDSD_MIPMAPCOUNT 0x00020000 #define DDSD_LINEARSIZE 0x00080000 #define DDSD_DEPTH 0x00800000 #define DDPF_ALPHAPIXELS 0x00000001 #define DDPF_FOURCC 0x00000004 #define DDPF_RGB 0x00000040 #define DDPF_LUMINANCE 0x00020000 #define FOURCC_DXT1 0x31545844 #define FOURCC_DXT3 0x33545844 #define FOURCC_DXT5 0x35545844 #define FOURCC_DX10 0x30315844 #define DDSCAPS_COMPLEX 0x00000008 #define DDSCAPS_TEXTURE 0x00001000 #define DDSCAPS_MIPMAP 0x00400000 #define DDSCAPS2_CUBEMAP 0x00000200 #define DDSCAPS2_CUBEMAP_POSITIVEX 0x00000400 #define DDSCAPS2_CUBEMAP_NEGATIVEX 0x00000800 #define DDSCAPS2_CUBEMAP_POSITIVEY 0x00001000 #define DDSCAPS2_CUBEMAP_NEGATIVEY 0x00002000 #define DDSCAPS2_CUBEMAP_POSITIVEZ 0x00004000 #define DDSCAPS2_CUBEMAP_NEGATIVEZ 0x00008000 #define DDSCAPS2_VOLUME 0x00200000 #define DDSEXT_DIMENSION_TEX2D 0x00000003 #define DDSEXTFLAGS_CUBEMAP 0x00000004 typedef enum DXGI_FORMAT { DXGI_FORMAT_UNKNOWN, DXGI_FORMAT_R32G32B32A32_TYPELESS, DXGI_FORMAT_R32G32B32A32_FLOAT, DXGI_FORMAT_R32G32B32A32_UINT, DXGI_FORMAT_R32G32B32A32_SINT, DXGI_FORMAT_R32G32B32_TYPELESS, DXGI_FORMAT_R32G32B32_FLOAT, DXGI_FORMAT_R32G32B32_UINT, DXGI_FORMAT_R32G32B32_SINT, DXGI_FORMAT_R16G16B16A16_TYPELESS, DXGI_FORMAT_R16G16B16A16_FLOAT, DXGI_FORMAT_R16G16B16A16_UNORM, DXGI_FORMAT_R16G16B16A16_UINT, DXGI_FORMAT_R16G16B16A16_SNORM, DXGI_FORMAT_R16G16B16A16_SINT, DXGI_FORMAT_R32G32_TYPELESS, DXGI_FORMAT_R32G32_FLOAT, DXGI_FORMAT_R32G32_UINT, DXGI_FORMAT_R32G32_SINT, DXGI_FORMAT_R32G8X24_TYPELESS, DXGI_FORMAT_D32_FLOAT_S8X24_UINT, DXGI_FORMAT_R32_FLOAT_X8X24_TYPELESS, DXGI_FORMAT_X32_TYPELESS_G8X24_UINT, DXGI_FORMAT_R10G10B10A2_TYPELESS, DXGI_FORMAT_R10G10B10A2_UNORM, DXGI_FORMAT_R10G10B10A2_UINT, DXGI_FORMAT_R11G11B10_FLOAT, DXGI_FORMAT_R8G8B8A8_TYPELESS, DXGI_FORMAT_R8G8B8A8_UNORM, DXGI_FORMAT_R8G8B8A8_UNORM_SRGB, DXGI_FORMAT_R8G8B8A8_UINT, DXGI_FORMAT_R8G8B8A8_SNORM, DXGI_FORMAT_R8G8B8A8_SINT, DXGI_FORMAT_R16G16_TYPELESS, DXGI_FORMAT_R16G16_FLOAT, DXGI_FORMAT_R16G16_UNORM, DXGI_FORMAT_R16G16_UINT, DXGI_FORMAT_R16G16_SNORM, DXGI_FORMAT_R16G16_SINT, DXGI_FORMAT_R32_TYPELESS, DXGI_FORMAT_D32_FLOAT, DXGI_FORMAT_R32_FLOAT, DXGI_FORMAT_R32_UINT, DXGI_FORMAT_R32_SINT, DXGI_FORMAT_R24G8_TYPELESS, DXGI_FORMAT_D24_UNORM_S8_UINT, DXGI_FORMAT_R24_UNORM_X8_TYPELESS, DXGI_FORMAT_X24_TYPELESS_G8_UINT, DXGI_FORMAT_R8G8_TYPELESS, DXGI_FORMAT_R8G8_UNORM, DXGI_FORMAT_R8G8_UINT, DXGI_FORMAT_R8G8_SNORM, DXGI_FORMAT_R8G8_SINT, DXGI_FORMAT_R16_TYPELESS, DXGI_FORMAT_R16_FLOAT, DXGI_FORMAT_D16_UNORM, DXGI_FORMAT_R16_UNORM, DXGI_FORMAT_R16_UINT, DXGI_FORMAT_R16_SNORM, DXGI_FORMAT_R16_SINT, DXGI_FORMAT_R8_TYPELESS, DXGI_FORMAT_R8_UNORM, DXGI_FORMAT_R8_UINT, DXGI_FORMAT_R8_SNORM, DXGI_FORMAT_R8_SINT, DXGI_FORMAT_A8_UNORM, DXGI_FORMAT_R1_UNORM, DXGI_FORMAT_R9G9B9E5_SHAREDEXP, DXGI_FORMAT_R8G8_B8G8_UNORM, DXGI_FORMAT_G8R8_G8B8_UNORM, DXGI_FORMAT_BC1_TYPELESS, DXGI_FORMAT_BC1_UNORM, DXGI_FORMAT_BC1_UNORM_SRGB, DXGI_FORMAT_BC2_TYPELESS, DXGI_FORMAT_BC2_UNORM, DXGI_FORMAT_BC2_UNORM_SRGB, DXGI_FORMAT_BC3_TYPELESS, DXGI_FORMAT_BC3_UNORM, DXGI_FORMAT_BC3_UNORM_SRGB, DXGI_FORMAT_BC4_TYPELESS, DXGI_FORMAT_BC4_UNORM, DXGI_FORMAT_BC4_SNORM, DXGI_FORMAT_BC5_TYPELESS, DXGI_FORMAT_BC5_UNORM, DXGI_FORMAT_BC5_SNORM, DXGI_FORMAT_B5G6R5_UNORM, DXGI_FORMAT_B5G5R5A1_UNORM, DXGI_FORMAT_B8G8R8A8_UNORM, DXGI_FORMAT_B8G8R8X8_UNORM, DXGI_FORMAT_R10G10B10_XR_BIAS_A2_UNORM, DXGI_FORMAT_B8G8R8A8_TYPELESS, DXGI_FORMAT_B8G8R8A8_UNORM_SRGB, DXGI_FORMAT_B8G8R8X8_TYPELESS, DXGI_FORMAT_B8G8R8X8_UNORM_SRGB, DXGI_FORMAT_BC6H_TYPELESS, DXGI_FORMAT_BC6H_UF16, DXGI_FORMAT_BC6H_SF16, DXGI_FORMAT_BC7_TYPELESS, DXGI_FORMAT_BC7_UNORM, DXGI_FORMAT_BC7_UNORM_SRGB, DXGI_FORMAT_AYUV, DXGI_FORMAT_Y410, DXGI_FORMAT_Y416, DXGI_FORMAT_NV12, DXGI_FORMAT_P010, DXGI_FORMAT_P016, DXGI_FORMAT_420_OPAQUE, DXGI_FORMAT_YUY2, DXGI_FORMAT_Y210, DXGI_FORMAT_Y216, DXGI_FORMAT_NV11, DXGI_FORMAT_AI44, DXGI_FORMAT_IA44, DXGI_FORMAT_P8, DXGI_FORMAT_A8P8, DXGI_FORMAT_B4G4R4A4_UNORM, DXGI_FORMAT_P208, DXGI_FORMAT_V208, DXGI_FORMAT_V408, DXGI_FORMAT_SAMPLER_FEEDBACK_MIN_MIP_OPAQUE, DXGI_FORMAT_SAMPLER_FEEDBACK_MIP_REGION_USED_OPAQUE, DXGI_FORMAT_FORCE_UINT } DXGI_FORMAT; #ifndef SIZE_MAX #define SIZE_MAX ((size_t) -1) #endif / Structure declarations. / typedef struct _DDSPixelFormat { size_t flags, fourcc, rgb_bitcount, r_bitmask, g_bitmask, b_bitmask, alpha_bitmask; } DDSPixelFormat; typedef struct _DDSInfo { size_t flags, height, width, pitchOrLinearSize, depth, mipmapcount, ddscaps1, ddscaps2, extFormat, extDimension, extFlags, extArraySize, extFlags2; DDSPixelFormat pixelformat; } DDSInfo; typedef struct _DDSColors { unsigned char r[4], g[4], b[4], a[4]; } DDSColors; typedef struct _BC7Colors { unsigned char r[6], g[6], b[6], a[6]; } BC7Colors; typedef struct _DDSVector4 { float x, y, z, w; } DDSVector4; typedef struct _DDSVector3 { float x, y, z; } DDSVector3; typedef struct _DDSSourceBlock { unsigned char start, end, error; } DDSSourceBlock; typedef struct _DDSSingleColorLookup { DDSSourceBlock sources[2]; } DDSSingleColorLookup; typedef struct _BC7ModeInfo { unsigned char partition_bits, num_subsets, color_precision, alpha_precision, num_pbits, index_precision, index2_precision; } BC7ModeInfo; typedef MagickBooleanType DDSDecoder(const ImageInfo ,Image ,const DDSInfo ,const MagickBooleanType, ExceptionInfo ); typedef MagickBooleanType DDSPixelDecoder(Image ,const DDSInfo ,ExceptionInfo ); static const DDSSingleColorLookup DDSLookup_5_4[] = { { { { 0, 0, 0 }, { 0, 0, 0 } } }, { { { 0, 0, 1 }, { 0, 1, 1 } } }, { { { 0, 0, 2 }, { 0, 1, 0 } } }, { { { 0, 0, 3 }, { 0, 1, 1 } } }, { { { 0, 0, 4 }, { 0, 2, 1 } } }, { { { 1, 0, 3 }, { 0, 2, 0 } } }, { { { 1, 0, 2 }, { 0, 2, 1 } } }, { { { 1, 0, 1 }, { 0, 3, 1 } } }, { { { 1, 0, 0 }, { 0, 3, 0 } } }, { { { 1, 0, 1 }, { 1, 2, 1 } } }, { { { 1, 0, 2 }, { 1, 2, 0 } } }, { { { 1, 0, 3 }, { 0, 4, 0 } } }, { { { 1, 0, 4 }, { 0, 5, 1 } } }, { { { 2, 0, 3 }, { 0, 5, 0 } } }, { { { 2, 0, 2 }, { 0, 5, 1 } } }, { { { 2, 0, 1 }, { 0, 6, 1 } } }, { { { 2, 0, 0 }, { 0, 6, 0 } } }, { { { 2, 0, 1 }, { 2, 3, 1 } } }, { { { 2, 0, 2 }, { 2, 3, 0 } } }, { { { 2, 0, 3 }, { 0, 7, 0 } } }, { { { 2, 0, 4 }, { 1, 6, 1 } } }, { { { 3, 0, 3 }, { 1, 6, 0 } } }, { { { 3, 0, 2 }, { 0, 8, 0 } } }, { { { 3, 0, 1 }, { 0, 9, 1 } } }, { { { 3, 0, 0 }, { 0, 9, 0 } } }, { { { 3, 0, 1 }, { 0, 9, 1 } } }, { { { 3, 0, 2 }, { 0, 10, 1 } } }, { { { 3, 0, 3 }, { 0, 10, 0 } } }, { { { 3, 0, 4 }, { 2, 7, 1 } } }, { { { 4, 0, 4 }, { 2, 7, 0 } } }, { { { 4, 0, 3 }, { 0, 11, 0 } } }, { { { 4, 0, 2 }, { 1, 10, 1 } } }, { { { 4, 0, 1 }, { 1, 10, 0 } } }, { { { 4, 0, 0 }, { 0, 12, 0 } } }, { { { 4, 0, 1 }, { 0, 13, 1 } } }, { { { 4, 0, 2 }, { 0, 13, 0 } } }, { { { 4, 0, 3 }, { 0, 13, 1 } } }, { { { 4, 0, 4 }, { 0, 14, 1 } } }, { { { 5, 0, 3 }, { 0, 14, 0 } } }, { { { 5, 0, 2 }, { 2, 11, 1 } } }, { { { 5, 0, 1 }, { 2, 11, 0 } } }, { { { 5, 0, 0 }, { 0, 15, 0 } } }, { { { 5, 0, 1 }, { 1, 14, 1 } } }, { { { 5, 0, 2 }, { 1, 14, 0 } } }, { { { 5, 0, 3 }, { 0, 16, 0 } } }, { { { 5, 0, 4 }, { 0, 17, 1 } } }, { { { 6, 0, 3 }, { 0, 17, 0 } } }, { { { 6, 0, 2 }, { 0, 17, 1 } } }, { { { 6, 0, 1 }, { 0, 18, 1 } } }, { { { 6, 0, 0 }, { 0, 18, 0 } } }, { { { 6, 0, 1 }, { 2, 15, 1 } } }, { { { 6, 0, 2 }, { 2, 15, 0 } } }, { { { 6, 0, 3 }, { 0, 19, 0 } } }, { { { 6, 0, 4 }, { 1, 18, 1 } } }, { { { 7, 0, 3 }, { 1, 18, 0 } } }, { { { 7, 0, 2 }, { 0, 20, 0 } } }, { { { 7, 0, 1 }, { 0, 21, 1 } } }, { { { 7, 0, 0 }, { 0, 21, 0 } } }, { { { 7, 0, 1 }, { 0, 21, 1 } } }, { { { 7, 0, 2 }, { 0, 22, 1 } } }, { { { 7, 0, 3 }, { 0, 22, 0 } } }, { { { 7, 0, 4 }, { 2, 19, 1 } } }, { { { 8, 0, 4 }, { 2, 19, 0 } } }, { { { 8, 0, 3 }, { 0, 23, 0 } } }, { { { 8, 0, 2 }, { 1, 22, 1 } } }, { { { 8, 0, 1 }, { 1, 22, 0 } } }, { { { 8, 0, 0 }, { 0, 24, 0 } } }, { { { 8, 0, 1 }, { 0, 25, 1 } } }, { { { 8, 0, 2 }, { 0, 25, 0 } } }, { { { 8, 0, 3 }, { 0, 25, 1 } } }, { { { 8, 0, 4 }, { 0, 26, 1 } } }, { { { 9, 0, 3 }, { 0, 26, 0 } } }, { { { 9, 0, 2 }, { 2, 23, 1 } } }, { { { 9, 0, 1 }, { 2, 23, 0 } } }, { { { 9, 0, 0 }, { 0, 27, 0 } } }, { { { 9, 0, 1 }, { 1, 26, 1 } } }, { { { 9, 0, 2 }, { 1, 26, 0 } } }, { { { 9, 0, 3 }, { 0, 28, 0 } } }, { { { 9, 0, 4 }, { 0, 29, 1 } } }, { { { 10, 0, 3 }, { 0, 29, 0 } } }, { { { 10, 0, 2 }, { 0, 29, 1 } } }, { { { 10, 0, 1 }, { 0, 30, 1 } } }, { { { 10, 0, 0 }, { 0, 30, 0 } } }, { { { 10, 0, 1 }, { 2, 27, 1 } } }, { { { 10, 0, 2 }, { 2, 27, 0 } } }, { { { 10, 0, 3 }, { 0, 31, 0 } } }, { { { 10, 0, 4 }, { 1, 30, 1 } } }, { { { 11, 0, 3 }, { 1, 30, 0 } } }, { { { 11, 0, 2 }, { 4, 24, 0 } } }, { { { 11, 0, 1 }, { 1, 31, 1 } } }, { { { 11, 0, 0 }, { 1, 31, 0 } } }, { { { 11, 0, 1 }, { 1, 31, 1 } } }, { { { 11, 0, 2 }, { 2, 30, 1 } } }, { { { 11, 0, 3 }, { 2, 30, 0 } } }, { { { 11, 0, 4 }, { 2, 31, 1 } } }, { { { 12, 0, 4 }, { 2, 31, 0 } } }, { { { 12, 0, 3 }, { 4, 27, 0 } } }, { { { 12, 0, 2 }, { 3, 30, 1 } } }, { { { 12, 0, 1 }, { 3, 30, 0 } } }, { { { 12, 0, 0 }, { 4, 28, 0 } } }, { { { 12, 0, 1 }, { 3, 31, 1 } } }, { { { 12, 0, 2 }, { 3, 31, 0 } } }, { { { 12, 0, 3 }, { 3, 31, 1 } } }, { { { 12, 0, 4 }, { 4, 30, 1 } } }, { { { 13, 0, 3 }, { 4, 30, 0 } } }, { { { 13, 0, 2 }, { 6, 27, 1 } } }, { { { 13, 0, 1 }, { 6, 27, 0 } } }, { { { 13, 0, 0 }, { 4, 31, 0 } } }, { { { 13, 0, 1 }, { 5, 30, 1 } } }, { { { 13, 0, 2 }, { 5, 30, 0 } } }, { { { 13, 0, 3 }, { 8, 24, 0 } } }, { { { 13, 0, 4 }, { 5, 31, 1 } } }, { { { 14, 0, 3 }, { 5, 31, 0 } } }, { { { 14, 0, 2 }, { 5, 31, 1 } } }, { { { 14, 0, 1 }, { 6, 30, 1 } } }, { { { 14, 0, 0 }, { 6, 30, 0 } } }, { { { 14, 0, 1 }, { 6, 31, 1 } } }, { { { 14, 0, 2 }, { 6, 31, 0 } } }, { { { 14, 0, 3 }, { 8, 27, 0 } } }, { { { 14, 0, 4 }, { 7, 30, 1 } } }, { { { 15, 0, 3 }, { 7, 30, 0 } } }, { { { 15, 0, 2 }, { 8, 28, 0 } } }, { { { 15, 0, 1 }, { 7, 31, 1 } } }, { { { 15, 0, 0 }, { 7, 31, 0 } } }, { { { 15, 0, 1 }, { 7, 31, 1 } } }, { { { 15, 0, 2 }, { 8, 30, 1 } } }, { { { 15, 0, 3 }, { 8, 30, 0 } } }, { { { 15, 0, 4 }, { 10, 27, 1 } } }, { { { 16, 0, 4 }, { 10, 27, 0 } } }, { { { 16, 0, 3 }, { 8, 31, 0 } } }, { { { 16, 0, 2 }, { 9, 30, 1 } } }, { { { 16, 0, 1 }, { 9, 30, 0 } } }, { { { 16, 0, 0 }, { 12, 24, 0 } } }, { { { 16, 0, 1 }, { 9, 31, 1 } } }, { { { 16, 0, 2 }, { 9, 31, 0 } } }, { { { 16, 0, 3 }, { 9, 31, 1 } } }, { { { 16, 0, 4 }, { 10, 30, 1 } } }, { { { 17, 0, 3 }, { 10, 30, 0 } } }, { { { 17, 0, 2 }, { 10, 31, 1 } } }, { { { 17, 0, 1 }, { 10, 31, 0 } } }, { { { 17, 0, 0 }, { 12, 27, 0 } } }, { { { 17, 0, 1 }, { 11, 30, 1 } } }, { { { 17, 0, 2 }, { 11, 30, 0 } } }, { { { 17, 0, 3 }, { 12, 28, 0 } } }, { { { 17, 0, 4 }, { 11, 31, 1 } } }, { { { 18, 0, 3 }, { 11, 31, 0 } } }, { { { 18, 0, 2 }, { 11, 31, 1 } } }, { { { 18, 0, 1 }, { 12, 30, 1 } } }, { { { 18, 0, 0 }, { 12, 30, 0 } } }, { { { 18, 0, 1 }, { 14, 27, 1 } } }, { { { 18, 0, 2 }, { 14, 27, 0 } } }, { { { 18, 0, 3 }, { 12, 31, 0 } } }, { { { 18, 0, 4 }, { 13, 30, 1 } } }, { { { 19, 0, 3 }, { 13, 30, 0 } } }, { { { 19, 0, 2 }, { 16, 24, 0 } } }, { { { 19, 0, 1 }, { 13, 31, 1 } } }, { { { 19, 0, 0 }, { 13, 31, 0 } } }, { { { 19, 0, 1 }, { 13, 31, 1 } } }, { { { 19, 0, 2 }, { 14, 30, 1 } } }, { { { 19, 0, 3 }, { 14, 30, 0 } } }, { { { 19, 0, 4 }, { 14, 31, 1 } } }, { { { 20, 0, 4 }, { 14, 31, 0 } } }, { { { 20, 0, 3 }, { 16, 27, 0 } } }, { { { 20, 0, 2 }, { 15, 30, 1 } } }, { { { 20, 0, 1 }, { 15, 30, 0 } } }, { { { 20, 0, 0 }, { 16, 28, 0 } } }, { { { 20, 0, 1 }, { 15, 31, 1 } } }, { { { 20, 0, 2 }, { 15, 31, 0 } } }, { { { 20, 0, 3 }, { 15, 31, 1 } } }, { { { 20, 0, 4 }, { 16, 30, 1 } } }, { { { 21, 0, 3 }, { 16, 30, 0 } } }, { { { 21, 0, 2 }, { 18, 27, 1 } } }, { { { 21, 0, 1 }, { 18, 27, 0 } } }, { { { 21, 0, 0 }, { 16, 31, 0 } } }, { { { 21, 0, 1 }, { 17, 30, 1 } } }, { { { 21, 0, 2 }, { 17, 30, 0 } } }, { { { 21, 0, 3 }, { 20, 24, 0 } } }, { { { 21, 0, 4 }, { 17, 31, 1 } } }, { { { 22, 0, 3 }, { 17, 31, 0 } } }, { { { 22, 0, 2 }, { 17, 31, 1 } } }, { { { 22, 0, 1 }, { 18, 30, 1 } } }, { { { 22, 0, 0 }, { 18, 30, 0 } } }, { { { 22, 0, 1 }, { 18, 31, 1 } } }, { { { 22, 0, 2 }, { 18, 31, 0 } } }, { { { 22, 0, 3 }, { 20, 27, 0 } } }, { { { 22, 0, 4 }, { 19, 30, 1 } } }, { { { 23, 0, 3 }, { 19, 30, 0 } } }, { { { 23, 0, 2 }, { 20, 28, 0 } } }, { { { 23, 0, 1 }, { 19, 31, 1 } } }, { { { 23, 0, 0 }, { 19, 31, 0 } } }, { { { 23, 0, 1 }, { 19, 31, 1 } } }, { { { 23, 0, 2 }, { 20, 30, 1 } } }, { { { 23, 0, 3 }, { 20, 30, 0 } } }, { { { 23, 0, 4 }, { 22, 27, 1 } } }, { { { 24, 0, 4 }, { 22, 27, 0 } } }, { { { 24, 0, 3 }, { 20, 31, 0 } } }, { { { 24, 0, 2 }, { 21, 30, 1 } } }, { { { 24, 0, 1 }, { 21, 30, 0 } } }, { { { 24, 0, 0 }, { 24, 24, 0 } } }, { { { 24, 0, 1 }, { 21, 31, 1 } } }, { { { 24, 0, 2 }, { 21, 31, 0 } } }, { { { 24, 0, 3 }, { 21, 31, 1 } } }, { { { 24, 0, 4 }, { 22, 30, 1 } } }, { { { 25, 0, 3 }, { 22, 30, 0 } } }, { { { 25, 0, 2 }, { 22, 31, 1 } } }, { { { 25, 0, 1 }, { 22, 31, 0 } } }, { { { 25, 0, 0 }, { 24, 27, 0 } } }, { { { 25, 0, 1 }, { 23, 30, 1 } } }, { { { 25, 0, 2 }, { 23, 30, 0 } } }, { { { 25, 0, 3 }, { 24, 28, 0 } } }, { { { 25, 0, 4 }, { 23, 31, 1 } } }, { { { 26, 0, 3 }, { 23, 31, 0 } } }, { { { 26, 0, 2 }, { 23, 31, 1 } } }, { { { 26, 0, 1 }, { 24, 30, 1 } } }, { { { 26, 0, 0 }, { 24, 30, 0 } } }, { { { 26, 0, 1 }, { 26, 27, 1 } } }, { { { 26, 0, 2 }, { 26, 27, 0 } } }, { { { 26, 0, 3 }, { 24, 31, 0 } } }, { { { 26, 0, 4 }, { 25, 30, 1 } } }, { { { 27, 0, 3 }, { 25, 30, 0 } } }, { { { 27, 0, 2 }, { 28, 24, 0 } } }, { { { 27, 0, 1 }, { 25, 31, 1 } } }, { { { 27, 0, 0 }, { 25, 31, 0 } } }, { { { 27, 0, 1 }, { 25, 31, 1 } } }, { { { 27, 0, 2 }, { 26, 30, 1 } } }, { { { 27, 0, 3 }, { 26, 30, 0 } } }, { { { 27, 0, 4 }, { 26, 31, 1 } } }, { { { 28, 0, 4 }, { 26, 31, 0 } } }, { { { 28, 0, 3 }, { 28, 27, 0 } } }, { { { 28, 0, 2 }, { 27, 30, 1 } } }, { { { 28, 0, 1 }, { 27, 30, 0 } } }, { { { 28, 0, 0 }, { 28, 28, 0 } } }, { { { 28, 0, 1 }, { 27, 31, 1 } } }, { { { 28, 0, 2 }, { 27, 31, 0 } } }, { { { 28, 0, 3 }, { 27, 31, 1 } } }, { { { 28, 0, 4 }, { 28, 30, 1 } } }, { { { 29, 0, 3 }, { 28, 30, 0 } } }, { { { 29, 0, 2 }, { 30, 27, 1 } } }, { { { 29, 0, 1 }, { 30, 27, 0 } } }, { { { 29, 0, 0 }, { 28, 31, 0 } } }, { { { 29, 0, 1 }, { 29, 30, 1 } } }, { { { 29, 0, 2 }, { 29, 30, 0 } } }, { { { 29, 0, 3 }, { 29, 30, 1 } } }, { { { 29, 0, 4 }, { 29, 31, 1 } } }, { { { 30, 0, 3 }, { 29, 31, 0 } } }, { { { 30, 0, 2 }, { 29, 31, 1 } } }, { { { 30, 0, 1 }, { 30, 30, 1 } } }, { { { 30, 0, 0 }, { 30, 30, 0 } } }, { { { 30, 0, 1 }, { 30, 31, 1 } } }, { { { 30, 0, 2 }, { 30, 31, 0 } } }, { { { 30, 0, 3 }, { 30, 31, 1 } } }, { { { 30, 0, 4 }, { 31, 30, 1 } } }, { { { 31, 0, 3 }, { 31, 30, 0 } } }, { { { 31, 0, 2 }, { 31, 30, 1 } } }, { { { 31, 0, 1 }, { 31, 31, 1 } } }, { { { 31, 0, 0 }, { 31, 31, 0 } } } }; static const DDSSingleColorLookup DDSLookup_6_4[] = { { { { 0, 0, 0 }, { 0, 0, 0 } } }, { { { 0, 0, 1 }, { 0, 1, 0 } } }, { { { 0, 0, 2 }, { 0, 2, 0 } } }, { { { 1, 0, 1 }, { 0, 3, 1 } } }, { { { 1, 0, 0 }, { 0, 3, 0 } } }, { { { 1, 0, 1 }, { 0, 4, 0 } } }, { { { 1, 0, 2 }, { 0, 5, 0 } } }, { { { 2, 0, 1 }, { 0, 6, 1 } } }, { { { 2, 0, 0 }, { 0, 6, 0 } } }, { { { 2, 0, 1 }, { 0, 7, 0 } } }, { { { 2, 0, 2 }, { 0, 8, 0 } } }, { { { 3, 0, 1 }, { 0, 9, 1 } } }, { { { 3, 0, 0 }, { 0, 9, 0 } } }, { { { 3, 0, 1 }, { 0, 10, 0 } } }, { { { 3, 0, 2 }, { 0, 11, 0 } } }, { { { 4, 0, 1 }, { 0, 12, 1 } } }, { { { 4, 0, 0 }, { 0, 12, 0 } } }, { { { 4, 0, 1 }, { 0, 13, 0 } } }, { { { 4, 0, 2 }, { 0, 14, 0 } } }, { { { 5, 0, 1 }, { 0, 15, 1 } } }, { { { 5, 0, 0 }, { 0, 15, 0 } } }, { { { 5, 0, 1 }, { 0, 16, 0 } } }, { { { 5, 0, 2 }, { 1, 15, 0 } } }, { { { 6, 0, 1 }, { 0, 17, 0 } } }, { { { 6, 0, 0 }, { 0, 18, 0 } } }, { { { 6, 0, 1 }, { 0, 19, 0 } } }, { { { 6, 0, 2 }, { 3, 14, 0 } } }, { { { 7, 0, 1 }, { 0, 20, 0 } } }, { { { 7, 0, 0 }, { 0, 21, 0 } } }, { { { 7, 0, 1 }, { 0, 22, 0 } } }, { { { 7, 0, 2 }, { 4, 15, 0 } } }, { { { 8, 0, 1 }, { 0, 23, 0 } } }, { { { 8, 0, 0 }, { 0, 24, 0 } } }, { { { 8, 0, 1 }, { 0, 25, 0 } } }, { { { 8, 0, 2 }, { 6, 14, 0 } } }, { { { 9, 0, 1 }, { 0, 26, 0 } } }, { { { 9, 0, 0 }, { 0, 27, 0 } } }, { { { 9, 0, 1 }, { 0, 28, 0 } } }, { { { 9, 0, 2 }, { 7, 15, 0 } } }, { { { 10, 0, 1 }, { 0, 29, 0 } } }, { { { 10, 0, 0 }, { 0, 30, 0 } } }, { { { 10, 0, 1 }, { 0, 31, 0 } } }, { { { 10, 0, 2 }, { 9, 14, 0 } } }, { { { 11, 0, 1 }, { 0, 32, 0 } } }, { { { 11, 0, 0 }, { 0, 33, 0 } } }, { { { 11, 0, 1 }, { 2, 30, 0 } } }, { { { 11, 0, 2 }, { 0, 34, 0 } } }, { { { 12, 0, 1 }, { 0, 35, 0 } } }, { { { 12, 0, 0 }, { 0, 36, 0 } } }, { { { 12, 0, 1 }, { 3, 31, 0 } } }, { { { 12, 0, 2 }, { 0, 37, 0 } } }, { { { 13, 0, 1 }, { 0, 38, 0 } } }, { { { 13, 0, 0 }, { 0, 39, 0 } } }, { { { 13, 0, 1 }, { 5, 30, 0 } } }, { { { 13, 0, 2 }, { 0, 40, 0 } } }, { { { 14, 0, 1 }, { 0, 41, 0 } } }, { { { 14, 0, 0 }, { 0, 42, 0 } } }, { { { 14, 0, 1 }, { 6, 31, 0 } } }, { { { 14, 0, 2 }, { 0, 43, 0 } } }, { { { 15, 0, 1 }, { 0, 44, 0 } } }, { { { 15, 0, 0 }, { 0, 45, 0 } } }, { { { 15, 0, 1 }, { 8, 30, 0 } } }, { { { 15, 0, 2 }, { 0, 46, 0 } } }, { { { 16, 0, 2 }, { 0, 47, 0 } } }, { { { 16, 0, 1 }, { 1, 46, 0 } } }, { { { 16, 0, 0 }, { 0, 48, 0 } } }, { { { 16, 0, 1 }, { 0, 49, 0 } } }, { { { 16, 0, 2 }, { 0, 50, 0 } } }, { { { 17, 0, 1 }, { 2, 47, 0 } } }, { { { 17, 0, 0 }, { 0, 51, 0 } } }, { { { 17, 0, 1 }, { 0, 52, 0 } } }, { { { 17, 0, 2 }, { 0, 53, 0 } } }, { { { 18, 0, 1 }, { 4, 46, 0 } } }, { { { 18, 0, 0 }, { 0, 54, 0 } } }, { { { 18, 0, 1 }, { 0, 55, 0 } } }, { { { 18, 0, 2 }, { 0, 56, 0 } } }, { { { 19, 0, 1 }, { 5, 47, 0 } } }, { { { 19, 0, 0 }, { 0, 57, 0 } } }, { { { 19, 0, 1 }, { 0, 58, 0 } } }, { { { 19, 0, 2 }, { 0, 59, 0 } } }, { { { 20, 0, 1 }, { 7, 46, 0 } } }, { { { 20, 0, 0 }, { 0, 60, 0 } } }, { { { 20, 0, 1 }, { 0, 61, 0 } } }, { { { 20, 0, 2 }, { 0, 62, 0 } } }, { { { 21, 0, 1 }, { 8, 47, 0 } } }, { { { 21, 0, 0 }, { 0, 63, 0 } } }, { { { 21, 0, 1 }, { 1, 62, 0 } } }, { { { 21, 0, 2 }, { 1, 63, 0 } } }, { { { 22, 0, 1 }, { 10, 46, 0 } } }, { { { 22, 0, 0 }, { 2, 62, 0 } } }, { { { 22, 0, 1 }, { 2, 63, 0 } } }, { { { 22, 0, 2 }, { 3, 62, 0 } } }, { { { 23, 0, 1 }, { 11, 47, 0 } } }, { { { 23, 0, 0 }, { 3, 63, 0 } } }, { { { 23, 0, 1 }, { 4, 62, 0 } } }, { { { 23, 0, 2 }, { 4, 63, 0 } } }, { { { 24, 0, 1 }, { 13, 46, 0 } } }, { { { 24, 0, 0 }, { 5, 62, 0 } } }, { { { 24, 0, 1 }, { 5, 63, 0 } } }, { { { 24, 0, 2 }, { 6, 62, 0 } } }, { { { 25, 0, 1 }, { 14, 47, 0 } } }, { { { 25, 0, 0 }, { 6, 63, 0 } } }, { { { 25, 0, 1 }, { 7, 62, 0 } } }, { { { 25, 0, 2 }, { 7, 63, 0 } } }, { { { 26, 0, 1 }, { 16, 45, 0 } } }, { { { 26, 0, 0 }, { 8, 62, 0 } } }, { { { 26, 0, 1 }, { 8, 63, 0 } } }, { { { 26, 0, 2 }, { 9, 62, 0 } } }, { { { 27, 0, 1 }, { 16, 48, 0 } } }, { { { 27, 0, 0 }, { 9, 63, 0 } } }, { { { 27, 0, 1 }, { 10, 62, 0 } } }, { { { 27, 0, 2 }, { 10, 63, 0 } } }, { { { 28, 0, 1 }, { 16, 51, 0 } } }, { { { 28, 0, 0 }, { 11, 62, 0 } } }, { { { 28, 0, 1 }, { 11, 63, 0 } } }, { { { 28, 0, 2 }, { 12, 62, 0 } } }, { { { 29, 0, 1 }, { 16, 54, 0 } } }, { { { 29, 0, 0 }, { 12, 63, 0 } } }, { { { 29, 0, 1 }, { 13, 62, 0 } } }, { { { 29, 0, 2 }, { 13, 63, 0 } } }, { { { 30, 0, 1 }, { 16, 57, 0 } } }, { { { 30, 0, 0 }, { 14, 62, 0 } } }, { { { 30, 0, 1 }, { 14, 63, 0 } } }, { { { 30, 0, 2 }, { 15, 62, 0 } } }, { { { 31, 0, 1 }, { 16, 60, 0 } } }, { { { 31, 0, 0 }, { 15, 63, 0 } } }, { { { 31, 0, 1 }, { 24, 46, 0 } } }, { { { 31, 0, 2 }, { 16, 62, 0 } } }, { { { 32, 0, 2 }, { 16, 63, 0 } } }, { { { 32, 0, 1 }, { 17, 62, 0 } } }, { { { 32, 0, 0 }, { 25, 47, 0 } } }, { { { 32, 0, 1 }, { 17, 63, 0 } } }, { { { 32, 0, 2 }, { 18, 62, 0 } } }, { { { 33, 0, 1 }, { 18, 63, 0 } } }, { { { 33, 0, 0 }, { 27, 46, 0 } } }, { { { 33, 0, 1 }, { 19, 62, 0 } } }, { { { 33, 0, 2 }, { 19, 63, 0 } } }, { { { 34, 0, 1 }, { 20, 62, 0 } } }, { { { 34, 0, 0 }, { 28, 47, 0 } } }, { { { 34, 0, 1 }, { 20, 63, 0 } } }, { { { 34, 0, 2 }, { 21, 62, 0 } } }, { { { 35, 0, 1 }, { 21, 63, 0 } } }, { { { 35, 0, 0 }, { 30, 46, 0 } } }, { { { 35, 0, 1 }, { 22, 62, 0 } } }, { { { 35, 0, 2 }, { 22, 63, 0 } } }, { { { 36, 0, 1 }, { 23, 62, 0 } } }, { { { 36, 0, 0 }, { 31, 47, 0 } } }, { { { 36, 0, 1 }, { 23, 63, 0 } } }, { { { 36, 0, 2 }, { 24, 62, 0 } } }, { { { 37, 0, 1 }, { 24, 63, 0 } } }, { { { 37, 0, 0 }, { 32, 47, 0 } } }, { { { 37, 0, 1 }, { 25, 62, 0 } } }, { { { 37, 0, 2 }, { 25, 63, 0 } } }, { { { 38, 0, 1 }, { 26, 62, 0 } } }, { { { 38, 0, 0 }, { 32, 50, 0 } } }, { { { 38, 0, 1 }, { 26, 63, 0 } } }, { { { 38, 0, 2 }, { 27, 62, 0 } } }, { { { 39, 0, 1 }, { 27, 63, 0 } } }, { { { 39, 0, 0 }, { 32, 53, 0 } } }, { { { 39, 0, 1 }, { 28, 62, 0 } } }, { { { 39, 0, 2 }, { 28, 63, 0 } } }, { { { 40, 0, 1 }, { 29, 62, 0 } } }, { { { 40, 0, 0 }, { 32, 56, 0 } } }, { { { 40, 0, 1 }, { 29, 63, 0 } } }, { { { 40, 0, 2 }, { 30, 62, 0 } } }, { { { 41, 0, 1 }, { 30, 63, 0 } } }, { { { 41, 0, 0 }, { 32, 59, 0 } } }, { { { 41, 0, 1 }, { 31, 62, 0 } } }, { { { 41, 0, 2 }, { 31, 63, 0 } } }, { { { 42, 0, 1 }, { 32, 61, 0 } } }, { { { 42, 0, 0 }, { 32, 62, 0 } } }, { { { 42, 0, 1 }, { 32, 63, 0 } } }, { { { 42, 0, 2 }, { 41, 46, 0 } } }, { { { 43, 0, 1 }, { 33, 62, 0 } } }, { { { 43, 0, 0 }, { 33, 63, 0 } } }, { { { 43, 0, 1 }, { 34, 62, 0 } } }, { { { 43, 0, 2 }, { 42, 47, 0 } } }, { { { 44, 0, 1 }, { 34, 63, 0 } } }, { { { 44, 0, 0 }, { 35, 62, 0 } } }, { { { 44, 0, 1 }, { 35, 63, 0 } } }, { { { 44, 0, 2 }, { 44, 46, 0 } } }, { { { 45, 0, 1 }, { 36, 62, 0 } } }, { { { 45, 0, 0 }, { 36, 63, 0 } } }, { { { 45, 0, 1 }, { 37, 62, 0 } } }, { { { 45, 0, 2 }, { 45, 47, 0 } } }, { { { 46, 0, 1 }, { 37, 63, 0 } } }, { { { 46, 0, 0 }, { 38, 62, 0 } } }, { { { 46, 0, 1 }, { 38, 63, 0 } } }, { { { 46, 0, 2 }, { 47, 46, 0 } } }, { { { 47, 0, 1 }, { 39, 62, 0 } } }, { { { 47, 0, 0 }, { 39, 63, 0 } } }, { { { 47, 0, 1 }, { 40, 62, 0 } } }, { { { 47, 0, 2 }, { 48, 46, 0 } } }, { { { 48, 0, 2 }, { 40, 63, 0 } } }, { { { 48, 0, 1 }, { 41, 62, 0 } } }, { { { 48, 0, 0 }, { 41, 63, 0 } } }, { { { 48, 0, 1 }, { 48, 49, 0 } } }, { { { 48, 0, 2 }, { 42, 62, 0 } } }, { { { 49, 0, 1 }, { 42, 63, 0 } } }, { { { 49, 0, 0 }, { 43, 62, 0 } } }, { { { 49, 0, 1 }, { 48, 52, 0 } } }, { { { 49, 0, 2 }, { 43, 63, 0 } } }, { { { 50, 0, 1 }, { 44, 62, 0 } } }, { { { 50, 0, 0 }, { 44, 63, 0 } } }, { { { 50, 0, 1 }, { 48, 55, 0 } } }, { { { 50, 0, 2 }, { 45, 62, 0 } } }, { { { 51, 0, 1 }, { 45, 63, 0 } } }, { { { 51, 0, 0 }, { 46, 62, 0 } } }, { { { 51, 0, 1 }, { 48, 58, 0 } } }, { { { 51, 0, 2 }, { 46, 63, 0 } } }, { { { 52, 0, 1 }, { 47, 62, 0 } } }, { { { 52, 0, 0 }, { 47, 63, 0 } } }, { { { 52, 0, 1 }, { 48, 61, 0 } } }, { { { 52, 0, 2 }, { 48, 62, 0 } } }, { { { 53, 0, 1 }, { 56, 47, 0 } } }, { { { 53, 0, 0 }, { 48, 63, 0 } } }, { { { 53, 0, 1 }, { 49, 62, 0 } } }, { { { 53, 0, 2 }, { 49, 63, 0 } } }, { { { 54, 0, 1 }, { 58, 46, 0 } } }, { { { 54, 0, 0 }, { 50, 62, 0 } } }, { { { 54, 0, 1 }, { 50, 63, 0 } } }, { { { 54, 0, 2 }, { 51, 62, 0 } } }, { { { 55, 0, 1 }, { 59, 47, 0 } } }, { { { 55, 0, 0 }, { 51, 63, 0 } } }, { { { 55, 0, 1 }, { 52, 62, 0 } } }, { { { 55, 0, 2 }, { 52, 63, 0 } } }, { { { 56, 0, 1 }, { 61, 46, 0 } } }, { { { 56, 0, 0 }, { 53, 62, 0 } } }, { { { 56, 0, 1 }, { 53, 63, 0 } } }, { { { 56, 0, 2 }, { 54, 62, 0 } } }, { { { 57, 0, 1 }, { 62, 47, 0 } } }, { { { 57, 0, 0 }, { 54, 63, 0 } } }, { { { 57, 0, 1 }, { 55, 62, 0 } } }, { { { 57, 0, 2 }, { 55, 63, 0 } } }, { { { 58, 0, 1 }, { 56, 62, 1 } } }, { { { 58, 0, 0 }, { 56, 62, 0 } } }, { { { 58, 0, 1 }, { 56, 63, 0 } } }, { { { 58, 0, 2 }, { 57, 62, 0 } } }, { { { 59, 0, 1 }, { 57, 63, 1 } } }, { { { 59, 0, 0 }, { 57, 63, 0 } } }, { { { 59, 0, 1 }, { 58, 62, 0 } } }, { { { 59, 0, 2 }, { 58, 63, 0 } } }, { { { 60, 0, 1 }, { 59, 62, 1 } } }, { { { 60, 0, 0 }, { 59, 62, 0 } } }, { { { 60, 0, 1 }, { 59, 63, 0 } } }, { { { 60, 0, 2 }, { 60, 62, 0 } } }, { { { 61, 0, 1 }, { 60, 63, 1 } } }, { { { 61, 0, 0 }, { 60, 63, 0 } } }, { { { 61, 0, 1 }, { 61, 62, 0 } } }, { { { 61, 0, 2 }, { 61, 63, 0 } } }, { { { 62, 0, 1 }, { 62, 62, 1 } } }, { { { 62, 0, 0 }, { 62, 62, 0 } } }, { { { 62, 0, 1 }, { 62, 63, 0 } } }, { { { 62, 0, 2 }, { 63, 62, 0 } } }, { { { 63, 0, 1 }, { 63, 63, 1 } } }, { { { 63, 0, 0 }, { 63, 63, 0 } } } }; static const DDSSingleColorLookup* DDS_LOOKUP[] = { DDSLookup_5_4, DDSLookup_6_4, DDSLookup_5_4 }; static const unsigned char BC7_weight2[] = { 0, 21, 43, 64 }; static const unsigned char BC7_weight3[] = { 0, 9, 18, 27, 37, 46, 55, 64 }; static const unsigned char BC7_weight4[] = { 0, 4, 9, 13, 17, 21, 26, 30, 34, 38, 43, 47, 51, 55, 60, 64 }; /* stores info for each mode of BC7 / static const BC7ModeInfo BC7_mode_info[8] = { { 4, 3, 4, 0, 6, 3, 0 }, / mode 0 / { 6, 2, 6, 0, 2, 3, 0 }, / mode 1 / { 6, 3, 5, 0, 0, 2, 0 }, / mode 2 / { 6, 2, 7, 0, 4, 2, 0 }, / mode 3 / { 0, 1, 5, 6, 0, 2, 3 }, / mode 4 / { 0, 1, 7, 8, 0, 2, 2 }, / mode 5 / { 0, 1, 7, 7, 2, 4, 0 }, / mode 6 / { 6, 2, 5, 5, 4, 2, 0 }, / mode 7 / }; static const unsigned char BC7_partition_table[2][64][16] = { { / BC7 Partition Set for 2 Subsets / { 0, 0, 1, 1, 0, 0, 1, 1, 0, 0, 1, 1, 0, 0, 1, 1 }, { 0, 0, 0, 1, 0, 0, 0, 1, 0, 0, 0, 1, 0, 0, 0, 1 }, { 0, 1, 1, 1, 0, 1, 1, 1, 0, 1, 1, 1, 0, 1, 1, 1 }, { 0, 0, 0, 1, 0, 0, 1, 1, 0, 0, 1, 1, 0, 1, 1, 1 }, { 0, 0, 0, 0, 0, 0, 0, 1, 0, 0, 0, 1, 0, 0, 1, 1 }, { 0, 0, 1, 1, 0, 1, 1, 1, 0, 1, 1, 1, 1, 1, 1, 1 }, { 0, 0, 0, 1, 0, 0, 1, 1, 0, 1, 1, 1, 1, 1, 1, 1 }, { 0, 0, 0, 0, 0, 0, 0, 1, 0, 0, 1, 1, 0, 1, 1, 1 }, { 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 1, 0, 0, 1, 1 }, { 0, 0, 1, 1, 0, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1 }, { 0, 0, 0, 0, 0, 0, 0, 1, 0, 1, 1, 1, 1, 1, 1, 1 }, { 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 1, 0, 1, 1, 1 }, { 0, 0, 0, 1, 0, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1 }, { 0, 0, 0, 0, 0, 0, 0, 0, 1, 1, 1, 1, 1, 1, 1, 1 }, { 0, 0, 0, 0, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1 }, { 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 1, 1, 1, 1 }, { 0, 0, 0, 0, 1, 0, 0, 0, 1, 1, 1, 0, 1, 1, 1, 1 }, { 0, 1, 1, 1, 0, 0, 0, 1, 0, 0, 0, 0, 0, 0, 0, 0 }, { 0, 0, 0, 0, 0, 0, 0, 0, 1, 0, 0, 0, 1, 1, 1, 0 }, { 0, 1, 1, 1, 0, 0, 1, 1, 0, 0, 0, 1, 0, 0, 0, 0 }, { 0, 0, 1, 1, 0, 0, 0, 1, 0, 0, 0, 0, 0, 0, 0, 0 }, { 0, 0, 0, 0, 1, 0, 0, 0, 1, 1, 0, 0, 1, 1, 1, 0 }, { 0, 0, 0, 0, 0, 0, 0, 0, 1, 0, 0, 0, 1, 1, 0, 0 }, { 0, 1, 1, 1, 0, 0, 1, 1, 0, 0, 1, 1, 0, 0, 0, 1 }, { 0, 0, 1, 1, 0, 0, 0, 1, 0, 0, 0, 1, 0, 0, 0, 0 }, { 0, 0, 0, 0, 1, 0, 0, 0, 1, 0, 0, 0, 1, 1, 0, 0 }, { 0, 1, 1, 0, 0, 1, 1, 0, 0, 1, 1, 0, 0, 1, 1, 0 }, { 0, 0, 1, 1, 0, 1, 1, 0, 0, 1, 1, 0, 1, 1, 0, 0 }, { 0, 0, 0, 1, 0, 1, 1, 1, 1, 1, 1, 0, 1, 0, 0, 0 }, { 0, 0, 0, 0, 1, 1, 1, 1, 1, 1, 1, 1, 0, 0, 0, 0 }, { 0, 1, 1, 1, 0, 0, 0, 1, 1, 0, 0, 0, 1, 1, 1, 0 }, { 0, 0, 1, 1, 1, 0, 0, 1, 1, 0, 0, 1, 1, 1, 0, 0 }, { 0, 1, 0, 1, 0, 1, 0, 1, 0, 1, 0, 1, 0, 1, 0, 1 }, { 0, 0, 0, 0, 1, 1, 1, 1, 0, 0, 0, 0, 1, 1, 1, 1 }, { 0, 1, 0, 1, 1, 0, 1, 0, 0, 1, 0, 1, 1, 0, 1, 0 }, { 0, 0, 1, 1, 0, 0, 1, 1, 1, 1, 0, 0, 1, 1, 0, 0 }, { 0, 0, 1, 1, 1, 1, 0, 0, 0, 0, 1, 1, 1, 1, 0, 0 }, { 0, 1, 0, 1, 0, 1, 0, 1, 1, 0, 1, 0, 1, 0, 1, 0 }, { 0, 1, 1, 0, 1, 0, 0, 1, 0, 1, 1, 0, 1, 0, 0, 1 }, { 0, 1, 0, 1, 1, 0, 1, 0, 1, 0, 1, 0, 0, 1, 0, 1 }, { 0, 1, 1, 1, 0, 0, 1, 1, 1, 1, 0, 0, 1, 1, 1, 0 }, { 0, 0, 0, 1, 0, 0, 1, 1, 1, 1, 0, 0, 1, 0, 0, 0 }, { 0, 0, 1, 1, 0, 0, 1, 0, 0, 1, 0, 0, 1, 1, 0, 0 }, { 0, 0, 1, 1, 1, 0, 1, 1, 1, 1, 0, 1, 1, 1, 0, 0 }, { 0, 1, 1, 0, 1, 0, 0, 1, 1, 0, 0, 1, 0, 1, 1, 0 }, { 0, 0, 1, 1, 1, 1, 0, 0, 1, 1, 0, 0, 0, 0, 1, 1 }, { 0, 1, 1, 0, 0, 1, 1, 0, 1, 0, 0, 1, 1, 0, 0, 1 }, { 0, 0, 0, 0, 0, 1, 1, 0, 0, 1, 1, 0, 0, 0, 0, 0 }, { 0, 1, 0, 0, 1, 1, 1, 0, 0, 1, 0, 0, 0, 0, 0, 0 }, { 0, 0, 1, 0, 0, 1, 1, 1, 0, 0, 1, 0, 0, 0, 0, 0 }, { 0, 0, 0, 0, 0, 0, 1, 0, 0, 1, 1, 1, 0, 0, 1, 0 }, { 0, 0, 0, 0, 0, 1, 0, 0, 1, 1, 1, 0, 0, 1, 0, 0 }, { 0, 1, 1, 0, 1, 1, 0, 0, 1, 0, 0, 1, 0, 0, 1, 1 }, { 0, 0, 1, 1, 0, 1, 1, 0, 1, 1, 0, 0, 1, 0, 0, 1 }, { 0, 1, 1, 0, 0, 0, 1, 1, 1, 0, 0, 1, 1, 1, 0, 0 }, { 0, 0, 1, 1, 1, 0, 0, 1, 1, 1, 0, 0, 0, 1, 1, 0 }, { 0, 1, 1, 0, 1, 1, 0, 0, 1, 1, 0, 0, 1, 0, 0, 1 }, { 0, 1, 1, 0, 0, 0, 1, 1, 0, 0, 1, 1, 1, 0, 0, 1 }, { 0, 1, 1, 1, 1, 1, 1, 0, 1, 0, 0, 0, 0, 0, 0, 1 }, { 0, 0, 0, 1, 1, 0, 0, 0, 1, 1, 1, 0, 0, 1, 1, 1 }, { 0, 0, 0, 0, 1, 1, 1, 1, 0, 0, 1, 1, 0, 0, 1, 1 }, { 0, 0, 1, 1, 0, 0, 1, 1, 1, 1, 1, 1, 0, 0, 0, 0 }, { 0, 0, 1, 0, 0, 0, 1, 0, 1, 1, 1, 0, 1, 1, 1, 0 }, { 0, 1, 0, 0, 0, 1, 0, 0, 0, 1, 1, 1, 0, 1, 1, 1 } }, { / BC7 Partition Set for 3 Subsets / { 0, 0, 1, 1, 0, 0, 1, 1, 0, 2, 2, 1, 2, 2, 2, 2 }, { 0, 0, 0, 1, 0, 0, 1, 1, 2, 2, 1, 1, 2, 2, 2, 1 }, { 0, 0, 0, 0, 2, 0, 0, 1, 2, 2, 1, 1, 2, 2, 1, 1 }, { 0, 2, 2, 2, 0, 0, 2, 2, 0, 0, 1, 1, 0, 1, 1, 1 }, { 0, 0, 0, 0, 0, 0, 0, 0, 1, 1, 2, 2, 1, 1, 2, 2 }, { 0, 0, 1, 1, 0, 0, 1, 1, 0, 0, 2, 2, 0, 0, 2, 2 }, { 0, 0, 2, 2, 0, 0, 2, 2, 1, 1, 1, 1, 1, 1, 1, 1 }, { 0, 0, 1, 1, 0, 0, 1, 1, 2, 2, 1, 1, 2, 2, 1, 1 }, { 0, 0, 0, 0, 0, 0, 0, 0, 1, 1, 1, 1, 2, 2, 2, 2 }, { 0, 0, 0, 0, 1, 1, 1, 1, 1, 1, 1, 1, 2, 2, 2, 2 }, { 0, 0, 0, 0, 1, 1, 1, 1, 2, 2, 2, 2, 2, 2, 2, 2 }, { 0, 0, 1, 2, 0, 0, 1, 2, 0, 0, 1, 2, 0, 0, 1, 2 }, { 0, 1, 1, 2, 0, 1, 1, 2, 0, 1, 1, 2, 0, 1, 1, 2 }, { 0, 1, 2, 2, 0, 1, 2, 2, 0, 1, 2, 2, 0, 1, 2, 2 }, { 0, 0, 1, 1, 0, 1, 1, 2, 1, 1, 2, 2, 1, 2, 2, 2 }, { 0, 0, 1, 1, 2, 0, 0, 1, 2, 2, 0, 0, 2, 2, 2, 0 }, { 0, 0, 0, 1, 0, 0, 1, 1, 0, 1, 1, 2, 1, 1, 2, 2 }, { 0, 1, 1, 1, 0, 0, 1, 1, 2, 0, 0, 1, 2, 2, 0, 0 }, { 0, 0, 0, 0, 1, 1, 2, 2, 1, 1, 2, 2, 1, 1, 2, 2 }, { 0, 0, 2, 2, 0, 0, 2, 2, 0, 0, 2, 2, 1, 1, 1, 1 }, { 0, 1, 1, 1, 0, 1, 1, 1, 0, 2, 2, 2, 0, 2, 2, 2 }, { 0, 0, 0, 1, 0, 0, 0, 1, 2, 2, 2, 1, 2, 2, 2, 1 }, { 0, 0, 0, 0, 0, 0, 1, 1, 0, 1, 2, 2, 0, 1, 2, 2 }, { 0, 0, 0, 0, 1, 1, 0, 0, 2, 2, 1, 0, 2, 2, 1, 0 }, { 0, 1, 2, 2, 0, 1, 2, 2, 0, 0, 1, 1, 0, 0, 0, 0 }, { 0, 0, 1, 2, 0, 0, 1, 2, 1, 1, 2, 2, 2, 2, 2, 2 }, { 0, 1, 1, 0, 1, 2, 2, 1, 1, 2, 2, 1, 0, 1, 1, 0 }, { 0, 0, 0, 0, 0, 1, 1, 0, 1, 2, 2, 1, 1, 2, 2, 1 }, { 0, 0, 2, 2, 1, 1, 0, 2, 1, 1, 0, 2, 0, 0, 2, 2 }, { 0, 1, 1, 0, 0, 1, 1, 0, 2, 0, 0, 2, 2, 2, 2, 2 }, { 0, 0, 1, 1, 0, 1, 2, 2, 0, 1, 2, 2, 0, 0, 1, 1 }, { 0, 0, 0, 0, 2, 0, 0, 0, 2, 2, 1, 1, 2, 2, 2, 1 }, { 0, 0, 0, 0, 0, 0, 0, 2, 1, 1, 2, 2, 1, 2, 2, 2 }, { 0, 2, 2, 2, 0, 0, 2, 2, 0, 0, 1, 2, 0, 0, 1, 1 }, { 0, 0, 1, 1, 0, 0, 1, 2, 0, 0, 2, 2, 0, 2, 2, 2 }, { 0, 1, 2, 0, 0, 1, 2, 0, 0, 1, 2, 0, 0, 1, 2, 0 }, { 0, 0, 0, 0, 1, 1, 1, 1, 2, 2, 2, 2, 0, 0, 0, 0 }, { 0, 1, 2, 0, 1, 2, 0, 1, 2, 0, 1, 2, 0, 1, 2, 0 }, { 0, 1, 2, 0, 2, 0, 1, 2, 1, 2, 0, 1, 0, 1, 2, 0 }, { 0, 0, 1, 1, 2, 2, 0, 0, 1, 1, 2, 2, 0, 0, 1, 1 }, { 0, 0, 1, 1, 1, 1, 2, 2, 2, 2, 0, 0, 0, 0, 1, 1 }, { 0, 1, 0, 1, 0, 1, 0, 1, 2, 2, 2, 2, 2, 2, 2, 2 }, { 0, 0, 0, 0, 0, 0, 0, 0, 2, 1, 2, 1, 2, 1, 2, 1 }, { 0, 0, 2, 2, 1, 1, 2, 2, 0, 0, 2, 2, 1, 1, 2, 2 }, { 0, 0, 2, 2, 0, 0, 1, 1, 0, 0, 2, 2, 0, 0, 1, 1 }, { 0, 2, 2, 0, 1, 2, 2, 1, 0, 2, 2, 0, 1, 2, 2, 1 }, { 0, 1, 0, 1, 2, 2, 2, 2, 2, 2, 2, 2, 0, 1, 0, 1 }, { 0, 0, 0, 0, 2, 1, 2, 1, 2, 1, 2, 1, 2, 1, 2, 1 }, { 0, 1, 0, 1, 0, 1, 0, 1, 0, 1, 0, 1, 2, 2, 2, 2 }, { 0, 2, 2, 2, 0, 1, 1, 1, 0, 2, 2, 2, 0, 1, 1, 1 }, { 0, 0, 0, 2, 1, 1, 1, 2, 0, 0, 0, 2, 1, 1, 1, 2 }, { 0, 0, 0, 0, 2, 1, 1, 2, 2, 1, 1, 2, 2, 1, 1, 2 }, { 0, 2, 2, 2, 0, 1, 1, 1, 0, 1, 1, 1, 0, 2, 2, 2 }, { 0, 0, 0, 2, 1, 1, 1, 2, 1, 1, 1, 2, 0, 0, 0, 2 }, { 0, 1, 1, 0, 0, 1, 1, 0, 0, 1, 1, 0, 2, 2, 2, 2 }, { 0, 0, 0, 0, 0, 0, 0, 0, 2, 1, 1, 2, 2, 1, 1, 2 }, { 0, 1, 1, 0, 0, 1, 1, 0, 2, 2, 2, 2, 2, 2, 2, 2 }, { 0, 0, 2, 2, 0, 0, 1, 1, 0, 0, 1, 1, 0, 0, 2, 2 }, { 0, 0, 2, 2, 1, 1, 2, 2, 1, 1, 2, 2, 0, 0, 2, 2 }, { 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 2, 1, 1, 2 }, { 0, 0, 0, 2, 0, 0, 0, 1, 0, 0, 0, 2, 0, 0, 0, 1 }, { 0, 2, 2, 2, 1, 2, 2, 2, 0, 2, 2, 2, 1, 2, 2, 2 }, { 0, 1, 0, 1, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2 }, { 0, 1, 1, 1, 2, 0, 1, 1, 2, 2, 0, 1, 2, 2, 2, 0 } } }; static const unsigned char BC7_anchor_index_table[4][64] = { / Anchor index values for the first subset / { 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0 }, / Anchor index values for the second subset of two-subset partitioning / { 15,15,15,15,15,15,15,15, 15,15,15,15,15,15,15,15, 15, 2, 8, 2, 2, 8, 8,15, 2, 8, 2, 2, 8, 8, 2, 2, 15,15, 6, 8, 2, 8,15,15, 2, 8, 2, 2, 2,15,15, 6, 6, 2, 6, 8,15,15, 2, 2, 15,15,15,15,15, 2, 2,15 }, / Anchor index values for the second subset of three-subset partitioning / { 3, 3,15,15, 8, 3,15,15, 8, 8, 6, 6, 6, 5, 3, 3, 3, 3, 8,15, 3, 3, 6,10, 5, 8, 8, 6, 8, 5,15,15, 8,15, 3, 5, 6,10, 8,15, 15, 3,15, 5,15,15,15,15, 3,15, 5, 5, 5, 8, 5,10, 5,10, 8,13,15,12, 3, 3 }, / Anchor index values for the third subset of three-subset partitioning / { 15, 8, 8, 3,15,15, 3, 8, 15,15,15,15,15,15,15, 8, 15, 8,15, 3,15, 8,15, 8, 3,15, 6,10,15,15,10, 8, 15, 3,15,10,10, 8, 9,10, 6,15, 8,15, 3, 6, 6, 8, 15, 3,15,15,15,15,15,15, 15,15,15,15, 3,15,15, 8 } }; / Macros / #define C565_r(x) (((x) & 0xF800) >> 11) #define C565_g(x) (((x) & 0x07E0) >> 5) #define C565_b(x) ((x) & 0x001F) #define C565_red(x) ( (C565_r(x) << 3 \| C565_r(x) >> 2)) #define C565_green(x) ( (C565_g(x) << 2 \| C565_g(x) >> 4)) #define C565_blue(x) ( (C565_b(x) << 3 \| C565_b(x) >> 2)) #define DIV2(x) ((x) > 1 ? ((x) >> 1) : 1) #define FixRange(min, max, steps) \ if (min > max) \ min = max; \ if ((ssize_t) max - min < steps) \ max = MagickMin(min + steps, 255); \ if ((ssize_t) max - min < steps) \ min = MagickMax(0, (ssize_t) max - steps) #define Dot(left, right) (left.xright.x) + (left.yright.y) + (left.zright.z) #define VectorInit(vector, value) vector.x = vector.y = vector.z = vector.w \ = value #define VectorInit3(vector, value) vector.x = vector.y = vector.z = value #define IsBitMask(mask, r, g, b, a) (mask.r_bitmask == r && mask.g_bitmask == \ g && mask.b_bitmask == b && mask.alpha_bitmask == a) /* Forward declarations / static MagickBooleanType WriteDDSImage(const ImageInfo ,Image ,ExceptionInfo ); static inline void VectorAdd(const DDSVector4 left, const DDSVector4 right, DDSVector4 destination) { destination->x = left.x + right.x; destination->y = left.y + right.y; destination->z = left.z + right.z; destination->w = left.w + right.w; } static inline void VectorClamp(DDSVector4 value) { value->x = MagickMin(1.0f,MagickMax(0.0f,value->x)); value->y = MagickMin(1.0f,MagickMax(0.0f,value->y)); value->z = MagickMin(1.0f,MagickMax(0.0f,value->z)); value->w = MagickMin(1.0f,MagickMax(0.0f,value->w)); } static inline void VectorClamp3(DDSVector3 value) { value->x = MagickMin(1.0f,MagickMax(0.0f,value->x)); value->y = MagickMin(1.0f,MagickMax(0.0f,value->y)); value->z = MagickMin(1.0f,MagickMax(0.0f,value->z)); } static inline void VectorCopy43(const DDSVector4 source, DDSVector3 destination) { destination->x = source.x; destination->y = source.y; destination->z = source.z; } static inline void VectorCopy44(const DDSVector4 source, DDSVector4 destination) { destination->x = source.x; destination->y = source.y; destination->z = source.z; destination->w = source.w; } static inline void VectorNegativeMultiplySubtract(const DDSVector4 a, const DDSVector4 b, const DDSVector4 c, DDSVector4 destination) { destination->x = c.x - (a.x * b.x); destination->y = c.y - (a.y * b.y); destination->z = c.z - (a.z * b.z); destination->w = c.w - (a.w * b.w); } static inline void VectorMultiply(const DDSVector4 left, const DDSVector4 right, DDSVector4 destination) { destination->x = left.x right.x; destination->y = left.y * right.y; destination->z = left.z * right.z; destination->w = left.w * right.w; } static inline void VectorMultiply3(const DDSVector3 left, const DDSVector3 right, DDSVector3 destination) { destination->x = left.x right.x; destination->y = left.y * right.y; destination->z = left.z * right.z; } static inline void VectorMultiplyAdd(const DDSVector4 a, const DDSVector4 b, const DDSVector4 c, DDSVector4 destination) { destination->x = (a.x b.x) + c.x; destination->y = (a.y * b.y) + c.y; destination->z = (a.z * b.z) + c.z; destination->w = (a.w * b.w) + c.w; } static inline void VectorMultiplyAdd3(const DDSVector3 a, const DDSVector3 b, const DDSVector3 c, DDSVector3 destination) { destination->x = (a.x b.x) + c.x; destination->y = (a.y * b.y) + c.y; destination->z = (a.z * b.z) + c.z; } static inline void VectorReciprocal(const DDSVector4 value, DDSVector4 destination) { destination->x = 1.0f / value.x; destination->y = 1.0f / value.y; destination->z = 1.0f / value.z; destination->w = 1.0f / value.w; } static inline void VectorSubtract(const DDSVector4 left, const DDSVector4 right, DDSVector4 destination) { destination->x = left.x - right.x; destination->y = left.y - right.y; destination->z = left.z - right.z; destination->w = left.w - right.w; } static inline void VectorSubtract3(const DDSVector3 left, const DDSVector3 right, DDSVector3 destination) { destination->x = left.x - right.x; destination->y = left.y - right.y; destination->z = left.z - right.z; } static inline void VectorTruncate(DDSVector4 value) { value->x = value->x > 0.0f ? floor(value->x) : ceil(value->x); value->y = value->y > 0.0f ? floor(value->y) : ceil(value->y); value->z = value->z > 0.0f ? floor(value->z) : ceil(value->z); value->w = value->w > 0.0f ? floor(value->w) : ceil(value->w); } static inline void VectorTruncate3(DDSVector3 value) { value->x = value->x > 0.0f ? floor(value->x) : ceil(value->x); value->y = value->y > 0.0f ? floor(value->y) : ceil(value->y); value->z = value->z > 0.0f ? floor(value->z) : ceil(value->z); } static inline size_t ClampToLimit(const float value, const size_t limit) { size_t result = (int) (value + 0.5f); if (result < 0.0f) return(0); if (result > limit) return(limit); return result; } static inline size_t ColorTo565(const DDSVector3 point) { size_t r = ClampToLimit(31.0fpoint.x,31); size_t g = ClampToLimit(63.0fpoint.y,63); size_t b = ClampToLimit(31.0fpoint.z,31); return (r << 11) \| (g << 5) \| b; } static inline unsigned char GetSubsetIndex(unsigned char numSubsets, unsigned char partition_id,size_t pixelIndex) { if (numSubsets == 2) return BC7_partition_table[0][partition_id][pixelIndex]; if (numSubsets == 3) return BC7_partition_table[1][partition_id][pixelIndex]; return 0; } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % I s D D S % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % IsDDS() returns MagickTrue if the image format type, identified by the % magick string, is DDS. % % The format of the IsDDS method is: % % MagickBooleanType IsDDS(const unsigned char magick,const size_t length) % % A description of each parameter follows: % % o magick: compare image format pattern against these bytes. % % o length: Specifies the length of the magick string. % / static MagickBooleanType IsDDS(const unsigned char magick, const size_t length) { if (length < 4) return(MagickFalse); if (LocaleNCompare((char ) magick,"DDS ", 4) == 0) return(MagickTrue); return(MagickFalse); } static MagickBooleanType ReadDDSInfo(Image image, DDSInfo dds_info) { size_t hdr_size, required; /* Seek to start of header / (void) SeekBlob(image, 4, SEEK_SET); / Check header field / hdr_size = ReadBlobLSBLong(image); if (hdr_size != 124) return MagickFalse; / Fill in DDS info struct / dds_info->flags = ReadBlobLSBLong(image); / Check required flags / required=(size_t) (DDSD_CAPS \| DDSD_WIDTH \| DDSD_HEIGHT \| DDSD_PIXELFORMAT); if ((dds_info->flags & required) != required) return MagickFalse; dds_info->height = ReadBlobLSBLong(image); dds_info->width = ReadBlobLSBLong(image); dds_info->pitchOrLinearSize = ReadBlobLSBLong(image); dds_info->depth = ReadBlobLSBLong(image); dds_info->mipmapcount = ReadBlobLSBLong(image); (void) SeekBlob(image, 44, SEEK_CUR); / reserved region of 11 DWORDs / / Read pixel format structure / hdr_size = ReadBlobLSBLong(image); if (hdr_size != 32) return MagickFalse; dds_info->pixelformat.flags = ReadBlobLSBLong(image); dds_info->pixelformat.fourcc = ReadBlobLSBLong(image); dds_info->pixelformat.rgb_bitcount = ReadBlobLSBLong(image); dds_info->pixelformat.r_bitmask = ReadBlobLSBLong(image); dds_info->pixelformat.g_bitmask = ReadBlobLSBLong(image); dds_info->pixelformat.b_bitmask = ReadBlobLSBLong(image); dds_info->pixelformat.alpha_bitmask = ReadBlobLSBLong(image); dds_info->ddscaps1 = ReadBlobLSBLong(image); dds_info->ddscaps2 = ReadBlobLSBLong(image); (void) SeekBlob(image, 12, SEEK_CUR); / 3 reserved DWORDs / / Read optional DX10 header if available / if ((dds_info->pixelformat.flags & DDPF_FOURCC) && (dds_info->pixelformat.fourcc == FOURCC_DX10)) { dds_info->extFormat = ReadBlobLSBLong(image); dds_info->extDimension = ReadBlobLSBLong(image); dds_info->extFlags = ReadBlobLSBLong(image); dds_info->extArraySize = ReadBlobLSBLong(image); dds_info->extFlags2 = ReadBlobLSBLong(image); } else { dds_info->extFormat = 0; dds_info->extDimension = 0; dds_info->extFlags = 0; dds_info->extArraySize = 0; dds_info->extFlags2 = 0; } return(MagickTrue); } static MagickBooleanType SetDXT1Pixels(Image image,ssize_t x,ssize_t y, DDSColors colors,size_t bits,Quantum q) { ssize_t i; ssize_t j; unsigned char code; for (j = 0; j < 4; j++) { for (i = 0; i < 4; i++) { if ((x + i) < (ssize_t) image->columns && (y + j) < (ssize_t) image->rows) { code=(unsigned char) ((bits >> ((j4+i)2)) & 0x3); SetPixelRed(image,ScaleCharToQuantum(colors.r[code]),q); SetPixelGreen(image,ScaleCharToQuantum(colors.g[code]),q); SetPixelBlue(image,ScaleCharToQuantum(colors.b[code]),q); SetPixelOpacity(image,ScaleCharToQuantum(colors.a[code]),q); if ((colors.a[code] != 0) && (image->alpha_trait == UndefinedPixelTrait)) return(MagickFalse); q+=GetPixelChannels(image); } } } return(MagickTrue); } static MagickBooleanType ReadMipmaps(const ImageInfo image_info,Image image, const DDSInfo dds_info,DDSPixelDecoder decoder,ExceptionInfo exception) { MagickBooleanType status; / Only skip mipmaps for textures and cube maps / if (EOFBlob(image) != MagickFalse) { ThrowFileException(exception,CorruptImageWarning,"UnexpectedEndOfFile", image->filename); return(MagickFalse); } status=MagickTrue; if (dds_info->ddscaps1 & DDSCAPS_MIPMAP && (dds_info->ddscaps1 & DDSCAPS_TEXTURE \|\| dds_info->ddscaps2 & DDSCAPS2_CUBEMAP)) { ssize_t i; size_t h, w; w=DIV2(dds_info->width); h=DIV2(dds_info->height); / Mipmapcount includes the main image, so start from one / for (i = 1; (i < (ssize_t) dds_info->mipmapcount) && w && h; i++) { AcquireNextImage(image_info,image,exception); if (image->next == (Image ) NULL) return(MagickFalse); image->next->alpha_trait=image->alpha_trait; image=SyncNextImageInList(image); status=SetImageExtent(image,w,h,exception); if (status == MagickFalse) break; status=decoder(image,dds_info,exception); if (status == MagickFalse) break; if ((w == 1) && (h == 1)) break; w=DIV2(w); h=DIV2(h); } } return(status); } static void CalculateColors(unsigned short c0, unsigned short c1, DDSColors c, MagickBooleanType ignoreAlpha) { c->a[0] = c->a[1] = c->a[2] = c->a[3] = 0; c->r[0] = (unsigned char) C565_red(c0); c->g[0] = (unsigned char) C565_green(c0); c->b[0] = (unsigned char) C565_blue(c0); c->r[1] = (unsigned char) C565_red(c1); c->g[1] = (unsigned char) C565_green(c1); c->b[1] = (unsigned char) C565_blue(c1); if (ignoreAlpha != MagickFalse \|\| c0 > c1) { c->r[2] = (unsigned char) ((2 c->r[0] + c->r[1]) / 3); c->g[2] = (unsigned char) ((2 * c->g[0] + c->g[1]) / 3); c->b[2] = (unsigned char) ((2 * c->b[0] + c->b[1]) / 3); c->r[3] = (unsigned char) ((c->r[0] + 2 * c->r[1]) / 3); c->g[3] = (unsigned char) ((c->g[0] + 2 * c->g[1]) / 3); c->b[3] = (unsigned char) ((c->b[0] + 2 * c->b[1]) / 3); } else { c->r[2] = (unsigned char) ((c->r[0] + c->r[1]) / 2); c->g[2] = (unsigned char) ((c->g[0] + c->g[1]) / 2); c->b[2] = (unsigned char) ((c->b[0] + c->b[1]) / 2); c->r[3] = c->g[3] = c->b[3] = 0; c->a[3] = 255; } } static MagickBooleanType ReadDXT1Pixels(Image image, const DDSInfo magick_unused(dds_info),ExceptionInfo exception) { DDSColors colors; Quantum q; ssize_t x; size_t bits; ssize_t y; unsigned short c0, c1; magick_unreferenced(dds_info); for (y = 0; y < (ssize_t) image->rows; y += 4) { for (x = 0; x < (ssize_t) image->columns; x += 4) { /* Get 4x4 patch of pixels to write on / q=QueueAuthenticPixels(image,x,y,MagickMin(4,image->columns-x), MagickMin(4,image->rows-y),exception); if (q == (Quantum ) NULL) return(MagickFalse); /* Read 8 bytes of data from the image / c0=ReadBlobLSBShort(image); c1=ReadBlobLSBShort(image); bits=ReadBlobLSBLong(image); CalculateColors(c0,c1,&colors,MagickFalse); if (EOFBlob(image) != MagickFalse) return(MagickFalse); / Write the pixels / if (SetDXT1Pixels(image,x,y,colors,bits,q) == MagickFalse) { / Correct alpha / SetImageAlpha(image,QuantumRange,exception); q=QueueAuthenticPixels(image,x,y,MagickMin(4,image->columns-x), MagickMin(4,image->rows-y),exception); if (q != (Quantum ) NULL) SetDXT1Pixels(image,x,y,colors,bits,q); } if (SyncAuthenticPixels(image,exception) == MagickFalse) return(MagickFalse); } if (EOFBlob(image) != MagickFalse) return(MagickFalse); } return(MagickTrue); } /* Skip the mipmap images for compressed (DXTn) dds files / static MagickBooleanType SkipDXTMipmaps(Image image,const DDSInfo dds_info, int texel_size,ExceptionInfo exception) { /* Only skip mipmaps for textures and cube maps / if (EOFBlob(image) != MagickFalse) { ThrowFileException(exception,CorruptImageWarning,"UnexpectedEndOfFile", image->filename); return(MagickFalse); } if (dds_info->ddscaps1 & DDSCAPS_MIPMAP && (dds_info->ddscaps1 & DDSCAPS_TEXTURE \|\| dds_info->ddscaps2 & DDSCAPS2_CUBEMAP)) { MagickOffsetType offset; ssize_t i; size_t h, w; w=DIV2(dds_info->width); h=DIV2(dds_info->height); / Mipmapcount includes the main image, so start from one / for (i = 1; (i < (ssize_t) dds_info->mipmapcount) && w && h; i++) { offset=(MagickOffsetType)((w+3)/4)((h+3)/4)texel_size; if (SeekBlob(image,offset,SEEK_CUR) < 0) break; w=DIV2(w); h=DIV2(h); if ((w == 1) && (h == 1)) break; } } return(MagickTrue); } static MagickBooleanType ReadDXT1(const ImageInfo image_info,Image image, const DDSInfo dds_info,const MagickBooleanType read_mipmaps, ExceptionInfo exception) { if (ReadDXT1Pixels(image,dds_info,exception) == MagickFalse) return(MagickFalse); if (read_mipmaps != MagickFalse) return(ReadMipmaps(image_info,image,dds_info,ReadDXT1Pixels,exception)); else return(SkipDXTMipmaps(image,dds_info,8,exception)); } static MagickBooleanType ReadDXT3Pixels(Image image, const DDSInfo magick_unused(dds_info),ExceptionInfo exception) { DDSColors colors; Quantum q; ssize_t i, x; unsigned char alpha; size_t a0, a1, bits, code; ssize_t j, y; unsigned short c0, c1; magick_unreferenced(dds_info); for (y = 0; y < (ssize_t) image->rows; y += 4) { for (x = 0; x < (ssize_t) image->columns; x += 4) { / Get 4x4 patch of pixels to write on / q = QueueAuthenticPixels(image, x, y, MagickMin(4, image->columns - x), MagickMin(4, image->rows - y),exception); if (q == (Quantum ) NULL) return(MagickFalse); /* Read alpha values (8 bytes) / a0 = ReadBlobLSBLong(image); a1 = ReadBlobLSBLong(image); / Read 8 bytes of data from the image / c0 = ReadBlobLSBShort(image); c1 = ReadBlobLSBShort(image); bits = ReadBlobLSBLong(image); CalculateColors(c0, c1, &colors, MagickTrue); if (EOFBlob(image) != MagickFalse) return(MagickFalse); / Write the pixels / for (j = 0; j < 4; j++) { for (i = 0; i < 4; i++) { if ((x + i) < (ssize_t) image->columns && (y + j) < (ssize_t) image->rows) { code = (bits >> ((4j+i)2)) & 0x3; SetPixelRed(image,ScaleCharToQuantum(colors.r[code]),q); SetPixelGreen(image,ScaleCharToQuantum(colors.g[code]),q); SetPixelBlue(image,ScaleCharToQuantum(colors.b[code]),q); / Extract alpha value: multiply 0..15 by 17 to get range 0..255 / if (j < 2) alpha = 17U (unsigned char) ((a0 >> (4(4j+i))) & 0xf); else alpha = 17U * (unsigned char) ((a1 >> (4(4(j-2)+i))) & 0xf); SetPixelAlpha(image,ScaleCharToQuantum((unsigned char) alpha),q); q+=GetPixelChannels(image); } } } if (SyncAuthenticPixels(image,exception) == MagickFalse) return(MagickFalse); } if (EOFBlob(image) != MagickFalse) return(MagickFalse); } return(MagickTrue); } static MagickBooleanType ReadDXT3(const ImageInfo image_info,Image image, const DDSInfo dds_info,const MagickBooleanType read_mipmaps, ExceptionInfo exception) { if (ReadDXT3Pixels(image,dds_info,exception) == MagickFalse) return(MagickFalse); if (read_mipmaps != MagickFalse) return(ReadMipmaps(image_info,image,dds_info,ReadDXT3Pixels,exception)); else return(SkipDXTMipmaps(image,dds_info,16,exception)); } static MagickBooleanType ReadDXT5Pixels(Image image, const DDSInfo magick_unused(dds_info),ExceptionInfo exception) { DDSColors colors; MagickSizeType alpha_bits; Quantum q; ssize_t i, x; unsigned char a0, a1; size_t alpha, bits, code, alpha_code; ssize_t j, y; unsigned short c0, c1; magick_unreferenced(dds_info); for (y = 0; y < (ssize_t) image->rows; y += 4) { for (x = 0; x < (ssize_t) image->columns; x += 4) { /* Get 4x4 patch of pixels to write on / q = QueueAuthenticPixels(image, x, y, MagickMin(4, image->columns - x), MagickMin(4, image->rows - y),exception); if (q == (Quantum ) NULL) return(MagickFalse); /* Read alpha values (8 bytes) / a0 = (unsigned char) ReadBlobByte(image); a1 = (unsigned char) ReadBlobByte(image); alpha_bits = (MagickSizeType)ReadBlobLSBLong(image); alpha_bits = alpha_bits \| ((MagickSizeType)ReadBlobLSBShort(image) << 32); / Read 8 bytes of data from the image / c0 = ReadBlobLSBShort(image); c1 = ReadBlobLSBShort(image); bits = ReadBlobLSBLong(image); CalculateColors(c0, c1, &colors, MagickTrue); if (EOFBlob(image) != MagickFalse) return(MagickFalse); / Write the pixels / for (j = 0; j < 4; j++) { for (i = 0; i < 4; i++) { if ((x + i) < (ssize_t) image->columns && (y + j) < (ssize_t) image->rows) { code = (bits >> ((4j+i)2)) & 0x3; SetPixelRed(image,ScaleCharToQuantum(colors.r[code]),q); SetPixelGreen(image,ScaleCharToQuantum(colors.g[code]),q); SetPixelBlue(image,ScaleCharToQuantum(colors.b[code]),q); / Extract alpha value / alpha_code = (size_t) (alpha_bits >> (3(4j+i))) & 0x7; if (alpha_code == 0) alpha = a0; else if (alpha_code == 1) alpha = a1; else if (a0 > a1) alpha = ((8-alpha_code) a0 + (alpha_code-1) * a1) / 7; else if (alpha_code == 6) alpha = 0; else if (alpha_code == 7) alpha = 255; else alpha = (((6-alpha_code) * a0 + (alpha_code-1) * a1) / 5); SetPixelAlpha(image,ScaleCharToQuantum((unsigned char) alpha),q); q+=GetPixelChannels(image); } } } if (SyncAuthenticPixels(image,exception) == MagickFalse) return(MagickFalse); } if (EOFBlob(image) != MagickFalse) return(MagickFalse); } return(MagickTrue); } static MagickBooleanType ReadDXT5(const ImageInfo image_info,Image image, const DDSInfo dds_info,const MagickBooleanType read_mipmaps, ExceptionInfo exception) { if (ReadDXT5Pixels(image,dds_info,exception) == MagickFalse) return(MagickFalse); if (read_mipmaps != MagickFalse) return(ReadMipmaps(image_info,image,dds_info,ReadDXT5Pixels,exception)); else return(SkipDXTMipmaps(image,dds_info,16,exception)); } static unsigned char GetBit(const unsigned char block,size_t start_bit) { size_t base, index; index=(start_bit) >> 3; base=(start_bit) - (index << 3); (start_bit)++; if (index > 15) return(0); return((block[index] >> base) & 0x01); } static unsigned char GetBits(const unsigned char block,size_t start_bit, unsigned char num_bits) { size_t base, first_bits, index, next_bits; unsigned char ret; index=(start_bit) >> 3; base=(start_bit)-(index << 3); if (index > 15) return(0); if (base + num_bits > 8) { first_bits=8-base; next_bits=num_bits-first_bits; ret=((block[index] >> base) \| (((block[index + 1]) & ((1u << next_bits) - 1)) << first_bits)); } else { ret=((block[index] >> base) & ((1 << num_bits) - 1)); } (start_bit)+=num_bits; return(ret); } static MagickBooleanType IsPixelAnchorIndex(unsigned char subset_index, unsigned char num_subsets,size_t pixelIndex,unsigned char partition_id) { size_t table_index; /* for first subset / if (subset_index == 0) table_index=0; / for second subset of two subset partitioning / else if ((subset_index == 1) && (num_subsets == 2)) table_index=1; / for second subset of three subset partitioning / else if ((subset_index == 1) && (num_subsets == 3)) table_index=2; / for third subset of three subset partitioning / else table_index=3; if (BC7_anchor_index_table[table_index][partition_id] == pixelIndex) return(MagickTrue); else return(MagickFalse); } static void ReadEndpoints(BC7Colors endpoints,const unsigned char block, size_t mode,size_t start_bit) { MagickBooleanType has_alpha, has_pbits; unsigned char alpha_bits, color_bits, pbit, pbit0, pbit1; size_t num_subsets, i; num_subsets=(size_t) BC7_mode_info[mode].num_subsets; color_bits=BC7_mode_info[mode].color_precision; /* red / for (i=0; i < num_subsets 2; i++) endpoints->r[i]=GetBits(block,start_bit,color_bits); /* green / for (i=0; i < num_subsets 2; i++) endpoints->g[i]=GetBits(block,start_bit,color_bits); /* blue / for (i=0; i < num_subsets 2; i++) endpoints->b[i]=GetBits(block,start_bit,color_bits); /* alpha / alpha_bits=BC7_mode_info[mode].alpha_precision; has_alpha=mode >= 4 ? MagickTrue : MagickFalse; if (has_alpha != MagickFalse) { for (i=0; i < num_subsets 2; i++) endpoints->a[i]=GetBits(block,start_bit,alpha_bits); } /* handle modes that have p bits / has_pbits=(mode == 0) \|\| (mode == 1) \|\| (mode == 3) \|\| (mode == 6) \|\| (mode == 7) ? MagickTrue : MagickFalse; if (has_pbits != MagickFalse) { for (i=0; i < num_subsets 2; i++) { endpoints->r[i] <<= 1; endpoints->g[i] <<= 1; endpoints->b[i] <<= 1; endpoints->a[i] <<= 1; } /* mode 1 shares a p-bit for both endpoints / if (mode == 1) { pbit0=GetBit(block,start_bit); pbit1=GetBit(block,start_bit); endpoints->r[0] \|= pbit0; endpoints->g[0] \|= pbit0; endpoints->b[0] \|= pbit0; endpoints->r[1] \|= pbit0; endpoints->g[1] \|= pbit0; endpoints->b[1] \|= pbit0; endpoints->r[2] \|= pbit1; endpoints->g[2] \|= pbit1; endpoints->b[2] \|= pbit1; endpoints->r[3] \|= pbit1; endpoints->g[3] \|= pbit1; endpoints->b[3] \|= pbit1; } else { for (i=0; i < num_subsets 2; i++) { pbit=GetBit(block,start_bit); endpoints->r[i] \|= pbit; endpoints->g[i] \|= pbit; endpoints->b[i] \|= pbit; endpoints->a[i] \|= pbit; } } } /* 1 bit increased due to the pbit / if (has_pbits != MagickFalse) { color_bits++; alpha_bits++; } / color and alpha bit shifting so that MSB lies in bit 7 / for (i=0; i < num_subsets 2; i++) { endpoints->r[i] <<= (8 - color_bits); endpoints->g[i] <<= (8 - color_bits); endpoints->b[i] <<= (8 - color_bits); endpoints->a[i] <<= (8 - alpha_bits); endpoints->r[i]=endpoints->r[i] \| (endpoints->r[i] >> color_bits); endpoints->g[i]=endpoints->g[i] \| (endpoints->g[i] >> color_bits); endpoints->b[i]=endpoints->b[i] \| (endpoints->b[i] >> color_bits); endpoints->a[i]=endpoints->a[i] \| (endpoints->a[i] >> alpha_bits); } if (has_alpha == MagickFalse) { for (i=0; i < num_subsets * 2; i++) endpoints->a[i]=255; } } static MagickBooleanType ReadBC7Pixels(Image image, const DDSInfo magick_unused(dds_info),ExceptionInfo exception) { BC7Colors colors; Quantum q; size_t mode, start_bit; ssize_t count, i, x, y; unsigned char a, alpha_indices[16], b, block[16], c0, c1, color_indices[16], g, index_prec, index2_prec, num_bits, num_subsets, partition_id, r, rotation, selector_bit, subset_indices[16], weight; magick_unreferenced(dds_info); memset(alpha_indices,0,sizeof(alpha_indices)); memset(block,0,sizeof(block)); memset(color_indices,0,sizeof(color_indices)); memset(subset_indices,0,sizeof(subset_indices)); for (y = 0; y < (ssize_t) image->rows; y += 4) { for (x = 0; x < (ssize_t) image->columns; x += 4) { size_t area; /* Get 4x4 patch of pixels to write on / q=QueueAuthenticPixels(image,x,y,MagickMin(4,image->columns-x), MagickMin(4,image->rows-y),exception); if (q == (Quantum ) NULL) return(MagickFalse); /* Read 16 bytes of data from the image / count=ReadBlob(image,16,block); if (count != 16) return(MagickFalse); if (EOFBlob(image) != MagickFalse) return(MagickFalse); / Get the mode of the block / start_bit=0; while (start_bit <= 8 && !GetBit(block, &start_bit)) {} mode=start_bit-1; if (mode > 7) return(MagickFalse); num_subsets=BC7_mode_info[mode].num_subsets; partition_id=0; / only these modes have more than 1 subset / if ((mode == 0) \|\| (mode == 1) \|\| (mode == 2) \|\| (mode == 3) \|\| (mode == 7)) { partition_id=GetBits(block,&start_bit,BC7_mode_info[mode].partition_bits); if (partition_id > 63) return(MagickFalse); } rotation=0; if ((mode == 4) \|\| (mode == 5)) rotation=GetBits(block,&start_bit,2); selector_bit=0; if (mode == 4) selector_bit=GetBit(block, &start_bit); ReadEndpoints(&colors,block,mode,&start_bit); index_prec=BC7_mode_info[mode].index_precision; index2_prec=BC7_mode_info[mode].index2_precision; if ((mode == 4) && (selector_bit == 1)) { index_prec=3; alpha_indices[0]=GetBit(block,&start_bit); for (i = 1; i < 16; i++) alpha_indices[i]=GetBits(block,&start_bit,2); } / get color and subset indices / for (i=0; i < 16; i++) { subset_indices[i]=GetSubsetIndex(num_subsets,partition_id,i); num_bits=index_prec; if (IsPixelAnchorIndex(subset_indices[i],num_subsets,i,partition_id)) num_bits--; color_indices[i]=GetBits(block,&start_bit,num_bits); } / get alpha indices if the block has it / if ((mode == 5) \|\| ((mode == 4) && (selector_bit == 0))) { alpha_indices[0]=GetBits(block,&start_bit,index2_prec - 1); for (i=1; i < 16; i++) alpha_indices[i]=GetBits(block,&start_bit,index2_prec); } / Write the pixels / area=MagickMin(MagickMin(4,image->columns-x)MagickMin(4,image->rows-y), 16); for (i=0; i < (ssize_t) area; i++) { unsigned char c2; c0=2 * subset_indices[i]; c1=(2 * subset_indices[i]) + 1; c2=color_indices[i]; weight=64; /* Color Interpolation / switch(index_prec) { case 2: if (c2 < sizeof(BC7_weight2)) weight=BC7_weight2[c2]; break; case 3: if (c2 < sizeof(BC7_weight3)) weight=BC7_weight3[c2]; break; default: if (c2 < sizeof(BC7_weight4)) weight=BC7_weight4[c2]; } r=((64 - weight) colors.r[c0] + weight * colors.r[c1] + 32) >> 6; g=((64 - weight) * colors.g[c0] + weight * colors.g[c1] + 32) >> 6; b=((64 - weight) * colors.b[c0] + weight * colors.b[c1] + 32) >> 6; a=((64 - weight) * colors.a[c0] + weight * colors.a[c1] + 32) >> 6; /* Interpolate alpha for mode 4 and 5 blocks / if (mode == 4 \|\| mode == 5) { unsigned char a0; a0=alpha_indices[i]; if (a0 < sizeof(BC7_weight2)) weight=BC7_weight2[a0]; if ((mode == 4) && (selector_bit == 0) && (a0 < sizeof(BC7_weight3))) weight=BC7_weight3[a0]; if ((c0 < sizeof(colors.a)) && (c1 < sizeof(colors.a))) a=((64 - weight) colors.a[c0] + weight * colors.a[c1] + 32) >> 6; } switch (rotation) { case 1: Swap(a,r); break; case 2: Swap(a,g); break; case 3: Swap(a,b); break; } SetPixelRed(image,ScaleCharToQuantum((unsigned char)r),q); SetPixelGreen(image,ScaleCharToQuantum((unsigned char)g),q); SetPixelBlue(image,ScaleCharToQuantum((unsigned char)b),q); SetPixelAlpha(image,ScaleCharToQuantum((unsigned char)a),q); q+=GetPixelChannels(image); } if (SyncAuthenticPixels(image,exception) == MagickFalse) return(MagickFalse); } if (EOFBlob(image) != MagickFalse) return(MagickFalse); } return(MagickTrue); } static MagickBooleanType ReadBC7(const ImageInfo image_info,Image image, const DDSInfo dds_info,const MagickBooleanType read_mipmaps, ExceptionInfo exception) { if (ReadBC7Pixels(image,dds_info,exception) == MagickFalse) return(MagickFalse); if (read_mipmaps != MagickFalse) return(ReadMipmaps(image_info,image,dds_info,ReadBC7Pixels,exception)); else return(SkipDXTMipmaps(image,dds_info,16,exception)); } static MagickBooleanType ReadUncompressedRGBPixels(Image image, const DDSInfo dds_info,ExceptionInfo exception) { Quantum q; ssize_t x, y; unsigned short color; for (y = 0; y < (ssize_t) image->rows; y++) { q=QueueAuthenticPixels(image,0,y,image->columns,1,exception); if (q == (Quantum ) NULL) return(MagickFalse); for (x = 0; x < (ssize_t) image->columns; x++) { if (dds_info->pixelformat.rgb_bitcount == 8 \|\| dds_info->extFormat == DXGI_FORMAT_R8_UNORM) SetPixelGray(image,ScaleCharToQuantum(ReadBlobByte(image)),q); else if (dds_info->pixelformat.rgb_bitcount == 16 \|\| dds_info->extFormat == DXGI_FORMAT_B5G6R5_UNORM) { color=ReadBlobShort(image); SetPixelRed(image,ScaleCharToQuantum((unsigned char) (((color >> 11)/31.0)255)),q); SetPixelGreen(image,ScaleCharToQuantum((unsigned char) ((((unsigned short)(color << 5) >> 10)/63.0)255)),q); SetPixelBlue(image,ScaleCharToQuantum((unsigned char) ((((unsigned short)(color << 11) >> 11)/31.0)255)),q); } else { SetPixelBlue(image,ScaleCharToQuantum((unsigned char) ReadBlobByte(image)),q); SetPixelGreen(image,ScaleCharToQuantum((unsigned char) ReadBlobByte(image)),q); SetPixelRed(image,ScaleCharToQuantum((unsigned char) ReadBlobByte(image)),q); if (dds_info->pixelformat.rgb_bitcount == 32 \|\| dds_info->extFormat == DXGI_FORMAT_B8G8R8X8_UNORM) (void) ReadBlobByte(image); } q+=GetPixelChannels(image); } if (SyncAuthenticPixels(image,exception) == MagickFalse) return(MagickFalse); if (EOFBlob(image) != MagickFalse) return(MagickFalse); } return(MagickTrue); } /* Skip the mipmap images for uncompressed (RGB or RGBA) dds files / static MagickBooleanType SkipRGBMipmaps(Image image,const DDSInfo dds_info, int pixel_size,ExceptionInfo exception) { /* Only skip mipmaps for textures and cube maps / if (EOFBlob(image) != MagickFalse) { ThrowFileException(exception,CorruptImageError,"UnexpectedEndOfFile", image->filename); return(MagickFalse); } if (dds_info->ddscaps1 & DDSCAPS_MIPMAP && (dds_info->ddscaps1 & DDSCAPS_TEXTURE \|\| dds_info->ddscaps2 & DDSCAPS2_CUBEMAP)) { MagickOffsetType offset; ssize_t i; size_t h, w; w=DIV2(dds_info->width); h=DIV2(dds_info->height); / Mipmapcount includes the main image, so start from one / for (i=1; (i < (ssize_t) dds_info->mipmapcount) && w && h; i++) { offset=(MagickOffsetType)whpixel_size; if (SeekBlob(image,offset,SEEK_CUR) < 0) break; w=DIV2(w); h=DIV2(h); if ((w == 1) && (h == 1)) break; } } return(MagickTrue); } static MagickBooleanType ReadUncompressedRGB(const ImageInfo image_info, Image image,const DDSInfo dds_info,const MagickBooleanType read_mipmaps, ExceptionInfo exception) { if (dds_info->pixelformat.rgb_bitcount == 8 \|\| dds_info->extFormat == DXGI_FORMAT_R8_UNORM) (void) SetImageType(image,GrayscaleType,exception); else if (dds_info->pixelformat.rgb_bitcount == 16 && !IsBitMask( dds_info->pixelformat,0xf800,0x07e0,0x001f,0x0000)) ThrowBinaryException(CorruptImageError,"ImageTypeNotSupported", image->filename); if (ReadUncompressedRGBPixels(image,dds_info,exception) == MagickFalse) return(MagickFalse); if (read_mipmaps != MagickFalse) return(ReadMipmaps(image_info,image,dds_info,ReadUncompressedRGBPixels, exception)); else return(SkipRGBMipmaps(image,dds_info,3,exception)); } static MagickBooleanType ReadUncompressedRGBAPixels(Image image, const DDSInfo dds_info,ExceptionInfo exception) { Quantum q; ssize_t alphaBits, x, y; unsigned short color; alphaBits=0; if (dds_info->pixelformat.rgb_bitcount == 16) { if (IsBitMask(dds_info->pixelformat,0x7c00,0x03e0,0x001f,0x8000)) alphaBits=1; else if (IsBitMask(dds_info->pixelformat,0x00ff,0x00ff,0x00ff,0xff00)) { alphaBits=2; (void) SetImageType(image,GrayscaleAlphaType,exception); } else if (IsBitMask(dds_info->pixelformat,0x0f00,0x00f0,0x000f,0xf000)) alphaBits=4; else ThrowBinaryException(CorruptImageError,"ImageTypeNotSupported", image->filename); } if (dds_info->extFormat == DXGI_FORMAT_B5G5R5A1_UNORM) alphaBits=1; for (y = 0; y < (ssize_t) image->rows; y++) { q = QueueAuthenticPixels(image, 0, y, image->columns, 1,exception); if (q == (Quantum ) NULL) return(MagickFalse); for (x = 0; x < (ssize_t) image->columns; x++) { if (dds_info->pixelformat.rgb_bitcount == 16 \|\| dds_info->extFormat == DXGI_FORMAT_B5G5R5A1_UNORM) { color=ReadBlobShort(image); if (alphaBits == 1) { SetPixelAlpha(image,(color & (1 << 15)) ? QuantumRange : 0,q); SetPixelRed(image,ScaleCharToQuantum((unsigned char) ((((unsigned short)(color << 1) >> 11)/31.0)255)),q); SetPixelGreen(image,ScaleCharToQuantum((unsigned char) ((((unsigned short)(color << 6) >> 11)/31.0)255)),q); SetPixelBlue(image,ScaleCharToQuantum((unsigned char) ((((unsigned short)(color << 11) >> 11)/31.0)255)),q); } else if (alphaBits == 2) { SetPixelAlpha(image,ScaleCharToQuantum((unsigned char) (color >> 8)),q); SetPixelGray(image,ScaleCharToQuantum((unsigned char)color),q); } else { SetPixelAlpha(image,ScaleCharToQuantum((unsigned char) (((color >> 12)/15.0)255)),q); SetPixelRed(image,ScaleCharToQuantum((unsigned char) ((((unsigned short)(color << 4) >> 12)/15.0)255)),q); SetPixelGreen(image,ScaleCharToQuantum((unsigned char) ((((unsigned short)(color << 8) >> 12)/15.0)255)),q); SetPixelBlue(image,ScaleCharToQuantum((unsigned char) ((((unsigned short)(color << 12) >> 12)/15.0)255)),q); } } else if (dds_info->extFormat == DXGI_FORMAT_R8G8B8A8_UNORM \|\| IsBitMask(dds_info->pixelformat,0x000000ff,0x0000ff00,0x00ff0000,0xff000000)) { SetPixelRed(image,ScaleCharToQuantum((unsigned char) ReadBlobByte(image)),q); SetPixelGreen(image,ScaleCharToQuantum((unsigned char) ReadBlobByte(image)),q); SetPixelBlue(image,ScaleCharToQuantum((unsigned char) ReadBlobByte(image)),q); SetPixelAlpha(image,ScaleCharToQuantum((unsigned char) ReadBlobByte(image)),q); } else { SetPixelBlue(image,ScaleCharToQuantum((unsigned char) ReadBlobByte(image)),q); SetPixelGreen(image,ScaleCharToQuantum((unsigned char) ReadBlobByte(image)),q); SetPixelRed(image,ScaleCharToQuantum((unsigned char) ReadBlobByte(image)),q); SetPixelAlpha(image,ScaleCharToQuantum((unsigned char) ReadBlobByte(image)),q); } q+=GetPixelChannels(image); } if (SyncAuthenticPixels(image,exception) == MagickFalse) return(MagickFalse); if (EOFBlob(image) != MagickFalse) return(MagickFalse); } return(MagickTrue); } static MagickBooleanType ReadUncompressedRGBA(const ImageInfo image_info, Image image,const DDSInfo dds_info,const MagickBooleanType read_mipmaps, ExceptionInfo exception) { if (ReadUncompressedRGBAPixels(image,dds_info,exception) == MagickFalse) return(MagickFalse); if (read_mipmaps != MagickFalse) return(ReadMipmaps(image_info,image,dds_info,ReadUncompressedRGBAPixels, exception)); else return(SkipRGBMipmaps(image,dds_info,4,exception)); } / %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % R e a d D D S I m a g e % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % ReadDDSImage() reads a DirectDraw Surface image file and returns it. It % allocates the memory necessary for the new Image structure and returns a % pointer to the new image. % % The format of the ReadDDSImage method is: % % Image ReadDDSImage(const ImageInfo image_info,ExceptionInfo exception) % % A description of each parameter follows: % % o image_info: The image info. % % o exception: return any errors or warnings in this structure. % / static Image ReadDDSImage(const ImageInfo image_info,ExceptionInfo exception) { const char option; CompressionType compression; DDSInfo dds_info; DDSDecoder decoder; Image image; MagickBooleanType status, cubemap, volume, read_mipmaps; PixelTrait alpha_trait; size_t n, num_images; /* Open image file. / assert(image_info != (const ImageInfo ) NULL); assert(image_info->signature == MagickCoreSignature); if (image_info->debug != MagickFalse) (void) LogMagickEvent(TraceEvent,GetMagickModule(),"%s", image_info->filename); assert(exception != (ExceptionInfo ) NULL); assert(exception->signature == MagickCoreSignature); cubemap=MagickFalse, volume=MagickFalse, read_mipmaps=MagickFalse; image=AcquireImage(image_info,exception); status=OpenBlob(image_info,image,ReadBinaryBlobMode,exception); if (status == MagickFalse) { image=DestroyImageList(image); return((Image ) NULL); } /* Initialize image structure. / if (ReadDDSInfo(image, &dds_info) != MagickTrue) ThrowReaderException(CorruptImageError,"ImproperImageHeader"); if (dds_info.ddscaps2 & DDSCAPS2_CUBEMAP) cubemap = MagickTrue; if (dds_info.ddscaps2 & DDSCAPS2_VOLUME && dds_info.depth > 0) volume = MagickTrue; / Determine pixel format / if (dds_info.pixelformat.flags & DDPF_RGB) { compression = NoCompression; if (dds_info.pixelformat.flags & DDPF_ALPHAPIXELS) { alpha_trait = BlendPixelTrait; decoder = ReadUncompressedRGBA; } else { alpha_trait = UndefinedPixelTrait; decoder = ReadUncompressedRGB; } } else if (dds_info.pixelformat.flags & DDPF_LUMINANCE) { compression = NoCompression; if (dds_info.pixelformat.flags & DDPF_ALPHAPIXELS) { / Not sure how to handle this / ThrowReaderException(CorruptImageError, "ImageTypeNotSupported"); } else { alpha_trait = UndefinedPixelTrait; decoder = ReadUncompressedRGB; } } else if (dds_info.pixelformat.flags & DDPF_FOURCC) { switch (dds_info.pixelformat.fourcc) { case FOURCC_DXT1: { alpha_trait = UndefinedPixelTrait; compression = DXT1Compression; decoder = ReadDXT1; break; } case FOURCC_DXT3: { alpha_trait = BlendPixelTrait; compression = DXT3Compression; decoder = ReadDXT3; break; } case FOURCC_DXT5: { alpha_trait = BlendPixelTrait; compression = DXT5Compression; decoder = ReadDXT5; break; } case FOURCC_DX10: { if (dds_info.extDimension != DDSEXT_DIMENSION_TEX2D) { ThrowReaderException(CorruptImageError, "ImageTypeNotSupported"); } switch (dds_info.extFormat) { case DXGI_FORMAT_R8_UNORM: { compression = NoCompression; alpha_trait = UndefinedPixelTrait; decoder = ReadUncompressedRGB; break; } case DXGI_FORMAT_B5G6R5_UNORM: { compression = NoCompression; alpha_trait = UndefinedPixelTrait; decoder = ReadUncompressedRGB; break; } case DXGI_FORMAT_B5G5R5A1_UNORM: { compression = NoCompression; alpha_trait = BlendPixelTrait; decoder = ReadUncompressedRGBA; break; } case DXGI_FORMAT_B8G8R8A8_UNORM: { compression = NoCompression; alpha_trait = BlendPixelTrait; decoder = ReadUncompressedRGBA; break; } case DXGI_FORMAT_R8G8B8A8_UNORM: { compression = NoCompression; alpha_trait = BlendPixelTrait; decoder = ReadUncompressedRGBA; break; } case DXGI_FORMAT_B8G8R8X8_UNORM: { compression = NoCompression; alpha_trait = UndefinedPixelTrait; decoder = ReadUncompressedRGB; break; } case DXGI_FORMAT_BC1_UNORM: { alpha_trait = UndefinedPixelTrait; compression = DXT1Compression; decoder = ReadDXT1; break; } case DXGI_FORMAT_BC2_UNORM: { alpha_trait = BlendPixelTrait; compression = DXT3Compression; decoder = ReadDXT3; break; } case DXGI_FORMAT_BC3_UNORM: { alpha_trait = BlendPixelTrait; compression = DXT5Compression; decoder = ReadDXT5; break; } case DXGI_FORMAT_BC7_UNORM: case DXGI_FORMAT_BC7_UNORM_SRGB: { alpha_trait = BlendPixelTrait; compression = BC7Compression; decoder = ReadBC7; break; } default: { / Unknown format / ThrowReaderException(CorruptImageError, "ImageTypeNotSupported"); } } if (dds_info.extFlags & DDSEXTFLAGS_CUBEMAP) cubemap = MagickTrue; num_images = dds_info.extArraySize; break; } default: { / Unknown FOURCC / ThrowReaderException(CorruptImageError, "ImageTypeNotSupported"); } } } else { / Neither compressed nor uncompressed... thus unsupported / ThrowReaderException(CorruptImageError, "ImageTypeNotSupported"); } num_images = 1; if (cubemap) { / Determine number of faces defined in the cubemap / num_images = 0; if (dds_info.ddscaps2 & DDSCAPS2_CUBEMAP_POSITIVEX) num_images++; if (dds_info.ddscaps2 & DDSCAPS2_CUBEMAP_NEGATIVEX) num_images++; if (dds_info.ddscaps2 & DDSCAPS2_CUBEMAP_POSITIVEY) num_images++; if (dds_info.ddscaps2 & DDSCAPS2_CUBEMAP_NEGATIVEY) num_images++; if (dds_info.ddscaps2 & DDSCAPS2_CUBEMAP_POSITIVEZ) num_images++; if (dds_info.ddscaps2 & DDSCAPS2_CUBEMAP_NEGATIVEZ) num_images++; } if (volume) num_images = dds_info.depth; if ((num_images == 0) \|\| (num_images > GetBlobSize(image))) ThrowReaderException(CorruptImageError,"ImproperImageHeader"); if (AcquireMagickResource(ListLengthResource,num_images) == MagickFalse) ThrowReaderException(ResourceLimitError,"ListLengthExceedsLimit"); option=GetImageOption(image_info,"dds:skip-mipmaps"); if (IsStringFalse(option) != MagickFalse) read_mipmaps=MagickTrue; for (n = 0; n < num_images; n++) { if (n != 0) { / Start a new image / if (EOFBlob(image) != MagickFalse) ThrowReaderException(CorruptImageError,"UnexpectedEndOfFile"); AcquireNextImage(image_info,image,exception); if (GetNextImageInList(image) == (Image ) NULL) return(DestroyImageList(image)); image=SyncNextImageInList(image); } image->alpha_trait=alpha_trait; image->compression=compression; image->columns=dds_info.width; image->rows=dds_info.height; image->storage_class=DirectClass; image->endian=LSBEndian; image->depth=8; if (image_info->ping != MagickFalse) { (void) CloseBlob(image); return(GetFirstImageInList(image)); } status=SetImageExtent(image,image->columns,image->rows,exception); if (status == MagickFalse) return(DestroyImageList(image)); (void) SetImageBackgroundColor(image,exception); status=(decoder)(image_info,image,&dds_info,read_mipmaps,exception); if (status == MagickFalse) { (void) CloseBlob(image); if (n == 0) return(DestroyImageList(image)); return(GetFirstImageInList(image)); } } (void) CloseBlob(image); return(GetFirstImageInList(image)); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % R e g i s t e r D D S I m a g e % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % RegisterDDSImage() adds attributes for the DDS image format to % the list of supported formats. The attributes include the image format % tag, a method to read and/or write the format, whether the format % supports the saving of more than one frame to the same file or blob, % whether the format supports native in-memory I/O, and a brief % description of the format. % % The format of the RegisterDDSImage method is: % % RegisterDDSImage(void) % / ModuleExport size_t RegisterDDSImage(void) { MagickInfo entry; entry = AcquireMagickInfo("DDS","DDS","Microsoft DirectDraw Surface"); entry->decoder = (DecodeImageHandler ) ReadDDSImage; entry->encoder = (EncodeImageHandler ) WriteDDSImage; entry->magick = (IsImageFormatHandler ) IsDDS; entry->flags\|=CoderDecoderSeekableStreamFlag; (void) RegisterMagickInfo(entry); entry = AcquireMagickInfo("DDS","DXT1","Microsoft DirectDraw Surface"); entry->decoder = (DecodeImageHandler ) ReadDDSImage; entry->encoder = (EncodeImageHandler ) WriteDDSImage; entry->magick = (IsImageFormatHandler ) IsDDS; entry->flags\|=CoderDecoderSeekableStreamFlag; (void) RegisterMagickInfo(entry); entry = AcquireMagickInfo("DDS","DXT5","Microsoft DirectDraw Surface"); entry->decoder = (DecodeImageHandler ) ReadDDSImage; entry->encoder = (EncodeImageHandler ) WriteDDSImage; entry->magick = (IsImageFormatHandler ) IsDDS; entry->flags\|=CoderDecoderSeekableStreamFlag; (void) RegisterMagickInfo(entry); return(MagickImageCoderSignature); } static void RemapIndices(const ssize_t map, const unsigned char source, unsigned char target) { ssize_t i; for (i = 0; i < 16; i++) { if (map[i] == -1) target[i] = 3; else target[i] = source[map[i]]; } } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % U n r e g i s t e r D D S I m a g e % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % UnregisterDDSImage() removes format registrations made by the % DDS module from the list of supported formats. % % The format of the UnregisterDDSImage method is: % % UnregisterDDSImage(void) % / ModuleExport void UnregisterDDSImage(void) { (void) UnregisterMagickInfo("DDS"); (void) UnregisterMagickInfo("DXT1"); (void) UnregisterMagickInfo("DXT5"); } / %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % W r i t e D D S I m a g e % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % WriteDDSImage() writes a DirectDraw Surface image file in the DXT5 format. % % The format of the WriteDDSImage method is: % % MagickBooleanType WriteDDSImage(const ImageInfo image_info,Image image) % % A description of each parameter follows. % % o image_info: the image info. % % o image: The image. % / static size_t CompressAlpha(const size_t min, const size_t max, const size_t steps, const ssize_t alphas, unsigned char* indices) { unsigned char codes[8]; ssize_t i; size_t error, index, j, least, value; codes[0] = (unsigned char) min; codes[1] = (unsigned char) max; codes[6] = 0; codes[7] = 255; for (i=1; i < (ssize_t) steps; i++) codes[i+1] = (unsigned char) (((steps-i)min + imax) / steps); error = 0; for (i=0; i<16; i++) { if (alphas[i] == -1) { indices[i] = 0; continue; } value = alphas[i]; least = SIZE_MAX; index = 0; for (j=0; j<8; j++) { size_t dist; dist = value - (size_t)codes[j]; dist = dist; if (dist < least) { least = dist; index = j; } } indices[i] = (unsigned char)index; error += least; } return error; } static MagickBooleanType ConstructOrdering(const size_t count, const DDSVector4 points, const DDSVector3 axis, DDSVector4 pointsWeights, DDSVector4 xSumwSum, unsigned char order, size_t iteration) { float dps[16], f; ssize_t i; size_t j; unsigned char c, o, p; o = order + (16iteration); for (i=0; i < (ssize_t) count; i++) { dps[i] = Dot(points[i],axis); o[i] = (unsigned char)i; } for (i=0; i < (ssize_t) count; i++) { for (j=i; j > 0 && dps[j] < dps[j - 1]; j--) { f = dps[j]; dps[j] = dps[j - 1]; dps[j - 1] = f; c = o[j]; o[j] = o[j - 1]; o[j - 1] = c; } } for (i=0; i < (ssize_t) iteration; i++) { MagickBooleanType same; p = order + (16i); same = MagickTrue; for (j=0; j < count; j++) { if (o[j] != p[j]) { same = MagickFalse; break; } } if (same != MagickFalse) return MagickFalse; } xSumwSum->x = 0; xSumwSum->y = 0; xSumwSum->z = 0; xSumwSum->w = 0; for (i=0; i < (ssize_t) count; i++) { DDSVector4 v; j = (size_t) o[i]; v.x = points[j].w points[j].x; v.y = points[j].w * points[j].y; v.z = points[j].w * points[j].z; v.w = points[j].w * 1.0f; VectorCopy44(v,&pointsWeights[i]); VectorAdd(xSumwSum,v,xSumwSum); } return MagickTrue; } static void CompressClusterFit(const size_t count, const DDSVector4 points, const ssize_t map, const DDSVector3 principle, const DDSVector4 metric, DDSVector3 start, DDSVector3* end, unsigned char indices) { DDSVector3 axis; DDSVector4 grid, gridrcp, half, onethird_onethird2, pointsWeights[16], two, twonineths, twothirds_twothirds2, xSumwSum; float bestError = 1e+37f; size_t bestIteration = 0, besti = 0, bestj = 0, bestk = 0, iterationIndex; ssize_t i; unsigned char o, order[128], unordered[16]; VectorInit(half,0.5f); VectorInit(two,2.0f); VectorInit(onethird_onethird2,1.0f/3.0f); onethird_onethird2.w = 1.0f/9.0f; VectorInit(twothirds_twothirds2,2.0f/3.0f); twothirds_twothirds2.w = 4.0f/9.0f; VectorInit(twonineths,2.0f/9.0f); grid.x = 31.0f; grid.y = 63.0f; grid.z = 31.0f; grid.w = 0.0f; gridrcp.x = 1.0f/31.0f; gridrcp.y = 1.0f/63.0f; gridrcp.z = 1.0f/31.0f; gridrcp.w = 0.0f; xSumwSum.x = 0.0f; xSumwSum.y = 0.0f; xSumwSum.z = 0.0f; xSumwSum.w = 0.0f; ConstructOrdering(count,points,principle,pointsWeights,&xSumwSum,order,0); for (iterationIndex = 0;;) { #if defined(MAGICKCORE_OPENMP_SUPPORT) #pragma omp parallel for schedule(dynamic,1) \ num_threads(GetMagickResourceLimit(ThreadResource)) #endif for (i=0; i < (ssize_t) count; i++) { DDSVector4 part0, part1, part2; size_t ii, j, k, kmin; VectorInit(part0,0.0f); for(ii=0; ii < (size_t) i; ii++) VectorAdd(pointsWeights[ii],part0,&part0); VectorInit(part1,0.0f); for (j=(size_t) i;;) { if (j == 0) { VectorCopy44(pointsWeights[0],&part2); kmin = 1; } else { VectorInit(part2,0.0f); kmin = j; } for (k=kmin;;) { DDSVector4 a, alpha2_sum, alphax_sum, alphabeta_sum, b, beta2_sum, betax_sum, e1, e2, factor, part3; float error; VectorSubtract(xSumwSum,part2,&part3); VectorSubtract(part3,part1,&part3); VectorSubtract(part3,part0,&part3); VectorMultiplyAdd(part1,twothirds_twothirds2,part0,&alphax_sum); VectorMultiplyAdd(part2,onethird_onethird2,alphax_sum,&alphax_sum); VectorInit(alpha2_sum,alphax_sum.w); VectorMultiplyAdd(part2,twothirds_twothirds2,part3,&betax_sum); VectorMultiplyAdd(part1,onethird_onethird2,betax_sum,&betax_sum); VectorInit(beta2_sum,betax_sum.w); VectorAdd(part1,part2,&alphabeta_sum); VectorInit(alphabeta_sum,alphabeta_sum.w); VectorMultiply(twonineths,alphabeta_sum,&alphabeta_sum); VectorMultiply(alpha2_sum,beta2_sum,&factor); VectorNegativeMultiplySubtract(alphabeta_sum,alphabeta_sum,factor, &factor); VectorReciprocal(factor,&factor); VectorMultiply(alphax_sum,beta2_sum,&a); VectorNegativeMultiplySubtract(betax_sum,alphabeta_sum,a,&a); VectorMultiply(a,factor,&a); VectorMultiply(betax_sum,alpha2_sum,&b); VectorNegativeMultiplySubtract(alphax_sum,alphabeta_sum,b,&b); VectorMultiply(b,factor,&b); VectorClamp(&a); VectorMultiplyAdd(grid,a,half,&a); VectorTruncate(&a); VectorMultiply(a,gridrcp,&a); VectorClamp(&b); VectorMultiplyAdd(grid,b,half,&b); VectorTruncate(&b); VectorMultiply(b,gridrcp,&b); VectorMultiply(b,b,&e1); VectorMultiply(e1,beta2_sum,&e1); VectorMultiply(a,a,&e2); VectorMultiplyAdd(e2,alpha2_sum,e1,&e1); VectorMultiply(a,b,&e2); VectorMultiply(e2,alphabeta_sum,&e2); VectorNegativeMultiplySubtract(a,alphax_sum,e2,&e2); VectorNegativeMultiplySubtract(b,betax_sum,e2,&e2); VectorMultiplyAdd(two,e2,e1,&e2); VectorMultiply(e2,metric,&e2); error = e2.x + e2.y + e2.z; if (error < bestError) { #if defined(MAGICKCORE_OPENMP_SUPPORT) #pragma omp critical (DDS_CompressClusterFit) #endif { if (error < bestError) { VectorCopy43(a,start); VectorCopy43(b,end); bestError = error; besti = i; bestj = j; bestk = k; bestIteration = iterationIndex; } } } if (k == count) break; VectorAdd(pointsWeights[k],part2,&part2); k++; } if (j == count) break; VectorAdd(pointsWeights[j],part1,&part1); j++; } } if (bestIteration != iterationIndex) break; iterationIndex++; if (iterationIndex == 8) break; VectorSubtract3(end,start,&axis); if (ConstructOrdering(count,points,axis,pointsWeights,&xSumwSum,order, iterationIndex) == MagickFalse) break; } o = order + (16bestIteration); for (i=0; i < (ssize_t) besti; i++) unordered[o[i]] = 0; for (i=besti; i < (ssize_t) bestj; i++) unordered[o[i]] = 2; for (i=bestj; i < (ssize_t) bestk; i++) unordered[o[i]] = 3; for (i=bestk; i < (ssize_t) count; i++) unordered[o[i]] = 1; RemapIndices(map,unordered,indices); } static void CompressRangeFit(const size_t count, const DDSVector4 points, const ssize_t map, const DDSVector3 principle, const DDSVector4 metric, DDSVector3 start, DDSVector3 end, unsigned char indices) { float d, bestDist, max, min, val; DDSVector3 codes[4], grid, gridrcp, half, dist; ssize_t i; size_t bestj, j; unsigned char closest[16]; VectorInit3(half,0.5f); grid.x = 31.0f; grid.y = 63.0f; grid.z = 31.0f; gridrcp.x = 1.0f/31.0f; gridrcp.y = 1.0f/63.0f; gridrcp.z = 1.0f/31.0f; if (count > 0) { VectorCopy43(points[0],start); VectorCopy43(points[0],end); min = max = Dot(points[0],principle); for (i=1; i < (ssize_t) count; i++) { val = Dot(points[i],principle); if (val < min) { VectorCopy43(points[i],start); min = val; } else if (val > max) { VectorCopy43(points[i],end); max = val; } } } VectorClamp3(start); VectorMultiplyAdd3(grid,start,half,start); VectorTruncate3(start); VectorMultiply3(start,gridrcp,start); VectorClamp3(end); VectorMultiplyAdd3(grid,end,half,end); VectorTruncate3(end); VectorMultiply3(end,gridrcp,end); codes[0] = start; codes[1] = end; codes[2].x = (start->x * (2.0f/3.0f)) + (end->x * (1.0f/3.0f)); codes[2].y = (start->y * (2.0f/3.0f)) + (end->y * (1.0f/3.0f)); codes[2].z = (start->z * (2.0f/3.0f)) + (end->z * (1.0f/3.0f)); codes[3].x = (start->x * (1.0f/3.0f)) + (end->x * (2.0f/3.0f)); codes[3].y = (start->y * (1.0f/3.0f)) + (end->y * (2.0f/3.0f)); codes[3].z = (start->z * (1.0f/3.0f)) + (end->z * (2.0f/3.0f)); for (i=0; i < (ssize_t) count; i++) { bestDist = 1e+37f; bestj = 0; for (j=0; j < 4; j++) { dist.x = (points[i].x - codes[j].x) * metric.x; dist.y = (points[i].y - codes[j].y) * metric.y; dist.z = (points[i].z - codes[j].z) * metric.z; d = Dot(dist,dist); if (d < bestDist) { bestDist = d; bestj = j; } } closest[i] = (unsigned char) bestj; } RemapIndices(map, closest, indices); } static void ComputeEndPoints(const DDSSingleColorLookup lookup[], const unsigned char color, DDSVector3 start, DDSVector3 end, unsigned char index) { ssize_t i; size_t c, maxError = SIZE_MAX; for (i=0; i < 2; i++) { const DDSSourceBlock sources[3]; size_t error = 0; for (c=0; c < 3; c++) { sources[c] = &lookup[c][color[c]].sources[i]; error += ((size_t) sources[c]->error) * ((size_t) sources[c]->error); } if (error > maxError) continue; start->x = (float) sources[0]->start / 31.0f; start->y = (float) sources[1]->start / 63.0f; start->z = (float) sources[2]->start / 31.0f; end->x = (float) sources[0]->end / 31.0f; end->y = (float) sources[1]->end / 63.0f; end->z = (float) sources[2]->end / 31.0f; index = (unsigned char) (2i); maxError = error; } } static void ComputePrincipleComponent(const float covariance, DDSVector3 principle) { DDSVector4 row0, row1, row2, v; ssize_t i; row0.x = covariance[0]; row0.y = covariance[1]; row0.z = covariance[2]; row0.w = 0.0f; row1.x = covariance[1]; row1.y = covariance[3]; row1.z = covariance[4]; row1.w = 0.0f; row2.x = covariance[2]; row2.y = covariance[4]; row2.z = covariance[5]; row2.w = 0.0f; VectorInit(v,1.0f); for (i=0; i < 8; i++) { DDSVector4 w; float a; w.x = row0.x * v.x; w.y = row0.y * v.x; w.z = row0.z * v.x; w.w = row0.w * v.x; w.x = (row1.x * v.y) + w.x; w.y = (row1.y * v.y) + w.y; w.z = (row1.z * v.y) + w.z; w.w = (row1.w * v.y) + w.w; w.x = (row2.x * v.z) + w.x; w.y = (row2.y * v.z) + w.y; w.z = (row2.z * v.z) + w.z; w.w = (row2.w * v.z) + w.w; a = (float) PerceptibleReciprocal(MagickMax(w.x,MagickMax(w.y,w.z))); v.x = w.x * a; v.y = w.y * a; v.z = w.z * a; v.w = w.w * a; } VectorCopy43(v,principle); } static void ComputeWeightedCovariance(const size_t count, const DDSVector4 points, float covariance) { DDSVector3 centroid; float total; size_t i; total = 0.0f; VectorInit3(centroid,0.0f); for (i=0; i < count; i++) { total += points[i].w; centroid.x += (points[i].x * points[i].w); centroid.y += (points[i].y * points[i].w); centroid.z += (points[i].z * points[i].w); } if( total > 1.192092896e-07F) { centroid.x /= total; centroid.y /= total; centroid.z /= total; } for (i=0; i < 6; i++) covariance[i] = 0.0f; for (i = 0; i < count; i++) { DDSVector3 a, b; a.x = points[i].x - centroid.x; a.y = points[i].y - centroid.y; a.z = points[i].z - centroid.z; b.x = points[i].w * a.x; b.y = points[i].w * a.y; b.z = points[i].w * a.z; covariance[0] += a.xb.x; covariance[1] += a.xb.y; covariance[2] += a.xb.z; covariance[3] += a.yb.y; covariance[4] += a.yb.z; covariance[5] += a.zb.z; } } static void WriteAlphas(Image image, const ssize_t alphas, size_t min5, size_t max5, size_t min7, size_t max7) { ssize_t i; size_t err5, err7, j; unsigned char indices5[16], indices7[16]; FixRange(min5,max5,5); err5 = CompressAlpha(min5,max5,5,alphas,indices5); FixRange(min7,max7,7); err7 = CompressAlpha(min7,max7,7,alphas,indices7); if (err7 < err5) { for (i=0; i < 16; i++) { unsigned char index; index = indices7[i]; if( index == 0 ) indices5[i] = 1; else if (index == 1) indices5[i] = 0; else indices5[i] = 9 - index; } min5 = max7; max5 = min7; } (void) WriteBlobByte(image,(unsigned char) min5); (void) WriteBlobByte(image,(unsigned char) max5); for(i=0; i < 2; i++) { size_t value = 0; for (j=0; j < 8; j++) { size_t index = (size_t) indices5[j + i8]; value \|= ( index << 3j ); } for (j=0; j < 3; j++) { size_t byte = (value >> 8j) & 0xff; (void) WriteBlobByte(image,(unsigned char) byte); } } } static void WriteIndices(Image image, const DDSVector3 start, const DDSVector3 end, unsigned char indices) { ssize_t i; size_t a, b; unsigned char remapped[16]; const unsigned char ind; a = ColorTo565(start); b = ColorTo565(end); for (i=0; i<16; i++) { if( a < b ) remapped[i] = (indices[i] ^ 0x1) & 0x3; else if( a == b ) remapped[i] = 0; else remapped[i] = indices[i]; } if( a < b ) Swap(a,b); (void) WriteBlobByte(image,(unsigned char) (a & 0xff)); (void) WriteBlobByte(image,(unsigned char) (a >> 8)); (void) WriteBlobByte(image,(unsigned char) (b & 0xff)); (void) WriteBlobByte(image,(unsigned char) (b >> 8)); for (i=0; i<4; i++) { ind = remapped + 4i; (void) WriteBlobByte(image,ind[0] \| (ind[1] << 2) \| (ind[2] << 4) \| (ind[3] << 6)); } } static void WriteCompressed(Image image, const size_t count, DDSVector4 points, const ssize_t map, const MagickBooleanType clusterFit) { float covariance[16]; DDSVector3 end, principle, start; DDSVector4 metric; unsigned char indices[16]; VectorInit(metric,1.0f); VectorInit3(start,0.0f); VectorInit3(end,0.0f); ComputeWeightedCovariance(count,points,covariance); ComputePrincipleComponent(covariance,&principle); if ((clusterFit == MagickFalse) \|\| (count == 0)) CompressRangeFit(count,points,map,principle,metric,&start,&end,indices); else CompressClusterFit(count,points,map,principle,metric,&start,&end,indices); WriteIndices(image,start,end,indices); } static void WriteSingleColorFit(Image image, const DDSVector4 points, const ssize_t map) { DDSVector3 start, end; ssize_t i; unsigned char color[3], index, indexes[16], indices[16]; color[0] = (unsigned char) ClampToLimit(255.0fpoints->x,255); color[1] = (unsigned char) ClampToLimit(255.0fpoints->y,255); color[2] = (unsigned char) ClampToLimit(255.0fpoints->z,255); index=0; ComputeEndPoints(DDS_LOOKUP,color,&start,&end,&index); for (i=0; i< 16; i++) indexes[i]=index; RemapIndices(map,indexes,indices); WriteIndices(image,start,end,indices); } static void WriteFourCC(Image image, const size_t compression, const MagickBooleanType clusterFit, const MagickBooleanType weightByAlpha, ExceptionInfo exception) { ssize_t x; ssize_t i, y, bx, by; const Quantum p; for (y=0; y < (ssize_t) image->rows; y+=4) { for (x=0; x < (ssize_t) image->columns; x+=4) { MagickBooleanType match; DDSVector4 point, points[16]; size_t count = 0, max5 = 0, max7 = 0, min5 = 255, min7 = 255, columns = 4, rows = 4; ssize_t alphas[16], map[16]; unsigned char alpha; if (x + columns >= image->columns) columns = image->columns - x; if (y + rows >= image->rows) rows = image->rows - y; p=GetVirtualPixels(image,x,y,columns,rows,exception); if (p == (const Quantum ) NULL) break; for (i=0; i<16; i++) { map[i] = -1; alphas[i] = -1; } for (by=0; by < (ssize_t) rows; by++) { for (bx=0; bx < (ssize_t) columns; bx++) { if (compression == FOURCC_DXT5) alpha = ScaleQuantumToChar(GetPixelAlpha(image,p)); else alpha = 255; if (compression == FOURCC_DXT5) { if (alpha < min7) min7 = alpha; if (alpha > max7) max7 = alpha; if (alpha != 0 && alpha < min5) min5 = alpha; if (alpha != 255 && alpha > max5) max5 = alpha; } alphas[4by + bx] = (size_t)alpha; point.x = (float)ScaleQuantumToChar(GetPixelRed(image,p)) / 255.0f; point.y = (float)ScaleQuantumToChar(GetPixelGreen(image,p)) / 255.0f; point.z = (float)ScaleQuantumToChar(GetPixelBlue(image,p)) / 255.0f; point.w = weightByAlpha ? (float)(alpha + 1) / 256.0f : 1.0f; p+=GetPixelChannels(image); match = MagickFalse; for (i=0; i < (ssize_t) count; i++) { if ((points[i].x == point.x) && (points[i].y == point.y) && (points[i].z == point.z) && (alpha >= 128 \|\| compression == FOURCC_DXT5)) { points[i].w += point.w; map[4by + bx] = i; match = MagickTrue; break; } } if (match != MagickFalse) continue; points[count].x = point.x; points[count].y = point.y; points[count].z = point.z; points[count].w = point.w; map[4by + bx] = count; count++; } } for (i=0; i < (ssize_t) count; i++) points[i].w = sqrt(points[i].w); if (compression == FOURCC_DXT5) WriteAlphas(image,alphas,min5,max5,min7,max7); if (count == 1) WriteSingleColorFit(image,points,map); else WriteCompressed(image,count,points,map,clusterFit); } } } static void WriteUncompressed(Image image, ExceptionInfo exception) { const Quantum p; ssize_t x; ssize_t y; for (y=0; y < (ssize_t) image->rows; y++) { p=GetVirtualPixels(image,0,y,image->columns,1,exception); if (p == (const Quantum ) NULL) break; for (x=0; x < (ssize_t) image->columns; x++) { (void) WriteBlobByte(image,ScaleQuantumToChar(GetPixelBlue(image,p))); (void) WriteBlobByte(image,ScaleQuantumToChar(GetPixelGreen(image,p))); (void) WriteBlobByte(image,ScaleQuantumToChar(GetPixelRed(image,p))); if (image->alpha_trait != UndefinedPixelTrait) (void) WriteBlobByte(image,ScaleQuantumToChar(GetPixelAlpha(image,p))); p+=GetPixelChannels(image); } } } static void WriteImageData(Image image, const size_t pixelFormat, const size_t compression,const MagickBooleanType clusterFit, const MagickBooleanType weightByAlpha, ExceptionInfo exception) { if (pixelFormat == DDPF_FOURCC) WriteFourCC(image,compression,clusterFit,weightByAlpha,exception); else WriteUncompressed(image,exception); } static MagickBooleanType WriteMipmaps(Image image,const ImageInfo image_info, const size_t pixelFormat,const size_t compression,const size_t mipmaps, const MagickBooleanType fromlist,const MagickBooleanType clusterFit, const MagickBooleanType weightByAlpha,ExceptionInfo exception) { const char option; Image mipmap_image, resize_image; MagickBooleanType fast_mipmaps, status; ssize_t i; size_t columns, rows; columns=DIV2(image->columns); rows=DIV2(image->rows); option=GetImageOption(image_info,"dds:fast-mipmaps"); fast_mipmaps=IsStringTrue(option); mipmap_image=image; resize_image=image; status=MagickTrue; for (i=0; i < (ssize_t) mipmaps; i++) { if (fromlist == MagickFalse) { mipmap_image=ResizeImage(resize_image,columns,rows,TriangleFilter, exception); if (mipmap_image == (Image ) NULL) { status=MagickFalse; break; } } else { mipmap_image=mipmap_image->next; if ((mipmap_image->columns != columns) \|\| (mipmap_image->rows != rows)) ThrowBinaryException(CoderError,"ImageColumnOrRowSizeIsNotSupported", image->filename); } DestroyBlob(mipmap_image); mipmap_image->blob=ReferenceBlob(image->blob); WriteImageData(mipmap_image,pixelFormat,compression,weightByAlpha, clusterFit,exception); if (fromlist == MagickFalse) { if (fast_mipmaps == MagickFalse) mipmap_image=DestroyImage(mipmap_image); else { if (resize_image != image) resize_image=DestroyImage(resize_image); resize_image=mipmap_image; } } columns=DIV2(columns); rows=DIV2(rows); } if (resize_image != image) resize_image=DestroyImage(resize_image); return(status); } static void WriteDDSInfo(Image image, const size_t pixelFormat, const size_t compression, const size_t mipmaps) { char software[MagickPathExtent]; ssize_t i; unsigned int format, caps, flags; flags=(unsigned int) (DDSD_CAPS \| DDSD_WIDTH \| DDSD_HEIGHT \| DDSD_PIXELFORMAT); caps=(unsigned int) DDSCAPS_TEXTURE; format=(unsigned int) pixelFormat; if (format == DDPF_FOURCC) flags=flags \| DDSD_LINEARSIZE; else flags=flags \| DDSD_PITCH; if (mipmaps > 0) { flags=flags \| (unsigned int) DDSD_MIPMAPCOUNT; caps=caps \| (unsigned int) (DDSCAPS_MIPMAP \| DDSCAPS_COMPLEX); } if (format != DDPF_FOURCC && image->alpha_trait != UndefinedPixelTrait) format=format \| DDPF_ALPHAPIXELS; (void) WriteBlob(image,4,(unsigned char ) "DDS "); (void) WriteBlobLSBLong(image,124); (void) WriteBlobLSBLong(image,flags); (void) WriteBlobLSBLong(image,(unsigned int) image->rows); (void) WriteBlobLSBLong(image,(unsigned int) image->columns); if (pixelFormat == DDPF_FOURCC) { /* Compressed DDS requires linear compressed size of first image / if (compression == FOURCC_DXT1) (void) WriteBlobLSBLong(image,(unsigned int) (MagickMax(1, (image->columns+3)/4)MagickMax(1,(image->rows+3)/4)8)); else / DXT5 / (void) WriteBlobLSBLong(image,(unsigned int) (MagickMax(1, (image->columns+3)/4)MagickMax(1,(image->rows+3)/4)16)); } else { / Uncompressed DDS requires byte pitch of first image / if (image->alpha_trait != UndefinedPixelTrait) (void) WriteBlobLSBLong(image,(unsigned int) (image->columns 4)); else (void) WriteBlobLSBLong(image,(unsigned int) (image->columns * 3)); } (void) WriteBlobLSBLong(image,0x00); (void) WriteBlobLSBLong(image,(unsigned int) mipmaps+1); (void) memset(software,0,sizeof(software)); (void) CopyMagickString(software,"IMAGEMAGICK",MagickPathExtent); (void) WriteBlob(image,44,(unsigned char ) software); (void) WriteBlobLSBLong(image,32); (void) WriteBlobLSBLong(image,format); if (pixelFormat == DDPF_FOURCC) { (void) WriteBlobLSBLong(image,(unsigned int) compression); for(i=0;i < 5;i++) / bitcount / masks / (void) WriteBlobLSBLong(image,0x00); } else { (void) WriteBlobLSBLong(image,0x00); if (image->alpha_trait != UndefinedPixelTrait) { (void) WriteBlobLSBLong(image,32); (void) WriteBlobLSBLong(image,0xff0000); (void) WriteBlobLSBLong(image,0xff00); (void) WriteBlobLSBLong(image,0xff); (void) WriteBlobLSBLong(image,0xff000000); } else { (void) WriteBlobLSBLong(image,24); (void) WriteBlobLSBLong(image,0xff0000); (void) WriteBlobLSBLong(image,0xff00); (void) WriteBlobLSBLong(image,0xff); (void) WriteBlobLSBLong(image,0x00); } } (void) WriteBlobLSBLong(image,caps); for(i=0;i < 4;i++) / ddscaps2 + reserved region / (void) WriteBlobLSBLong(image,0x00); } static MagickBooleanType WriteDDSImage(const ImageInfo image_info, Image image, ExceptionInfo exception) { const char option; size_t compression, columns, maxMipmaps, mipmaps, pixelFormat, rows; MagickBooleanType clusterFit, fromlist, status, weightByAlpha; assert(image_info != (const ImageInfo ) NULL); assert(image_info->signature == MagickCoreSignature); assert(image != (Image ) NULL); assert(image->signature == MagickCoreSignature); if (image->debug != MagickFalse) (void) LogMagickEvent(TraceEvent,GetMagickModule(),"%s",image->filename); status=OpenBlob(image_info,image,WriteBinaryBlobMode,exception); if (status == MagickFalse) return(status); if (IssRGBCompatibleColorspace(image->colorspace) == MagickFalse) (void) TransformImageColorspace(image,sRGBColorspace,exception); pixelFormat=DDPF_FOURCC; compression=FOURCC_DXT5; if (image->alpha_trait == UndefinedPixelTrait) compression=FOURCC_DXT1; if (LocaleCompare(image_info->magick,"dxt1") == 0) compression=FOURCC_DXT1; if (image_info->compression == DXT1Compression) compression=FOURCC_DXT1; else if (image_info->compression == NoCompression) pixelFormat=DDPF_RGB; option=GetImageOption(image_info,"dds:compression"); if (option != (char ) NULL) { if (LocaleCompare(option,"dxt1") == 0) compression=FOURCC_DXT1; if (LocaleCompare(option,"none") == 0) pixelFormat=DDPF_RGB; } clusterFit=MagickFalse; weightByAlpha=MagickFalse; if (pixelFormat == DDPF_FOURCC) { option=GetImageOption(image_info,"dds:cluster-fit"); if (IsStringTrue(option) != MagickFalse) { clusterFit=MagickTrue; if (compression != FOURCC_DXT1) { option=GetImageOption(image_info,"dds:weight-by-alpha"); if (IsStringTrue(option) != MagickFalse) weightByAlpha=MagickTrue; } } } mipmaps=0; fromlist=MagickFalse; option=GetImageOption(image_info,"dds:mipmaps"); if (option != (char ) NULL) { if (LocaleNCompare(option,"fromlist",8) == 0) { Image next; fromlist=MagickTrue; next=image->next; while(next != (Image ) NULL) { mipmaps++; next=next->next; } } } if ((mipmaps == 0) && ((image->columns & (image->columns - 1)) == 0) && ((image->rows & (image->rows - 1)) == 0)) { maxMipmaps=SIZE_MAX; if (option != (char ) NULL) maxMipmaps=StringToUnsignedLong(option); if (maxMipmaps != 0) { columns=image->columns; rows=image->rows; while ((columns != 1 \|\| rows != 1) && mipmaps != maxMipmaps) { columns=DIV2(columns); rows=DIV2(rows); mipmaps++; } } } option=GetImageOption(image_info,"dds:raw"); if (IsStringTrue(option) == MagickFalse) WriteDDSInfo(image,pixelFormat,compression,mipmaps); else mipmaps=0; WriteImageData(image,pixelFormat,compression,clusterFit,weightByAlpha, exception); if ((mipmaps > 0) && (WriteMipmaps(image,image_info,pixelFormat,compression, mipmaps,fromlist,clusterFit,weightByAlpha,exception) == MagickFalse)) return(MagickFalse); (void) CloseBlob(image); return(MagickTrue); }
crop_and_resize.c	#include <TH/TH.h> #include <THC/THC.h> #include <stdio.h> #include <math.h> // symbol to be automatically resolved by PyTorch libs extern THCState state; void CropAndResizePerBox( const float image_data, const int batch_size, const int depth, const int image_height, const int image_width, const float * boxes_data, const int * box_index_data, const int start_box, const int limit_box, float * corps_data, const int crop_height, const int crop_width, const float extrapolation_value ) { const int image_channel_elements = image_height * image_width; const int image_elements = depth * image_channel_elements; const int channel_elements = crop_height * crop_width; const int crop_elements = depth * channel_elements; int b; #pragma omp parallel for for (b = start_box; b < limit_box; ++b) { const float * box = boxes_data + b * 4; const float y1 = box[0]; const float x1 = box[1]; const float y2 = box[2]; const float x2 = box[3]; const int b_in = box_index_data[b]; if (b_in < 0 \|\| b_in >= batch_size) { printf("Error: batch_index %d out of range [0, %d)\n", b_in, batch_size); exit(-1); } const float height_scale = (crop_height > 1) ? (y2 - y1) * (image_height - 1) / (crop_height - 1) : 0; const float width_scale = (crop_width > 1) ? (x2 - x1) * (image_width - 1) / (crop_width - 1) : 0; for (int y = 0; y < crop_height; ++y) { const float in_y = (crop_height > 1) ? y1 * (image_height - 1) + y * height_scale : 0.5 * (y1 + y2) * (image_height - 1); if (in_y < 0 \|\| in_y > image_height - 1) { for (int x = 0; x < crop_width; ++x) { for (int d = 0; d < depth; ++d) { // crops(b, y, x, d) = extrapolation_value; corps_data[crop_elements * b + channel_elements * d + y * crop_width + x] = extrapolation_value; } } continue; } const int top_y_index = floorf(in_y); const int bottom_y_index = ceilf(in_y); const float y_lerp = in_y - top_y_index; for (int x = 0; x < crop_width; ++x) { const float in_x = (crop_width > 1) ? x1 * (image_width - 1) + x * width_scale : 0.5 * (x1 + x2) * (image_width - 1); if (in_x < 0 \|\| in_x > image_width - 1) { for (int d = 0; d < depth; ++d) { corps_data[crop_elements * b + channel_elements * d + y * crop_width + x] = extrapolation_value; } continue; } const int left_x_index = floorf(in_x); const int right_x_index = ceilf(in_x); const float x_lerp = in_x - left_x_index; for (int d = 0; d < depth; ++d) { const float pimage = image_data + b_in image_elements + d * image_channel_elements; const float top_left = pimage[top_y_index * image_width + left_x_index]; const float top_right = pimage[top_y_index * image_width + right_x_index]; const float bottom_left = pimage[bottom_y_index * image_width + left_x_index]; const float bottom_right = pimage[bottom_y_index * image_width + right_x_index]; const float top = top_left + (top_right - top_left) * x_lerp; const float bottom = bottom_left + (bottom_right - bottom_left) * x_lerp; corps_data[crop_elements * b + channel_elements * d + y * crop_width + x] = top + (bottom - top) * y_lerp; } } // end for x } // end for y } // end for b } void crop_and_resize_forward( THFloatTensor * image, THFloatTensor * boxes, // [y1, x1, y2, x2] THIntTensor * box_index, // range in [0, batch_size) const float extrapolation_value, const int crop_height, const int crop_width, THFloatTensor * crops ) { //const int batch_size = image->size[0]; //const int depth = image->size[1]; //const int image_height = image->size[2]; //const int image_width = image->size[3]; //const int num_boxes = boxes->size[0]; const int batch_size = THCudaTensor_size(state, image, 0); const int depth = THCudaTensor_size(state, image, 1); const int image_height = THCudaTensor_size(state, image, 2); const int image_width = THCudaTensor_size(state, image, 3); const int num_boxes = THCudaTensor_size(state, boxes, 0); // init output space THFloatTensor_resize4d(crops, num_boxes, depth, crop_height, crop_width); THFloatTensor_zero(crops); // crop_and_resize for each box CropAndResizePerBox( THFloatTensor_data(image), batch_size, depth, image_height, image_width, THFloatTensor_data(boxes), THIntTensor_data(box_index), 0, num_boxes, THFloatTensor_data(crops), crop_height, crop_width, extrapolation_value ); } void crop_and_resize_backward( THFloatTensor * grads, THFloatTensor * boxes, // [y1, x1, y2, x2] THIntTensor * box_index, // range in [0, batch_size) THFloatTensor * grads_image // resize to [bsize, c, hc, wc] ) { // shape //const int batch_size = grads_image->size[0]; //const int depth = grads_image->size[1]; //const int image_height = grads_image->size[2]; //const int image_width = grads_image->size[3]; //const int num_boxes = grads->size[0]; //const int crop_height = grads->size[2]; //const int crop_width = grads->size[3]; const int batch_size = THCudaTensor_size(state, grads_image, 0); const int depth = THCudaTensor_size(state, grads_image, 1); const int image_height = THCudaTensor_size(state, grads_image, 2); const int image_width = THCudaTensor_size(state, grads_image, 3); const int num_boxes = THCudaTensor_size(state, grads, 0); const int crop_height = THCudaTensor_size(state, grads,2); const int crop_width = THCudaTensor_size(state,grads,3); // n_elements const int image_channel_elements = image_height * image_width; const int image_elements = depth * image_channel_elements; const int channel_elements = crop_height * crop_width; const int crop_elements = depth * channel_elements; // init output space THFloatTensor_zero(grads_image); // data pointer const float * grads_data = THFloatTensor_data(grads); const float * boxes_data = THFloatTensor_data(boxes); const int * box_index_data = THIntTensor_data(box_index); float * grads_image_data = THFloatTensor_data(grads_image); for (int b = 0; b < num_boxes; ++b) { const float * box = boxes_data + b * 4; const float y1 = box[0]; const float x1 = box[1]; const float y2 = box[2]; const float x2 = box[3]; const int b_in = box_index_data[b]; if (b_in < 0 \|\| b_in >= batch_size) { printf("Error: batch_index %d out of range [0, %d)\n", b_in, batch_size); exit(-1); } const float height_scale = (crop_height > 1) ? (y2 - y1) * (image_height - 1) / (crop_height - 1) : 0; const float width_scale = (crop_width > 1) ? (x2 - x1) * (image_width - 1) / (crop_width - 1) : 0; for (int y = 0; y < crop_height; ++y) { const float in_y = (crop_height > 1) ? y1 * (image_height - 1) + y * height_scale : 0.5 * (y1 + y2) * (image_height - 1); if (in_y < 0 \|\| in_y > image_height - 1) { continue; } const int top_y_index = floorf(in_y); const int bottom_y_index = ceilf(in_y); const float y_lerp = in_y - top_y_index; for (int x = 0; x < crop_width; ++x) { const float in_x = (crop_width > 1) ? x1 * (image_width - 1) + x * width_scale : 0.5 * (x1 + x2) * (image_width - 1); if (in_x < 0 \|\| in_x > image_width - 1) { continue; } const int left_x_index = floorf(in_x); const int right_x_index = ceilf(in_x); const float x_lerp = in_x - left_x_index; for (int d = 0; d < depth; ++d) { float pimage = grads_image_data + b_in image_elements + d * image_channel_elements; const float grad_val = grads_data[crop_elements * b + channel_elements * d + y * crop_width + x]; const float dtop = (1 - y_lerp) * grad_val; pimage[top_y_index * image_width + left_x_index] += (1 - x_lerp) * dtop; pimage[top_y_index * image_width + right_x_index] += x_lerp * dtop; const float dbottom = y_lerp * grad_val; pimage[bottom_y_index * image_width + left_x_index] += (1 - x_lerp) * dbottom; pimage[bottom_y_index * image_width + right_x_index] += x_lerp * dbottom; } // end d } // end x } // end y } // end b }
symm_x_dia_n_hi_col.c	#include "alphasparse/kernel.h" #include "alphasparse/util.h" #include "alphasparse/opt.h" #ifdef _OPENMP #include <omp.h> #endif alphasparse_status_t ONAME(const ALPHA_Number alpha, const ALPHA_SPMAT_DIA mat, const ALPHA_Number x, const ALPHA_INT columns, const ALPHA_INT ldx, const ALPHA_Number beta, ALPHA_Number y, const ALPHA_INT ldy) { ALPHA_INT num_threads = alpha_get_thread_num(); #ifdef _OPENMP #pragma omp parallel for num_threads(num_threads) #endif for (ALPHA_INT cc = 0; cc < columns; ++cc) { ALPHA_Number Y = &y[index2(cc,0,ldy)]; for (ALPHA_INT i = 0; i < mat->rows; i++) alpha_mul(Y[i],Y[i],beta); const ALPHA_Number* X = &x[index2(cc,0,ldx)]; for(ALPHA_INT di = 0; di < mat->ndiag;++di){ ALPHA_INT d = mat->distance[di]; if(d > 0){ ALPHA_INT ars = alpha_max(0,-d); ALPHA_INT acs = alpha_max(0,d); ALPHA_INT an = alpha_min(mat->rows - ars,mat->cols - acs); for(ALPHA_INT i = 0; i < an; ++i){ ALPHA_INT ar = ars + i; ALPHA_INT ac = acs + i; ALPHA_Number val; alpha_mul(val,mat->values[index2(di,ar,mat->lval)],alpha); alpha_madde(Y[ar],val,X[ac]); alpha_madde(Y[ac],val,X[ar]); } } if(d == 0){ for(ALPHA_INT r = 0; r < mat->rows; ++r){ ALPHA_Number val; alpha_mul(val,mat->values[index2(di,r,mat->lval)],alpha); alpha_madde(Y[r],val,X[r]); } } } } return ALPHA_SPARSE_STATUS_SUCCESS; }
par_vector.c	/****************************************************************************** * Copyright (c) 1998 Lawrence Livermore National Security, LLC and other * HYPRE Project Developers. See the top-level COPYRIGHT file for details. * * SPDX-License-Identifier: (Apache-2.0 OR MIT) ****************************************************************************/ /**************************************************************************** * * Member functions for hypre_Vector class. * ****************************************************************************/ #include "_hypre_parcsr_mv.h" HYPRE_Int hypre_FillResponseParToVectorAll(void, HYPRE_Int, HYPRE_Int, void, MPI_Comm, void, HYPRE_Int); /-------------------------------------------------------------------------- hypre_ParVectorCreate --------------------------------------------------------------------------/ /* If create is called and partitioning is NOT null, then it is assumed that it is array of length 2 containing the start row of the calling processor followed by the start row of the next processor - AHB 6/05 / hypre_ParVector hypre_ParVectorCreate( MPI_Comm comm, HYPRE_BigInt global_size, HYPRE_BigInt partitioning_in ) { hypre_ParVector vector; HYPRE_Int num_procs, my_id, local_size; HYPRE_BigInt partitioning[2]; if (global_size < 0) { hypre_error_in_arg(2); return NULL; } vector = hypre_CTAlloc(hypre_ParVector, 1, HYPRE_MEMORY_HOST); hypre_MPI_Comm_rank(comm, &my_id); if (!partitioning_in) { hypre_MPI_Comm_size(comm, &num_procs); hypre_GenerateLocalPartitioning(global_size, num_procs, my_id, partitioning); } else { partitioning[0] = partitioning_in[0]; partitioning[1] = partitioning_in[1]; } local_size = (HYPRE_Int) (partitioning[1] - partitioning[0]); hypre_ParVectorAssumedPartition(vector) = NULL; hypre_ParVectorComm(vector) = comm; hypre_ParVectorGlobalSize(vector) = global_size; hypre_ParVectorPartitioning(vector)[0] = partitioning[0]; hypre_ParVectorPartitioning(vector)[1] = partitioning[1]; hypre_ParVectorFirstIndex(vector) = hypre_ParVectorPartitioning(vector)[0]; hypre_ParVectorLastIndex(vector) = hypre_ParVectorPartitioning(vector)[1] - 1; hypre_ParVectorLocalVector(vector) = hypre_SeqVectorCreate(local_size); /* set defaults / hypre_ParVectorOwnsData(vector) = 1; hypre_ParVectorActualLocalSize(vector) = 0; return vector; } /-------------------------------------------------------------------------- * hypre_ParMultiVectorCreate --------------------------------------------------------------------------/ hypre_ParVector * hypre_ParMultiVectorCreate( MPI_Comm comm, HYPRE_BigInt global_size, HYPRE_BigInt partitioning, HYPRE_Int num_vectors ) { / note that global_size is the global length of a single vector / hypre_ParVector vector = hypre_ParVectorCreate( comm, global_size, partitioning ); hypre_ParVectorNumVectors(vector) = num_vectors; return vector; } /-------------------------------------------------------------------------- hypre_ParVectorDestroy --------------------------------------------------------------------------/ HYPRE_Int hypre_ParVectorDestroy( hypre_ParVector vector ) { if (vector) { if ( hypre_ParVectorOwnsData(vector) ) { hypre_SeqVectorDestroy(hypre_ParVectorLocalVector(vector)); } if (hypre_ParVectorAssumedPartition(vector)) { hypre_AssumedPartitionDestroy(hypre_ParVectorAssumedPartition(vector)); } hypre_TFree(vector, HYPRE_MEMORY_HOST); } return hypre_error_flag; } /-------------------------------------------------------------------------- * hypre_ParVectorInitialize --------------------------------------------------------------------------/ HYPRE_Int hypre_ParVectorInitialize_v2( hypre_ParVector vector, HYPRE_MemoryLocation memory_location ) { if (!vector) { hypre_error_in_arg(1); return hypre_error_flag; } hypre_SeqVectorInitialize_v2(hypre_ParVectorLocalVector(vector), memory_location); hypre_ParVectorActualLocalSize(vector) = hypre_VectorSize(hypre_ParVectorLocalVector(vector)); return hypre_error_flag; } HYPRE_Int hypre_ParVectorInitialize( hypre_ParVector vector ) { return hypre_ParVectorInitialize_v2(vector, hypre_ParVectorMemoryLocation(vector)); } /-------------------------------------------------------------------------- hypre_ParVectorSetDataOwner --------------------------------------------------------------------------/ HYPRE_Int hypre_ParVectorSetDataOwner( hypre_ParVector vector, HYPRE_Int owns_data ) { if (!vector) { hypre_error_in_arg(1); return hypre_error_flag; } hypre_ParVectorOwnsData(vector) = owns_data; return hypre_error_flag; } /-------------------------------------------------------------------------- * hypre_ParVectorSetNumVectors * call before calling hypre_ParVectorInitialize * probably this will do more harm than good, use hypre_ParMultiVectorCreate --------------------------------------------------------------------------/ #if 0 HYPRE_Int hypre_ParVectorSetNumVectors( hypre_ParVector vector, HYPRE_Int num_vectors ) { HYPRE_Int ierr = 0; hypre_Vector local_vector = hypre_ParVectorLocalVector(v); hypre_SeqVectorSetNumVectors( local_vector, num_vectors ); return ierr; } #endif /-------------------------------------------------------------------------- hypre_ParVectorRead --------------------------------------------------------------------------/ hypre_ParVector* hypre_ParVectorRead( MPI_Comm comm, const char file_name ) { char new_file_name[80]; hypre_ParVector par_vector; HYPRE_Int my_id; HYPRE_BigInt partitioning[2]; HYPRE_BigInt global_size; FILE fp; hypre_MPI_Comm_rank(comm, &my_id); hypre_sprintf(new_file_name, "%s.INFO.%d", file_name, my_id); fp = fopen(new_file_name, "r"); hypre_fscanf(fp, "%b\n", &global_size); hypre_fscanf(fp, "%b\n", &partitioning[0]); hypre_fscanf(fp, "%b\n", &partitioning[1]); fclose (fp); par_vector = hypre_CTAlloc(hypre_ParVector, 1, HYPRE_MEMORY_HOST); hypre_ParVectorComm(par_vector) = comm; hypre_ParVectorGlobalSize(par_vector) = global_size; hypre_ParVectorFirstIndex(par_vector) = partitioning[0]; hypre_ParVectorLastIndex(par_vector) = partitioning[1] - 1; hypre_ParVectorPartitioning(par_vector)[0] = partitioning[0]; hypre_ParVectorPartitioning(par_vector)[1] = partitioning[1]; hypre_ParVectorOwnsData(par_vector) = 1; hypre_sprintf(new_file_name, "%s.%d", file_name, my_id); hypre_ParVectorLocalVector(par_vector) = hypre_SeqVectorRead(new_file_name); / multivector code not written yet / hypre_assert( hypre_ParVectorNumVectors(par_vector) == 1 ); return par_vector; } /-------------------------------------------------------------------------- * hypre_ParVectorPrint --------------------------------------------------------------------------/ HYPRE_Int hypre_ParVectorPrint( hypre_ParVector vector, const char file_name ) { char new_file_name[80]; hypre_Vector local_vector; MPI_Comm comm; HYPRE_Int my_id; HYPRE_BigInt partitioning; HYPRE_BigInt global_size; FILE fp; if (!vector) { hypre_error_in_arg(1); return hypre_error_flag; } local_vector = hypre_ParVectorLocalVector(vector); comm = hypre_ParVectorComm(vector); partitioning = hypre_ParVectorPartitioning(vector); global_size = hypre_ParVectorGlobalSize(vector); hypre_MPI_Comm_rank(comm, &my_id); hypre_sprintf(new_file_name, "%s.%d", file_name, my_id); hypre_SeqVectorPrint(local_vector, new_file_name); hypre_sprintf(new_file_name, "%s.INFO.%d", file_name, my_id); fp = fopen(new_file_name, "w"); hypre_fprintf(fp, "%b\n", global_size); hypre_fprintf(fp, "%b\n", partitioning[0]); hypre_fprintf(fp, "%b\n", partitioning[1]); fclose(fp); return hypre_error_flag; } /-------------------------------------------------------------------------- * hypre_ParVectorSetConstantValues --------------------------------------------------------------------------/ HYPRE_Int hypre_ParVectorSetConstantValues( hypre_ParVector v, HYPRE_Complex value ) { hypre_Vector v_local = hypre_ParVectorLocalVector(v); return hypre_SeqVectorSetConstantValues(v_local, value); } /-------------------------------------------------------------------------- hypre_ParVectorSetRandomValues --------------------------------------------------------------------------/ HYPRE_Int hypre_ParVectorSetRandomValues( hypre_ParVector v, HYPRE_Int seed ) { HYPRE_Int my_id; hypre_Vector v_local = hypre_ParVectorLocalVector(v); MPI_Comm comm = hypre_ParVectorComm(v); hypre_MPI_Comm_rank(comm, &my_id); seed = (my_id + 1); return hypre_SeqVectorSetRandomValues(v_local, seed); } /-------------------------------------------------------------------------- * hypre_ParVectorCopy --------------------------------------------------------------------------/ HYPRE_Int hypre_ParVectorCopy( hypre_ParVector x, hypre_ParVector y ) { hypre_Vector x_local = hypre_ParVectorLocalVector(x); hypre_Vector y_local = hypre_ParVectorLocalVector(y); return hypre_SeqVectorCopy(x_local, y_local); } /-------------------------------------------------------------------------- hypre_ParVectorCloneShallow * returns a complete copy of a hypre_ParVector x - a shallow copy, re-using * the partitioning and data arrays of x --------------------------------------------------------------------------/ hypre_ParVector * hypre_ParVectorCloneShallow( hypre_ParVector x ) { hypre_ParVector y = hypre_ParVectorCreate(hypre_ParVectorComm(x), hypre_ParVectorGlobalSize(x), hypre_ParVectorPartitioning(x)); hypre_ParVectorOwnsData(y) = 1; /* ...This vector owns its local vector, although the local vector doesn't * own _its_ data / hypre_SeqVectorDestroy( hypre_ParVectorLocalVector(y) ); hypre_ParVectorLocalVector(y) = hypre_SeqVectorCloneShallow(hypre_ParVectorLocalVector(x) ); hypre_ParVectorFirstIndex(y) = hypre_ParVectorFirstIndex(x); return y; } hypre_ParVector hypre_ParVectorCloneDeep_v2( hypre_ParVector x, HYPRE_MemoryLocation memory_location ) { hypre_ParVector y = hypre_ParVectorCreate(hypre_ParVectorComm(x), hypre_ParVectorGlobalSize(x), hypre_ParVectorPartitioning(x)); hypre_ParVectorOwnsData(y) = 1; hypre_SeqVectorDestroy( hypre_ParVectorLocalVector(y) ); hypre_ParVectorLocalVector(y) = hypre_SeqVectorCloneDeep_v2( hypre_ParVectorLocalVector(x), memory_location ); hypre_ParVectorFirstIndex(y) = hypre_ParVectorFirstIndex(x); //RL: WHY HERE? return y; } HYPRE_Int hypre_ParVectorMigrate(hypre_ParVector x, HYPRE_MemoryLocation memory_location) { if (!x) { return hypre_error_flag; } if ( hypre_GetActualMemLocation(memory_location) != hypre_GetActualMemLocation(hypre_ParVectorMemoryLocation(x)) ) { hypre_Vector x_local = hypre_SeqVectorCloneDeep_v2(hypre_ParVectorLocalVector(x), memory_location); hypre_SeqVectorDestroy(hypre_ParVectorLocalVector(x)); hypre_ParVectorLocalVector(x) = x_local; } else { hypre_VectorMemoryLocation(hypre_ParVectorLocalVector(x)) = memory_location; } return hypre_error_flag; } /-------------------------------------------------------------------------- hypre_ParVectorScale --------------------------------------------------------------------------/ HYPRE_Int hypre_ParVectorScale( HYPRE_Complex alpha, hypre_ParVector y ) { hypre_Vector y_local = hypre_ParVectorLocalVector(y); return hypre_SeqVectorScale( alpha, y_local); } /-------------------------------------------------------------------------- hypre_ParVectorAxpy --------------------------------------------------------------------------/ HYPRE_Int hypre_ParVectorAxpy( HYPRE_Complex alpha, hypre_ParVector x, hypre_ParVector y ) { hypre_Vector x_local = hypre_ParVectorLocalVector(x); hypre_Vector y_local = hypre_ParVectorLocalVector(y); return hypre_SeqVectorAxpy( alpha, x_local, y_local); } /-------------------------------------------------------------------------- hypre_ParVectorInnerProd --------------------------------------------------------------------------/ HYPRE_Real hypre_ParVectorInnerProd( hypre_ParVector x, hypre_ParVector y ) { MPI_Comm comm = hypre_ParVectorComm(x); hypre_Vector x_local = hypre_ParVectorLocalVector(x); hypre_Vector y_local = hypre_ParVectorLocalVector(y); HYPRE_Real result = 0.0; HYPRE_Real local_result = hypre_SeqVectorInnerProd(x_local, y_local); #ifdef HYPRE_PROFILE hypre_profile_times[HYPRE_TIMER_ID_ALL_REDUCE] -= hypre_MPI_Wtime(); #endif hypre_MPI_Allreduce(&local_result, &result, 1, HYPRE_MPI_REAL, hypre_MPI_SUM, comm); #ifdef HYPRE_PROFILE hypre_profile_times[HYPRE_TIMER_ID_ALL_REDUCE] += hypre_MPI_Wtime(); #endif return result; } /-------------------------------------------------------------------------- hypre_ParVectorElmdivpy * y = y + x ./ b [MATLAB Notation] --------------------------------------------------------------------------/ HYPRE_Int hypre_ParVectorElmdivpy( hypre_ParVector x, hypre_ParVector b, hypre_ParVector y ) { hypre_Vector x_local = hypre_ParVectorLocalVector(x); hypre_Vector b_local = hypre_ParVectorLocalVector(b); hypre_Vector y_local = hypre_ParVectorLocalVector(y); return hypre_SeqVectorElmdivpy(x_local, b_local, y_local); } /-------------------------------------------------------------------------- hypre_ParVectorElmdivpyMarked * y[i] += x[i] / b[i] where marker[i] == marker_val --------------------------------------------------------------------------/ HYPRE_Int hypre_ParVectorElmdivpyMarked( hypre_ParVector x, hypre_ParVector b, hypre_ParVector y, HYPRE_Int marker, HYPRE_Int marker_val ) { hypre_Vector x_local = hypre_ParVectorLocalVector(x); hypre_Vector b_local = hypre_ParVectorLocalVector(b); hypre_Vector y_local = hypre_ParVectorLocalVector(y); return hypre_SeqVectorElmdivpyMarked(x_local, b_local, y_local, marker, marker_val); } /-------------------------------------------------------------------------- * hypre_VectorToParVector: * generates a ParVector from a Vector on proc 0 and distributes the pieces * to the other procs in comm --------------------------------------------------------------------------/ hypre_ParVector * hypre_VectorToParVector ( MPI_Comm comm, hypre_Vector v, HYPRE_BigInt vec_starts ) { HYPRE_BigInt global_size; HYPRE_BigInt global_vec_starts = NULL; HYPRE_BigInt first_index; HYPRE_BigInt last_index; HYPRE_Int local_size; HYPRE_Int num_vectors; HYPRE_Int num_procs, my_id; HYPRE_Int global_vecstride, vecstride, idxstride; hypre_ParVector par_vector; hypre_Vector local_vector; HYPRE_Complex v_data; HYPRE_Complex local_data; hypre_MPI_Request requests; hypre_MPI_Status status, status0; HYPRE_Int i, j, k, p; hypre_MPI_Comm_size(comm, &num_procs); hypre_MPI_Comm_rank(comm, &my_id); if (my_id == 0) { global_size = (HYPRE_BigInt)hypre_VectorSize(v); v_data = hypre_VectorData(v); num_vectors = hypre_VectorNumVectors(v); / for multivectors / global_vecstride = hypre_VectorVectorStride(v); } hypre_MPI_Bcast(&global_size, 1, HYPRE_MPI_INT, 0, comm); hypre_MPI_Bcast(&num_vectors, 1, HYPRE_MPI_INT, 0, comm); hypre_MPI_Bcast(&global_vecstride, 1, HYPRE_MPI_INT, 0, comm); if (num_vectors == 1) { par_vector = hypre_ParVectorCreate(comm, global_size, vec_starts); } else { par_vector = hypre_ParMultiVectorCreate(comm, global_size, vec_starts, num_vectors); } vec_starts = hypre_ParVectorPartitioning(par_vector); first_index = hypre_ParVectorFirstIndex(par_vector); last_index = hypre_ParVectorLastIndex(par_vector); local_size = (HYPRE_Int)(last_index - first_index) + 1; if (my_id == 0) { global_vec_starts = hypre_CTAlloc(HYPRE_BigInt, num_procs + 1, HYPRE_MEMORY_HOST); } hypre_MPI_Gather(&first_index, 1, HYPRE_MPI_BIG_INT, global_vec_starts, 1, HYPRE_MPI_BIG_INT, 0, comm); if (my_id == 0) { global_vec_starts[num_procs] = hypre_ParVectorGlobalSize(par_vector); } hypre_ParVectorInitialize(par_vector); local_vector = hypre_ParVectorLocalVector(par_vector); local_data = hypre_VectorData(local_vector); vecstride = hypre_VectorVectorStride(local_vector); idxstride = hypre_VectorIndexStride(local_vector); / so far the only implemented multivector StorageMethod is 0 / hypre_assert( idxstride == 1 ); if (my_id == 0) { requests = hypre_CTAlloc(hypre_MPI_Request, num_vectors (num_procs - 1), HYPRE_MEMORY_HOST); status = hypre_CTAlloc(hypre_MPI_Status, num_vectors * (num_procs - 1), HYPRE_MEMORY_HOST); k = 0; for (p = 1; p < num_procs; p++) for (j = 0; j < num_vectors; ++j) { hypre_MPI_Isend( &v_data[(HYPRE_Int) global_vec_starts[p]] + j * global_vecstride, (HYPRE_Int)(global_vec_starts[p + 1] - global_vec_starts[p]), HYPRE_MPI_COMPLEX, p, 0, comm, &requests[k++] ); } if (num_vectors == 1) { for (i = 0; i < local_size; i++) { local_data[i] = v_data[i]; } } else { for (j = 0; j < num_vectors; ++j) { for (i = 0; i < local_size; i++) { local_data[i + j * vecstride] = v_data[i + j * global_vecstride]; } } } hypre_MPI_Waitall(num_procs - 1, requests, status); hypre_TFree(requests, HYPRE_MEMORY_HOST); hypre_TFree(status, HYPRE_MEMORY_HOST); } else { for ( j = 0; j < num_vectors; ++j ) hypre_MPI_Recv( local_data + j * vecstride, local_size, HYPRE_MPI_COMPLEX, 0, 0, comm, &status0 ); } if (global_vec_starts) { hypre_TFree(global_vec_starts, HYPRE_MEMORY_HOST); } return par_vector; } /-------------------------------------------------------------------------- hypre_ParVectorToVectorAll: * generates a Vector on every proc which has a piece of the data * from a ParVector on several procs in comm, * vec_starts needs to contain the partitioning across all procs in comm --------------------------------------------------------------------------/ hypre_Vector * hypre_ParVectorToVectorAll( hypre_ParVector par_v ) { MPI_Comm comm = hypre_ParVectorComm(par_v); HYPRE_BigInt global_size = hypre_ParVectorGlobalSize(par_v); hypre_Vector local_vector = hypre_ParVectorLocalVector(par_v); HYPRE_Int num_procs, my_id; HYPRE_Int num_vectors = hypre_ParVectorNumVectors(par_v); hypre_Vector vector; HYPRE_Complex vector_data; HYPRE_Complex local_data; HYPRE_Int local_size; hypre_MPI_Request requests; hypre_MPI_Status status; HYPRE_Int i, j; HYPRE_Int used_procs; HYPRE_Int num_types, num_requests; HYPRE_Int vec_len, proc_id; HYPRE_Int new_vec_starts; HYPRE_Int num_contacts; HYPRE_Int contact_proc_list[1]; HYPRE_Int contact_send_buf[1]; HYPRE_Int contact_send_buf_starts[2]; HYPRE_Int max_response_size; HYPRE_Int response_recv_buf = NULL; HYPRE_Int response_recv_buf_starts = NULL; hypre_DataExchangeResponse response_obj; hypre_ProcListElements send_proc_obj; HYPRE_Int send_info = NULL; hypre_MPI_Status status1; HYPRE_Int count, tag1 = 112, tag2 = 223; HYPRE_Int start; hypre_MPI_Comm_size(comm, &num_procs); hypre_MPI_Comm_rank(comm, &my_id); local_size = (HYPRE_Int)(hypre_ParVectorLastIndex(par_v) - hypre_ParVectorFirstIndex(par_v) + 1); /* determine procs which hold data of par_v and store ids in used_procs / / we need to do an exchange data for this. If I own row then I will contact processor 0 with the endpoint of my local range / if (local_size > 0) { num_contacts = 1; contact_proc_list[0] = 0; contact_send_buf[0] = hypre_ParVectorLastIndex(par_v); contact_send_buf_starts[0] = 0; contact_send_buf_starts[1] = 1; } else { num_contacts = 0; contact_send_buf_starts[0] = 0; contact_send_buf_starts[1] = 0; } /build the response object/ /send_proc_obj will be for saving info from contacts / send_proc_obj.length = 0; send_proc_obj.storage_length = 10; send_proc_obj.id = hypre_CTAlloc(HYPRE_Int, send_proc_obj.storage_length, HYPRE_MEMORY_HOST); send_proc_obj.vec_starts = hypre_CTAlloc(HYPRE_Int, send_proc_obj.storage_length + 1, HYPRE_MEMORY_HOST); send_proc_obj.vec_starts[0] = 0; send_proc_obj.element_storage_length = 10; send_proc_obj.elements = hypre_CTAlloc(HYPRE_BigInt, send_proc_obj.element_storage_length, HYPRE_MEMORY_HOST); max_response_size = 0; / each response is null / response_obj.fill_response = hypre_FillResponseParToVectorAll; response_obj.data1 = NULL; response_obj.data2 = &send_proc_obj; /this is where we keep info from contacts/ hypre_DataExchangeList(num_contacts, contact_proc_list, contact_send_buf, contact_send_buf_starts, sizeof(HYPRE_Int), //0, &response_obj, sizeof(HYPRE_Int), &response_obj, max_response_size, 1, comm, (void) &response_recv_buf, &response_recv_buf_starts); / now processor 0 should have a list of ranges for processors that have rows - these are in send_proc_obj - it needs to create the new list of processors and also an array of vec starts - and send to those who own row/ if (my_id) { if (local_size) { / look for a message from processor 0 / hypre_MPI_Probe(0, tag1, comm, &status1); hypre_MPI_Get_count(&status1, HYPRE_MPI_INT, &count); send_info = hypre_CTAlloc(HYPRE_Int, count, HYPRE_MEMORY_HOST); hypre_MPI_Recv(send_info, count, HYPRE_MPI_INT, 0, tag1, comm, &status1); / now unpack / num_types = send_info[0]; used_procs = hypre_CTAlloc(HYPRE_Int, num_types, HYPRE_MEMORY_HOST); new_vec_starts = hypre_CTAlloc(HYPRE_Int, num_types + 1, HYPRE_MEMORY_HOST); for (i = 1; i <= num_types; i++) { used_procs[i - 1] = (HYPRE_Int)send_info[i]; } for (i = num_types + 1; i < count; i++) { new_vec_starts[i - num_types - 1] = send_info[i] ; } } else / clean up and exit / { hypre_TFree(send_proc_obj.vec_starts, HYPRE_MEMORY_HOST); hypre_TFree(send_proc_obj.id, HYPRE_MEMORY_HOST); hypre_TFree(send_proc_obj.elements, HYPRE_MEMORY_HOST); if (response_recv_buf) { hypre_TFree(response_recv_buf, HYPRE_MEMORY_HOST); } if (response_recv_buf_starts) { hypre_TFree(response_recv_buf_starts, HYPRE_MEMORY_HOST); } return NULL; } } else / my_id ==0 / { num_types = send_proc_obj.length; used_procs = hypre_CTAlloc(HYPRE_Int, num_types, HYPRE_MEMORY_HOST); new_vec_starts = hypre_CTAlloc(HYPRE_Int, num_types + 1, HYPRE_MEMORY_HOST); new_vec_starts[0] = 0; for (i = 0; i < num_types; i++) { used_procs[i] = send_proc_obj.id[i]; new_vec_starts[i + 1] = send_proc_obj.elements[i] + 1; } hypre_qsort0(used_procs, 0, num_types - 1); hypre_qsort0(new_vec_starts, 0, num_types); /now we need to put into an array to send / count = 2 num_types + 2; send_info = hypre_CTAlloc(HYPRE_Int, count, HYPRE_MEMORY_HOST); send_info[0] = num_types; for (i = 1; i <= num_types; i++) { send_info[i] = (HYPRE_Int)used_procs[i - 1]; } for (i = num_types + 1; i < count; i++) { send_info[i] = new_vec_starts[i - num_types - 1]; } requests = hypre_CTAlloc(hypre_MPI_Request, num_types, HYPRE_MEMORY_HOST); status = hypre_CTAlloc(hypre_MPI_Status, num_types, HYPRE_MEMORY_HOST); /* don't send to myself - these are sorted so my id would be first/ start = 0; if (used_procs[0] == 0) { start = 1; } for (i = start; i < num_types; i++) { hypre_MPI_Isend(send_info, count, HYPRE_MPI_INT, used_procs[i], tag1, comm, &requests[i - start]); } hypre_MPI_Waitall(num_types - start, requests, status); hypre_TFree(status, HYPRE_MEMORY_HOST); hypre_TFree(requests, HYPRE_MEMORY_HOST); } / clean up / hypre_TFree(send_proc_obj.vec_starts, HYPRE_MEMORY_HOST); hypre_TFree(send_proc_obj.id, HYPRE_MEMORY_HOST); hypre_TFree(send_proc_obj.elements, HYPRE_MEMORY_HOST); hypre_TFree(send_info, HYPRE_MEMORY_HOST); if (response_recv_buf) { hypre_TFree(response_recv_buf, HYPRE_MEMORY_HOST); } if (response_recv_buf_starts) { hypre_TFree(response_recv_buf_starts, HYPRE_MEMORY_HOST); } / now proc 0 can exit if it has no rows / if (!local_size) { hypre_TFree(used_procs, HYPRE_MEMORY_HOST); hypre_TFree(new_vec_starts, HYPRE_MEMORY_HOST); return NULL; } / everyone left has rows and knows: new_vec_starts, num_types, and used_procs / / this vector should be rather small / local_data = hypre_VectorData(local_vector); vector = hypre_SeqVectorCreate((HYPRE_Int)global_size); hypre_VectorNumVectors(vector) = num_vectors; hypre_SeqVectorInitialize(vector); vector_data = hypre_VectorData(vector); num_requests = 2 num_types; requests = hypre_CTAlloc(hypre_MPI_Request, num_requests, HYPRE_MEMORY_HOST); status = hypre_CTAlloc(hypre_MPI_Status, num_requests, HYPRE_MEMORY_HOST); /* initialize data exchange among used_procs and generate vector - here we send to ourself also/ j = 0; for (i = 0; i < num_types; i++) { proc_id = used_procs[i]; vec_len = (HYPRE_Int)(new_vec_starts[i + 1] - new_vec_starts[i]); hypre_MPI_Irecv(&vector_data[(HYPRE_Int)new_vec_starts[i]], num_vectors vec_len, HYPRE_MPI_COMPLEX, proc_id, tag2, comm, &requests[j++]); } for (i = 0; i < num_types; i++) { hypre_MPI_Isend(local_data, num_vectors * local_size, HYPRE_MPI_COMPLEX, used_procs[i], tag2, comm, &requests[j++]); } hypre_MPI_Waitall(num_requests, requests, status); if (num_requests) { hypre_TFree(requests, HYPRE_MEMORY_HOST); hypre_TFree(status, HYPRE_MEMORY_HOST); hypre_TFree(used_procs, HYPRE_MEMORY_HOST); } hypre_TFree(new_vec_starts, HYPRE_MEMORY_HOST); return vector; } /-------------------------------------------------------------------------- hypre_ParVectorPrintIJ --------------------------------------------------------------------------/ HYPRE_Int hypre_ParVectorPrintIJ( hypre_ParVector vector, HYPRE_Int base_j, const char filename ) { MPI_Comm comm; HYPRE_BigInt global_size, j; HYPRE_BigInt partitioning; HYPRE_Complex local_data; HYPRE_Int myid, num_procs, i, part0; char new_filename[255]; FILE file; if (!vector) { hypre_error_in_arg(1); return hypre_error_flag; } comm = hypre_ParVectorComm(vector); global_size = hypre_ParVectorGlobalSize(vector); partitioning = hypre_ParVectorPartitioning(vector); / multivector code not written yet / hypre_assert( hypre_ParVectorNumVectors(vector) == 1 ); if ( hypre_ParVectorNumVectors(vector) != 1 ) { hypre_error_in_arg(1); } hypre_MPI_Comm_rank(comm, &myid); hypre_MPI_Comm_size(comm, &num_procs); hypre_sprintf(new_filename, "%s.%05d", filename, myid); if ((file = fopen(new_filename, "w")) == NULL) { hypre_error_w_msg(HYPRE_ERROR_GENERIC, "Error: can't open output file %s\n"); return hypre_error_flag; } local_data = hypre_VectorData(hypre_ParVectorLocalVector(vector)); hypre_fprintf(file, "%b \n", global_size); for (i = 0; i < 2; i++) { hypre_fprintf(file, "%b ", partitioning[i] + base_j); } hypre_fprintf(file, "\n"); part0 = partitioning[0]; for (j = part0; j < partitioning[1]; j++) { hypre_fprintf(file, "%b %.14e\n", j + base_j, local_data[(HYPRE_Int)(j - part0)]); } fclose(file); return hypre_error_flag; } /-------------------------------------------------------------------------- * hypre_ParVectorReadIJ * Warning: wrong base for assumed partition if base > 0 --------------------------------------------------------------------------/ HYPRE_Int hypre_ParVectorReadIJ( MPI_Comm comm, const char filename, HYPRE_Int base_j_ptr, hypre_ParVector *vector_ptr ) { HYPRE_BigInt global_size, J; hypre_ParVector vector; hypre_Vector local_vector; HYPRE_Complex local_data; HYPRE_BigInt partitioning[2]; HYPRE_Int base_j; HYPRE_Int myid, num_procs, i, j; char new_filename[255]; FILE file; hypre_MPI_Comm_size(comm, &num_procs); hypre_MPI_Comm_rank(comm, &myid); hypre_sprintf(new_filename, "%s.%05d", filename, myid); if ((file = fopen(new_filename, "r")) == NULL) { hypre_error_w_msg(HYPRE_ERROR_GENERIC, "Error: can't open output file %s\n"); return hypre_error_flag; } hypre_fscanf(file, "%b", &global_size); / this may need to be changed so that the base is available in the file! / hypre_fscanf(file, "%b", partitioning); for (i = 0; i < 2; i++) { hypre_fscanf(file, "%b", partitioning + i); } / This is not yet implemented correctly! / base_j = 0; vector = hypre_ParVectorCreate(comm, global_size, partitioning); hypre_ParVectorInitialize(vector); local_vector = hypre_ParVectorLocalVector(vector); local_data = hypre_VectorData(local_vector); for (j = 0; j < (HYPRE_Int)(partitioning[1] - partitioning[0]); j++) { hypre_fscanf(file, "%b %le", &J, local_data + j); } fclose(file); base_j_ptr = base_j; vector_ptr = vector; / multivector code not written yet / hypre_assert( hypre_ParVectorNumVectors(vector) == 1 ); if ( hypre_ParVectorNumVectors(vector) != 1 ) { hypre_error(HYPRE_ERROR_GENERIC); } return hypre_error_flag; } /-------------------------------------------------------------------- * hypre_FillResponseParToVectorAll * Fill response function for determining the send processors * data exchange --------------------------------------------------------------------/ HYPRE_Int hypre_FillResponseParToVectorAll( void p_recv_contact_buf, HYPRE_Int contact_size, HYPRE_Int contact_proc, void ro, MPI_Comm comm, void *p_send_response_buf, HYPRE_Int response_message_size ) { HYPRE_Int myid; HYPRE_Int i, index, count, elength; HYPRE_BigInt recv_contact_buf = (HYPRE_BigInt ) p_recv_contact_buf; hypre_DataExchangeResponse response_obj = (hypre_DataExchangeResponse)ro; hypre_ProcListElements send_proc_obj = (hypre_ProcListElements)response_obj->data2; hypre_MPI_Comm_rank(comm, &myid ); /check to see if we need to allocate more space in send_proc_obj for ids/ if (send_proc_obj->length == send_proc_obj->storage_length) { send_proc_obj->storage_length += 10; /add space for 10 more processors/ send_proc_obj->id = hypre_TReAlloc(send_proc_obj->id, HYPRE_Int, send_proc_obj->storage_length, HYPRE_MEMORY_HOST); send_proc_obj->vec_starts = hypre_TReAlloc(send_proc_obj->vec_starts, HYPRE_Int, send_proc_obj->storage_length + 1, HYPRE_MEMORY_HOST); } /initialize/ count = send_proc_obj->length; index = send_proc_obj->vec_starts[count]; /this is the number of elements/ /send proc/ send_proc_obj->id[count] = contact_proc; /do we need more storage for the elements?/ if (send_proc_obj->element_storage_length < index + contact_size) { elength = hypre_max(contact_size, 10); elength += index; send_proc_obj->elements = hypre_TReAlloc(send_proc_obj->elements, HYPRE_BigInt, elength, HYPRE_MEMORY_HOST); send_proc_obj->element_storage_length = elength; } /populate send_proc_obj/ for (i = 0; i < contact_size; i++) { send_proc_obj->elements[index++] = recv_contact_buf[i]; } send_proc_obj->vec_starts[count + 1] = index; send_proc_obj->length++; /output - no message to return (confirmation) / response_message_size = 0; return hypre_error_flag; } / ----------------------------------------------------------------------------- * return the sum of all local elements of the vector * ----------------------------------------------------------------------------- / HYPRE_Complex hypre_ParVectorLocalSumElts( hypre_ParVector vector ) { return hypre_SeqVectorSumElts( hypre_ParVectorLocalVector(vector) ); } HYPRE_Int hypre_ParVectorGetValuesHost(hypre_ParVector vector, HYPRE_Int num_values, HYPRE_BigInt indices, HYPRE_BigInt base, HYPRE_Complex values) { HYPRE_Int i, ierr = 0; HYPRE_BigInt first_index = hypre_ParVectorFirstIndex(vector); HYPRE_BigInt last_index = hypre_ParVectorLastIndex(vector); hypre_Vector local_vector = hypre_ParVectorLocalVector(vector); HYPRE_Complex data = hypre_VectorData(local_vector); / if (hypre_VectorOwnsData(local_vector) == 0) { hypre_error_w_msg(HYPRE_ERROR_GENERIC,"Vector does not own data! -- hypre_ParVectorGetValues."); return hypre_error_flag; } / if (indices) { #ifdef HYPRE_USING_OPENMP #pragma omp parallel for private(i) reduction(+:ierr) HYPRE_SMP_SCHEDULE #endif for (i = 0; i < num_values; i++) { HYPRE_BigInt index = indices[i] - base; if (index < first_index \|\| index > last_index) { ierr ++; } else { HYPRE_Int local_index = (HYPRE_Int) (index - first_index); values[i] = data[local_index]; } } if (ierr) { hypre_error_in_arg(3); hypre_error_w_msg(HYPRE_ERROR_GENERIC, "Index out of range! -- hypre_ParVectorGetValues."); hypre_printf("Index out of range! -- hypre_ParVectorGetValues\n"); } } else { if (num_values > hypre_VectorSize(local_vector)) { hypre_error_in_arg(2); return hypre_error_flag; } #ifdef HYPRE_USING_OPENMP #pragma omp parallel for private(i) HYPRE_SMP_SCHEDULE #endif for (i = 0; i < num_values; i++) { values[i] = data[i]; } } return hypre_error_flag; } HYPRE_Int hypre_ParVectorGetValues2(hypre_ParVector vector, HYPRE_Int num_values, HYPRE_BigInt indices, HYPRE_BigInt base, HYPRE_Complex values) { #if defined(HYPRE_USING_CUDA) \|\| defined(HYPRE_USING_HIP) if (HYPRE_EXEC_DEVICE == hypre_GetExecPolicy1( hypre_ParVectorMemoryLocation(vector) )) { hypre_ParVectorGetValuesDevice(vector, num_values, indices, base, values); } else #endif { hypre_ParVectorGetValuesHost(vector, num_values, indices, base, values); } return hypre_error_flag; } HYPRE_Int hypre_ParVectorGetValues(hypre_ParVector vector, HYPRE_Int num_values, HYPRE_BigInt indices, HYPRE_Complex *values) { return hypre_ParVectorGetValues2(vector, num_values, indices, 0, values); }
feature.c	/* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % FFFFF EEEEE AAA TTTTT U U RRRR EEEEE % % F E A A T U U R R E % % FFF EEE AAAAA T U U RRRR EEE % % F E A A T U U R R E % % F EEEEE A A T UUU R R EEEEE % % % % % % MagickCore Image Feature Methods % % % % Software Design % % Cristy % % July 1992 % % % % % % Copyright 1999-2020 ImageMagick Studio LLC, a non-profit organization % % dedicated to making software imaging solutions freely available. % % % % You may not use this file except in compliance with the License. You may % % obtain a copy of the License at % % % % https://imagemagick.org/script/license.php % % % % Unless required by applicable law or agreed to in writing, software % % distributed under the License is distributed on an "AS IS" BASIS, % % WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. % % See the License for the specific language governing permissions and % % limitations under the License. % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % / / Include declarations. / #include "MagickCore/studio.h" #include "MagickCore/animate.h" #include "MagickCore/artifact.h" #include "MagickCore/blob.h" #include "MagickCore/blob-private.h" #include "MagickCore/cache.h" #include "MagickCore/cache-private.h" #include "MagickCore/cache-view.h" #include "MagickCore/channel.h" #include "MagickCore/client.h" #include "MagickCore/color.h" #include "MagickCore/color-private.h" #include "MagickCore/colorspace.h" #include "MagickCore/colorspace-private.h" #include "MagickCore/composite.h" #include "MagickCore/composite-private.h" #include "MagickCore/compress.h" #include "MagickCore/constitute.h" #include "MagickCore/display.h" #include "MagickCore/draw.h" #include "MagickCore/enhance.h" #include "MagickCore/exception.h" #include "MagickCore/exception-private.h" #include "MagickCore/feature.h" #include "MagickCore/gem.h" #include "MagickCore/geometry.h" #include "MagickCore/list.h" #include "MagickCore/image-private.h" #include "MagickCore/magic.h" #include "MagickCore/magick.h" #include "MagickCore/matrix.h" #include "MagickCore/memory_.h" #include "MagickCore/module.h" #include "MagickCore/monitor.h" #include "MagickCore/monitor-private.h" #include "MagickCore/morphology-private.h" #include "MagickCore/option.h" #include "MagickCore/paint.h" #include "MagickCore/pixel-accessor.h" #include "MagickCore/profile.h" #include "MagickCore/property.h" #include "MagickCore/quantize.h" #include "MagickCore/quantum-private.h" #include "MagickCore/random_.h" #include "MagickCore/resource_.h" #include "MagickCore/segment.h" #include "MagickCore/semaphore.h" #include "MagickCore/signature-private.h" #include "MagickCore/string_.h" #include "MagickCore/thread-private.h" #include "MagickCore/timer.h" #include "MagickCore/utility.h" #include "MagickCore/version.h" / %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % C a n n y E d g e I m a g e % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % CannyEdgeImage() uses a multi-stage algorithm to detect a wide range of % edges in images. % % The format of the CannyEdgeImage method is: % % Image CannyEdgeImage(const Image image,const double radius, % const double sigma,const double lower_percent, % const double upper_percent,ExceptionInfo exception) % % A description of each parameter follows: % % o image: the image. % % o radius: the radius of the gaussian smoothing filter. % % o sigma: the sigma of the gaussian smoothing filter. % % o lower_percent: percentage of edge pixels in the lower threshold. % % o upper_percent: percentage of edge pixels in the upper threshold. % % o exception: return any errors or warnings in this structure. % / typedef struct _CannyInfo { double magnitude, intensity; int orientation; ssize_t x, y; } CannyInfo; static inline MagickBooleanType IsAuthenticPixel(const Image image, const ssize_t x,const ssize_t y) { if ((x < 0) \|\| (x >= (ssize_t) image->columns)) return(MagickFalse); if ((y < 0) \|\| (y >= (ssize_t) image->rows)) return(MagickFalse); return(MagickTrue); } static MagickBooleanType TraceEdges(Image edge_image,CacheView edge_view, MatrixInfo canny_cache,const ssize_t x,const ssize_t y, const double lower_threshold,ExceptionInfo exception) { CannyInfo edge, pixel; MagickBooleanType status; register Quantum q; register ssize_t i; q=GetCacheViewAuthenticPixels(edge_view,x,y,1,1,exception); if (q == (Quantum ) NULL) return(MagickFalse); q=QuantumRange; status=SyncCacheViewAuthenticPixels(edge_view,exception); if (status == MagickFalse) return(MagickFalse); if (GetMatrixElement(canny_cache,0,0,&edge) == MagickFalse) return(MagickFalse); edge.x=x; edge.y=y; if (SetMatrixElement(canny_cache,0,0,&edge) == MagickFalse) return(MagickFalse); for (i=1; i != 0; ) { ssize_t v; i--; status=GetMatrixElement(canny_cache,i,0,&edge); if (status == MagickFalse) return(MagickFalse); for (v=(-1); v <= 1; v++) { ssize_t u; for (u=(-1); u <= 1; u++) { if ((u == 0) && (v == 0)) continue; if (IsAuthenticPixel(edge_image,edge.x+u,edge.y+v) == MagickFalse) continue; /* Not an edge if gradient value is below the lower threshold. / q=GetCacheViewAuthenticPixels(edge_view,edge.x+u,edge.y+v,1,1, exception); if (q == (Quantum ) NULL) return(MagickFalse); status=GetMatrixElement(canny_cache,edge.x+u,edge.y+v,&pixel); if (status == MagickFalse) return(MagickFalse); if ((GetPixelIntensity(edge_image,q) == 0.0) && (pixel.intensity >= lower_threshold)) { q=QuantumRange; status=SyncCacheViewAuthenticPixels(edge_view,exception); if (status == MagickFalse) return(MagickFalse); edge.x+=u; edge.y+=v; status=SetMatrixElement(canny_cache,i,0,&edge); if (status == MagickFalse) return(MagickFalse); i++; } } } } return(MagickTrue); } MagickExport Image CannyEdgeImage(const Image image,const double radius, const double sigma,const double lower_percent,const double upper_percent, ExceptionInfo exception) { #define CannyEdgeImageTag "CannyEdge/Image" CacheView edge_view; CannyInfo element; char geometry[MagickPathExtent]; double lower_threshold, max, min, upper_threshold; Image edge_image; KernelInfo kernel_info; MagickBooleanType status; MagickOffsetType progress; MatrixInfo canny_cache; ssize_t y; assert(image != (const Image ) NULL); assert(image->signature == MagickCoreSignature); if (image->debug != MagickFalse) (void) LogMagickEvent(TraceEvent,GetMagickModule(),"%s",image->filename); assert(exception != (ExceptionInfo ) NULL); assert(exception->signature == MagickCoreSignature); /* Filter out noise. / (void) FormatLocaleString(geometry,MagickPathExtent, "blur:%.20gx%.20g;blur:%.20gx%.20g+90",radius,sigma,radius,sigma); kernel_info=AcquireKernelInfo(geometry,exception); if (kernel_info == (KernelInfo ) NULL) ThrowImageException(ResourceLimitError,"MemoryAllocationFailed"); edge_image=MorphologyImage(image,ConvolveMorphology,1,kernel_info,exception); kernel_info=DestroyKernelInfo(kernel_info); if (edge_image == (Image ) NULL) return((Image ) NULL); if (TransformImageColorspace(edge_image,GRAYColorspace,exception) == MagickFalse) { edge_image=DestroyImage(edge_image); return((Image ) NULL); } (void) SetImageAlphaChannel(edge_image,OffAlphaChannel,exception); / Find the intensity gradient of the image. / canny_cache=AcquireMatrixInfo(edge_image->columns,edge_image->rows, sizeof(CannyInfo),exception); if (canny_cache == (MatrixInfo ) NULL) { edge_image=DestroyImage(edge_image); return((Image ) NULL); } status=MagickTrue; edge_view=AcquireVirtualCacheView(edge_image,exception); #if defined(MAGICKCORE_OPENMP_SUPPORT) #pragma omp parallel for schedule(static) shared(status) \ magick_number_threads(edge_image,edge_image,edge_image->rows,1) #endif for (y=0; y < (ssize_t) edge_image->rows; y++) { register const Quantum magick_restrict p; register ssize_t x; if (status == MagickFalse) continue; p=GetCacheViewVirtualPixels(edge_view,0,y,edge_image->columns+1,2, exception); if (p == (const Quantum ) NULL) { status=MagickFalse; continue; } for (x=0; x < (ssize_t) edge_image->columns; x++) { CannyInfo pixel; double dx, dy; register const Quantum magick_restrict kernel_pixels; ssize_t v; static double Gx[2][2] = { { -1.0, +1.0 }, { -1.0, +1.0 } }, Gy[2][2] = { { +1.0, +1.0 }, { -1.0, -1.0 } }; (void) memset(&pixel,0,sizeof(pixel)); dx=0.0; dy=0.0; kernel_pixels=p; for (v=0; v < 2; v++) { ssize_t u; for (u=0; u < 2; u++) { double intensity; intensity=GetPixelIntensity(edge_image,kernel_pixels+u); dx+=0.5Gx[v][u]intensity; dy+=0.5Gy[v][u]intensity; } kernel_pixels+=edge_image->columns+1; } pixel.magnitude=hypot(dx,dy); pixel.orientation=0; if (fabs(dx) > MagickEpsilon) { double slope; slope=dy/dx; if (slope < 0.0) { if (slope < -2.41421356237) pixel.orientation=0; else if (slope < -0.414213562373) pixel.orientation=1; else pixel.orientation=2; } else { if (slope > 2.41421356237) pixel.orientation=0; else if (slope > 0.414213562373) pixel.orientation=3; else pixel.orientation=2; } } if (SetMatrixElement(canny_cache,x,y,&pixel) == MagickFalse) continue; p+=GetPixelChannels(edge_image); } } edge_view=DestroyCacheView(edge_view); /* Non-maxima suppression, remove pixels that are not considered to be part of an edge. / progress=0; (void) GetMatrixElement(canny_cache,0,0,&element); max=element.intensity; min=element.intensity; edge_view=AcquireAuthenticCacheView(edge_image,exception); #if defined(MAGICKCORE_OPENMP_SUPPORT) #pragma omp parallel for schedule(static) shared(status) \ magick_number_threads(edge_image,edge_image,edge_image->rows,1) #endif for (y=0; y < (ssize_t) edge_image->rows; y++) { register Quantum magick_restrict q; register ssize_t x; if (status == MagickFalse) continue; q=GetCacheViewAuthenticPixels(edge_view,0,y,edge_image->columns,1, exception); if (q == (Quantum ) NULL) { status=MagickFalse; continue; } for (x=0; x < (ssize_t) edge_image->columns; x++) { CannyInfo alpha_pixel, beta_pixel, pixel; (void) GetMatrixElement(canny_cache,x,y,&pixel); switch (pixel.orientation) { case 0: default: { / 0 degrees, north and south. / (void) GetMatrixElement(canny_cache,x,y-1,&alpha_pixel); (void) GetMatrixElement(canny_cache,x,y+1,&beta_pixel); break; } case 1: { / 45 degrees, northwest and southeast. / (void) GetMatrixElement(canny_cache,x-1,y-1,&alpha_pixel); (void) GetMatrixElement(canny_cache,x+1,y+1,&beta_pixel); break; } case 2: { / 90 degrees, east and west. / (void) GetMatrixElement(canny_cache,x-1,y,&alpha_pixel); (void) GetMatrixElement(canny_cache,x+1,y,&beta_pixel); break; } case 3: { / 135 degrees, northeast and southwest. / (void) GetMatrixElement(canny_cache,x+1,y-1,&beta_pixel); (void) GetMatrixElement(canny_cache,x-1,y+1,&alpha_pixel); break; } } pixel.intensity=pixel.magnitude; if ((pixel.magnitude < alpha_pixel.magnitude) \|\| (pixel.magnitude < beta_pixel.magnitude)) pixel.intensity=0; (void) SetMatrixElement(canny_cache,x,y,&pixel); #if defined(MAGICKCORE_OPENMP_SUPPORT) #pragma omp critical (MagickCore_CannyEdgeImage) #endif { if (pixel.intensity < min) min=pixel.intensity; if (pixel.intensity > max) max=pixel.intensity; } q=0; q+=GetPixelChannels(edge_image); } if (SyncCacheViewAuthenticPixels(edge_view,exception) == MagickFalse) status=MagickFalse; } edge_view=DestroyCacheView(edge_view); /* Estimate hysteresis threshold. / lower_threshold=lower_percent(max-min)+min; upper_threshold=upper_percent(max-min)+min; / Hysteresis threshold. / edge_view=AcquireAuthenticCacheView(edge_image,exception); for (y=0; y < (ssize_t) edge_image->rows; y++) { register ssize_t x; if (status == MagickFalse) continue; for (x=0; x < (ssize_t) edge_image->columns; x++) { CannyInfo pixel; register const Quantum magick_restrict p; /* Edge if pixel gradient higher than upper threshold. / p=GetCacheViewVirtualPixels(edge_view,x,y,1,1,exception); if (p == (const Quantum ) NULL) continue; status=GetMatrixElement(canny_cache,x,y,&pixel); if (status == MagickFalse) continue; if ((GetPixelIntensity(edge_image,p) == 0.0) && (pixel.intensity >= upper_threshold)) status=TraceEdges(edge_image,edge_view,canny_cache,x,y,lower_threshold, exception); } if (image->progress_monitor != (MagickProgressMonitor) NULL) { MagickBooleanType proceed; #if defined(MAGICKCORE_OPENMP_SUPPORT) #pragma omp atomic #endif progress++; proceed=SetImageProgress(image,CannyEdgeImageTag,progress,image->rows); if (proceed == MagickFalse) status=MagickFalse; } } edge_view=DestroyCacheView(edge_view); /* Free resources. / canny_cache=DestroyMatrixInfo(canny_cache); return(edge_image); } / %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % G e t I m a g e F e a t u r e s % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % GetImageFeatures() returns features for each channel in the image in % each of four directions (horizontal, vertical, left and right diagonals) % for the specified distance. The features include the angular second % moment, contrast, correlation, sum of squares: variance, inverse difference % moment, sum average, sum varience, sum entropy, entropy, difference variance, % difference entropy, information measures of correlation 1, information % measures of correlation 2, and maximum correlation coefficient. You can % access the red channel contrast, for example, like this: % % channel_features=GetImageFeatures(image,1,exception); % contrast=channel_features[RedPixelChannel].contrast[0]; % % Use MagickRelinquishMemory() to free the features buffer. % % The format of the GetImageFeatures method is: % % ChannelFeatures GetImageFeatures(const Image image, % const size_t distance,ExceptionInfo exception) % % A description of each parameter follows: % % o image: the image. % % o distance: the distance. % % o exception: return any errors or warnings in this structure. % / static inline double MagickLog10(const double x) { #define Log10Epsilon (1.0e-11) if (fabs(x) < Log10Epsilon) return(log10(Log10Epsilon)); return(log10(fabs(x))); } MagickExport ChannelFeatures GetImageFeatures(const Image image, const size_t distance,ExceptionInfo exception) { typedef struct _ChannelStatistics { PixelInfo direction[4]; / horizontal, vertical, left and right diagonals / } ChannelStatistics; CacheView image_view; ChannelFeatures channel_features; ChannelStatistics cooccurrence, correlation, density_x, density_xy, density_y, entropy_x, entropy_xy, entropy_xy1, entropy_xy2, entropy_y, mean, *Q, sum, sum_squares, variance; PixelPacket gray, grays; MagickBooleanType status; register ssize_t i, r; size_t length; unsigned int number_grays; assert(image != (Image ) NULL); assert(image->signature == MagickCoreSignature); if (image->debug != MagickFalse) (void) LogMagickEvent(TraceEvent,GetMagickModule(),"%s",image->filename); if ((image->columns < (distance+1)) \|\| (image->rows < (distance+1))) return((ChannelFeatures ) NULL); length=MaxPixelChannels+1UL; channel_features=(ChannelFeatures ) AcquireQuantumMemory(length, sizeof(channel_features)); if (channel_features == (ChannelFeatures ) NULL) ThrowFatalException(ResourceLimitFatalError,"MemoryAllocationFailed"); (void) memset(channel_features,0,length* sizeof(channel_features)); / Form grays. / grays=(PixelPacket ) AcquireQuantumMemory(MaxMap+1UL,sizeof(grays)); if (grays == (PixelPacket ) NULL) { channel_features=(ChannelFeatures ) RelinquishMagickMemory( channel_features); (void) ThrowMagickException(exception,GetMagickModule(), ResourceLimitError,"MemoryAllocationFailed","`%s'",image->filename); return(channel_features); } for (i=0; i <= (ssize_t) MaxMap; i++) { grays[i].red=(~0U); grays[i].green=(~0U); grays[i].blue=(~0U); grays[i].alpha=(~0U); grays[i].black=(~0U); } status=MagickTrue; image_view=AcquireVirtualCacheView(image,exception); #if defined(MAGICKCORE_OPENMP_SUPPORT) #pragma omp parallel for schedule(static) shared(status) \ magick_number_threads(image,image,image->rows,1) #endif for (r=0; r < (ssize_t) image->rows; r++) { register const Quantum magick_restrict p; register ssize_t x; if (status == MagickFalse) continue; p=GetCacheViewVirtualPixels(image_view,0,r,image->columns,1,exception); if (p == (const Quantum ) NULL) { status=MagickFalse; continue; } for (x=0; x < (ssize_t) image->columns; x++) { grays[ScaleQuantumToMap(GetPixelRed(image,p))].red= ScaleQuantumToMap(GetPixelRed(image,p)); grays[ScaleQuantumToMap(GetPixelGreen(image,p))].green= ScaleQuantumToMap(GetPixelGreen(image,p)); grays[ScaleQuantumToMap(GetPixelBlue(image,p))].blue= ScaleQuantumToMap(GetPixelBlue(image,p)); if (image->colorspace == CMYKColorspace) grays[ScaleQuantumToMap(GetPixelBlack(image,p))].black= ScaleQuantumToMap(GetPixelBlack(image,p)); if (image->alpha_trait != UndefinedPixelTrait) grays[ScaleQuantumToMap(GetPixelAlpha(image,p))].alpha= ScaleQuantumToMap(GetPixelAlpha(image,p)); p+=GetPixelChannels(image); } } image_view=DestroyCacheView(image_view); if (status == MagickFalse) { grays=(PixelPacket ) RelinquishMagickMemory(grays); channel_features=(ChannelFeatures ) RelinquishMagickMemory( channel_features); return(channel_features); } (void) memset(&gray,0,sizeof(gray)); for (i=0; i <= (ssize_t) MaxMap; i++) { if (grays[i].red != ~0U) grays[gray.red++].red=grays[i].red; if (grays[i].green != ~0U) grays[gray.green++].green=grays[i].green; if (grays[i].blue != ~0U) grays[gray.blue++].blue=grays[i].blue; if (image->colorspace == CMYKColorspace) if (grays[i].black != ~0U) grays[gray.black++].black=grays[i].black; if (image->alpha_trait != UndefinedPixelTrait) if (grays[i].alpha != ~0U) grays[gray.alpha++].alpha=grays[i].alpha; } / Allocate spatial dependence matrix. / number_grays=gray.red; if (gray.green > number_grays) number_grays=gray.green; if (gray.blue > number_grays) number_grays=gray.blue; if (image->colorspace == CMYKColorspace) if (gray.black > number_grays) number_grays=gray.black; if (image->alpha_trait != UndefinedPixelTrait) if (gray.alpha > number_grays) number_grays=gray.alpha; cooccurrence=(ChannelStatistics ) AcquireQuantumMemory(number_grays, sizeof(cooccurrence)); density_x=(ChannelStatistics ) AcquireQuantumMemory(2(number_grays+1), sizeof(density_x)); density_xy=(ChannelStatistics ) AcquireQuantumMemory(2(number_grays+1), sizeof(density_xy)); density_y=(ChannelStatistics ) AcquireQuantumMemory(2(number_grays+1), sizeof(density_y)); Q=(ChannelStatistics ) AcquireQuantumMemory(number_grays,sizeof(Q)); sum=(ChannelStatistics ) AcquireQuantumMemory(number_grays,sizeof(sum)); if ((cooccurrence == (ChannelStatistics *) NULL) \|\| (density_x == (ChannelStatistics ) NULL) \|\| (density_xy == (ChannelStatistics ) NULL) \|\| (density_y == (ChannelStatistics ) NULL) \|\| (Q == (ChannelStatistics *) NULL) \|\| (sum == (ChannelStatistics ) NULL)) { if (Q != (ChannelStatistics *) NULL) { for (i=0; i < (ssize_t) number_grays; i++) Q[i]=(ChannelStatistics ) RelinquishMagickMemory(Q[i]); Q=(ChannelStatistics *) RelinquishMagickMemory(Q); } if (sum != (ChannelStatistics ) NULL) sum=(ChannelStatistics ) RelinquishMagickMemory(sum); if (density_y != (ChannelStatistics ) NULL) density_y=(ChannelStatistics ) RelinquishMagickMemory(density_y); if (density_xy != (ChannelStatistics ) NULL) density_xy=(ChannelStatistics ) RelinquishMagickMemory(density_xy); if (density_x != (ChannelStatistics ) NULL) density_x=(ChannelStatistics ) RelinquishMagickMemory(density_x); if (cooccurrence != (ChannelStatistics ) NULL) { for (i=0; i < (ssize_t) number_grays; i++) cooccurrence[i]=(ChannelStatistics ) RelinquishMagickMemory(cooccurrence[i]); cooccurrence=(ChannelStatistics *) RelinquishMagickMemory( cooccurrence); } grays=(PixelPacket ) RelinquishMagickMemory(grays); channel_features=(ChannelFeatures ) RelinquishMagickMemory( channel_features); (void) ThrowMagickException(exception,GetMagickModule(), ResourceLimitError,"MemoryAllocationFailed","`%s'",image->filename); return(channel_features); } (void) memset(&correlation,0,sizeof(correlation)); (void) memset(density_x,0,2(number_grays+1)sizeof(density_x)); (void) memset(density_xy,0,2(number_grays+1)sizeof(density_xy)); (void) memset(density_y,0,2(number_grays+1)sizeof(density_y)); (void) memset(&mean,0,sizeof(mean)); (void) memset(sum,0,number_grayssizeof(sum)); (void) memset(&sum_squares,0,sizeof(sum_squares)); (void) memset(density_xy,0,2number_grayssizeof(density_xy)); (void) memset(&entropy_x,0,sizeof(entropy_x)); (void) memset(&entropy_xy,0,sizeof(entropy_xy)); (void) memset(&entropy_xy1,0,sizeof(entropy_xy1)); (void) memset(&entropy_xy2,0,sizeof(entropy_xy2)); (void) memset(&entropy_y,0,sizeof(entropy_y)); (void) memset(&variance,0,sizeof(variance)); for (i=0; i < (ssize_t) number_grays; i++) { cooccurrence[i]=(ChannelStatistics ) AcquireQuantumMemory(number_grays, sizeof(*cooccurrence)); Q[i]=(ChannelStatistics ) AcquireQuantumMemory(number_grays,sizeof(*Q)); if ((cooccurrence[i] == (ChannelStatistics ) NULL) \|\| (Q[i] == (ChannelStatistics ) NULL)) break; (void) memset(cooccurrence[i],0,number_grays sizeof(*cooccurrence)); (void) memset(Q[i],0,number_grayssizeof(*Q)); } if (i < (ssize_t) number_grays) { for (i--; i >= 0; i--) { if (Q[i] != (ChannelStatistics ) NULL) Q[i]=(ChannelStatistics ) RelinquishMagickMemory(Q[i]); if (cooccurrence[i] != (ChannelStatistics ) NULL) cooccurrence[i]=(ChannelStatistics ) RelinquishMagickMemory(cooccurrence[i]); } Q=(ChannelStatistics ) RelinquishMagickMemory(Q); cooccurrence=(ChannelStatistics ) RelinquishMagickMemory(cooccurrence); sum=(ChannelStatistics ) RelinquishMagickMemory(sum); density_y=(ChannelStatistics ) RelinquishMagickMemory(density_y); density_xy=(ChannelStatistics ) RelinquishMagickMemory(density_xy); density_x=(ChannelStatistics ) RelinquishMagickMemory(density_x); grays=(PixelPacket ) RelinquishMagickMemory(grays); channel_features=(ChannelFeatures ) RelinquishMagickMemory( channel_features); (void) ThrowMagickException(exception,GetMagickModule(), ResourceLimitError,"MemoryAllocationFailed","`%s'",image->filename); return(channel_features); } / Initialize spatial dependence matrix. / status=MagickTrue; image_view=AcquireVirtualCacheView(image,exception); for (r=0; r < (ssize_t) image->rows; r++) { register const Quantum magick_restrict p; register ssize_t x; ssize_t offset, u, v; if (status == MagickFalse) continue; p=GetCacheViewVirtualPixels(image_view,-(ssize_t) distance,r,image->columns+ 2distance,distance+2,exception); if (p == (const Quantum ) NULL) { status=MagickFalse; continue; } p+=distanceGetPixelChannels(image);; for (x=0; x < (ssize_t) image->columns; x++) { for (i=0; i < 4; i++) { switch (i) { case 0: default: { / Horizontal adjacency. / offset=(ssize_t) distance; break; } case 1: { / Vertical adjacency. / offset=(ssize_t) (image->columns+2distance); break; } case 2: { /* Right diagonal adjacency. / offset=(ssize_t) ((image->columns+2distance)-distance); break; } case 3: { /* Left diagonal adjacency. / offset=(ssize_t) ((image->columns+2distance)+distance); break; } } u=0; v=0; while (grays[u].red != ScaleQuantumToMap(GetPixelRed(image,p))) u++; while (grays[v].red != ScaleQuantumToMap(GetPixelRed(image,p+offsetGetPixelChannels(image)))) v++; cooccurrence[u][v].direction[i].red++; cooccurrence[v][u].direction[i].red++; u=0; v=0; while (grays[u].green != ScaleQuantumToMap(GetPixelGreen(image,p))) u++; while (grays[v].green != ScaleQuantumToMap(GetPixelGreen(image,p+offsetGetPixelChannels(image)))) v++; cooccurrence[u][v].direction[i].green++; cooccurrence[v][u].direction[i].green++; u=0; v=0; while (grays[u].blue != ScaleQuantumToMap(GetPixelBlue(image,p))) u++; while (grays[v].blue != ScaleQuantumToMap(GetPixelBlue(image,p+offsetGetPixelChannels(image)))) v++; cooccurrence[u][v].direction[i].blue++; cooccurrence[v][u].direction[i].blue++; if (image->colorspace == CMYKColorspace) { u=0; v=0; while (grays[u].black != ScaleQuantumToMap(GetPixelBlack(image,p))) u++; while (grays[v].black != ScaleQuantumToMap(GetPixelBlack(image,p+offsetGetPixelChannels(image)))) v++; cooccurrence[u][v].direction[i].black++; cooccurrence[v][u].direction[i].black++; } if (image->alpha_trait != UndefinedPixelTrait) { u=0; v=0; while (grays[u].alpha != ScaleQuantumToMap(GetPixelAlpha(image,p))) u++; while (grays[v].alpha != ScaleQuantumToMap(GetPixelAlpha(image,p+offsetGetPixelChannels(image)))) v++; cooccurrence[u][v].direction[i].alpha++; cooccurrence[v][u].direction[i].alpha++; } } p+=GetPixelChannels(image); } } grays=(PixelPacket ) RelinquishMagickMemory(grays); image_view=DestroyCacheView(image_view); if (status == MagickFalse) { for (i=0; i < (ssize_t) number_grays; i++) cooccurrence[i]=(ChannelStatistics ) RelinquishMagickMemory(cooccurrence[i]); cooccurrence=(ChannelStatistics ) RelinquishMagickMemory(cooccurrence); channel_features=(ChannelFeatures ) RelinquishMagickMemory( channel_features); (void) ThrowMagickException(exception,GetMagickModule(), ResourceLimitError,"MemoryAllocationFailed","`%s'",image->filename); return(channel_features); } /* Normalize spatial dependence matrix. / for (i=0; i < 4; i++) { double normalize; register ssize_t y; switch (i) { case 0: default: { / Horizontal adjacency. / normalize=2.0image->rows(image->columns-distance); break; } case 1: { / Vertical adjacency. / normalize=2.0(image->rows-distance)image->columns; break; } case 2: { / Right diagonal adjacency. / normalize=2.0(image->rows-distance)(image->columns-distance); break; } case 3: { / Left diagonal adjacency. / normalize=2.0(image->rows-distance)(image->columns-distance); break; } } normalize=PerceptibleReciprocal(normalize); for (y=0; y < (ssize_t) number_grays; y++) { register ssize_t x; for (x=0; x < (ssize_t) number_grays; x++) { cooccurrence[x][y].direction[i].red=normalize; cooccurrence[x][y].direction[i].green=normalize; cooccurrence[x][y].direction[i].blue=normalize; if (image->colorspace == CMYKColorspace) cooccurrence[x][y].direction[i].black=normalize; if (image->alpha_trait != UndefinedPixelTrait) cooccurrence[x][y].direction[i].alpha=normalize; } } } /* Compute texture features. / #if defined(MAGICKCORE_OPENMP_SUPPORT) #pragma omp parallel for schedule(static) shared(status) \ magick_number_threads(image,image,number_grays,1) #endif for (i=0; i < 4; i++) { register ssize_t y; for (y=0; y < (ssize_t) number_grays; y++) { register ssize_t x; for (x=0; x < (ssize_t) number_grays; x++) { / Angular second moment: measure of homogeneity of the image. / channel_features[RedPixelChannel].angular_second_moment[i]+= cooccurrence[x][y].direction[i].red cooccurrence[x][y].direction[i].red; channel_features[GreenPixelChannel].angular_second_moment[i]+= cooccurrence[x][y].direction[i].green* cooccurrence[x][y].direction[i].green; channel_features[BluePixelChannel].angular_second_moment[i]+= cooccurrence[x][y].direction[i].blue* cooccurrence[x][y].direction[i].blue; if (image->colorspace == CMYKColorspace) channel_features[BlackPixelChannel].angular_second_moment[i]+= cooccurrence[x][y].direction[i].black* cooccurrence[x][y].direction[i].black; if (image->alpha_trait != UndefinedPixelTrait) channel_features[AlphaPixelChannel].angular_second_moment[i]+= cooccurrence[x][y].direction[i].alpha* cooccurrence[x][y].direction[i].alpha; /* Correlation: measure of linear-dependencies in the image. / sum[y].direction[i].red+=cooccurrence[x][y].direction[i].red; sum[y].direction[i].green+=cooccurrence[x][y].direction[i].green; sum[y].direction[i].blue+=cooccurrence[x][y].direction[i].blue; if (image->colorspace == CMYKColorspace) sum[y].direction[i].black+=cooccurrence[x][y].direction[i].black; if (image->alpha_trait != UndefinedPixelTrait) sum[y].direction[i].alpha+=cooccurrence[x][y].direction[i].alpha; correlation.direction[i].red+=xycooccurrence[x][y].direction[i].red; correlation.direction[i].green+=xy* cooccurrence[x][y].direction[i].green; correlation.direction[i].blue+=xy cooccurrence[x][y].direction[i].blue; if (image->colorspace == CMYKColorspace) correlation.direction[i].black+=xy cooccurrence[x][y].direction[i].black; if (image->alpha_trait != UndefinedPixelTrait) correlation.direction[i].alpha+=xy cooccurrence[x][y].direction[i].alpha; /* Inverse Difference Moment. / channel_features[RedPixelChannel].inverse_difference_moment[i]+= cooccurrence[x][y].direction[i].red/((y-x)(y-x)+1); channel_features[GreenPixelChannel].inverse_difference_moment[i]+= cooccurrence[x][y].direction[i].green/((y-x)(y-x)+1); channel_features[BluePixelChannel].inverse_difference_moment[i]+= cooccurrence[x][y].direction[i].blue/((y-x)(y-x)+1); if (image->colorspace == CMYKColorspace) channel_features[BlackPixelChannel].inverse_difference_moment[i]+= cooccurrence[x][y].direction[i].black/((y-x)(y-x)+1); if (image->alpha_trait != UndefinedPixelTrait) channel_features[AlphaPixelChannel].inverse_difference_moment[i]+= cooccurrence[x][y].direction[i].alpha/((y-x)(y-x)+1); /* Sum average. / density_xy[y+x+2].direction[i].red+= cooccurrence[x][y].direction[i].red; density_xy[y+x+2].direction[i].green+= cooccurrence[x][y].direction[i].green; density_xy[y+x+2].direction[i].blue+= cooccurrence[x][y].direction[i].blue; if (image->colorspace == CMYKColorspace) density_xy[y+x+2].direction[i].black+= cooccurrence[x][y].direction[i].black; if (image->alpha_trait != UndefinedPixelTrait) density_xy[y+x+2].direction[i].alpha+= cooccurrence[x][y].direction[i].alpha; / Entropy. / channel_features[RedPixelChannel].entropy[i]-= cooccurrence[x][y].direction[i].red MagickLog10(cooccurrence[x][y].direction[i].red); channel_features[GreenPixelChannel].entropy[i]-= cooccurrence[x][y].direction[i].green* MagickLog10(cooccurrence[x][y].direction[i].green); channel_features[BluePixelChannel].entropy[i]-= cooccurrence[x][y].direction[i].blue* MagickLog10(cooccurrence[x][y].direction[i].blue); if (image->colorspace == CMYKColorspace) channel_features[BlackPixelChannel].entropy[i]-= cooccurrence[x][y].direction[i].black* MagickLog10(cooccurrence[x][y].direction[i].black); if (image->alpha_trait != UndefinedPixelTrait) channel_features[AlphaPixelChannel].entropy[i]-= cooccurrence[x][y].direction[i].alpha* MagickLog10(cooccurrence[x][y].direction[i].alpha); /* Information Measures of Correlation. / density_x[x].direction[i].red+=cooccurrence[x][y].direction[i].red; density_x[x].direction[i].green+=cooccurrence[x][y].direction[i].green; density_x[x].direction[i].blue+=cooccurrence[x][y].direction[i].blue; if (image->alpha_trait != UndefinedPixelTrait) density_x[x].direction[i].alpha+= cooccurrence[x][y].direction[i].alpha; if (image->colorspace == CMYKColorspace) density_x[x].direction[i].black+= cooccurrence[x][y].direction[i].black; density_y[y].direction[i].red+=cooccurrence[x][y].direction[i].red; density_y[y].direction[i].green+=cooccurrence[x][y].direction[i].green; density_y[y].direction[i].blue+=cooccurrence[x][y].direction[i].blue; if (image->colorspace == CMYKColorspace) density_y[y].direction[i].black+= cooccurrence[x][y].direction[i].black; if (image->alpha_trait != UndefinedPixelTrait) density_y[y].direction[i].alpha+= cooccurrence[x][y].direction[i].alpha; } mean.direction[i].red+=ysum[y].direction[i].red; sum_squares.direction[i].red+=yysum[y].direction[i].red; mean.direction[i].green+=ysum[y].direction[i].green; sum_squares.direction[i].green+=yysum[y].direction[i].green; mean.direction[i].blue+=ysum[y].direction[i].blue; sum_squares.direction[i].blue+=yysum[y].direction[i].blue; if (image->colorspace == CMYKColorspace) { mean.direction[i].black+=ysum[y].direction[i].black; sum_squares.direction[i].black+=yysum[y].direction[i].black; } if (image->alpha_trait != UndefinedPixelTrait) { mean.direction[i].alpha+=ysum[y].direction[i].alpha; sum_squares.direction[i].alpha+=yysum[y].direction[i].alpha; } } /* Correlation: measure of linear-dependencies in the image. / channel_features[RedPixelChannel].correlation[i]= (correlation.direction[i].red-mean.direction[i].red mean.direction[i].red)/(sqrt(sum_squares.direction[i].red- (mean.direction[i].redmean.direction[i].red))sqrt( sum_squares.direction[i].red-(mean.direction[i].red* mean.direction[i].red))); channel_features[GreenPixelChannel].correlation[i]= (correlation.direction[i].green-mean.direction[i].green* mean.direction[i].green)/(sqrt(sum_squares.direction[i].green- (mean.direction[i].greenmean.direction[i].green))sqrt( sum_squares.direction[i].green-(mean.direction[i].green* mean.direction[i].green))); channel_features[BluePixelChannel].correlation[i]= (correlation.direction[i].blue-mean.direction[i].blue* mean.direction[i].blue)/(sqrt(sum_squares.direction[i].blue- (mean.direction[i].bluemean.direction[i].blue))sqrt( sum_squares.direction[i].blue-(mean.direction[i].blue* mean.direction[i].blue))); if (image->colorspace == CMYKColorspace) channel_features[BlackPixelChannel].correlation[i]= (correlation.direction[i].black-mean.direction[i].black* mean.direction[i].black)/(sqrt(sum_squares.direction[i].black- (mean.direction[i].blackmean.direction[i].black))sqrt( sum_squares.direction[i].black-(mean.direction[i].black* mean.direction[i].black))); if (image->alpha_trait != UndefinedPixelTrait) channel_features[AlphaPixelChannel].correlation[i]= (correlation.direction[i].alpha-mean.direction[i].alpha* mean.direction[i].alpha)/(sqrt(sum_squares.direction[i].alpha- (mean.direction[i].alphamean.direction[i].alpha))sqrt( sum_squares.direction[i].alpha-(mean.direction[i].alpha* mean.direction[i].alpha))); } /* Compute more texture features. / #if defined(MAGICKCORE_OPENMP_SUPPORT) #pragma omp parallel for schedule(static) shared(status) \ magick_number_threads(image,image,number_grays,1) #endif for (i=0; i < 4; i++) { register ssize_t x; for (x=2; x < (ssize_t) (2number_grays); x++) { /* Sum average. / channel_features[RedPixelChannel].sum_average[i]+= xdensity_xy[x].direction[i].red; channel_features[GreenPixelChannel].sum_average[i]+= xdensity_xy[x].direction[i].green; channel_features[BluePixelChannel].sum_average[i]+= xdensity_xy[x].direction[i].blue; if (image->colorspace == CMYKColorspace) channel_features[BlackPixelChannel].sum_average[i]+= xdensity_xy[x].direction[i].black; if (image->alpha_trait != UndefinedPixelTrait) channel_features[AlphaPixelChannel].sum_average[i]+= xdensity_xy[x].direction[i].alpha; /* Sum entropy. / channel_features[RedPixelChannel].sum_entropy[i]-= density_xy[x].direction[i].red MagickLog10(density_xy[x].direction[i].red); channel_features[GreenPixelChannel].sum_entropy[i]-= density_xy[x].direction[i].green* MagickLog10(density_xy[x].direction[i].green); channel_features[BluePixelChannel].sum_entropy[i]-= density_xy[x].direction[i].blue* MagickLog10(density_xy[x].direction[i].blue); if (image->colorspace == CMYKColorspace) channel_features[BlackPixelChannel].sum_entropy[i]-= density_xy[x].direction[i].black* MagickLog10(density_xy[x].direction[i].black); if (image->alpha_trait != UndefinedPixelTrait) channel_features[AlphaPixelChannel].sum_entropy[i]-= density_xy[x].direction[i].alpha* MagickLog10(density_xy[x].direction[i].alpha); /* Sum variance. / channel_features[RedPixelChannel].sum_variance[i]+= (x-channel_features[RedPixelChannel].sum_entropy[i]) (x-channel_features[RedPixelChannel].sum_entropy[i])* density_xy[x].direction[i].red; channel_features[GreenPixelChannel].sum_variance[i]+= (x-channel_features[GreenPixelChannel].sum_entropy[i])* (x-channel_features[GreenPixelChannel].sum_entropy[i])* density_xy[x].direction[i].green; channel_features[BluePixelChannel].sum_variance[i]+= (x-channel_features[BluePixelChannel].sum_entropy[i])* (x-channel_features[BluePixelChannel].sum_entropy[i])* density_xy[x].direction[i].blue; if (image->colorspace == CMYKColorspace) channel_features[BlackPixelChannel].sum_variance[i]+= (x-channel_features[BlackPixelChannel].sum_entropy[i])* (x-channel_features[BlackPixelChannel].sum_entropy[i])* density_xy[x].direction[i].black; if (image->alpha_trait != UndefinedPixelTrait) channel_features[AlphaPixelChannel].sum_variance[i]+= (x-channel_features[AlphaPixelChannel].sum_entropy[i])* (x-channel_features[AlphaPixelChannel].sum_entropy[i])* density_xy[x].direction[i].alpha; } } /* Compute more texture features. / #if defined(MAGICKCORE_OPENMP_SUPPORT) #pragma omp parallel for schedule(static) shared(status) \ magick_number_threads(image,image,number_grays,1) #endif for (i=0; i < 4; i++) { register ssize_t y; for (y=0; y < (ssize_t) number_grays; y++) { register ssize_t x; for (x=0; x < (ssize_t) number_grays; x++) { / Sum of Squares: Variance / variance.direction[i].red+=(y-mean.direction[i].red+1) (y-mean.direction[i].red+1)cooccurrence[x][y].direction[i].red; variance.direction[i].green+=(y-mean.direction[i].green+1) (y-mean.direction[i].green+1)cooccurrence[x][y].direction[i].green; variance.direction[i].blue+=(y-mean.direction[i].blue+1) (y-mean.direction[i].blue+1)cooccurrence[x][y].direction[i].blue; if (image->colorspace == CMYKColorspace) variance.direction[i].black+=(y-mean.direction[i].black+1) (y-mean.direction[i].black+1)cooccurrence[x][y].direction[i].black; if (image->alpha_trait != UndefinedPixelTrait) variance.direction[i].alpha+=(y-mean.direction[i].alpha+1) (y-mean.direction[i].alpha+1)* cooccurrence[x][y].direction[i].alpha; /* Sum average / Difference Variance. / density_xy[MagickAbsoluteValue(y-x)].direction[i].red+= cooccurrence[x][y].direction[i].red; density_xy[MagickAbsoluteValue(y-x)].direction[i].green+= cooccurrence[x][y].direction[i].green; density_xy[MagickAbsoluteValue(y-x)].direction[i].blue+= cooccurrence[x][y].direction[i].blue; if (image->colorspace == CMYKColorspace) density_xy[MagickAbsoluteValue(y-x)].direction[i].black+= cooccurrence[x][y].direction[i].black; if (image->alpha_trait != UndefinedPixelTrait) density_xy[MagickAbsoluteValue(y-x)].direction[i].alpha+= cooccurrence[x][y].direction[i].alpha; / Information Measures of Correlation. / entropy_xy.direction[i].red-=cooccurrence[x][y].direction[i].red MagickLog10(cooccurrence[x][y].direction[i].red); entropy_xy.direction[i].green-=cooccurrence[x][y].direction[i].green* MagickLog10(cooccurrence[x][y].direction[i].green); entropy_xy.direction[i].blue-=cooccurrence[x][y].direction[i].blue* MagickLog10(cooccurrence[x][y].direction[i].blue); if (image->colorspace == CMYKColorspace) entropy_xy.direction[i].black-=cooccurrence[x][y].direction[i].black* MagickLog10(cooccurrence[x][y].direction[i].black); if (image->alpha_trait != UndefinedPixelTrait) entropy_xy.direction[i].alpha-= cooccurrence[x][y].direction[i].alphaMagickLog10( cooccurrence[x][y].direction[i].alpha); entropy_xy1.direction[i].red-=(cooccurrence[x][y].direction[i].red MagickLog10(density_x[x].direction[i].reddensity_y[y].direction[i].red)); entropy_xy1.direction[i].green-=(cooccurrence[x][y].direction[i].green MagickLog10(density_x[x].direction[i].green* density_y[y].direction[i].green)); entropy_xy1.direction[i].blue-=(cooccurrence[x][y].direction[i].blue* MagickLog10(density_x[x].direction[i].bluedensity_y[y].direction[i].blue)); if (image->colorspace == CMYKColorspace) entropy_xy1.direction[i].black-=( cooccurrence[x][y].direction[i].blackMagickLog10( density_x[x].direction[i].blackdensity_y[y].direction[i].black)); if (image->alpha_trait != UndefinedPixelTrait) entropy_xy1.direction[i].alpha-=( cooccurrence[x][y].direction[i].alphaMagickLog10( density_x[x].direction[i].alphadensity_y[y].direction[i].alpha)); entropy_xy2.direction[i].red-=(density_x[x].direction[i].red density_y[y].direction[i].redMagickLog10(density_x[x].direction[i].red density_y[y].direction[i].red)); entropy_xy2.direction[i].green-=(density_x[x].direction[i].green* density_y[y].direction[i].greenMagickLog10(density_x[x].direction[i].green density_y[y].direction[i].green)); entropy_xy2.direction[i].blue-=(density_x[x].direction[i].blue* density_y[y].direction[i].blueMagickLog10(density_x[x].direction[i].blue density_y[y].direction[i].blue)); if (image->colorspace == CMYKColorspace) entropy_xy2.direction[i].black-=(density_x[x].direction[i].black* density_y[y].direction[i].blackMagickLog10( density_x[x].direction[i].blackdensity_y[y].direction[i].black)); if (image->alpha_trait != UndefinedPixelTrait) entropy_xy2.direction[i].alpha-=(density_x[x].direction[i].alpha* density_y[y].direction[i].alphaMagickLog10( density_x[x].direction[i].alphadensity_y[y].direction[i].alpha)); } } channel_features[RedPixelChannel].variance_sum_of_squares[i]= variance.direction[i].red; channel_features[GreenPixelChannel].variance_sum_of_squares[i]= variance.direction[i].green; channel_features[BluePixelChannel].variance_sum_of_squares[i]= variance.direction[i].blue; if (image->colorspace == CMYKColorspace) channel_features[BlackPixelChannel].variance_sum_of_squares[i]= variance.direction[i].black; if (image->alpha_trait != UndefinedPixelTrait) channel_features[AlphaPixelChannel].variance_sum_of_squares[i]= variance.direction[i].alpha; } /* Compute more texture features. / (void) memset(&variance,0,sizeof(variance)); (void) memset(&sum_squares,0,sizeof(sum_squares)); #if defined(MAGICKCORE_OPENMP_SUPPORT) #pragma omp parallel for schedule(static) shared(status) \ magick_number_threads(image,image,number_grays,1) #endif for (i=0; i < 4; i++) { register ssize_t x; for (x=0; x < (ssize_t) number_grays; x++) { / Difference variance. / variance.direction[i].red+=density_xy[x].direction[i].red; variance.direction[i].green+=density_xy[x].direction[i].green; variance.direction[i].blue+=density_xy[x].direction[i].blue; if (image->colorspace == CMYKColorspace) variance.direction[i].black+=density_xy[x].direction[i].black; if (image->alpha_trait != UndefinedPixelTrait) variance.direction[i].alpha+=density_xy[x].direction[i].alpha; sum_squares.direction[i].red+=density_xy[x].direction[i].red density_xy[x].direction[i].red; sum_squares.direction[i].green+=density_xy[x].direction[i].green* density_xy[x].direction[i].green; sum_squares.direction[i].blue+=density_xy[x].direction[i].blue* density_xy[x].direction[i].blue; if (image->colorspace == CMYKColorspace) sum_squares.direction[i].black+=density_xy[x].direction[i].black* density_xy[x].direction[i].black; if (image->alpha_trait != UndefinedPixelTrait) sum_squares.direction[i].alpha+=density_xy[x].direction[i].alpha* density_xy[x].direction[i].alpha; /* Difference entropy. / channel_features[RedPixelChannel].difference_entropy[i]-= density_xy[x].direction[i].red MagickLog10(density_xy[x].direction[i].red); channel_features[GreenPixelChannel].difference_entropy[i]-= density_xy[x].direction[i].green* MagickLog10(density_xy[x].direction[i].green); channel_features[BluePixelChannel].difference_entropy[i]-= density_xy[x].direction[i].blue* MagickLog10(density_xy[x].direction[i].blue); if (image->colorspace == CMYKColorspace) channel_features[BlackPixelChannel].difference_entropy[i]-= density_xy[x].direction[i].black* MagickLog10(density_xy[x].direction[i].black); if (image->alpha_trait != UndefinedPixelTrait) channel_features[AlphaPixelChannel].difference_entropy[i]-= density_xy[x].direction[i].alpha* MagickLog10(density_xy[x].direction[i].alpha); /* Information Measures of Correlation. / entropy_x.direction[i].red-=(density_x[x].direction[i].red MagickLog10(density_x[x].direction[i].red)); entropy_x.direction[i].green-=(density_x[x].direction[i].green* MagickLog10(density_x[x].direction[i].green)); entropy_x.direction[i].blue-=(density_x[x].direction[i].blue* MagickLog10(density_x[x].direction[i].blue)); if (image->colorspace == CMYKColorspace) entropy_x.direction[i].black-=(density_x[x].direction[i].black* MagickLog10(density_x[x].direction[i].black)); if (image->alpha_trait != UndefinedPixelTrait) entropy_x.direction[i].alpha-=(density_x[x].direction[i].alpha* MagickLog10(density_x[x].direction[i].alpha)); entropy_y.direction[i].red-=(density_y[x].direction[i].red* MagickLog10(density_y[x].direction[i].red)); entropy_y.direction[i].green-=(density_y[x].direction[i].green* MagickLog10(density_y[x].direction[i].green)); entropy_y.direction[i].blue-=(density_y[x].direction[i].blue* MagickLog10(density_y[x].direction[i].blue)); if (image->colorspace == CMYKColorspace) entropy_y.direction[i].black-=(density_y[x].direction[i].black* MagickLog10(density_y[x].direction[i].black)); if (image->alpha_trait != UndefinedPixelTrait) entropy_y.direction[i].alpha-=(density_y[x].direction[i].alpha* MagickLog10(density_y[x].direction[i].alpha)); } /* Difference variance. / channel_features[RedPixelChannel].difference_variance[i]= (((double) number_graysnumber_grayssum_squares.direction[i].red)- (variance.direction[i].redvariance.direction[i].red))/ ((double) number_graysnumber_graysnumber_graysnumber_grays); channel_features[GreenPixelChannel].difference_variance[i]= (((double) number_graysnumber_grayssum_squares.direction[i].green)- (variance.direction[i].greenvariance.direction[i].green))/ ((double) number_graysnumber_graysnumber_graysnumber_grays); channel_features[BluePixelChannel].difference_variance[i]= (((double) number_graysnumber_grayssum_squares.direction[i].blue)- (variance.direction[i].bluevariance.direction[i].blue))/ ((double) number_graysnumber_graysnumber_graysnumber_grays); if (image->colorspace == CMYKColorspace) channel_features[BlackPixelChannel].difference_variance[i]= (((double) number_graysnumber_grayssum_squares.direction[i].black)- (variance.direction[i].blackvariance.direction[i].black))/ ((double) number_graysnumber_graysnumber_graysnumber_grays); if (image->alpha_trait != UndefinedPixelTrait) channel_features[AlphaPixelChannel].difference_variance[i]= (((double) number_graysnumber_grayssum_squares.direction[i].alpha)- (variance.direction[i].alphavariance.direction[i].alpha))/ ((double) number_graysnumber_graysnumber_graysnumber_grays); / Information Measures of Correlation. / channel_features[RedPixelChannel].measure_of_correlation_1[i]= (entropy_xy.direction[i].red-entropy_xy1.direction[i].red)/ (entropy_x.direction[i].red > entropy_y.direction[i].red ? entropy_x.direction[i].red : entropy_y.direction[i].red); channel_features[GreenPixelChannel].measure_of_correlation_1[i]= (entropy_xy.direction[i].green-entropy_xy1.direction[i].green)/ (entropy_x.direction[i].green > entropy_y.direction[i].green ? entropy_x.direction[i].green : entropy_y.direction[i].green); channel_features[BluePixelChannel].measure_of_correlation_1[i]= (entropy_xy.direction[i].blue-entropy_xy1.direction[i].blue)/ (entropy_x.direction[i].blue > entropy_y.direction[i].blue ? entropy_x.direction[i].blue : entropy_y.direction[i].blue); if (image->colorspace == CMYKColorspace) channel_features[BlackPixelChannel].measure_of_correlation_1[i]= (entropy_xy.direction[i].black-entropy_xy1.direction[i].black)/ (entropy_x.direction[i].black > entropy_y.direction[i].black ? entropy_x.direction[i].black : entropy_y.direction[i].black); if (image->alpha_trait != UndefinedPixelTrait) channel_features[AlphaPixelChannel].measure_of_correlation_1[i]= (entropy_xy.direction[i].alpha-entropy_xy1.direction[i].alpha)/ (entropy_x.direction[i].alpha > entropy_y.direction[i].alpha ? entropy_x.direction[i].alpha : entropy_y.direction[i].alpha); channel_features[RedPixelChannel].measure_of_correlation_2[i]= (sqrt(fabs(1.0-exp(-2.0(double) (entropy_xy2.direction[i].red- entropy_xy.direction[i].red))))); channel_features[GreenPixelChannel].measure_of_correlation_2[i]= (sqrt(fabs(1.0-exp(-2.0(double) (entropy_xy2.direction[i].green- entropy_xy.direction[i].green))))); channel_features[BluePixelChannel].measure_of_correlation_2[i]= (sqrt(fabs(1.0-exp(-2.0(double) (entropy_xy2.direction[i].blue- entropy_xy.direction[i].blue))))); if (image->colorspace == CMYKColorspace) channel_features[BlackPixelChannel].measure_of_correlation_2[i]= (sqrt(fabs(1.0-exp(-2.0(double) (entropy_xy2.direction[i].black- entropy_xy.direction[i].black))))); if (image->alpha_trait != UndefinedPixelTrait) channel_features[AlphaPixelChannel].measure_of_correlation_2[i]= (sqrt(fabs(1.0-exp(-2.0(double) (entropy_xy2.direction[i].alpha- entropy_xy.direction[i].alpha))))); } /* Compute more texture features. / #if defined(MAGICKCORE_OPENMP_SUPPORT) #pragma omp parallel for schedule(static) shared(status) \ magick_number_threads(image,image,number_grays,1) #endif for (i=0; i < 4; i++) { ssize_t z; for (z=0; z < (ssize_t) number_grays; z++) { register ssize_t y; ChannelStatistics pixel; (void) memset(&pixel,0,sizeof(pixel)); for (y=0; y < (ssize_t) number_grays; y++) { register ssize_t x; for (x=0; x < (ssize_t) number_grays; x++) { / Contrast: amount of local variations present in an image. / if (((y-x) == z) \|\| ((x-y) == z)) { pixel.direction[i].red+=cooccurrence[x][y].direction[i].red; pixel.direction[i].green+=cooccurrence[x][y].direction[i].green; pixel.direction[i].blue+=cooccurrence[x][y].direction[i].blue; if (image->colorspace == CMYKColorspace) pixel.direction[i].black+=cooccurrence[x][y].direction[i].black; if (image->alpha_trait != UndefinedPixelTrait) pixel.direction[i].alpha+= cooccurrence[x][y].direction[i].alpha; } / Maximum Correlation Coefficient. / if ((fabs(density_x[z].direction[i].red) > MagickEpsilon) && (fabs(density_y[x].direction[i].red) > MagickEpsilon)) Q[z][y].direction[i].red+=cooccurrence[z][x].direction[i].red cooccurrence[y][x].direction[i].red/density_x[z].direction[i].red/ density_y[x].direction[i].red; if ((fabs(density_x[z].direction[i].green) > MagickEpsilon) && (fabs(density_y[x].direction[i].red) > MagickEpsilon)) Q[z][y].direction[i].green+=cooccurrence[z][x].direction[i].green* cooccurrence[y][x].direction[i].green/ density_x[z].direction[i].green/density_y[x].direction[i].red; if ((fabs(density_x[z].direction[i].blue) > MagickEpsilon) && (fabs(density_y[x].direction[i].blue) > MagickEpsilon)) Q[z][y].direction[i].blue+=cooccurrence[z][x].direction[i].blue* cooccurrence[y][x].direction[i].blue/ density_x[z].direction[i].blue/density_y[x].direction[i].blue; if (image->colorspace == CMYKColorspace) if ((fabs(density_x[z].direction[i].black) > MagickEpsilon) && (fabs(density_y[x].direction[i].black) > MagickEpsilon)) Q[z][y].direction[i].black+=cooccurrence[z][x].direction[i].black* cooccurrence[y][x].direction[i].black/ density_x[z].direction[i].black/density_y[x].direction[i].black; if (image->alpha_trait != UndefinedPixelTrait) if ((fabs(density_x[z].direction[i].alpha) > MagickEpsilon) && (fabs(density_y[x].direction[i].alpha) > MagickEpsilon)) Q[z][y].direction[i].alpha+= cooccurrence[z][x].direction[i].alpha* cooccurrence[y][x].direction[i].alpha/ density_x[z].direction[i].alpha/ density_y[x].direction[i].alpha; } } channel_features[RedPixelChannel].contrast[i]+=zz pixel.direction[i].red; channel_features[GreenPixelChannel].contrast[i]+=zz pixel.direction[i].green; channel_features[BluePixelChannel].contrast[i]+=zz pixel.direction[i].blue; if (image->colorspace == CMYKColorspace) channel_features[BlackPixelChannel].contrast[i]+=zz pixel.direction[i].black; if (image->alpha_trait != UndefinedPixelTrait) channel_features[AlphaPixelChannel].contrast[i]+=zz pixel.direction[i].alpha; } /* Maximum Correlation Coefficient. Future: return second largest eigenvalue of Q. / channel_features[RedPixelChannel].maximum_correlation_coefficient[i]= sqrt((double) -1.0); channel_features[GreenPixelChannel].maximum_correlation_coefficient[i]= sqrt((double) -1.0); channel_features[BluePixelChannel].maximum_correlation_coefficient[i]= sqrt((double) -1.0); if (image->colorspace == CMYKColorspace) channel_features[BlackPixelChannel].maximum_correlation_coefficient[i]= sqrt((double) -1.0); if (image->alpha_trait != UndefinedPixelTrait) channel_features[AlphaPixelChannel].maximum_correlation_coefficient[i]= sqrt((double) -1.0); } / Relinquish resources. / sum=(ChannelStatistics ) RelinquishMagickMemory(sum); for (i=0; i < (ssize_t) number_grays; i++) Q[i]=(ChannelStatistics ) RelinquishMagickMemory(Q[i]); Q=(ChannelStatistics ) RelinquishMagickMemory(Q); density_y=(ChannelStatistics ) RelinquishMagickMemory(density_y); density_xy=(ChannelStatistics ) RelinquishMagickMemory(density_xy); density_x=(ChannelStatistics ) RelinquishMagickMemory(density_x); for (i=0; i < (ssize_t) number_grays; i++) cooccurrence[i]=(ChannelStatistics ) RelinquishMagickMemory(cooccurrence[i]); cooccurrence=(ChannelStatistics ) RelinquishMagickMemory(cooccurrence); return(channel_features); } / %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % H o u g h L i n e I m a g e % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % Use HoughLineImage() in conjunction with any binary edge extracted image (we % recommand Canny) to identify lines in the image. The algorithm accumulates % counts for every white pixel for every possible orientation (for angles from % 0 to 179 in 1 degree increments) and distance from the center of the image to % the corner (in 1 px increments) and stores the counts in an accumulator % matrix of angle vs distance. The size of the accumulator is 180x(diagonal/2). % Next it searches this space for peaks in counts and converts the locations % of the peaks to slope and intercept in the normal x,y input image space. Use % the slope/intercepts to find the endpoints clipped to the bounds of the % image. The lines are then drawn. The counts are a measure of the length of % the lines. % % The format of the HoughLineImage method is: % % Image HoughLineImage(const Image image,const size_t width, % const size_t height,const size_t threshold,ExceptionInfo exception) % % A description of each parameter follows: % % o image: the image. % % o width, height: find line pairs as local maxima in this neighborhood. % % o threshold: the line count threshold. % % o exception: return any errors or warnings in this structure. % / static inline double MagickRound(double x) { /* Round the fraction to nearest integer. / if ((x-floor(x)) < (ceil(x)-x)) return(floor(x)); return(ceil(x)); } static Image RenderHoughLines(const ImageInfo image_info,const size_t columns, const size_t rows,ExceptionInfo exception) { #define BoundingBox "viewbox" DrawInfo draw_info; Image image; MagickBooleanType status; /* Open image. / image=AcquireImage(image_info,exception); status=OpenBlob(image_info,image,ReadBinaryBlobMode,exception); if (status == MagickFalse) { image=DestroyImageList(image); return((Image ) NULL); } image->columns=columns; image->rows=rows; draw_info=CloneDrawInfo(image_info,(DrawInfo ) NULL); draw_info->affine.sx=image->resolution.x == 0.0 ? 1.0 : image->resolution.x/ DefaultResolution; draw_info->affine.sy=image->resolution.y == 0.0 ? 1.0 : image->resolution.y/ DefaultResolution; image->columns=(size_t) (draw_info->affine.sximage->columns); image->rows=(size_t) (draw_info->affine.syimage->rows); status=SetImageExtent(image,image->columns,image->rows,exception); if (status == MagickFalse) return(DestroyImageList(image)); if (SetImageBackgroundColor(image,exception) == MagickFalse) { image=DestroyImageList(image); return((Image ) NULL); } /* Render drawing. / if (GetBlobStreamData(image) == (unsigned char ) NULL) draw_info->primitive=FileToString(image->filename,~0UL,exception); else { draw_info->primitive=(char ) AcquireQuantumMemory(1,(size_t) GetBlobSize(image)+1); if (draw_info->primitive != (char ) NULL) { (void) memcpy(draw_info->primitive,GetBlobStreamData(image), (size_t) GetBlobSize(image)); draw_info->primitive[GetBlobSize(image)]='\0'; } } (void) DrawImage(image,draw_info,exception); draw_info=DestroyDrawInfo(draw_info); (void) CloseBlob(image); return(GetFirstImageInList(image)); } MagickExport Image HoughLineImage(const Image image,const size_t width, const size_t height,const size_t threshold,ExceptionInfo exception) { #define HoughLineImageTag "HoughLine/Image" CacheView image_view; char message[MagickPathExtent], path[MagickPathExtent]; const char artifact; double hough_height; Image lines_image = NULL; ImageInfo image_info; int file; MagickBooleanType status; MagickOffsetType progress; MatrixInfo accumulator; PointInfo center; register ssize_t y; size_t accumulator_height, accumulator_width, line_count; /* Create the accumulator. / assert(image != (const Image ) NULL); assert(image->signature == MagickCoreSignature); if (image->debug != MagickFalse) (void) LogMagickEvent(TraceEvent,GetMagickModule(),"%s",image->filename); assert(exception != (ExceptionInfo ) NULL); assert(exception->signature == MagickCoreSignature); accumulator_width=180; hough_height=((sqrt(2.0)(double) (image->rows > image->columns ? image->rows : image->columns))/2.0); accumulator_height=(size_t) (2.0hough_height); accumulator=AcquireMatrixInfo(accumulator_width,accumulator_height, sizeof(double),exception); if (accumulator == (MatrixInfo ) NULL) ThrowImageException(ResourceLimitError,"MemoryAllocationFailed"); if (NullMatrix(accumulator) == MagickFalse) { accumulator=DestroyMatrixInfo(accumulator); ThrowImageException(ResourceLimitError,"MemoryAllocationFailed"); } /* Populate the accumulator. / status=MagickTrue; progress=0; center.x=(double) image->columns/2.0; center.y=(double) image->rows/2.0; image_view=AcquireVirtualCacheView(image,exception); for (y=0; y < (ssize_t) image->rows; y++) { register const Quantum magick_restrict p; register ssize_t x; if (status == MagickFalse) continue; p=GetCacheViewVirtualPixels(image_view,0,y,image->columns,1,exception); if (p == (Quantum ) NULL) { status=MagickFalse; continue; } for (x=0; x < (ssize_t) image->columns; x++) { if (GetPixelIntensity(image,p) > (QuantumRange/2.0)) { register ssize_t i; for (i=0; i < 180; i++) { double count, radius; radius=(((double) x-center.x)cos(DegreesToRadians((double) i)))+ (((double) y-center.y)sin(DegreesToRadians((double) i))); (void) GetMatrixElement(accumulator,i,(ssize_t) MagickRound(radius+hough_height),&count); count++; (void) SetMatrixElement(accumulator,i,(ssize_t) MagickRound(radius+hough_height),&count); } } p+=GetPixelChannels(image); } if (image->progress_monitor != (MagickProgressMonitor) NULL) { MagickBooleanType proceed; #if defined(MAGICKCORE_OPENMP_SUPPORT) #pragma omp atomic #endif progress++; proceed=SetImageProgress(image,CannyEdgeImageTag,progress,image->rows); if (proceed == MagickFalse) status=MagickFalse; } } image_view=DestroyCacheView(image_view); if (status == MagickFalse) { accumulator=DestroyMatrixInfo(accumulator); return((Image ) NULL); } /* Generate line segments from accumulator. / file=AcquireUniqueFileResource(path); if (file == -1) { accumulator=DestroyMatrixInfo(accumulator); return((Image ) NULL); } (void) FormatLocaleString(message,MagickPathExtent, "# Hough line transform: %.20gx%.20g%+.20g\n",(double) width, (double) height,(double) threshold); if (write(file,message,strlen(message)) != (ssize_t) strlen(message)) status=MagickFalse; (void) FormatLocaleString(message,MagickPathExtent, "viewbox 0 0 %.20g %.20g\n",(double) image->columns,(double) image->rows); if (write(file,message,strlen(message)) != (ssize_t) strlen(message)) status=MagickFalse; (void) FormatLocaleString(message,MagickPathExtent, "# x1,y1 x2,y2 # count angle distance\n"); if (write(file,message,strlen(message)) != (ssize_t) strlen(message)) status=MagickFalse; line_count=image->columns > image->rows ? image->columns/4 : image->rows/4; if (threshold != 0) line_count=threshold; for (y=0; y < (ssize_t) accumulator_height; y++) { register ssize_t x; for (x=0; x < (ssize_t) accumulator_width; x++) { double count; (void) GetMatrixElement(accumulator,x,y,&count); if (count >= (double) line_count) { double maxima; SegmentInfo line; ssize_t v; /* Is point a local maxima? / maxima=count; for (v=(-((ssize_t) height/2)); v <= (((ssize_t) height/2)); v++) { ssize_t u; for (u=(-((ssize_t) width/2)); u <= (((ssize_t) width/2)); u++) { if ((u != 0) \|\| (v !=0)) { (void) GetMatrixElement(accumulator,x+u,y+v,&count); if (count > maxima) { maxima=count; break; } } } if (u < (ssize_t) (width/2)) break; } (void) GetMatrixElement(accumulator,x,y,&count); if (maxima > count) continue; if ((x >= 45) && (x <= 135)) { / y = (r-x cos(t))/sin(t) / line.x1=0.0; line.y1=((double) (y-(accumulator_height/2.0))-((line.x1- (image->columns/2.0))cos(DegreesToRadians((double) x))))/ sin(DegreesToRadians((double) x))+(image->rows/2.0); line.x2=(double) image->columns; line.y2=((double) (y-(accumulator_height/2.0))-((line.x2- (image->columns/2.0))cos(DegreesToRadians((double) x))))/ sin(DegreesToRadians((double) x))+(image->rows/2.0); } else { / x = (r-y cos(t))/sin(t) / line.y1=0.0; line.x1=((double) (y-(accumulator_height/2.0))-((line.y1- (image->rows/2.0))sin(DegreesToRadians((double) x))))/ cos(DegreesToRadians((double) x))+(image->columns/2.0); line.y2=(double) image->rows; line.x2=((double) (y-(accumulator_height/2.0))-((line.y2- (image->rows/2.0))sin(DegreesToRadians((double) x))))/ cos(DegreesToRadians((double) x))+(image->columns/2.0); } (void) FormatLocaleString(message,MagickPathExtent, "line %g,%g %g,%g # %g %g %g\n",line.x1,line.y1,line.x2,line.y2, maxima,(double) x,(double) y); if (write(file,message,strlen(message)) != (ssize_t) strlen(message)) status=MagickFalse; } } } (void) close(file); / Render lines to image canvas. / image_info=AcquireImageInfo(); image_info->background_color=image->background_color; (void) FormatLocaleString(image_info->filename,MagickPathExtent,"%s",path); artifact=GetImageArtifact(image,"background"); if (artifact != (const char ) NULL) (void) SetImageOption(image_info,"background",artifact); artifact=GetImageArtifact(image,"fill"); if (artifact != (const char ) NULL) (void) SetImageOption(image_info,"fill",artifact); artifact=GetImageArtifact(image,"stroke"); if (artifact != (const char ) NULL) (void) SetImageOption(image_info,"stroke",artifact); artifact=GetImageArtifact(image,"strokewidth"); if (artifact != (const char ) NULL) (void) SetImageOption(image_info,"strokewidth",artifact); lines_image=RenderHoughLines(image_info,image->columns,image->rows,exception); artifact=GetImageArtifact(image,"hough-lines:accumulator"); if ((lines_image != (Image ) NULL) && (IsStringTrue(artifact) != MagickFalse)) { Image accumulator_image; accumulator_image=MatrixToImage(accumulator,exception); if (accumulator_image != (Image ) NULL) AppendImageToList(&lines_image,accumulator_image); } /* Free resources. / accumulator=DestroyMatrixInfo(accumulator); image_info=DestroyImageInfo(image_info); (void) RelinquishUniqueFileResource(path); return(GetFirstImageInList(lines_image)); } / %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % M e a n S h i f t I m a g e % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % MeanShiftImage() delineate arbitrarily shaped clusters in the image. For % each pixel, it visits all the pixels in the neighborhood specified by % the window centered at the pixel and excludes those that are outside the % radius=(window-1)/2 surrounding the pixel. From those pixels, it finds those % that are within the specified color distance from the current mean, and % computes a new x,y centroid from those coordinates and a new mean. This new % x,y centroid is used as the center for a new window. This process iterates % until it converges and the final mean is replaces the (original window % center) pixel value. It repeats this process for the next pixel, etc., % until it processes all pixels in the image. Results are typically better with % colorspaces other than sRGB. We recommend YIQ, YUV or YCbCr. % % The format of the MeanShiftImage method is: % % Image MeanShiftImage(const Image image,const size_t width, % const size_t height,const double color_distance, % ExceptionInfo exception) % % A description of each parameter follows: % % o image: the image. % % o width, height: find pixels in this neighborhood. % % o color_distance: the color distance. % % o exception: return any errors or warnings in this structure. % / MagickExport Image MeanShiftImage(const Image image,const size_t width, const size_t height,const double color_distance,ExceptionInfo exception) { #define MaxMeanShiftIterations 100 #define MeanShiftImageTag "MeanShift/Image" CacheView image_view, mean_view, pixel_view; Image mean_image; MagickBooleanType status; MagickOffsetType progress; ssize_t y; assert(image != (const Image ) NULL); assert(image->signature == MagickCoreSignature); if (image->debug != MagickFalse) (void) LogMagickEvent(TraceEvent,GetMagickModule(),"%s",image->filename); assert(exception != (ExceptionInfo ) NULL); assert(exception->signature == MagickCoreSignature); mean_image=CloneImage(image,0,0,MagickTrue,exception); if (mean_image == (Image ) NULL) return((Image ) NULL); if (SetImageStorageClass(mean_image,DirectClass,exception) == MagickFalse) { mean_image=DestroyImage(mean_image); return((Image ) NULL); } status=MagickTrue; progress=0; image_view=AcquireVirtualCacheView(image,exception); pixel_view=AcquireVirtualCacheView(image,exception); mean_view=AcquireAuthenticCacheView(mean_image,exception); #if defined(MAGICKCORE_OPENMP_SUPPORT) #pragma omp parallel for schedule(static) shared(status,progress) \ magick_number_threads(mean_image,mean_image,mean_image->rows,1) #endif for (y=0; y < (ssize_t) mean_image->rows; y++) { register const Quantum magick_restrict p; register Quantum magick_restrict q; register ssize_t x; if (status == MagickFalse) continue; p=GetCacheViewVirtualPixels(image_view,0,y,image->columns,1,exception); q=GetCacheViewAuthenticPixels(mean_view,0,y,mean_image->columns,1, exception); if ((p == (const Quantum ) NULL) \|\| (q == (Quantum ) NULL)) { status=MagickFalse; continue; } for (x=0; x < (ssize_t) mean_image->columns; x++) { PixelInfo mean_pixel, previous_pixel; PointInfo mean_location, previous_location; register ssize_t i; GetPixelInfo(image,&mean_pixel); GetPixelInfoPixel(image,p,&mean_pixel); mean_location.x=(double) x; mean_location.y=(double) y; for (i=0; i < MaxMeanShiftIterations; i++) { double distance, gamma; PixelInfo sum_pixel; PointInfo sum_location; ssize_t count, v; sum_location.x=0.0; sum_location.y=0.0; GetPixelInfo(image,&sum_pixel); previous_location=mean_location; previous_pixel=mean_pixel; count=0; for (v=(-((ssize_t) height/2)); v <= (((ssize_t) height/2)); v++) { ssize_t u; for (u=(-((ssize_t) width/2)); u <= (((ssize_t) width/2)); u++) { if ((vv+uu) <= (ssize_t) ((width/2)(height/2))) { PixelInfo pixel; status=GetOneCacheViewVirtualPixelInfo(pixel_view,(ssize_t) MagickRound(mean_location.x+u),(ssize_t) MagickRound( mean_location.y+v),&pixel,exception); distance=(mean_pixel.red-pixel.red)(mean_pixel.red-pixel.red)+ (mean_pixel.green-pixel.green)(mean_pixel.green-pixel.green)+ (mean_pixel.blue-pixel.blue)(mean_pixel.blue-pixel.blue); if (distance <= (color_distancecolor_distance)) { sum_location.x+=mean_location.x+u; sum_location.y+=mean_location.y+v; sum_pixel.red+=pixel.red; sum_pixel.green+=pixel.green; sum_pixel.blue+=pixel.blue; sum_pixel.alpha+=pixel.alpha; count++; } } } } gamma=PerceptibleReciprocal(count); mean_location.x=gammasum_location.x; mean_location.y=gammasum_location.y; mean_pixel.red=gammasum_pixel.red; mean_pixel.green=gammasum_pixel.green; mean_pixel.blue=gammasum_pixel.blue; mean_pixel.alpha=gammasum_pixel.alpha; distance=(mean_location.x-previous_location.x) (mean_location.x-previous_location.x)+ (mean_location.y-previous_location.y)* (mean_location.y-previous_location.y)+ 255.0QuantumScale(mean_pixel.red-previous_pixel.red)* 255.0QuantumScale(mean_pixel.red-previous_pixel.red)+ 255.0QuantumScale(mean_pixel.green-previous_pixel.green)* 255.0QuantumScale(mean_pixel.green-previous_pixel.green)+ 255.0QuantumScale(mean_pixel.blue-previous_pixel.blue)* 255.0QuantumScale(mean_pixel.blue-previous_pixel.blue); if (distance <= 3.0) break; } SetPixelRed(mean_image,ClampToQuantum(mean_pixel.red),q); SetPixelGreen(mean_image,ClampToQuantum(mean_pixel.green),q); SetPixelBlue(mean_image,ClampToQuantum(mean_pixel.blue),q); SetPixelAlpha(mean_image,ClampToQuantum(mean_pixel.alpha),q); p+=GetPixelChannels(image); q+=GetPixelChannels(mean_image); } if (SyncCacheViewAuthenticPixels(mean_view,exception) == MagickFalse) status=MagickFalse; if (image->progress_monitor != (MagickProgressMonitor) NULL) { MagickBooleanType proceed; #if defined(MAGICKCORE_OPENMP_SUPPORT) #pragma omp atomic #endif progress++; proceed=SetImageProgress(image,MeanShiftImageTag,progress,image->rows); if (proceed == MagickFalse) status=MagickFalse; } } mean_view=DestroyCacheView(mean_view); pixel_view=DestroyCacheView(pixel_view); image_view=DestroyCacheView(image_view); return(mean_image); }
moleintor.c	/* Copyright 2014-2018 The PySCF Developers. All Rights Reserved. Licensed under the Apache License, Version 2.0 (the "License"); you may not use this file except in compliance with the License. You may obtain a copy of the License at http://www.apache.org/licenses/LICENSE-2.0 Unless required by applicable law or agreed to in writing, software distributed under the License is distributed on an "AS IS" BASIS, WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. See the License for the specific language governing permissions and limitations under the License. * * Author: Qiming Sun <osirpt.sun@gmail.com> / #include <stdlib.h> #include <complex.h> //#include <omp.h> #include "config.h" #include "cint.h" #define PLAIN 0 #define HERMITIAN 1 #define ANTIHERMI 2 #define NCTRMAX 64 static void cart_or_sph(int (intor)(), int (num_cgto)(), double mat, int ncomp, int hermi, int bralst, int nbra, int ketlst, int nket, int atm, int natm, int bas, int nbas, double env) { int ish; int ilocs[nbra+1]; int naoi = 0; int naoj = 0; for (ish = 0; ish < nbra; ish++) { ilocs[ish] = naoi; naoi += (num_cgto)(bralst[ish], bas); } ilocs[nbra] = naoi; for (ish = 0; ish < nket; ish++) { naoj += (num_cgto)(ketlst[ish], bas); } #pragma omp parallel default(none) \ shared(intor, num_cgto, mat, ncomp, hermi, bralst, nbra, ketlst, nket,\ atm, natm, bas, nbas, env, naoi, naoj, ilocs) \ private(ish) { int jsh, jsh1, i, j, i0, j0, icomp; int di, dj, iloc, jloc; int shls[2]; double buf = malloc(sizeof(double)NCTRMAXNCTRMAXncomp); double pmat, pbuf; #pragma omp for nowait schedule(dynamic) for (ish = 0; ish < nbra; ish++) { iloc = ilocs[ish]; di = ilocs[ish+1] - iloc; if (hermi == PLAIN) { jsh1 = nket; } else { jsh1 = ish + 1; } for (jloc = 0, jsh = 0; jsh < jsh1; jsh++, jloc+=dj) { dj = (num_cgto)(ketlst[jsh], bas); shls[0] = bralst[ish]; shls[1] = ketlst[jsh]; (intor)(buf, shls, atm, natm, bas, nbas, env); for (icomp = 0; icomp < ncomp; icomp++) { pmat = mat + icompnaoinaoj; pbuf = buf + icompdidj; for (i0=iloc, i=0; i < di; i++, i0++) { for (j0=jloc, j=0; j < dj; j++, j0++) { pmat[i0naoj+j0] = pbuf[jdi+i]; } } } } } free(buf); } } void GTO1eintor_sph(int (intor)(), double mat, int ncomp, int hermi, int bralst, int nbra, int ketlst, int nket, int atm, int natm, int bas, int nbas, double env) { cart_or_sph(intor, CINTcgto_spheric, mat, ncomp, hermi, bralst, nbra, ketlst, nket, atm, natm, bas, nbas, env); } void GTO1eintor_cart(int (intor)(), double mat, int ncomp, int hermi, int bralst, int nbra, int ketlst, int nket, int atm, int natm, int bas, int nbas, double env) { cart_or_sph(intor, CINTcgto_cart, mat, ncomp, hermi, bralst, nbra, ketlst, nket, atm, natm, bas, nbas, env); } void GTO1eintor_spinor(int (intor)(), double complex mat, int ncomp, int hermi, int bralst, int nbra, int ketlst, int nket, int atm, int natm, int bas, int nbas, double env) { int ish; int ilocs[nbra+1]; int naoi = 0; int naoj = 0; for (ish = 0; ish < nbra; ish++) { ilocs[ish] = naoi; naoi += CINTcgto_spinor(bralst[ish], bas); } ilocs[nbra] = naoi; for (ish = 0; ish < nket; ish++) { naoj += CINTcgto_spinor(ketlst[ish], bas); } #pragma omp parallel default(none) \ shared(intor, mat, ncomp, hermi, bralst, nbra, ketlst, nket,\ atm, natm, bas, nbas, env, naoi, naoj, ilocs) \ private(ish) { int jsh, jsh1, i, j, i0, j0, icomp; int di, dj, iloc, jloc; int shls[2]; double complex buf = malloc(sizeof(double complex)NCTRMAXNCTRMAX4ncomp); double complex pmat, pbuf; #pragma omp for nowait schedule(dynamic) for (ish = 0; ish < nbra; ish++) { iloc = ilocs[ish]; di = CINTcgto_spinor(bralst[ish], bas); if (hermi == PLAIN) { jsh1 = nket; } else { jsh1 = ish + 1; } for (jloc = 0, jsh = 0; jsh < jsh1; jsh++, jloc+=dj) { dj = CINTcgto_spinor(ketlst[jsh], bas); shls[0] = bralst[ish]; shls[1] = ketlst[jsh]; (intor)(buf, shls, atm, natm, bas, nbas, env); for (icomp = 0; icomp < ncomp; icomp++) { pmat = mat + icompnaoinaoj; pbuf = buf + icompdidj; for (i0=iloc, i=0; i < di; i++, i0++) { for (j0=jloc, j=0; j < dj; j++, j0++) { pmat[i0naoj+j0] = pbuf[jdi+i]; } } } } } free(buf); } } void GTO1e_intor_drv(int (intor)(), double mat, size_t ijoff, int basrange, int naoi, int naoj, int iloc, int jloc, int ncomp, int hermi, CINTOpt cintopt, int atm, int natm, int bas, int nbas, double env) { #pragma omp parallel default(none) \ shared(intor, mat, ijoff, basrange, naoi, naoj, iloc, jloc, \ ncomp, hermi, cintopt, atm, natm, bas, nbas, env) { int ish, jsh, i, j, i0, j0, icomp; int brastart = basrange[0]; int bracount = basrange[1]; int ketstart = basrange[2]; int ketcount = basrange[3]; int di, dj; int shls[2]; double buf = malloc(sizeof(double)NCTRMAXNCTRMAXncomp); double pmat, pbuf; #pragma omp for nowait schedule(dynamic) for (ish = 0; ish < bracount; ish++) { di = iloc[ish+1] - iloc[ish]; for (jsh = 0; jsh < ketcount; jsh++) { if (hermi != PLAIN && iloc[ish] < jloc[jsh]) { continue; } dj = jloc[jsh+1] - jloc[jsh]; shls[0] = brastart + ish; shls[1] = ketstart + jsh; (intor)(buf, shls, atm, natm, bas, nbas, env); for (icomp = 0; icomp < ncomp; icomp++) { pmat = mat + icompnaoinaoj + ijoff; pbuf = buf + icompdidj; for (i0=iloc[ish], i=0; i < di; i++, i0++) { for (j0=jloc[jsh], j=0; j < dj; j++, j0++) { pmat[i0naoj+j0] = pbuf[jdi+i]; } } } } } free(buf); } } void GTO1e_spinor_drv(int (intor)(), double complex mat, size_t ijoff, int basrange, int naoi, int naoj, int iloc, int jloc, int ncomp, int hermi, CINTOpt cintopt, int atm, int natm, int bas, int nbas, double env) { #pragma omp parallel default(none) \ shared(intor, mat, ijoff, basrange, naoi, naoj, iloc, jloc, \ ncomp, hermi, cintopt, atm, natm, bas, nbas, env) { int ish, jsh, i, j, i0, j0, icomp; int brastart = basrange[0]; int bracount = basrange[1]; int ketstart = basrange[2]; int ketcount = basrange[3]; int di, dj; int shls[2]; double complex buf = malloc(sizeof(double)NCTRMAXNCTRMAXncomp); double complex pmat, pbuf; #pragma omp for nowait schedule(dynamic) for (ish = 0; ish < bracount; ish++) { di = iloc[ish+1] - iloc[ish]; for (jsh = 0; jsh < ketcount; jsh++) { if (hermi != PLAIN && iloc[ish] < jloc[jsh]) { continue; } dj = jloc[jsh+1] - jloc[jsh]; shls[0] = brastart + ish; shls[1] = ketstart + jsh; (intor)(buf, shls, atm, natm, bas, nbas, env); for (icomp = 0; icomp < ncomp; icomp++) { pmat = mat + icompnaoinaoj + ijoff; pbuf = buf + icompdidj; for (i0=iloc[ish], i=0; i < di; i++, i0++) { for (j0=jloc[jsh], j=0; j < dj; j++, j0++) { pmat[i0naoj+j0] = pbuf[jdi+i]; } } } } } free(buf); } }
3045.c	/* POLYBENCH/GPU-OPENMP * * This file is a part of the Polybench/GPU-OpenMP suite * * Contact: * William Killian <killian@udel.edu> * * Copyright 2013, The University of Delaware / #include <stdio.h> #include <unistd.h> #include <string.h> #include <math.h> / Include polybench common header. / #include <polybench.h> / Include benchmark-specific header. / / Default data type is double, default size is 4000. / #include "3mm.h" / Array initialization. / static void init_array(int ni, int nj, int nk, int nl, int nm, DATA_TYPE POLYBENCH_2D(A,NI,NK,ni,nk), DATA_TYPE POLYBENCH_2D(B,NK,NJ,nk,nj), DATA_TYPE POLYBENCH_2D(C,NJ,NM,nj,nm), DATA_TYPE POLYBENCH_2D(D,NM,NL,nm,nl)) { int i, j; for (i = 0; i < ni; i++) for (j = 0; j < nk; j++) A[i][j] = ((DATA_TYPE) ij) / ni; for (i = 0; i < nk; i++) for (j = 0; j < nj; j++) B[i][j] = ((DATA_TYPE) i(j+1)) / nj; for (i = 0; i < nj; i++) for (j = 0; j < nm; j++) C[i][j] = ((DATA_TYPE) i(j+3)) / nl; for (i = 0; i < nm; i++) for (j = 0; j < nl; j++) D[i][j] = ((DATA_TYPE) i(j+2)) / nk; } / DCE code. Must scan the entire live-out data. Can be used also to check the correctness of the output. / static void print_array(int ni, int nl, DATA_TYPE POLYBENCH_2D(G,NI,NL,ni,nl)) { int i, j; for (i = 0; i < ni; i++) for (j = 0; j < nl; j++) { fprintf (stderr, DATA_PRINTF_MODIFIER, G[i][j]); if ((i ni + j) % 20 == 0) fprintf (stderr, "\n"); } fprintf (stderr, "\n"); } /* Main computational kernel. The whole function will be timed, including the call and return. / static void kernel_3mm(int ni, int nj, int nk, int nl, int nm, DATA_TYPE POLYBENCH_2D(E,NI,NJ,ni,nj), DATA_TYPE POLYBENCH_2D(A,NI,NK,ni,nk), DATA_TYPE POLYBENCH_2D(B,NK,NJ,nk,nj), DATA_TYPE POLYBENCH_2D(F,NJ,NL,nj,nl), DATA_TYPE POLYBENCH_2D(C,NJ,NM,nj,nm), DATA_TYPE POLYBENCH_2D(D,NM,NL,nm,nl), DATA_TYPE POLYBENCH_2D(G,NI,NL,ni,nl)) { int i, j, k; #pragma scop #pragma omp parallel private (j, k) num_threads(1) { / E := AB / #pragma omp for schedule(static, 1) for (i = 0; i < _PB_NI; i++) for (j = 0; j < _PB_NJ; j++) { E[i][j] = 0; for (k = 0; k < _PB_NK; ++k) E[i][j] += A[i][k] * B[k][j]; } /* F := CD / #pragma omp for schedule(static, 1) for (i = 0; i < _PB_NJ; i++) for (j = 0; j < _PB_NL; j++) { F[i][j] = 0; for (k = 0; k < _PB_NM; ++k) F[i][j] += C[i][k] * D[k][j]; } /* G := EF / #pragma omp for schedule(static, 1) for (i = 0; i < _PB_NI; i++) for (j = 0; j < _PB_NL; j++) { G[i][j] = 0; for (k = 0; k < _PB_NJ; ++k) G[i][j] += E[i][k] * F[k][j]; } } #pragma endscop } int main(int argc, char** argv) { /* Retrieve problem size. / int ni = NI; int nj = NJ; int nk = NK; int nl = NL; int nm = NM; / Variable declaration/allocation. / POLYBENCH_2D_ARRAY_DECL(E, DATA_TYPE, NI, NJ, ni, nj); POLYBENCH_2D_ARRAY_DECL(A, DATA_TYPE, NI, NK, ni, nk); POLYBENCH_2D_ARRAY_DECL(B, DATA_TYPE, NK, NJ, nk, nj); POLYBENCH_2D_ARRAY_DECL(F, DATA_TYPE, NJ, NL, nj, nl); POLYBENCH_2D_ARRAY_DECL(C, DATA_TYPE, NJ, NM, nj, nm); POLYBENCH_2D_ARRAY_DECL(D, DATA_TYPE, NM, NL, nm, nl); POLYBENCH_2D_ARRAY_DECL(G, DATA_TYPE, NI, NL, ni, nl); / Initialize array(s). / init_array (ni, nj, nk, nl, nm, POLYBENCH_ARRAY(A), POLYBENCH_ARRAY(B), POLYBENCH_ARRAY(C), POLYBENCH_ARRAY(D)); / Start timer. / polybench_start_instruments; / Run kernel. / kernel_3mm (ni, nj, nk, nl, nm, POLYBENCH_ARRAY(E), POLYBENCH_ARRAY(A), POLYBENCH_ARRAY(B), POLYBENCH_ARRAY(F), POLYBENCH_ARRAY(C), POLYBENCH_ARRAY(D), POLYBENCH_ARRAY(G)); / Stop and print timer. / polybench_stop_instruments; polybench_print_instruments; / Prevent dead-code elimination. All live-out data must be printed by the function call in argument. / polybench_prevent_dce(print_array(ni, nl, POLYBENCH_ARRAY(G))); / Be clean. */ POLYBENCH_FREE_ARRAY(E); POLYBENCH_FREE_ARRAY(A); POLYBENCH_FREE_ARRAY(B); POLYBENCH_FREE_ARRAY(F); POLYBENCH_FREE_ARRAY(C); POLYBENCH_FREE_ARRAY(D); POLYBENCH_FREE_ARRAY(G); return 0; }
threaded_eigen_matrix.h	/* * Copyright (c) 2017 Ivan Iakoupov * * Permission is hereby granted, free of charge, to any person obtaining a * copy of this software and associated documentation files (the "Software"), * to deal in the Software without restriction, including without limitation * the rights to use, copy, modify, merge, publish, distribute, sublicense, * and/or sell copies of the Software, and to permit persons to whom the * Software is furnished to do so, subject to the following conditions: * * The above copyright notice and this permission notice shall be included * in all copies or substantial portions of the Software. * * THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR * IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, * FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL * THE AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER * LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING * FROM, OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER * DEALINGS IN THE SOFTWARE. / #ifndef THREADED_EIGEN_MATRIX_H #define THREADED_EIGEN_MATRIX_H #include <omp.h> #include <vector> #include "Eigen/Dense" class ThreadedEigenMatrix { int m_rows; int m_cols; int m_threads; std::vector<Eigen::MatrixXcd> m_matrix_chunks; std::vector<int> m_block_start_indices; public: ThreadedEigenMatrix() : m_threads(omp_get_max_threads()), m_rows(0), m_cols(0) {} explicit ThreadedEigenMatrix(std::function<std::complex<double>(int,int)> f, int rows, int cols) : m_threads(omp_get_max_threads()), m_rows(rows), m_cols(cols) { m_matrix_chunks.resize(m_threads); const int normal_chunk_size = m_rows/m_threads; std::vector<int> chunk_sizes(m_threads); for (int n = 0; n < m_threads; ++n) { chunk_sizes[n] = normal_chunk_size; } // The last chunk size can be different const int last_chunk_size = m_rows - (m_threads-1)normal_chunk_size; chunk_sizes[m_threads-1] = last_chunk_size; #pragma omp parallel for for (int n = 0; n < m_threads; ++n) { const int chunk_size = chunk_sizes[n]; m_matrix_chunks[n] = Eigen::MatrixXcd::Zero(chunk_size, m_cols); for (int i = 0; i < chunk_size; ++i) { for (int j = 0; j < m_cols; ++j) { m_matrix_chunks[n](i,j) = f(i + nnormal_chunk_size, j); } } } m_block_start_indices.resize(m_threads); int rowsSum = 0; for (int j = 0; j < m_threads; ++j) { m_block_start_indices[j] = rowsSum; rowsSum += m_matrix_chunks[j].rows(); } } explicit ThreadedEigenMatrix(Eigen::MatrixXcd M) : m_threads(omp_get_max_threads()), m_rows(M.rows()), m_cols(M.cols()) { m_matrix_chunks.resize(m_threads); const int normal_chunk_size = m_rows/m_threads; std::vector<int> chunk_sizes(m_threads); for (int n = 0; n < m_threads; ++n) { chunk_sizes[n] = normal_chunk_size; } // The last chunk size can be different const int last_chunk_size = m_rows - (m_threads-1)normal_chunk_size; chunk_sizes[m_threads-1] = last_chunk_size; #pragma omp parallel for for (int n = 0; n < m_threads; ++n) { const int chunk_size = chunk_sizes[n]; m_matrix_chunks[n] = Eigen::MatrixXcd::Zero(chunk_size, m_cols); for (int i = 0; i < chunk_size; ++i) { for (int j = 0; j < m_cols; ++j) { m_matrix_chunks[n](i,j) = M(i + nnormal_chunk_size, j); } } } m_block_start_indices.resize(m_threads); int rowsSum = 0; for (int j = 0; j < m_threads; ++j) { m_block_start_indices[j] = rowsSum; rowsSum += m_matrix_chunks[j].rows(); } } Eigen::VectorXcd operator(const Eigen::VectorXcd &v) const { Eigen::VectorXcd ret(m_rows); #pragma omp parallel for for (int j = 0; j < m_threads; ++j) { const int block_start = m_block_start_indices[j]; const int block_end = block_start + m_matrix_chunks[j].rows(); Eigen::VectorXcd ret_i = m_matrix_chunks[j]*v; for (int k = block_start; k < block_end; ++k) { ret(k) = ret_i(k-block_start); } } return ret; } }; #endif // THREADED_EIGEN_MATRIX_H
omp_lock.c	<ompts:test> <ompts:testdescription>Test which checks the omp_set_lock and the omp_unset_lock function by counting the threads entering and exiting a single region with locks.</ompts:testdescription> <ompts:ompversion>2.0</ompts:ompversion> <ompts:directive>omp_lock</ompts:directive> <ompts:dependences>omp flush</ompts:dependences> <ompts:testcode> #include <stdio.h> #include "omp_testsuite.h" omp_lock_t lck; int <ompts:testcode:functionname>omp_lock</ompts:testcode:functionname>(FILE * logFile) { int nr_threads_in_single = 0; int result = 0; int nr_iterations = 0; int i; omp_init_lock (&lck); #pragma omp parallel shared(lck) { #pragma omp for for(i = 0; i < LOOPCOUNT; i++) { <ompts:orphan> <ompts:check>omp_set_lock (&lck);</ompts:check> </ompts:orphan> #pragma omp flush nr_threads_in_single++; #pragma omp flush nr_iterations++; nr_threads_in_single--; result = result + nr_threads_in_single; <ompts:orphan> <ompts:check>omp_unset_lock(&lck);</ompts:check> </ompts:orphan> } } omp_destroy_lock (&lck); return ((result == 0) && (nr_iterations == LOOPCOUNT)); } </ompts:testcode> </ompts:test>
dataset.h	/! Copyright (c) 2016 Microsoft Corporation. All rights reserved. * Licensed under the MIT License. See LICENSE file in the project root for license information. / #ifndef LIGHTGBM_DATASET_H_ #define LIGHTGBM_DATASET_H_ #include <LightGBM/config.h> #include <LightGBM/feature_group.h> #include <LightGBM/meta.h> #include <LightGBM/utils/common.h> #include <LightGBM/utils/openmp_wrapper.h> #include <LightGBM/utils/random.h> #include <LightGBM/utils/text_reader.h> #include <string> #include <functional> #include <memory> #include <mutex> #include <unordered_set> #include <utility> #include <vector> namespace LightGBM { /! \brief forward declaration / class DatasetLoader; /! * \brief This class is used to store some meta(non-feature) data for training data, * e.g. labels, weights, initial scores, query level informations. * * Some details: * 1. Label, used for training. * 2. Weights, weighs of records, optional * 3. Query Boundaries, necessary for lambdarank. * The documents of i-th query is in [ query_boundaries[i], query_boundaries[i+1] ) * 4. Query Weights, auto calculate by weights and query_boundaries(if both of them are existed) * the weight for i-th query is sum(query_boundaries[i] , .., query_boundaries[i+1]) / (query_boundaries[i + 1] - query_boundaries[i+1]) * 5. Initial score. optional. if existing, the model will boost from this score, otherwise will start from 0. / class Metadata { public: /! * \brief Null constructor / Metadata(); /! * \brief Initialization will load query level informations, since it is need for sampling data * \param data_filename Filename of data * \param init_score_filename Filename of initial score / void Init(const char data_filename, const char* initscore_file); /! \brief init as subset * \param metadata Filename of data * \param used_indices * \param num_used_indices / void Init(const Metadata& metadata, const data_size_t used_indices, data_size_t num_used_indices); /! \brief Initial with binary memory * \param memory Pointer to memory / void LoadFromMemory(const void memory); /! \brief Destructor / ~Metadata(); /! \brief Initial work, will allocate space for label, weight(if exists) and query(if exists) * \param num_data Number of training data * \param weight_idx Index of weight column, < 0 means doesn't exists * \param query_idx Index of query id column, < 0 means doesn't exists / void Init(data_size_t num_data, int weight_idx, int query_idx); /! * \brief Partition label by used indices * \param used_indices Indices of local used / void PartitionLabel(const std::vector<data_size_t>& used_indices); /! * \brief Partition meta data according to local used indices if need * \param num_all_data Number of total training data, including other machines' data on parallel learning * \param used_data_indices Indices of local used training data / void CheckOrPartition(data_size_t num_all_data, const std::vector<data_size_t>& used_data_indices); void SetLabel(const label_t label, data_size_t len); void SetWeights(const label_t* weights, data_size_t len); void SetQuery(const data_size_t* query, data_size_t len); /! \brief Set initial scores * \param init_score Initial scores, this class will manage memory for init_score. / void SetInitScore(const double init_score, data_size_t len); /! \brief Save binary data to file * \param file File want to write / void SaveBinaryToFile(const VirtualFileWriter writer) const; /! \brief Get sizes in byte of this object / size_t SizesInByte() const; /! * \brief Get pointer of label * \return Pointer of label / inline const label_t label() const { return label_.data(); } /! \brief Set label for one record * \param idx Index of this record * \param value Label value of this record / inline void SetLabelAt(data_size_t idx, label_t value) { label_[idx] = value; } /! * \brief Set Weight for one record * \param idx Index of this record * \param value Weight value of this record / inline void SetWeightAt(data_size_t idx, label_t value) { weights_[idx] = value; } /! * \brief Set Query Id for one record * \param idx Index of this record * \param value Query Id value of this record / inline void SetQueryAt(data_size_t idx, data_size_t value) { queries_[idx] = static_cast<data_size_t>(value); } /! * \brief Get weights, if not exists, will return nullptr * \return Pointer of weights / inline const label_t weights() const { if (!weights_.empty()) { return weights_.data(); } else { return nullptr; } } /! \brief Get data boundaries on queries, if not exists, will return nullptr * we assume data will order by query, * the interval of [query_boundaris[i], query_boundaris[i+1]) * is the data indices for query i. * \return Pointer of data boundaries on queries / inline const data_size_t query_boundaries() const { if (!query_boundaries_.empty()) { return query_boundaries_.data(); } else { return nullptr; } } /! \brief Get Number of queries * \return Number of queries / inline data_size_t num_queries() const { return num_queries_; } /! * \brief Get weights for queries, if not exists, will return nullptr * \return Pointer of weights for queries / inline const label_t query_weights() const { if (!query_weights_.empty()) { return query_weights_.data(); } else { return nullptr; } } /! \brief Get initial scores, if not exists, will return nullptr * \return Pointer of initial scores / inline const double init_score() const { if (!init_score_.empty()) { return init_score_.data(); } else { return nullptr; } } /! \brief Get size of initial scores / inline int64_t num_init_score() const { return num_init_score_; } /! \brief Disable copy / Metadata& operator=(const Metadata&) = delete; /! \brief Disable copy / Metadata(const Metadata&) = delete; private: /! \brief Load initial scores from file / void LoadInitialScore(const char initscore_file); /! \brief Load wights from file / void LoadWeights(); /! \brief Load query boundaries from file / void LoadQueryBoundaries(); /! \brief Load query wights / void LoadQueryWeights(); /! \brief Filename of current data / std::string data_filename_; /! \brief Number of data / data_size_t num_data_; /! \brief Number of weights, used to check correct weight file / data_size_t num_weights_; /! \brief Label data / std::vector<label_t> label_; /! \brief Weights data / std::vector<label_t> weights_; /! \brief Query boundaries / std::vector<data_size_t> query_boundaries_; /! \brief Query weights / std::vector<label_t> query_weights_; /! \brief Number of querys / data_size_t num_queries_; /! \brief Number of Initial score, used to check correct weight file / int64_t num_init_score_; /! \brief Initial score / std::vector<double> init_score_; /! \brief Queries data / std::vector<data_size_t> queries_; /! \brief mutex for threading safe call / std::mutex mutex_; bool weight_load_from_file_; bool query_load_from_file_; bool init_score_load_from_file_; }; /! \brief Interface for Parser / class Parser { public: /! \brief virtual destructor / virtual ~Parser() {} /! \brief Parse one line with label * \param str One line record, string format, should end with '\0' * \param out_features Output columns, store in (column_idx, values) * \param out_label Label will store to this if exists / virtual void ParseOneLine(const char str, std::vector<std::pair<int, double>>* out_features, double* out_label) const = 0; virtual int NumFeatures() const = 0; /! \brief Create an object of parser, will auto choose the format depend on file * \param filename One Filename of data * \param num_features Pass num_features of this data file if you know, <=0 means don't know * \param label_idx index of label column * \return Object of parser / static Parser CreateParser(const char* filename, bool header, int num_features, int label_idx); }; /! \brief The main class of data set, which are used to training or validation / class Dataset { public: friend DatasetLoader; LIGHTGBM_EXPORT Dataset(); LIGHTGBM_EXPORT Dataset(data_size_t num_data); void Construct( std::vector<std::unique_ptr<BinMapper>> bin_mappers, int num_total_features, const std::vector<std::vector<double>>& forced_bins, int** sample_non_zero_indices, const int* num_per_col, size_t total_sample_cnt, const Config& io_config); /! \brief Destructor / LIGHTGBM_EXPORT ~Dataset(); LIGHTGBM_EXPORT bool CheckAlign(const Dataset& other) const { if (num_features_ != other.num_features_) { return false; } if (num_total_features_ != other.num_total_features_) { return false; } if (label_idx_ != other.label_idx_) { return false; } for (int i = 0; i < num_features_; ++i) { if (!FeatureBinMapper(i)->CheckAlign((other.FeatureBinMapper(i)))) { return false; } } return true; } inline void PushOneRow(int tid, data_size_t row_idx, const std::vector<double>& feature_values) { if (is_finish_load_) { return; } for (size_t i = 0; i < feature_values.size() && i < static_cast<size_t>(num_total_features_); ++i) { int feature_idx = used_feature_map_[i]; if (feature_idx >= 0) { const int group = feature2group_[feature_idx]; const int sub_feature = feature2subfeature_[feature_idx]; feature_groups_[group]->PushData(tid, sub_feature, row_idx, feature_values[i]); } } } inline void PushOneRow(int tid, data_size_t row_idx, const std::vector<std::pair<int, double>>& feature_values) { if (is_finish_load_) { return; } for (auto& inner_data : feature_values) { if (inner_data.first >= num_total_features_) { continue; } int feature_idx = used_feature_map_[inner_data.first]; if (feature_idx >= 0) { const int group = feature2group_[feature_idx]; const int sub_feature = feature2subfeature_[feature_idx]; feature_groups_[group]->PushData(tid, sub_feature, row_idx, inner_data.second); } } } inline void PushOneData(int tid, data_size_t row_idx, int group, int sub_feature, double value) { feature_groups_[group]->PushData(tid, sub_feature, row_idx, value); } inline int RealFeatureIndex(int fidx) const { return real_feature_idx_[fidx]; } inline int InnerFeatureIndex(int col_idx) const { return used_feature_map_[col_idx]; } inline int Feature2Group(int feature_idx) const { return feature2group_[feature_idx]; } inline int Feture2SubFeature(int feature_idx) const { return feature2subfeature_[feature_idx]; } inline uint64_t GroupBinBoundary(int group_idx) const { return group_bin_boundaries_[group_idx]; } inline uint64_t NumTotalBin() const { return group_bin_boundaries_.back(); } inline std::vector<int> ValidFeatureIndices() const { std::vector<int> ret; for (int i = 0; i < num_total_features_; ++i) { if (used_feature_map_[i] >= 0) { ret.push_back(i); } } return ret; } void ReSize(data_size_t num_data); void CopySubset(const Dataset fullset, const data_size_t* used_indices, data_size_t num_used_indices, bool need_meta_data); LIGHTGBM_EXPORT void FinishLoad(); LIGHTGBM_EXPORT bool SetFloatField(const char* field_name, const float* field_data, data_size_t num_element); LIGHTGBM_EXPORT bool SetDoubleField(const char* field_name, const double* field_data, data_size_t num_element); LIGHTGBM_EXPORT bool SetIntField(const char* field_name, const int* field_data, data_size_t num_element); LIGHTGBM_EXPORT bool GetFloatField(const char* field_name, data_size_t* out_len, const float** out_ptr); LIGHTGBM_EXPORT bool GetDoubleField(const char* field_name, data_size_t* out_len, const double** out_ptr); LIGHTGBM_EXPORT bool GetIntField(const char* field_name, data_size_t* out_len, const int** out_ptr); LIGHTGBM_EXPORT bool GetInt8Field(const char* field_name, data_size_t* out_len, const int8_t** out_ptr); /! \brief Save current dataset into binary file, will save to "filename.bin" / LIGHTGBM_EXPORT void SaveBinaryFile(const char bin_filename); LIGHTGBM_EXPORT void DumpTextFile(const char* text_filename); LIGHTGBM_EXPORT void CopyFeatureMapperFrom(const Dataset* dataset); LIGHTGBM_EXPORT void CreateValid(const Dataset* dataset); void ConstructHistograms(const std::vector<int8_t>& is_feature_used, const data_size_t* data_indices, data_size_t num_data, int leaf_idx, std::vector<std::unique_ptr<OrderedBin>>* ordered_bins, const score_t* gradients, const score_t* hessians, score_t* ordered_gradients, score_t* ordered_hessians, bool is_constant_hessian, HistogramBinEntry* histogram_data) const; void FixHistogram(int feature_idx, double sum_gradient, double sum_hessian, data_size_t num_data, HistogramBinEntry* data) const; inline data_size_t Split(int feature, const uint32_t* threshold, int num_threshold, bool default_left, data_size_t* data_indices, data_size_t num_data, data_size_t* lte_indices, data_size_t* gt_indices) const { const int group = feature2group_[feature]; const int sub_feature = feature2subfeature_[feature]; return feature_groups_[group]->Split(sub_feature, threshold, num_threshold, default_left, data_indices, num_data, lte_indices, gt_indices); } inline int SubFeatureBinOffset(int i) const { const int sub_feature = feature2subfeature_[i]; if (sub_feature == 0) { return 1; } else { return 0; } } inline int FeatureNumBin(int i) const { const int group = feature2group_[i]; const int sub_feature = feature2subfeature_[i]; return feature_groups_[group]->bin_mappers_[sub_feature]->num_bin(); } inline int8_t FeatureMonotone(int i) const { if (monotone_types_.empty()) { return 0; } else { return monotone_types_[i]; } } inline double FeaturePenalte(int i) const { if (feature_penalty_.empty()) { return 1; } else { return feature_penalty_[i]; } } bool HasMonotone() const { if (monotone_types_.empty()) { return false; } else { for (size_t i = 0; i < monotone_types_.size(); ++i) { if (monotone_types_[i] != 0) { return true; } } return false; } } inline int FeatureGroupNumBin(int group) const { return feature_groups_[group]->num_total_bin_; } inline const BinMapper* FeatureBinMapper(int i) const { const int group = feature2group_[i]; const int sub_feature = feature2subfeature_[i]; return feature_groups_[group]->bin_mappers_[sub_feature].get(); } inline const Bin* FeatureBin(int i) const { const int group = feature2group_[i]; return feature_groups_[group]->bin_data_.get(); } inline const Bin* FeatureGroupBin(int group) const { return feature_groups_[group]->bin_data_.get(); } inline bool FeatureGroupIsSparse(int group) const { return feature_groups_[group]->is_sparse_; } inline BinIterator* FeatureIterator(int i) const { const int group = feature2group_[i]; const int sub_feature = feature2subfeature_[i]; return feature_groups_[group]->SubFeatureIterator(sub_feature); } inline BinIterator* FeatureGroupIterator(int group) const { return feature_groups_[group]->FeatureGroupIterator(); } inline double RealThreshold(int i, uint32_t threshold) const { const int group = feature2group_[i]; const int sub_feature = feature2subfeature_[i]; return feature_groups_[group]->bin_mappers_[sub_feature]->BinToValue(threshold); } // given a real threshold, find the closest threshold bin inline uint32_t BinThreshold(int i, double threshold_double) const { const int group = feature2group_[i]; const int sub_feature = feature2subfeature_[i]; return feature_groups_[group]->bin_mappers_[sub_feature]->ValueToBin(threshold_double); } inline void CreateOrderedBins(std::vector<std::unique_ptr<OrderedBin>>* ordered_bins) const { ordered_bins->resize(num_groups_); OMP_INIT_EX(); #pragma omp parallel for schedule(guided) for (int i = 0; i < num_groups_; ++i) { OMP_LOOP_EX_BEGIN(); ordered_bins->at(i).reset(feature_groups_[i]->bin_data_->CreateOrderedBin()); OMP_LOOP_EX_END(); } OMP_THROW_EX(); } /! \brief Get meta data pointer * \return Pointer of meta data / inline const Metadata& metadata() const { return metadata_; } /! \brief Get Number of used features / inline int num_features() const { return num_features_; } /! \brief Get Number of feature groups / inline int num_feature_groups() const { return num_groups_;} /! \brief Get Number of total features / inline int num_total_features() const { return num_total_features_; } /! \brief Get the index of label column / inline int label_idx() const { return label_idx_; } /! \brief Get names of current data set / inline const std::vector<std::string>& feature_names() const { return feature_names_; } inline void set_feature_names(const std::vector<std::string>& feature_names) { if (feature_names.size() != static_cast<size_t>(num_total_features_)) { Log::Fatal("Size of feature_names error, should equal with total number of features"); } feature_names_ = std::vector<std::string>(feature_names); // replace ' ' in feature_names with '_' bool spaceInFeatureName = false; for (auto& feature_name : feature_names_) { // check ascii if (!Common::CheckASCII(feature_name)) { Log::Fatal("Do not support non-ascii characters in feature name."); } if (feature_name.find(' ') != std::string::npos) { spaceInFeatureName = true; std::replace(feature_name.begin(), feature_name.end(), ' ', '_'); } } if (spaceInFeatureName) { Log::Warning("Find whitespaces in feature_names, replace with underlines"); } } inline std::vector<std::string> feature_infos() const { std::vector<std::string> bufs; for (int i = 0; i < num_total_features_; i++) { int fidx = used_feature_map_[i]; if (fidx == -1) { bufs.push_back("none"); } else { const auto bin_mapper = FeatureBinMapper(fidx); bufs.push_back(bin_mapper->bin_info()); } } return bufs; } void ResetConfig(const char parameters); /! \brief Get Number of data / inline data_size_t num_data() const { return num_data_; } /! \brief Disable copy / Dataset& operator=(const Dataset&) = delete; /! \brief Disable copy / Dataset(const Dataset&) = delete; void addFeaturesFrom(Dataset* other); private: std::string data_filename_; /! \brief Store used features / std::vector<std::unique_ptr<FeatureGroup>> feature_groups_; /! \brief Mapper from real feature index to used index/ std::vector<int> used_feature_map_; /! \brief Number of used features/ int num_features_; /! \brief Number of total features/ int num_total_features_; /! \brief Number of total data/ data_size_t num_data_; /! \brief Store some label level data/ Metadata metadata_; /! \brief index of label column / int label_idx_ = 0; /! \brief Threshold for treating a feature as a sparse feature / double sparse_threshold_; /! \brief store feature names / std::vector<std::string> feature_names_; /! \brief store feature names / static const char* binary_file_token; int num_groups_; std::vector<int> real_feature_idx_; std::vector<int> feature2group_; std::vector<int> feature2subfeature_; std::vector<uint64_t> group_bin_boundaries_; std::vector<int> group_feature_start_; std::vector<int> group_feature_cnt_; std::vector<int8_t> monotone_types_; std::vector<double> feature_penalty_; bool is_finish_load_; int max_bin_; std::vector<int32_t> max_bin_by_feature_; std::vector<std::vector<double>> forced_bin_bounds_; int bin_construct_sample_cnt_; int min_data_in_bin_; bool use_missing_; bool zero_as_missing_; }; } // namespace LightGBM #endif // LightGBM_DATA_H_
dSchCompUdt-2Ddynamic.c	/! \file Copyright (c) 2003, The Regents of the University of California, through Lawrence Berkeley National Laboratory (subject to receipt of any required approvals from U.S. Dept. of Energy) All rights reserved. The source code is distributed under BSD license, see the file License.txt at the top-level directory. / /! @file \brief This file contains the main loop of pdgstrf which involves rank k * update of the Schur complement. * Uses 2D partitioning for the scatter phase. * * <pre> * -- Distributed SuperLU routine (version 5.4) -- * Lawrence Berkeley National Lab, Univ. of California Berkeley. * October 1, 2014 * * Modified: * September 14, 2017 * - First gather U-panel, then depending on "ldu" (excluding leading zeros), * gather only trailing columns of the L-panel corresponding to the nonzero * of U-rows. * - Padding zeros for nice dimensions of GEMM. * * June 1, 2018 add parallel AWPM pivoting; add back arrive_at_ublock() / #define SCHEDULE_STRATEGY guided / * Buffers: * [ lookAhead_L_buff \| Remain_L_buff ] : stores the gathered L-panel * (A matrix in C := AB ) bigU : stores the U-panel (B matrix in C := AB) bigV : stores the block GEMM result (C matrix in C := AB) / if ( msg0 && msg2 ) { /* L(:,k) and U(k,:) are not empty. / int cum_nrow = 0; / cumulative number of nonzero rows in L(:,k) / int temp_nbrow; / nonzero rows in current block L(i,k) / lptr = lptr0; luptr = luptr0; int Lnbrow, Rnbrow; / number of nonzero rows in look-ahead window, and remaining part. / /****************************************************************** * Separating L blocks into the top part within look-ahead window * and the remaining ones. ******************************************************************/ int lookAheadBlk=0, RemainBlk=0; tt_start = SuperLU_timer_(); / Sherry -- can this loop be threaded?? / / Loop through all blocks in L(:,k) to set up pointers to the start * of each block in the data arrays. * - lookAheadFullRow[i] := number of nonzero rows from block 0 to i * - lookAheadStRow[i] := number of nonzero rows before block i * - lookAhead_lptr[i] := point to the start of block i in L's index[] * - (ditto Remain_Info[i]) / for (int i = 0; i < nlb; ++i) { ib = lsub[lptr]; / Block number of L(i,k). / temp_nbrow = lsub[lptr+1]; / Number of full rows. / int look_up_flag = 1; / assume ib is outside look-up window / for (int j = k0+1; j < SUPERLU_MIN (k0 + num_look_aheads+2, nsupers ); ++j) { if ( ib == perm_c_supno[j] ) { look_up_flag = 0; / flag ib within look-up window / break; / Sherry -- can exit the loop?? / } } if ( look_up_flag == 0 ) { / ib is within look-up window / if (lookAheadBlk==0) { lookAheadFullRow[lookAheadBlk] = temp_nbrow; } else { lookAheadFullRow[lookAheadBlk] = temp_nbrow + lookAheadFullRow[lookAheadBlk-1]; } lookAheadStRow[lookAheadBlk] = cum_nrow; lookAhead_lptr[lookAheadBlk] = lptr; lookAhead_ib[lookAheadBlk] = ib; lookAheadBlk++; } else { / ib is not in look-up window / if ( RemainBlk==0 ) { Remain_info[RemainBlk].FullRow = temp_nbrow; } else { Remain_info[RemainBlk].FullRow = temp_nbrow + Remain_info[RemainBlk-1].FullRow; } RemainStRow[RemainBlk] = cum_nrow; // Remain_lptr[RemainBlk] = lptr; Remain_info[RemainBlk].lptr = lptr; // Remain_ib[RemainBlk] = ib; Remain_info[RemainBlk].ib = ib; RemainBlk++; } cum_nrow += temp_nbrow; lptr += LB_DESCRIPTOR; / Skip descriptor. / lptr += temp_nbrow; / Move to next block / luptr += temp_nbrow; } / for i ... set up pointers for all blocks in L(:,k) / lptr = lptr0; luptr = luptr0; / leading dimension of L look-ahead buffer, same as Lnbrow / //int LDlookAhead_LBuff = lookAheadBlk==0 ? 0 :lookAheadFullRow[lookAheadBlk-1]; Lnbrow = lookAheadBlk==0 ? 0 : lookAheadFullRow[lookAheadBlk-1]; / leading dimension of L remaining buffer, same as Rnbrow / //int LDRemain_LBuff = RemainBlk==0 ? 0 : Remain_info[RemainBlk-1].FullRow; Rnbrow = RemainBlk==0 ? 0 : Remain_info[RemainBlk-1].FullRow; / assert( cum_nrow == (LDlookAhead_LBuff + LDRemain_LBuff) );/ / Piyush fix / //int LDlookAhead_LBuff = lookAheadBlk==0? 0 : lookAheadFullRow[lookAheadBlk-1]; nbrow = Lnbrow + Rnbrow; / total number of rows in L / LookAheadRowSepMOP += 2knsupc(nbrow); /********************************************** * Gather U blocks (AFTER LOOK-AHEAD WINDOW) * **********************************************/ tt_start = SuperLU_timer_(); if ( nbrow > 0 ) { / L(:,k) is not empty / / * Counting U blocks / ldu = 0; / Calculate ldu for U(k,:) after look-ahead window. / ncols = 0; / Total number of nonzero columns in U(k,:) / int temp_ncols = 0; / jj0 contains the look-ahead window that was updated in dlook_ahead_update.c. Now the search can continue from that point, not to start from block 0. / #if 0 // Sherry comment out 5/21/208 / Save pointers at location right after look-ahead window for later restart. / iukp0 = iukp; rukp0 = rukp; #endif / if ( iam==0 ) printf("--- k0 %d, k %d, jj0 %d, nub %d\n", k0, k, jj0, nub);/ / * Loop through all blocks in U(k,:) to set up pointers to the start * of each block in the data arrays, store them in Ublock_info[j] * for block U(k,j). / for (j = jj0; j < nub; ++j) { / jj0 starts after look-ahead window. / temp_ncols = 0; #if 1 / Cannot remove following call, since perm_u != Identity / arrive_at_ublock( j, &iukp, &rukp, &jb, &ljb, &nsupc, iukp0, rukp0, usub, perm_u, xsup, grid ); #else jb = usub[iukp]; / ljb = LBj (jb, grid); Local block number of U(k,j). / nsupc = SuperSize(jb); iukp += UB_DESCRIPTOR; / Start fstnz of block U(k,j). / #endif Ublock_info[j].iukp = iukp; Ublock_info[j].rukp = rukp; Ublock_info[j].jb = jb; / if ( iam==0 ) printf("j %d: Ublock_info[j].iukp %d, Ublock_info[j].rukp %d," "Ublock_info[j].jb %d, nsupc %d\n", j, Ublock_info[j].iukp, Ublock_info[j].rukp, Ublock_info[j].jb, nsupc); / / Prepare to call GEMM. / jj = iukp; for (; jj < iukp+nsupc; ++jj) { segsize = klst - usub[jj]; if ( segsize ) { ++temp_ncols; if ( segsize > ldu ) ldu = segsize; } } Ublock_info[j].full_u_cols = temp_ncols; ncols += temp_ncols; #if 0 // Sherry comment out 5/31/2018 / /* Jump number of nonzeros in block U(k,jj); Move to block U(k,j+1) in nzval[] array. / rukp += usub[iukp - 1]; iukp += nsupc; #endif } / end for j ... compute ldu & ncols / / Now doing prefix sum on full_u_cols. * After this, full_u_cols is the number of nonzero columns * from block 0 to block j. / for ( j = jj0+1; j < nub; ++j) { Ublock_info[j].full_u_cols += Ublock_info[j-1].full_u_cols; } / Padding zeros to make {m,n,k} multiple of vector length. / jj = 8; //n; if (gemm_padding > 0 && Rnbrow > jj && ncols > jj && ldu > jj) { gemm_m_pad = Rnbrow + (Rnbrow % GEMM_PADLEN); gemm_n_pad = ncols + (ncols % GEMM_PADLEN); //gemm_n_pad = ncols; //gemm_k_pad = ldu + (ldu % GEMM_PADLEN); gemm_k_pad = ldu; for (i = Rnbrow; i < gemm_m_pad; ++i) // padding A matrix for (j = 0; j < gemm_k_pad; ++j) Remain_L_buff[i + jgemm_m_pad] = zero; for (i = 0; i < Rnbrow; ++i) for (j = ldu; j < gemm_k_pad; ++j) Remain_L_buff[i + jgemm_m_pad] = zero; for (i = ldu; i < gemm_k_pad; ++i) // padding B matrix for (j = 0; j < gemm_n_pad; ++j) bigU[i + jgemm_k_pad] = zero; for (i = 0; i < ldu; ++i) for (j = ncols; j < gemm_n_pad; ++j) bigU[i + jgemm_k_pad] = zero; } else { gemm_m_pad = Rnbrow; gemm_n_pad = ncols; gemm_k_pad = ldu; } tempu = bigU; / buffer the entire row block U(k,:) / / Gather U(k,:) into buffer bigU[] to prepare for GEMM / #ifdef _OPENMP #pragma omp parallel for firstprivate(iukp, rukp) \ private(j,tempu, jb, nsupc,ljb,segsize, lead_zero, jj, i) \ default (shared) schedule(SCHEDULE_STRATEGY) #endif for (j = jj0; j < nub; ++j) { / jj0 starts after look-ahead window. / if (j==jj0) tempu = bigU; //else tempu = bigU + ldu Ublock_info[j-1].full_u_cols; else tempu = bigU + gemm_k_pad * Ublock_info[j-1].full_u_cols; /* == processing each of the remaining columns in parallel == / #if 0 / Can remove following call, since search was already done. / arrive_at_ublock(j, &iukp, &rukp, &jb, &ljb, &nsupc, iukp0, rukp0, usub,perm_u, xsup, grid); #else iukp = Ublock_info[j].iukp; rukp = Ublock_info[j].rukp; jb = Ublock_info[j].jb; nsupc = SuperSize (jb ); #endif / Copy from U(k,j) to tempu[], padding zeros. / for (jj = iukp; jj < iukp+nsupc; ++jj) { segsize = klst - usub[jj]; if ( segsize ) { lead_zero = ldu - segsize; for (i = 0; i < lead_zero; ++i) tempu[i] = zero; //tempu += lead_zero; #if (_OPENMP>=201307) #pragma omp simd #endif for (i = 0; i < segsize; ++i) tempu[i+lead_zero] = uval[rukp+i]; rukp += segsize; tempu += gemm_k_pad; } } } / parallel for j = jj0 .. nub / #if 0 if (ldu==0) printf("[%d] .. k0 %d, before updating: ldu %d, Lnbrow %d, Rnbrow %d, ncols %d\n",iam,k0,ldu,Lnbrow,Rnbrow, ncols); fflush(stdout); #endif GatherMOP += 2lduncols; } / end if (nbrow>0), end gather U blocks / GatherUTimer += SuperLU_timer_() - tt_start; int jj_cpu = nub; / limit between CPU and GPU / int thread_id; /tempv = bigV;/ /********************* * Gather L blocks * *********************/ tt_start = SuperLU_timer_(); / Loop through the look-ahead blocks to copy Lval into the buffer / #ifdef _OPENMP #pragma omp parallel for private(j,jj,tempu,tempv) default (shared) #endif for (i = 0; i < lookAheadBlk; ++i) { int StRowDest, temp_nbrow; if ( i==0 ) { StRowDest = 0; temp_nbrow = lookAheadFullRow[0]; } else { StRowDest = lookAheadFullRow[i-1]; temp_nbrow = lookAheadFullRow[i]-lookAheadFullRow[i-1]; } int StRowSource = lookAheadStRow[i]; / Now copying one block into L lookahead buffer / / #pragma omp parallel for (gives slow down) / // for (int j = 0; j < knsupc; ++j) { for (j = knsupc-ldu; j < knsupc; ++j) { / skip leading columns corresponding to zero U rows / #if 1 / Better let compiler generate memcpy or vectorized code. / //tempu = &lookAhead_L_buff[StRowDest + jLDlookAhead_LBuff]; //tempu = &lookAhead_L_buff[StRowDest + j * Lnbrow]; tempu = &lookAhead_L_buff[StRowDest + (j - (knsupc-ldu)) * Lnbrow]; tempv = &lusup[luptr+jnsupr + StRowSource]; #if (_OPENMP>=201307) #pragma omp simd #endif for (jj = 0; jj < temp_nbrow; ++jj) tempu[jj] = tempv[jj]; #else //memcpy(&lookAhead_L_buff[StRowDest + jLDlookAhead_LBuff], memcpy(&lookAhead_L_buff[StRowDest + (j - (knsupc-ldu)) * Lnbrow], &lusup[luptr+jnsupr + StRowSource], temp_nbrow sizeof(double) ); #endif } /* end for j ... / } / parallel for i ... gather Lval blocks from lookahead window / / Loop through the remaining blocks to copy Lval into the buffer / #ifdef _OPENMP #pragma omp parallel for private(i,j,jj,tempu,tempv) default (shared) \ schedule(SCHEDULE_STRATEGY) #endif for (int i = 0; i < RemainBlk; ++i) { int StRowDest, temp_nbrow; if ( i==0 ) { StRowDest = 0; temp_nbrow = Remain_info[0].FullRow; } else { StRowDest = Remain_info[i-1].FullRow; temp_nbrow = Remain_info[i].FullRow - Remain_info[i-1].FullRow; } int StRowSource = RemainStRow[i]; / Now copying a block into L remaining buffer / // #pragma omp parallel for (gives slow down) // for (int j = 0; j < knsupc; ++j) { for (int j = knsupc-ldu; j < knsupc; ++j) { // printf("StRowDest %d Rnbrow %d StRowSource %d \n", StRowDest,Rnbrow ,StRowSource); #if 1 / Better let compiler generate memcpy or vectorized code. / //tempu = &Remain_L_buff[StRowDest + jLDRemain_LBuff]; //tempu = &Remain_L_buff[StRowDest + (j - (knsupc-ldu)) * Rnbrow]; tempu = &Remain_L_buff[StRowDest + (j - (knsupc-ldu)) * gemm_m_pad]; tempv = &lusup[luptr + jnsupr + StRowSource]; #if (_OPENMP>=201307) #pragma omp simd #endif for (jj = 0; jj < temp_nbrow; ++jj) tempu[jj] = tempv[jj]; #else //memcpy(&Remain_L_buff[StRowDest + jLDRemain_LBuff], memcpy(&Remain_L_buff[StRowDest + (j - (knsupc-ldu)) * gemm_m_pad], &lusup[luptr+jnsupr + StRowSource], temp_nbrow sizeof(double) ); #endif } /* end for j ... / } / parallel for i ... copy Lval into the remaining buffer / tt_end = SuperLU_timer_(); GatherLTimer += tt_end - tt_start; /************************************************************************ * Perform GEMM (look-ahead L part, and remain L part) followed by Scatter ************************************************************************/ tempu = bigU; / setting to the start of padded U(k,:) / if ( Lnbrow>0 && ldu>0 && ncols>0 ) { / Both L(:,k) and U(k,:) nonempty / /************************************************************** * Updating blocks in look-ahead window of the LU(look-ahead-rows,:) **************************************************************/ / Count flops for total GEMM calls / ncols = Ublock_info[nub-1].full_u_cols; flops_t flps = 2.0 (flops_t)Lnbrow * ldu * ncols; LookAheadScatterMOP += 3 * Lnbrow * ncols; /* scatter-add / schur_flop_counter += flps; stat->ops[FACT] += flps; LookAheadGEMMFlOp += flps; #ifdef _OPENMP #pragma omp parallel default (shared) private(thread_id) { thread_id = omp_get_thread_num(); / Ideally, should organize the loop as: for (j = 0; j < nub; ++j) { for (lb = 0; lb < lookAheadBlk; ++lb) { L(lb,k) X U(k,j) -> tempv[] } } But now, we use collapsed loop to achieve more parallelism. Total number of block updates is: (# of lookAheadBlk in L(:,k)) X (# of blocks in U(k,:)) / int i = sizeof(int); int indirect_thread = indirect + (ldt + CACHELINE/i) * thread_id; int* indirect2_thread = indirect2 + (ldt + CACHELINE/i) * thread_id; #pragma omp for \ private (nsupc,ljb,lptr,ib,temp_nbrow,cum_nrow) \ schedule(dynamic) #else /* not use _OPENMP / thread_id = 0; int indirect_thread = indirect; int* indirect2_thread = indirect2; #endif /* Each thread is assigned one loop index ij, responsible for block update L(lb,k) * U(k,j) -> tempv[]. / for (int ij = 0; ij < lookAheadBlk(nub-jj0); ++ij) { /* jj0 starts after look-ahead window. / int j = ij/lookAheadBlk + jj0; int lb = ij%lookAheadBlk; / Getting U block U(k,j) information / / unsigned long long ut_start, ut_end; / int_t rukp = Ublock_info[j].rukp; int_t iukp = Ublock_info[j].iukp; int jb = Ublock_info[j].jb; int nsupc = SuperSize(jb); int ljb = LBj (jb, grid); / destination column block / int st_col; int ncols; / Local variable counts only columns in the block / if ( j > jj0 ) { / jj0 starts after look-ahead window. / ncols = Ublock_info[j].full_u_cols-Ublock_info[j-1].full_u_cols; st_col = Ublock_info[j-1].full_u_cols; } else { ncols = Ublock_info[j].full_u_cols; st_col = 0; } / Getting L block L(i,k) information / int_t lptr = lookAhead_lptr[lb]; int ib = lookAhead_ib[lb]; int temp_nbrow = lsub[lptr+1]; lptr += LB_DESCRIPTOR; int cum_nrow = (lb==0 ? 0 : lookAheadFullRow[lb-1]); / Block-by-block GEMM in look-ahead window / #if 0 i = sizeof(double); double tempv1 = bigV + thread_id * (ldtldt + CACHELINE/i); #else double tempv1 = bigV + thread_id * (ldtldt); #endif #if ( PRNTlevel>= 1) if (thread_id == 0) tt_start = SuperLU_timer_(); gemm_max_m = SUPERLU_MAX(gemm_max_m, temp_nbrow); gemm_max_n = SUPERLU_MAX(gemm_max_n, ncols); gemm_max_k = SUPERLU_MAX(gemm_max_k, ldu); #endif #if defined (USE_VENDOR_BLAS) dgemm_("N", "N", &temp_nbrow, &ncols, &ldu, &alpha, //&lookAhead_L_buff[(knsupc-ldu)Lnbrow+cum_nrow], &Lnbrow, &lookAhead_L_buff[cum_nrow], &Lnbrow, &tempu[st_colldu], &ldu, &beta, tempv1, &temp_nbrow, 1, 1); #else dgemm_("N", "N", &temp_nbrow, &ncols, &ldu, &alpha, //&lookAhead_L_buff[(knsupc-ldu)Lnbrow+cum_nrow], &Lnbrow, &lookAhead_L_buff[cum_nrow], &Lnbrow, &tempu[st_colldu], &ldu, &beta, tempv1, &temp_nbrow); #endif #if (PRNTlevel>=1 ) if (thread_id == 0) { tt_end = SuperLU_timer_(); LookAheadGEMMTimer += tt_end - tt_start; tt_start = tt_end; } #endif if ( ib < jb ) { dscatter_u ( ib, jb, nsupc, iukp, xsup, klst, temp_nbrow, lptr, temp_nbrow, lsub, usub, tempv1, Ufstnz_br_ptr, Unzval_br_ptr, grid ); } else { #if 0 //#ifdef USE_VTUNE __SSC_MARK(0x111);// start SDE tracing, note uses 2 underscores __itt_resume(); // start VTune, again use 2 underscores #endif dscatter_l ( ib, ljb, nsupc, iukp, xsup, klst, temp_nbrow, lptr, temp_nbrow, usub, lsub, tempv1, indirect_thread, indirect2_thread, Lrowind_bc_ptr, Lnzval_bc_ptr, grid ); #if 0 //#ifdef USE_VTUNE __itt_pause(); // stop VTune __SSC_MARK(0x222); // stop SDE tracing #endif } #if ( PRNTlevel>=1 ) if (thread_id == 0) LookAheadScatterTimer += SuperLU_timer_() - tt_start; #endif } / end omp for ij = ... / #ifdef _OPENMP } / end omp parallel / #endif } / end if Lnbrow>0 ... look-ahead GEMM and scatter / /************************************************************** * Updating remaining rows and columns on CPU. **************************************************************/ ncols = jj_cpu==0 ? 0 : Ublock_info[jj_cpu-1].full_u_cols; if ( Rnbrow>0 && ldu>0 ) { / There are still blocks remaining ... / double flps = 2.0 (double)Rnbrow * ldu * ncols; schur_flop_counter += flps; stat->ops[FACT] += flps; #if ( PRNTlevel>=1 ) RemainGEMM_flops += flps; gemm_max_m = SUPERLU_MAX(gemm_max_m, Rnbrow); gemm_max_n = SUPERLU_MAX(gemm_max_n, ncols); gemm_max_k = SUPERLU_MAX(gemm_max_k, ldu); tt_start = SuperLU_timer_(); /* printf("[%d] .. k0 %d, before large GEMM: %d-%d-%d, RemainBlk %d\n", iam, k0,Rnbrow,ldu,ncols,RemainBlk); fflush(stdout); assert( Rnbrowncols < bigv_size ); / #endif /* calling aggregated large GEMM, result stored in bigV[]. / #if defined (USE_VENDOR_BLAS) //dgemm_("N", "N", &Rnbrow, &ncols, &ldu, &alpha, dgemm_("N", "N", &gemm_m_pad, &gemm_n_pad, &gemm_k_pad, &alpha, //&Remain_L_buff[(knsupc-ldu)Rnbrow], &Rnbrow, &Remain_L_buff[0], &gemm_m_pad, &bigU[0], &gemm_k_pad, &beta, bigV, &gemm_m_pad, 1, 1); #else //dgemm_("N", "N", &Rnbrow, &ncols, &ldu, &alpha, dgemm_("N", "N", &gemm_m_pad, &gemm_n_pad, &gemm_k_pad, &alpha, //&Remain_L_buff[(knsupc-ldu)Rnbrow], &Rnbrow, &Remain_L_buff[0], &gemm_m_pad, &bigU[0], &gemm_k_pad, &beta, bigV, &gemm_m_pad); #endif #if ( PRNTlevel>=1 ) tt_end = SuperLU_timer_(); RemainGEMMTimer += tt_end - tt_start; #if ( PROFlevel>=1 ) //fprintf(fgemm, "%8d%8d%8d %16.8e\n", Rnbrow, ncols, ldu, // (tt_end - tt_start)1e6); // time in microsecond //fflush(fgemm); gemm_stats[gemm_count].m = Rnbrow; gemm_stats[gemm_count].n = ncols; gemm_stats[gemm_count].k = ldu; gemm_stats[gemm_count++].microseconds = (tt_end - tt_start) * 1e6; #endif tt_start = SuperLU_timer_(); #endif #ifdef USE_VTUNE __SSC_MARK(0x111);// start SDE tracing, note uses 2 underscores __itt_resume(); // start VTune, again use 2 underscores #endif /* Scatter into destination block-by-block. / #ifdef _OPENMP #pragma omp parallel default(shared) private(thread_id) { thread_id = omp_get_thread_num(); / Ideally, should organize the loop as: for (j = 0; j < jj_cpu; ++j) { for (lb = 0; lb < RemainBlk; ++lb) { L(lb,k) X U(k,j) -> tempv[] } } But now, we use collapsed loop to achieve more parallelism. Total number of block updates is: (# of RemainBlk in L(:,k)) X (# of blocks in U(k,:)) / int i = sizeof(int); int indirect_thread = indirect + (ldt + CACHELINE/i) * thread_id; int* indirect2_thread = indirect2 + (ldt + CACHELINE/i) * thread_id; #pragma omp for \ private (j,lb,rukp,iukp,jb,nsupc,ljb,lptr,ib,temp_nbrow,cum_nrow) \ schedule(dynamic) #else /* not use _OPENMP / thread_id = 0; int indirect_thread = indirect; int* indirect2_thread = indirect2; #endif /* Each thread is assigned one loop index ij, responsible for block update L(lb,k) * U(k,j) -> tempv[]. / for (int ij = 0; ij < RemainBlk(jj_cpu-jj0); ++ij) { /* jj_cpu := nub, jj0 starts after look-ahead window. / int j = ij / RemainBlk + jj0; / j-th block in U panel / int lb = ij % RemainBlk; / lb-th block in L panel / / Getting U block U(k,j) information / / unsigned long long ut_start, ut_end; / int_t rukp = Ublock_info[j].rukp; int_t iukp = Ublock_info[j].iukp; int jb = Ublock_info[j].jb; int nsupc = SuperSize(jb); int ljb = LBj (jb, grid); int st_col; int ncols; if ( j>jj0 ) { ncols = Ublock_info[j].full_u_cols - Ublock_info[j-1].full_u_cols; st_col = Ublock_info[j-1].full_u_cols; } else { ncols = Ublock_info[j].full_u_cols; st_col = 0; } / Getting L block L(i,k) information / int_t lptr = Remain_info[lb].lptr; int ib = Remain_info[lb].ib; int temp_nbrow = lsub[lptr+1]; lptr += LB_DESCRIPTOR; int cum_nrow = (lb==0 ? 0 : Remain_info[lb-1].FullRow); / tempv1 points to block(i,j) in bigV : LDA == Rnbrow / //double tempv1 = bigV + (st_col * Rnbrow + cum_nrow); Sherry double* tempv1 = bigV + (st_col * gemm_m_pad + cum_nrow); /* Sherry / // printf("[%d] .. before scatter: ib %d, jb %d, temp_nbrow %d, Rnbrow %d\n", iam, ib, jb, temp_nbrow, Rnbrow); fflush(stdout); / Now scattering the block / if ( ib < jb ) { dscatter_u ( ib, jb, nsupc, iukp, xsup, //klst, Rnbrow, /** klst, temp_nbrow, Sherry / klst, gemm_m_pad, /** klst, temp_nbrow, Sherry / lptr, temp_nbrow, / row dimension of the block / lsub, usub, tempv1, Ufstnz_br_ptr, Unzval_br_ptr, grid ); } else { dscatter_l( ib, ljb, nsupc, iukp, xsup, //klst, temp_nbrow, Sherry klst, gemm_m_pad, /** temp_nbrow, Sherry / lptr, temp_nbrow, / row dimension of the block / usub, lsub, tempv1, indirect_thread, indirect2_thread, Lrowind_bc_ptr,Lnzval_bc_ptr, grid ); } } / end omp for (int ij =...) / #ifdef _OPENMP } / end omp parallel region / #endif #if ( PRNTlevel>=1 ) RemainScatterTimer += SuperLU_timer_() - tt_start; #endif #ifdef USE_VTUNE __itt_pause(); // stop VTune __SSC_MARK(0x222); // stop SDE tracing #endif } / end if Rnbrow>0 ... update remaining block / } / end if L(:,k) and U(k,:) are not empty */
LLT_ROF_core.c	/* This work is part of the Core Imaging Library developed by Visual Analytics and Imaging System Group of the Science Technology Facilities Council, STFC Copyright 2017 Daniil Kazantsev Copyright 2017 Srikanth Nagella, Edoardo Pasca Licensed under the Apache License, Version 2.0 (the "License"); you may not use this file except in compliance with the License. You may obtain a copy of the License at http://www.apache.org/licenses/LICENSE-2.0 Unless required by applicable law or agreed to in writing, software distributed under the License is distributed on an "AS IS" BASIS, WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. See the License for the specific language governing permissions and limitations under the License. / #include "LLT_ROF_core.h" #define EPS_LLT 1.0e-12 #define EPS_ROF 1.0e-12 #define MAX(x, y) (((x) > (y)) ? (x) : (y)) #define MIN(x, y) (((x) < (y)) ? (x) : (y)) /sign function/ int signLLT(float x) { return (x > 0) - (x < 0); } / C-OMP implementation of Lysaker, Lundervold and Tai (LLT) model [1] combined with Rudin-Osher-Fatemi [2] TV regularisation penalty. * * This penalty can deliver visually pleasant piecewise-smooth recovery if regularisation parameters are selected well. * The rule of thumb for selection is to start with lambdaLLT = 0 (just the ROF-TV model) and then proceed to increase * lambdaLLT starting with smaller values. * * Input Parameters: * 1. U0 - original noise image/volume * 2. lambdaROF - ROF-related regularisation parameter * 3. lambdaLLT - LLT-related regularisation parameter * 4. tau - time-marching step * 5. iter - iterations number (for both models) * 6. eplsilon: tolerance constant * * Output: * [1] Filtered/regularized image/volume * [2] Information vector which contains [iteration no., reached tolerance] * * References: * [1] Lysaker, M., Lundervold, A. and Tai, X.C., 2003. Noise removal using fourth-order partial differential equation with applications to medical magnetic resonance images in space and time. IEEE Transactions on image processing, 12(12), pp.1579-1590. * [2] Rudin, Osher, Fatemi, "Nonlinear Total Variation based noise removal algorithms" / float LLT_ROF_CPU_main(float Input, float Output, float infovector, float lambdaROF, float lambdaLLT, int iterationsNumb, float tau, float epsil, int dimX, int dimY, int dimZ) { long DimTotal; int ll, j; float re, re1; re = 0.0f; re1 = 0.0f; int count = 0; float D1_LLT=NULL, D2_LLT=NULL, D3_LLT=NULL, D1_ROF=NULL, D2_ROF=NULL, D3_ROF=NULL, Output_prev=NULL; DimTotal = (long)(dimXdimYdimZ); D1_ROF = calloc(DimTotal, sizeof(float)); D2_ROF = calloc(DimTotal, sizeof(float)); D3_ROF = calloc(DimTotal, sizeof(float)); D1_LLT = calloc(DimTotal, sizeof(float)); D2_LLT = calloc(DimTotal, sizeof(float)); D3_LLT = calloc(DimTotal, sizeof(float)); copyIm(Input, Output, (long)(dimX), (long)(dimY), (long)(dimZ)); / initialize / if (epsil != 0.0f) Output_prev = calloc(DimTotal, sizeof(float)); for(ll = 0; ll < iterationsNumb; ll++) { if ((epsil != 0.0f) && (ll % 5 == 0)) copyIm(Output, Output_prev, (long)(dimX), (long)(dimY), (long)(dimZ)); if (dimZ == 1) { / 2D case / /*************ROF***************/ / calculate first-order differences / D1_func_ROF(Output, D1_ROF, (long)(dimX), (long)(dimY), 1l); D2_func_ROF(Output, D2_ROF, (long)(dimX), (long)(dimY), 1l); /*************LLT***************/ / estimate second-order derrivatives / der2D_LLT(Output, D1_LLT, D2_LLT, (long)(dimX), (long)(dimY), 1l); / Joint update for ROF and LLT models / Update2D_LLT_ROF(Input, Output, D1_LLT, D2_LLT, D1_ROF, D2_ROF, lambdaROF, lambdaLLT, tau, (long)(dimX), (long)(dimY), 1l); } else { / 3D case / / calculate first-order differences / D1_func_ROF(Output, D1_ROF, (long)(dimX), (long)(dimY), (long)(dimZ)); D2_func_ROF(Output, D2_ROF, (long)(dimX), (long)(dimY), (long)(dimZ)); D3_func_ROF(Output, D3_ROF, (long)(dimX), (long)(dimY), (long)(dimZ)); /*************LLT***************/ / estimate second-order derrivatives / der3D_LLT(Output, D1_LLT, D2_LLT, D3_LLT,(long)(dimX), (long)(dimY), (long)(dimZ)); / Joint update for ROF and LLT models / Update3D_LLT_ROF(Input, Output, D1_LLT, D2_LLT, D3_LLT, D1_ROF, D2_ROF, D3_ROF, lambdaROF, lambdaLLT, tau, (long)(dimX), (long)(dimY), (long)(dimZ)); } / check early stopping criteria / if ((epsil != 0.0f) && (ll % 5 == 0)) { re = 0.0f; re1 = 0.0f; for(j=0; j<DimTotal; j++) { re += powf(Output[j] - Output_prev[j],2); re1 += powf(Output[j],2); } re = sqrtf(re)/sqrtf(re1); if (re < epsil) count++; if (count > 3) break; } } /end of iterations/ free(D1_LLT);free(D2_LLT);free(D3_LLT); free(D1_ROF);free(D2_ROF);free(D3_ROF); if (epsil != 0.0f) free(Output_prev); /adding info into info_vector / infovector[0] = (float)(ll); /iterations number (if stopped earlier based on tolerance)/ infovector[1] = re; / reached tolerance / return 0; } /**********************************************************************/ /******************LLT-related functions *************************/ /**********************************************************************/ float der2D_LLT(float U, float D1, float D2, long dimX, long dimY, long dimZ) { long i, j, index, i_p, i_m, j_m, j_p; float dxx, dyy, denom_xx, denom_yy; #pragma omp parallel for shared(U,D1,D2) private(i, j, index, i_p, i_m, j_m, j_p, denom_xx, denom_yy, dxx, dyy) for (i = 0; i<dimX; i++) { for (j = 0; j<dimY; j++) { index = jdimX+i; / symmetric boundary conditions (Neuman) / i_p = i + 1; if (i_p == dimX) i_p = i - 1; i_m = i - 1; if (i_m < 0) i_m = i + 1; j_p = j + 1; if (j_p == dimY) j_p = j - 1; j_m = j - 1; if (j_m < 0) j_m = j + 1; dxx = U[jdimX+i_p] - 2.0fU[index] + U[jdimX+i_m]; dyy = U[j_pdimX+i] - 2.0fU[index] + U[j_mdimX+i]; denom_xx = fabs(dxx) + EPS_LLT; denom_yy = fabs(dyy) + EPS_LLT; D1[index] = dxx / denom_xx; D2[index] = dyy / denom_yy; } } return 1; } float der3D_LLT(float U, float D1, float D2, float D3, long dimX, long dimY, long dimZ) { long i, j, k, i_p, i_m, j_m, j_p, k_p, k_m, index; float dxx, dyy, dzz, denom_xx, denom_yy, denom_zz; #pragma omp parallel for shared(U,D1,D2,D3) private(i, j, index, k, i_p, i_m, j_m, j_p, k_p, k_m, denom_xx, denom_yy, denom_zz, dxx, dyy, dzz) for (i = 0; i<dimX; i++) { for (j = 0; j<dimY; j++) { for (k = 0; k<dimZ; k++) { / symmetric boundary conditions (Neuman) / i_p = i + 1; if (i_p == dimX) i_p = i - 1; i_m = i - 1; if (i_m < 0) i_m = i + 1; j_p = j + 1; if (j_p == dimY) j_p = j - 1; j_m = j - 1; if (j_m < 0) j_m = j + 1; k_p = k + 1; if (k_p == dimZ) k_p = k - 1; k_m = k - 1; if (k_m < 0) k_m = k + 1; index = (dimXdimY)k + jdimX+i; dxx = U[(dimXdimY)k + jdimX+i_p] - 2.0fU[index] + U[(dimXdimY)k + jdimX+i_m]; dyy = U[(dimXdimY)k + j_pdimX+i] - 2.0fU[index] + U[(dimXdimY)k + j_mdimX+i]; dzz = U[(dimXdimY)k_p + jdimX+i] - 2.0fU[index] + U[(dimXdimY)k_m + jdimX+i]; denom_xx = fabs(dxx) + EPS_LLT; denom_yy = fabs(dyy) + EPS_LLT; denom_zz = fabs(dzz) + EPS_LLT; D1[index] = dxx / denom_xx; D2[index] = dyy / denom_yy; D3[index] = dzz / denom_zz; } } } return 1; } /**********************************************************************/ /******************ROF-related functions *************************/ /**********************************************************************/ / calculate differences 1 / float D1_func_ROF(float A, float D1, long dimX, long dimY, long dimZ) { float NOMx_1, NOMy_1, NOMy_0, NOMz_1, NOMz_0, denom1, denom2,denom3, T1; long i,j,k,i1,i2,k1,j1,j2,k2,index; if (dimZ > 1) { #pragma omp parallel for shared (A, D1, dimX, dimY, dimZ) private(index, i, j, k, i1, j1, k1, i2, j2, k2, NOMx_1,NOMy_1,NOMy_0,NOMz_1,NOMz_0,denom1,denom2,denom3,T1) for(j=0; j<dimY; j++) { for(i=0; i<dimX; i++) { for(k=0; k<dimZ; k++) { index = (dimXdimY)k + jdimX+i; /* symmetric boundary conditions (Neuman) / i1 = i + 1; if (i1 >= dimX) i1 = i-1; i2 = i - 1; if (i2 < 0) i2 = i+1; j1 = j + 1; if (j1 >= dimY) j1 = j-1; j2 = j - 1; if (j2 < 0) j2 = j+1; k1 = k + 1; if (k1 >= dimZ) k1 = k-1; k2 = k - 1; if (k2 < 0) k2 = k+1; / Forward-backward differences / NOMx_1 = A[(dimXdimY)k + j1dimX + i] - A[index]; /* x+ / NOMy_1 = A[(dimXdimY)k + jdimX + i1] - A[index]; /* y+ / /NOMx_0 = (A[(i)dimY + j] - A[(i2)dimY + j]); / / x- / NOMy_0 = A[index] - A[(dimXdimY)k + jdimX + i2]; /* y- / NOMz_1 = A[(dimXdimY)k1 + jdimX + i] - A[index]; /* z+ / NOMz_0 = A[index] - A[(dimXdimY)k2 + jdimX + i]; /* z- / denom1 = NOMx_1NOMx_1; denom2 = 0.5f(signLLT(NOMy_1) + signLLT(NOMy_0))(MIN(fabs(NOMy_1),fabs(NOMy_0))); denom2 = denom2denom2; denom3 = 0.5f(signLLT(NOMz_1) + signLLT(NOMz_0))(MIN(fabs(NOMz_1),fabs(NOMz_0))); denom3 = denom3denom3; T1 = sqrt(denom1 + denom2 + denom3 + EPS_ROF); D1[index] = NOMx_1/T1; }}} } else { #pragma omp parallel for shared (A, D1, dimX, dimY) private(i, j, i1, j1, i2, j2,NOMx_1,NOMy_1,NOMy_0,denom1,denom2,T1,index) for(j=0; j<dimY; j++) { for(i=0; i<dimX; i++) { index = jdimX+i; / symmetric boundary conditions (Neuman) / i1 = i + 1; if (i1 >= dimX) i1 = i-1; i2 = i - 1; if (i2 < 0) i2 = i+1; j1 = j + 1; if (j1 >= dimY) j1 = j-1; j2 = j - 1; if (j2 < 0) j2 = j+1; / Forward-backward differences / NOMx_1 = A[j1dimX + i] - A[index]; /* x+ / NOMy_1 = A[jdimX + i1] - A[index]; /* y+ / /NOMx_0 = (A[(i)dimY + j] - A[(i2)dimY + j]); / / x- / NOMy_0 = A[index] - A[(j)dimX + i2]; /* y- / denom1 = NOMx_1NOMx_1; denom2 = 0.5f(signLLT(NOMy_1) + signLLT(NOMy_0))(MIN(fabs(NOMy_1),fabs(NOMy_0))); denom2 = denom2denom2; T1 = sqrtf(denom1 + denom2 + EPS_ROF); D1[index] = NOMx_1/T1; }} } return D1; } /* calculate differences 2 / float D2_func_ROF(float A, float D2, long dimX, long dimY, long dimZ) { float NOMx_1, NOMy_1, NOMx_0, NOMz_1, NOMz_0, denom1, denom2, denom3, T2; long i,j,k,i1,i2,k1,j1,j2,k2,index; if (dimZ > 1) { #pragma omp parallel for shared (A, D2, dimX, dimY, dimZ) private(index, i, j, k, i1, j1, k1, i2, j2, k2, NOMx_1, NOMy_1, NOMx_0, NOMz_1, NOMz_0, denom1, denom2, denom3, T2) for(j=0; j<dimY; j++) { for(i=0; i<dimX; i++) { for(k=0; k<dimZ; k++) { index = (dimXdimY)k + jdimX+i; /* symmetric boundary conditions (Neuman) / i1 = i + 1; if (i1 >= dimX) i1 = i-1; i2 = i - 1; if (i2 < 0) i2 = i+1; j1 = j + 1; if (j1 >= dimY) j1 = j-1; j2 = j - 1; if (j2 < 0) j2 = j+1; k1 = k + 1; if (k1 >= dimZ) k1 = k-1; k2 = k - 1; if (k2 < 0) k2 = k+1; / Forward-backward differences / NOMx_1 = A[(dimXdimY)k + (j1)dimX + i] - A[index]; /* x+ / NOMy_1 = A[(dimXdimY)k + (j)dimX + i1] - A[index]; /* y+ / NOMx_0 = A[index] - A[(dimXdimY)k + (j2)dimX + i]; /* x- / NOMz_1 = A[(dimXdimY)k1 + jdimX + i] - A[index]; /* z+ / NOMz_0 = A[index] - A[(dimXdimY)k2 + (j)dimX + i]; /* z- / denom1 = NOMy_1NOMy_1; denom2 = 0.5f(signLLT(NOMx_1) + signLLT(NOMx_0))(MIN(fabs(NOMx_1),fabs(NOMx_0))); denom2 = denom2denom2; denom3 = 0.5f(signLLT(NOMz_1) + signLLT(NOMz_0))(MIN(fabs(NOMz_1),fabs(NOMz_0))); denom3 = denom3denom3; T2 = sqrtf(denom1 + denom2 + denom3 + EPS_ROF); D2[index] = NOMy_1/T2; }}} } else { #pragma omp parallel for shared (A, D2, dimX, dimY) private(i, j, i1, j1, i2, j2, NOMx_1,NOMy_1,NOMx_0,denom1,denom2,T2,index) for(j=0; j<dimY; j++) { for(i=0; i<dimX; i++) { index = jdimX+i; / symmetric boundary conditions (Neuman) / i1 = i + 1; if (i1 >= dimX) i1 = i-1; i2 = i - 1; if (i2 < 0) i2 = i+1; j1 = j + 1; if (j1 >= dimY) j1 = j-1; j2 = j - 1; if (j2 < 0) j2 = j+1; / Forward-backward differences / NOMx_1 = A[j1dimX + i] - A[index]; /* x+ / NOMy_1 = A[jdimX + i1] - A[index]; /* y+ / NOMx_0 = A[index] - A[j2dimX + i]; /* x- / /NOMy_0 = A[(i)dimY + j] - A[(i)dimY + j2]; / / y- / denom1 = NOMy_1NOMy_1; denom2 = 0.5f(signLLT(NOMx_1) + signLLT(NOMx_0))(MIN(fabs(NOMx_1),fabs(NOMx_0))); denom2 = denom2denom2; T2 = sqrtf(denom1 + denom2 + EPS_ROF); D2[index] = NOMy_1/T2; }} } return D2; } /* calculate differences 3 / float D3_func_ROF(float A, float D3, long dimX, long dimY, long dimZ) { float NOMx_1, NOMy_1, NOMx_0, NOMy_0, NOMz_1, denom1, denom2, denom3, T3; long index,i,j,k,i1,i2,k1,j1,j2,k2; #pragma omp parallel for shared (A, D3, dimX, dimY, dimZ) private(index, i, j, k, i1, j1, k1, i2, j2, k2, NOMx_1, NOMy_1, NOMy_0, NOMx_0, NOMz_1, denom1, denom2, denom3, T3) for(j=0; j<dimY; j++) { for(i=0; i<dimX; i++) { for(k=0; k<dimZ; k++) { index = (dimXdimY)k + jdimX+i; /* symmetric boundary conditions (Neuman) / i1 = i + 1; if (i1 >= dimX) i1 = i-1; i2 = i - 1; if (i2 < 0) i2 = i+1; j1 = j + 1; if (j1 >= dimY) j1 = j-1; j2 = j - 1; if (j2 < 0) j2 = j+1; k1 = k + 1; if (k1 >= dimZ) k1 = k-1; k2 = k - 1; if (k2 < 0) k2 = k+1; / Forward-backward differences / NOMx_1 = A[(dimXdimY)k + (j1)dimX + i] - A[index]; /* x+ / NOMy_1 = A[(dimXdimY)k + (j)dimX + i1] - A[index]; /* y+ / NOMy_0 = A[index] - A[(dimXdimY)k + (j)dimX + i2]; /* y- / NOMx_0 = A[index] - A[(dimXdimY)k + (j2)dimX + i]; /* x- / NOMz_1 = A[(dimXdimY)k1 + jdimX + i] - A[index]; /* z+ / /NOMz_0 = A[(dimXdimY)k + (i)dimY + j] - A[(dimXdimY)k2 + (i)dimY + j]; / / z- / denom1 = NOMz_1NOMz_1; denom2 = 0.5f(signLLT(NOMx_1) + signLLT(NOMx_0))(MIN(fabs(NOMx_1),fabs(NOMx_0))); denom2 = denom2denom2; denom3 = 0.5f(signLLT(NOMy_1) + signLLT(NOMy_0))(MIN(fabs(NOMy_1),fabs(NOMy_0))); denom3 = denom3denom3; T3 = sqrtf(denom1 + denom2 + denom3 + EPS_ROF); D3[index] = NOMz_1/T3; }}} return D3; } /**********************************************************************/ /******************ROF-LLT-related functions *********************/ /**********************************************************************/ float Update2D_LLT_ROF(float U0, float U, float D1_LLT, float D2_LLT, float D1_ROF, float D2_ROF, float lambdaROF, float lambdaLLT, float tau, long dimX, long dimY, long dimZ) { long i, j, index, i_p, i_m, j_m, j_p; float div, laplc, dxx, dyy, dv1, dv2; #pragma omp parallel for shared(U,U0) private(i, j, index, i_p, i_m, j_m, j_p, laplc, div, dxx, dyy, dv1, dv2) for (i = 0; i<dimX; i++) { for (j = 0; j<dimY; j++) { index = jdimX+i; /* symmetric boundary conditions (Neuman) / i_p = i + 1; if (i_p == dimX) i_p = i - 1; i_m = i - 1; if (i_m < 0) i_m = i + 1; j_p = j + 1; if (j_p == dimY) j_p = j - 1; j_m = j - 1; if (j_m < 0) j_m = j + 1; /LLT-related part/ dxx = D1_LLT[jdimX+i_p] - 2.0fD1_LLT[index] + D1_LLT[jdimX+i_m]; dyy = D2_LLT[j_pdimX+i] - 2.0fD2_LLT[index] + D2_LLT[j_mdimX+i]; laplc = dxx + dyy; /build Laplacian/ /ROF-related part/ dv1 = D1_ROF[index] - D1_ROF[j_mdimX + i]; dv2 = D2_ROF[index] - D2_ROF[jdimX + i_m]; div = dv1 + dv2; /build Divirgent/ /combine all into one cost function to minimise / U[index] += tau(lambdaROF(div) - lambdaLLT(laplc) - (U[index] - U0[index])); } } return U; } float Update3D_LLT_ROF(float U0, float U, float D1_LLT, float D2_LLT, float D3_LLT, float D1_ROF, float D2_ROF, float D3_ROF, float lambdaROF, float lambdaLLT, float tau, long dimX, long dimY, long dimZ) { long i, j, k, i_p, i_m, j_m, j_p, k_p, k_m, index; float div, laplc, dxx, dyy, dzz, dv1, dv2, dv3; #pragma omp parallel for shared(U,U0) private(i, j, k, index, i_p, i_m, j_m, j_p, k_p, k_m, laplc, div, dxx, dyy, dzz, dv1, dv2, dv3) for (i = 0; i<dimX; i++) { for (j = 0; j<dimY; j++) { for (k = 0; k<dimZ; k++) { / symmetric boundary conditions (Neuman) / i_p = i + 1; if (i_p == dimX) i_p = i - 1; i_m = i - 1; if (i_m < 0) i_m = i + 1; j_p = j + 1; if (j_p == dimY) j_p = j - 1; j_m = j - 1; if (j_m < 0) j_m = j + 1; k_p = k + 1; if (k_p == dimZ) k_p = k - 1; k_m = k - 1; if (k_m < 0) k_m = k + 1; index = (dimXdimY)k + jdimX+i; /LLT-related part/ dxx = D1_LLT[(dimXdimY)k + jdimX+i_p] - 2.0fD1_LLT[index] + D1_LLT[(dimXdimY)k + jdimX+i_m]; dyy = D2_LLT[(dimXdimY)k + j_pdimX+i] - 2.0fD2_LLT[index] + D2_LLT[(dimXdimY)k + j_mdimX+i]; dzz = D3_LLT[(dimXdimY)k_p + jdimX+i] - 2.0fD3_LLT[index] + D3_LLT[(dimXdimY)k_m + jdimX+i]; laplc = dxx + dyy + dzz; /build Laplacian/ /ROF-related part/ dv1 = D1_ROF[index] - D1_ROF[(dimXdimY)k + j_mdimX+i]; dv2 = D2_ROF[index] - D2_ROF[(dimXdimY)k + jdimX+i_m]; dv3 = D3_ROF[index] - D3_ROF[(dimXdimY)k_m + jdimX+i]; div = dv1 + dv2 + dv3; /build Divirgent/ /combine all into one cost function to minimise / U[index] += tau(lambdaROF(div) - lambdaLLT(laplc) - (U[index] - U0[index])); } } } return U; }
io.c	/* -- mode: C; tab-width: 2; indent-tabs-mode: nil; fill-column: 79; coding: iso-latin-1-unix -- / / hpcc.c / #include <hpcc.h> #include <ctype.h> #include <string.h> #include <time.h> #ifdef _OPENMP #include <omp.h> #endif static double HPCC_MemProc = -1.0, HPCC_MemVal = -1.0; static int HPCC_MemSpec = -1; static int ReadInts(char buf, int n, int val) { int i, j; for (j = i = 0; i < n; i++) { if (sscanf( buf + j, "%d", val + i ) != 1) { i--; break; } for (; buf[j] && isdigit(buf[j]); j++) ; / EMPTY / for (; buf[j] && ! isdigit(buf[j]); j++) ; / EMPTY / if (! buf[j]) { i--; break; } } return i + 1; } static int HPCC_InitHPL(HPCC_Params p) { HPL_pdinfo( &p->test, &p->ns, p->nval, &p->nbs, p->nbval, &p->porder, &p->npqs, p->pval, p->qval, &p->npfs, p->pfaval, &p->nbms, p->nbmval, &p->ndvs, p->ndvval, &p->nrfs, p->rfaval, &p->ntps, p->topval, &p->ndhs, p->ndhval, &p->fswap, &p->tswap, &p->L1notran, &p->Unotran, &p->equil, &p->align ); if (p->test.thrsh <= 0.0) p->Failure = 1; return 0; } static int iiamax(int n, int x, int incx) { int i, v, mx, idx = 0; idx = 0; mx = (x[0] < 0 ? -x[0] : x[0]); for (i = 0; i < n; i += incx) { v = (x[i] < 0 ? -x[i] : x[i]); if (mx < v) {mx = v; idx = i;} } return idx; } static void icopy(int n, int src, int sinc, int dst, int dinc) { int i; for (i = n; i; i--) { dst = src; dst += dinc; src += sinc; } } int HPCC_InputFileInit(HPCC_Params params) { int myRank, commSize; int i, j, n, ioErr, lastConfigLine = 32, line, rv, maxHPLn; char buf[82]; int nbuf = 82; FILE f, outputFile; MPI_Comm comm = MPI_COMM_WORLD; MPI_Comm_size( comm, &commSize ); MPI_Comm_rank( comm, &myRank ); if (0 == myRank) { f = fopen( params->inFname, "r" ); if (! f) { ioErr = 1; goto ioEnd; } /* skip irrelevant lines in config file / for (line = 0; line < lastConfigLine; line++) if (! fgets( buf, nbuf, f )) break; if (line < lastConfigLine) { / if didn't read all the required lines / ioErr = 1; goto ioEnd; } / Get values of N for PTRANS / line++; fgets( buf, nbuf, f ); rv = sscanf( buf, "%d", &n ); if (rv != 1 \|\| n < 0) { / parse error or negative value/ n = 0; BEGIN_IO(myRank, params->outFname, outputFile); fprintf( outputFile, "Error in line %d of the input file.\n", line ); END_IO( myRank, outputFile ); } n = Mmin( n, HPL_MAX_PARAM ); line++; fgets( buf, nbuf, f ); ReadInts( buf, n, params->PTRANSnval ); / find the largest matrix for HPL / maxHPLn = params->nval[iiamax( params->ns, params->nval, 1 )]; for (j = i = 0; i < n; i++) { / if memory for PTRANS is at least 90% of what's used for HPL / if (params->PTRANSnval[i] >= 0.9486 maxHPLn * 0.5) { params->PTRANSnval[j] = params->PTRANSnval[i]; j++; } } n = j; /* only this many entries use enough memory / / copy matrix sizes from HPL, divide by 2 so both PTRANS matrices (plus "work" arrays) occupy as much as HPL's one / for (i = 0; i < params->ns; i++) params->PTRANSnval[i + n] = params->nval[i] / 2; params->PTRANSns = n + params->ns; / Get values of block sizes / line++; fgets( buf, nbuf, f ); rv = sscanf( buf, "%d", &n ); if (rv != 1 \|\| n < 0) { / parse error or negative value/ n = 0; BEGIN_IO( myRank, params->outFname, outputFile ); fprintf( outputFile, "Error in line %d of the input file.\n", line ); END_IO( myRank, outputFile ); } n = Mmin( n, HPL_MAX_PARAM ); line++; fgets( buf, nbuf, f ); ReadInts( buf, n, params->PTRANSnbval ); icopy( params->nbs, params->nbval, 1, params->PTRANSnbval + n, 1 ); params->PTRANSnbs = n + params->nbs; ioErr = 0; ioEnd: if (f) fclose( f ); } MPI_Bcast( &ioErr, 1, MPI_INT, 0, comm ); if (ioErr) { / copy matrix sizes from HPL, divide by 2 so both PTRANS matrices (plus "work" arrays) occupy as much as HPL's one / for (i = 0; i < params->ns; i++) params->PTRANSnval[i] = params->nval[i] / 2; params->PTRANSns = params->ns; icopy( params->nbs, params->nbval, 1, params->PTRANSnbval, 1 ); params->PTRANSnbs = params->nbs; } / broadcast what's been read on node 0 / MPI_Bcast( &params->PTRANSns, 1, MPI_INT, 0, comm ); if (params->PTRANSns > 0) MPI_Bcast( &params->PTRANSnval, params->PTRANSns, MPI_INT, 0, comm ); MPI_Bcast( &params->PTRANSnbs, 1, MPI_INT, 0, comm ); if (params->PTRANSnbs > 0) MPI_Bcast( &params->PTRANSnbval, params->PTRANSnbs, MPI_INT, 0, comm ); / copy what HPL has / params->PTRANSnpqs = params->npqs; icopy( params->npqs, params->qval, 1, params->PTRANSqval, 1 ); icopy( params->npqs, params->pval, 1, params->PTRANSpval, 1 ); return ioErr; } static int ErrorReduce(FILE f, char str, int eCode, MPI_Comm comm) { int rCode; if (eCode) eCode = 1; / make sure error is indicated with 1 / MPI_Allreduce( &eCode, &rCode, 1, MPI_INT, MPI_SUM, comm ); if (rCode) { if (f) fprintf( f, "%s", str ); return -1; } return 0; } int HPCC_Init(HPCC_Params params) { int myRank, commSize; int i, nMax, nbMax, procCur, procMax, procMin, errCode; double totalMem; char inFname[12] = "hpccinf.txt", outFname[13] = "hpccoutf.txt"; FILE outputFile; MPI_Comm comm = MPI_COMM_WORLD; time_t currentTime; char hostname[MPI_MAX_PROCESSOR_NAME + 1]; int hostnameLen; #ifdef HPCC_MEMALLCTR size_t hpl_mem, ptrans_mem; long dMemSize; #endif outputFile = NULL; MPI_Comm_size( comm, &commSize ); MPI_Comm_rank( comm, &myRank ); strcpy( params->inFname, inFname ); strcpy( params->outFname, outFname ); if (0 == myRank) outputFile = fopen( params->outFname, "a" ); errCode = 0; if (sizeof(u64Int) < 8 \|\| sizeof(s64Int) < 8) errCode = 1; if (ErrorReduce( outputFile, "No 64-bit integer type available.", errCode, comm )) return -1; i = MPI_Get_processor_name( hostname, &hostnameLen ); if (i) hostname[0] = 0; else hostname[Mmax(hostnameLen, MPI_MAX_PROCESSOR_NAME)] = 0; time( &currentTime ); BEGIN_IO( myRank, params->outFname, outputFile ); fprintf( outputFile, "########################################################################\n" ); fprintf( outputFile, "This is the DARPA/DOE HPC Challenge Benchmark version %d.%d.%d October 2012\n", HPCC_VERSION_MAJOR, HPCC_VERSION_MINOR, HPCC_VERSION_MICRO ); fprintf( outputFile, "Produced by Jack Dongarra and Piotr Luszczek\n" ); fprintf( outputFile, "Innovative Computing Laboratory\n" ); fprintf( outputFile, "University of Tennessee Knoxville and Oak Ridge National Laboratory\n\n" ); fprintf( outputFile, "See the source files for authors of specific codes.\n" ); fprintf( outputFile, "Compiled on %s at %s\n", __DATE__ , __TIME__ ); fprintf( outputFile, "Current time (%ld) is %s\n",(long)currentTime,ctime(&currentTime)); fprintf( outputFile, "Hostname: '%s'\n", hostname ); fprintf( outputFile, "########################################################################\n" ); END_IO( myRank, outputFile ); params->Failure = 0; HPCC_InitHPL( params ); / HPL calls exit() if there is a problem / HPCC_InputFileInit( params ); params->RunHPL = 0; params->RunStarDGEMM = 0; params->RunSingleDGEMM = 0; params->RunPTRANS = 0; params->RunStarStream = 0; params->RunSingleStream = 0; params->RunMPIRandomAccess_LCG = 0; params->RunStarRandomAccess_LCG = 0; params->RunSingleRandomAccess_LCG = 0; params->RunMPIRandomAccess = 0; params->RunStarRandomAccess = 0; params->RunSingleRandomAccess = 0; params->RunLatencyBandwidth = 0; params->RunMPIFFT = 0; params->RunStarFFT = 0; params->RunSingleFFT = 0; params->RunHPL = params->RunStarDGEMM = params->RunSingleDGEMM = params->RunPTRANS = params->RunStarStream = params->RunSingleStream = params->RunMPIRandomAccess_LCG = params->RunStarRandomAccess_LCG = params->RunSingleRandomAccess_LCG = params->RunMPIRandomAccess = params->RunStarRandomAccess = params->RunSingleRandomAccess = params->RunMPIFFT = params->RunStarFFT = params->RunSingleFFT = params->RunLatencyBandwidth = 1; params->MPIRandomAccess_LCG_GUPs = params->MPIRandomAccess_GUPs = params->StarGUPs = params->SingleGUPs = params->StarDGEMMGflops = params->SingleDGEMMGflops = -1.0; params->StarStreamCopyGBs = params->StarStreamScaleGBs = params->StarStreamAddGBs = params->StarStreamTriadGBs = params->SingleStreamCopyGBs = params->SingleStreamScaleGBs = params->SingleStreamAddGBs = params->SingleStreamTriadGBs = params->SingleFFTGflops = params->StarFFTGflops = params->MPIFFTGflops = params->MPIFFT_maxErr = params->MaxPingPongLatency = params-> RandomlyOrderedRingLatency = params-> MinPingPongBandwidth = params->NaturallyOrderedRingBandwidth = params->RandomlyOrderedRingBandwidth = params->MinPingPongLatency = params->AvgPingPongLatency = params->MaxPingPongBandwidth = params->AvgPingPongBandwidth = params->NaturallyOrderedRingLatency = -1.0; params->HPLrdata.Gflops = -1000.0; params->HPLrdata.time = params->HPLrdata.eps = params->HPLrdata.RnormI = params->HPLrdata.Anorm1 = params->HPLrdata.AnormI = params->HPLrdata.Xnorm1 = params->HPLrdata.XnormI = -1.0; params->HPLrdata.N = params->HPLrdata.NB = params->HPLrdata.nprow = params->HPLrdata.npcol = params->HPLrdata.depth = params->HPLrdata.nbdiv = params->HPLrdata.nbmin = -1; params->HPLrdata.cpfact = params->HPLrdata.crfact = params->HPLrdata.ctop = params->HPLrdata.order = '-'; params->PTRANSrdata.GBs = params->PTRANSrdata.time = params->PTRANSrdata.residual = -1.0; params->PTRANSrdata.n = params->PTRANSrdata.nb = params->PTRANSrdata.nprow = params->PTRANSrdata.npcol = -1; params->MPIRandomAccess_LCG_ErrorsFraction = params->MPIRandomAccess_ErrorsFraction = params->MPIRandomAccess_LCG_time = params->MPIRandomAccess_LCG_CheckTime = params->MPIRandomAccess_time = params->MPIRandomAccess_CheckTime = params->MPIRandomAccess_LCG_TimeBound = params->MPIRandomAccess_TimeBound = -1.0; params->DGEMM_N = params->FFT_N = params->StreamVectorSize = params->MPIRandomAccess_LCG_Algorithm = params->MPIRandomAccess_Algorithm = params->MPIFFT_Procs = -1; params->StreamThreads = 1; params->FFTEnblk = params->FFTEnp = params->FFTEl2size = -1; params->MPIFFT_N = params->RandomAccess_LCG_N = params->MPIRandomAccess_LCG_N = params->MPIRandomAccess_LCG_Errors = params->RandomAccess_N = params->MPIRandomAccess_N = params->MPIRandomAccess_Errors = params->MPIRandomAccess_LCG_ExeUpdates = params->MPIRandomAccess_ExeUpdates = (s64Int)(-1); procMax = procMin = params->pval[0] params->qval[0]; for (i = 1; i < params->npqs; ++i) { procCur = params->pval[i] * params->qval[i]; if (procMax < procCur) procMax = procCur; if (procMin > procCur) procMin = procCur; } params->HPLMaxProc = procMax; params->HPLMinProc = procMin; nMax = params->nval[iiamax( params->ns, params->nval, 1 )]; /* totalMem = (nMaxnMax) sizeof(double) / totalMem = nMax; totalMem = nMax; totalMem = sizeof(double); params->HPLMaxProcMem = totalMem / procMin; for (i = 0; i < MPIFFT_TIMING_COUNT; i++) params->MPIFFTtimingsForward[i] = 0.0; i = iiamax( params->PTRANSnbs, params->PTRANSnbval, 1 ); nbMax = params->PTRANSnbval[i]; #ifdef HPCC_MEMALLCTR MaxMem( commSize, 0, 0, params->PTRANSns, params->PTRANSnval, params->PTRANSnval, params->PTRANSnbs, params->PTRANSnbval, params->PTRANSnbval, params->PTRANSnpqs, params->PTRANSpval, params->PTRANSqval, &dMemSize ); ptrans_mem = dMemSize sizeof(double) + 3 * commSize * sizeof(int); hpl_mem = params->HPLMaxProcMem + (nMax + nbMax) * sizeof(double) * nbMax; HPCC_alloc_init( Mmax( ptrans_mem, hpl_mem ) ); #endif return 0; } int HPCC_Finalize(HPCC_Params params) { int myRank, commSize; int i; FILE outputFile; MPI_Comm comm = MPI_COMM_WORLD; time_t currentTime; #ifdef HPCC_MEMALLCTR HPCC_alloc_finalize(); #endif time( &currentTime ); MPI_Comm_rank( comm, &myRank ); MPI_Comm_size( comm, &commSize ); BEGIN_IO(myRank, params->outFname, outputFile); fprintf( outputFile, "Begin of Summary section.\n" ); fprintf( outputFile, "VersionMajor=%d\n", HPCC_VERSION_MAJOR ); fprintf( outputFile, "VersionMinor=%d\n", HPCC_VERSION_MINOR ); fprintf( outputFile, "VersionMicro=%d\n", HPCC_VERSION_MICRO ); fprintf( outputFile, "VersionRelease=%c\n", HPCC_VERSION_RELEASE ); fprintf( outputFile, "LANG=%s\n", "C" ); fprintf( outputFile, "Success=%d\n", params->Failure ? 0 : 1 ); fprintf( outputFile, "sizeof_char=%d\n", (int)sizeof(char) ); fprintf( outputFile, "sizeof_short=%d\n", (int)sizeof(short) ); fprintf( outputFile, "sizeof_int=%d\n", (int)sizeof(int) ); fprintf( outputFile, "sizeof_long=%d\n", (int)sizeof(long) ); fprintf( outputFile, "sizeof_void_ptr=%d\n", (int)sizeof(void) ); fprintf( outputFile, "sizeof_size_t=%d\n", (int)sizeof(size_t) ); fprintf( outputFile, "sizeof_float=%d\n", (int)sizeof(float) ); fprintf( outputFile, "sizeof_double=%d\n", (int)sizeof(double) ); fprintf( outputFile, "sizeof_s64Int=%d\n", (int)sizeof(s64Int) ); fprintf( outputFile, "sizeof_u64Int=%d\n", (int)sizeof(u64Int) ); fprintf( outputFile, "sizeof_struct_double_double=%d\n", (int)sizeof(struct{double HPCC_r,HPCC_i;}) ); fprintf( outputFile, "CommWorldProcs=%d\n", commSize ); fprintf( outputFile, "MPI_Wtick=%e\n", MPI_Wtick() ); fprintf( outputFile, "HPL_Tflops=%g\n", params->HPLrdata.Gflops 1e-3 ); fprintf( outputFile, "HPL_time=%g\n", params->HPLrdata.time ); fprintf( outputFile, "HPL_eps=%g\n", params->HPLrdata.eps ); fprintf( outputFile, "HPL_RnormI=%g\n", params->HPLrdata.RnormI ); fprintf( outputFile, "HPL_Anorm1=%g\n", params->HPLrdata.Anorm1 ); fprintf( outputFile, "HPL_AnormI=%g\n", params->HPLrdata.AnormI ); fprintf( outputFile, "HPL_Xnorm1=%g\n", params->HPLrdata.Xnorm1 ); fprintf( outputFile, "HPL_XnormI=%g\n", params->HPLrdata.XnormI ); fprintf( outputFile, "HPL_BnormI=%g\n", params->HPLrdata.BnormI ); fprintf( outputFile, "HPL_N=%d\n", params->HPLrdata.N ); fprintf( outputFile, "HPL_NB=%d\n", params->HPLrdata.NB ); fprintf( outputFile, "HPL_nprow=%d\n", params->HPLrdata.nprow ); fprintf( outputFile, "HPL_npcol=%d\n", params->HPLrdata.npcol ); fprintf( outputFile, "HPL_depth=%d\n", params->HPLrdata.depth ); fprintf( outputFile, "HPL_nbdiv=%d\n", params->HPLrdata.nbdiv ); fprintf( outputFile, "HPL_nbmin=%d\n", params->HPLrdata.nbmin ); fprintf( outputFile, "HPL_cpfact=%c\n", params->HPLrdata.cpfact ); fprintf( outputFile, "HPL_crfact=%c\n", params->HPLrdata.crfact ); fprintf( outputFile, "HPL_ctop=%c\n", params->HPLrdata.ctop ); fprintf( outputFile, "HPL_order=%c\n", params->HPLrdata.order ); fprintf( outputFile, "HPL_dMACH_EPS=%e\n", HPL_dlamch( HPL_MACH_EPS ) ); fprintf( outputFile, "HPL_dMACH_SFMIN=%e\n",HPL_dlamch( HPL_MACH_SFMIN ) ); fprintf( outputFile, "HPL_dMACH_BASE=%e\n", HPL_dlamch( HPL_MACH_BASE ) ); fprintf( outputFile, "HPL_dMACH_PREC=%e\n", HPL_dlamch( HPL_MACH_PREC ) ); fprintf( outputFile, "HPL_dMACH_MLEN=%e\n", HPL_dlamch( HPL_MACH_MLEN ) ); fprintf( outputFile, "HPL_dMACH_RND=%e\n", HPL_dlamch( HPL_MACH_RND ) ); fprintf( outputFile, "HPL_dMACH_EMIN=%e\n", HPL_dlamch( HPL_MACH_EMIN ) ); fprintf( outputFile, "HPL_dMACH_RMIN=%e\n", HPL_dlamch( HPL_MACH_RMIN ) ); fprintf( outputFile, "HPL_dMACH_EMAX=%e\n", HPL_dlamch( HPL_MACH_EMAX ) ); fprintf( outputFile, "HPL_dMACH_RMAX=%e\n", HPL_dlamch( HPL_MACH_RMAX ) ); fprintf( outputFile, "HPL_sMACH_EPS=%e\n", (double)HPL_slamch( HPL_MACH_EPS ) ); fprintf( outputFile, "HPL_sMACH_SFMIN=%e\n",(double)HPL_slamch( HPL_MACH_SFMIN ) ); fprintf( outputFile, "HPL_sMACH_BASE=%e\n", (double)HPL_slamch( HPL_MACH_BASE ) ); fprintf( outputFile, "HPL_sMACH_PREC=%e\n", (double)HPL_slamch( HPL_MACH_PREC ) ); fprintf( outputFile, "HPL_sMACH_MLEN=%e\n", (double)HPL_slamch( HPL_MACH_MLEN ) ); fprintf( outputFile, "HPL_sMACH_RND=%e\n", (double)HPL_slamch( HPL_MACH_RND ) ); fprintf( outputFile, "HPL_sMACH_EMIN=%e\n", (double)HPL_slamch( HPL_MACH_EMIN ) ); fprintf( outputFile, "HPL_sMACH_RMIN=%e\n", (double)HPL_slamch( HPL_MACH_RMIN ) ); fprintf( outputFile, "HPL_sMACH_EMAX=%e\n", (double)HPL_slamch( HPL_MACH_EMAX ) ); fprintf( outputFile, "HPL_sMACH_RMAX=%e\n", (double)HPL_slamch( HPL_MACH_RMAX ) ); fprintf( outputFile, "dweps=%e\n", HPCC_dweps() ); fprintf( outputFile, "sweps=%e\n", (double)HPCC_sweps() ); fprintf( outputFile, "HPLMaxProcs=%d\n", params->HPLMaxProc ); fprintf( outputFile, "HPLMinProcs=%d\n", params->HPLMinProc ); fprintf( outputFile, "DGEMM_N=%d\n", params->DGEMM_N ); fprintf( outputFile, "StarDGEMM_Gflops=%g\n", params->StarDGEMMGflops ); fprintf( outputFile, "SingleDGEMM_Gflops=%g\n", params->SingleDGEMMGflops ); fprintf( outputFile, "PTRANS_GBs=%g\n", params->PTRANSrdata.GBs ); fprintf( outputFile, "PTRANS_time=%g\n", params->PTRANSrdata.time ); fprintf( outputFile, "PTRANS_residual=%g\n", params->PTRANSrdata.residual ); fprintf( outputFile, "PTRANS_n=%d\n", params->PTRANSrdata.n ); fprintf( outputFile, "PTRANS_nb=%d\n", params->PTRANSrdata.nb ); fprintf( outputFile, "PTRANS_nprow=%d\n", params->PTRANSrdata.nprow ); fprintf( outputFile, "PTRANS_npcol=%d\n", params->PTRANSrdata.npcol ); fprintf( outputFile, "MPIRandomAccess_LCG_N=" FSTR64 "\n", params->MPIRandomAccess_LCG_N ); fprintf( outputFile, "MPIRandomAccess_LCG_time=%g\n", params->MPIRandomAccess_LCG_time ); fprintf( outputFile, "MPIRandomAccess_LCG_CheckTime=%g\n", params->MPIRandomAccess_LCG_CheckTime ); fprintf( outputFile, "MPIRandomAccess_LCG_Errors=" FSTR64 "\n", params->MPIRandomAccess_LCG_Errors ); fprintf( outputFile, "MPIRandomAccess_LCG_ErrorsFraction=%g\n", params->MPIRandomAccess_LCG_ErrorsFraction ); fprintf( outputFile, "MPIRandomAccess_LCG_ExeUpdates=" FSTR64 "\n", params->MPIRandomAccess_LCG_ExeUpdates ); fprintf( outputFile, "MPIRandomAccess_LCG_GUPs=%g\n", params->MPIRandomAccess_LCG_GUPs ); fprintf( outputFile, "MPIRandomAccess_LCG_TimeBound=%g\n", params->MPIRandomAccess_LCG_TimeBound ); fprintf( outputFile, "MPIRandomAccess_LCG_Algorithm=%d\n", params->MPIRandomAccess_LCG_Algorithm ); fprintf( outputFile, "MPIRandomAccess_N=" FSTR64 "\n", params->MPIRandomAccess_N ); fprintf( outputFile, "MPIRandomAccess_time=%g\n", params->MPIRandomAccess_time ); fprintf( outputFile, "MPIRandomAccess_CheckTime=%g\n", params->MPIRandomAccess_CheckTime ); fprintf( outputFile, "MPIRandomAccess_Errors=" FSTR64 "\n", params->MPIRandomAccess_Errors ); fprintf( outputFile, "MPIRandomAccess_ErrorsFraction=%g\n", params->MPIRandomAccess_ErrorsFraction ); fprintf( outputFile, "MPIRandomAccess_ExeUpdates=" FSTR64 "\n", params->MPIRandomAccess_ExeUpdates ); fprintf( outputFile, "MPIRandomAccess_GUPs=%g\n", params->MPIRandomAccess_GUPs ); fprintf( outputFile, "MPIRandomAccess_TimeBound=%g\n", params->MPIRandomAccess_TimeBound ); fprintf( outputFile, "MPIRandomAccess_Algorithm=%d\n", params->MPIRandomAccess_Algorithm ); fprintf( outputFile, "RandomAccess_LCG_N=" FSTR64 "\n", params->RandomAccess_LCG_N ); fprintf( outputFile, "StarRandomAccess_LCG_GUPs=%g\n", params->Star_LCG_GUPs ); fprintf( outputFile, "SingleRandomAccess_LCG_GUPs=%g\n", params->Single_LCG_GUPs ); fprintf( outputFile, "RandomAccess_N=" FSTR64 "\n", params->RandomAccess_N ); fprintf( outputFile, "StarRandomAccess_GUPs=%g\n", params->StarGUPs ); fprintf( outputFile, "SingleRandomAccess_GUPs=%g\n", params->SingleGUPs ); fprintf( outputFile, "STREAM_VectorSize=%d\n", params->StreamVectorSize ); fprintf( outputFile, "STREAM_Threads=%d\n", params->StreamThreads ); fprintf( outputFile, "StarSTREAM_Copy=%g\n", params->StarStreamCopyGBs ); fprintf( outputFile, "StarSTREAM_Scale=%g\n", params->StarStreamScaleGBs ); fprintf( outputFile, "StarSTREAM_Add=%g\n", params->StarStreamAddGBs ); fprintf( outputFile, "StarSTREAM_Triad=%g\n", params->StarStreamTriadGBs ); fprintf( outputFile, "SingleSTREAM_Copy=%g\n", params->SingleStreamCopyGBs ); fprintf( outputFile, "SingleSTREAM_Scale=%g\n", params->SingleStreamScaleGBs ); fprintf( outputFile, "SingleSTREAM_Add=%g\n", params->SingleStreamAddGBs ); fprintf( outputFile, "SingleSTREAM_Triad=%g\n", params->SingleStreamTriadGBs ); fprintf( outputFile, "FFT_N=%d\n", params->FFT_N ); fprintf( outputFile, "StarFFT_Gflops=%g\n", params->StarFFTGflops ); fprintf( outputFile, "SingleFFT_Gflops=%g\n", params->SingleFFTGflops ); fprintf( outputFile, "MPIFFT_N=" FSTR64 "\n", params->MPIFFT_N ); fprintf( outputFile, "MPIFFT_Gflops=%g\n", params->MPIFFTGflops ); fprintf( outputFile, "MPIFFT_maxErr=%g\n", params->MPIFFT_maxErr ); fprintf( outputFile, "MPIFFT_Procs=%d\n", params->MPIFFT_Procs ); fprintf( outputFile, "MaxPingPongLatency_usec=%g\n", params->MaxPingPongLatency ); fprintf( outputFile, "RandomlyOrderedRingLatency_usec=%g\n", params->RandomlyOrderedRingLatency ); fprintf( outputFile, "MinPingPongBandwidth_GBytes=%g\n", params->MinPingPongBandwidth ); fprintf( outputFile, "NaturallyOrderedRingBandwidth_GBytes=%g\n", params->NaturallyOrderedRingBandwidth ); fprintf( outputFile, "RandomlyOrderedRingBandwidth_GBytes=%g\n", params->RandomlyOrderedRingBandwidth ); fprintf( outputFile, "MinPingPongLatency_usec=%g\n", params->MinPingPongLatency ); fprintf( outputFile, "AvgPingPongLatency_usec=%g\n", params->AvgPingPongLatency ); fprintf( outputFile, "MaxPingPongBandwidth_GBytes=%g\n", params->MaxPingPongBandwidth ); fprintf( outputFile, "AvgPingPongBandwidth_GBytes=%g\n", params->AvgPingPongBandwidth ); fprintf( outputFile, "NaturallyOrderedRingLatency_usec=%g\n", params->NaturallyOrderedRingLatency ); fprintf( outputFile, "FFTEnblk=%d\n", params->FFTEnblk ); fprintf( outputFile, "FFTEnp=%d\n", params->FFTEnp ); fprintf( outputFile, "FFTEl2size=%d\n", params->FFTEl2size ); #ifdef _OPENMP fprintf( outputFile, "M_OPENMP=%ld\n", (long)(_OPENMP) ); #pragma omp parallel { #pragma omp single nowait { fprintf( outputFile, "omp_get_num_threads=%d\n", omp_get_num_threads() ); fprintf( outputFile, "omp_get_max_threads=%d\n", omp_get_max_threads() ); fprintf( outputFile, "omp_get_num_procs=%d\n", omp_get_num_procs() ); } } #else fprintf( outputFile, "M_OPENMP=%ld\n", -1L ); fprintf( outputFile, "omp_get_num_threads=%d\n", 0 ); fprintf( outputFile, "omp_get_max_threads=%d\n", 0 ); fprintf( outputFile, "omp_get_num_procs=%d\n", 0 ); #endif fprintf( outputFile, "MemProc=%g\n", HPCC_MemProc ); fprintf( outputFile, "MemSpec=%d\n", HPCC_MemSpec ); fprintf( outputFile, "MemVal=%g\n", HPCC_MemVal ); for (i = 0; i < MPIFFT_TIMING_COUNT - 1; i++) fprintf( outputFile, "MPIFFT_time%d=%g\n", i, params->MPIFFTtimingsForward[i+1] - params->MPIFFTtimingsForward[i] ); /* CPS: C Preprocessor Symbols / i = 0; #ifdef HPCC_FFT_235 i = 1; #endif fprintf( outputFile, "CPS_HPCC_FFT_235=%d\n", i ); i = 0; #ifdef HPCC_FFTW_ESTIMATE i = 1; #endif fprintf( outputFile, "CPS_HPCC_FFTW_ESTIMATE=%d\n", i ); i = 0; #ifdef HPCC_MEMALLCTR i = 1; #endif fprintf( outputFile, "CPS_HPCC_MEMALLCTR=%d\n", i ); i = 0; #ifdef HPL_USE_GETPROCESSTIMES i = 1; #endif fprintf( outputFile, "CPS_HPL_USE_GETPROCESSTIMES=%d\n", i ); i = 0; #ifdef RA_SANDIA_NOPT i = 1; #endif fprintf( outputFile, "CPS_RA_SANDIA_NOPT=%d\n", i ); i = 0; #ifdef RA_SANDIA_OPT2 i = 1; #endif fprintf( outputFile, "CPS_RA_SANDIA_OPT2=%d\n", i ); i = 0; #ifdef USING_FFTW i = 1; #endif fprintf( outputFile, "CPS_USING_FFTW=%d\n", i ); fprintf( outputFile, "End of Summary section.%s\n", "" ); fprintf( outputFile, "########################################################################\n" ); fprintf( outputFile, "End of HPC Challenge tests.\n" ); fprintf( outputFile, "Current time (%ld) is %s\n",(long)currentTime,ctime(&currentTime)); fprintf( outputFile, "########################################################################\n" ); END_IO( myRank, outputFile ); return 0; } int HPCC_LocalVectorSize(HPCC_Params params, int vecCnt, size_t size, int pow2) { int flg2, maxIntBits2; /* this is the maximum power of 2 that that can be held in a signed integer (for a 4-byte integer, 2*31-1 is the maximum integer, so the maximum power of 2 is 30) / maxIntBits2 = sizeof(int) * 8 - 2; /* flg2 = floor(log2(params->HPLMaxProcMem / size / vecCnt)) / for (flg2 = 1; params->HPLMaxProcMem / size / vecCnt >> flg2; ++flg2) ; / EMPTY / --flg2; if (flg2 <= maxIntBits2) { if (pow2) return 1 << flg2; return params->HPLMaxProcMem / size / vecCnt; } return 1 << maxIntBits2; } int HPCC_ProcessGrid(int P, int Q, MPI_Comm comm) { int myRank, commSize; int i, p, q, nproc; MPI_Comm_size( comm, &commSize ); MPI_Comm_rank( comm, &myRank ); for (nproc = commSize; ; --nproc) { / this loop makes at most two iterations / for (i = (int)sqrt( nproc ); i > 1; --i) { q = nproc / i; p = nproc / q; if (p q == nproc) { P = p; Q = q; return 0; } } /* if the code gets here `nproc' is small or is a prime / if (nproc < 20) { / do 1D grid for small process counts / P = 1; Q = nproc; return 0; } } return 0; } size_t HPCC_Memory(MPI_Comm comm) { int myRank, commSize; int num_threads; char memFile[13] = "hpccmemf.txt"; char buf[HPL_LINE_MAX]; int nbuf = HPL_LINE_MAX; char sVal; FILE f; double mult, mval, procMem; size_t rv; mult = 1.0; num_threads = 1; MPI_Comm_size( comm, &commSize ); MPI_Comm_rank( comm, &myRank ); #ifdef _OPENMP #pragma omp parallel { #pragma omp single nowait { num_threads = omp_get_num_threads(); } } #endif if (myRank == 0) { procMem = 64; f = fopen( memFile, "r" ); if (f) { if (fgets( buf, nbuf, f )) { if (strncmp( "Total=", buf, 6 ) == 0) { mult = 1.0 / commSize; sVal = buf + 6; HPCC_MemSpec = 1; } else if (strncmp( "Thread=", buf, 7 ) == 0) { mult = num_threads; sVal = buf + 7; HPCC_MemSpec = 2; } else if (strncmp( "Process=", buf, 8 ) == 0) { mult = 1.0; sVal = buf + 8; HPCC_MemSpec = 3; } else sVal = NULL; if (sVal && 1 == sscanf( sVal, "%lf", &mval )) { procMem = mval mult; HPCC_MemVal = mval; } } fclose( f ); } } MPI_Bcast( &procMem, 1, MPI_DOUBLE, 0, comm ); rv = procMem; rv = 1024; rv = 1024; HPCC_MemProc = procMem; return rv; } int HPCC_Defaults(HPL_T_test TEST, int NS, int N, int NBS, int NB, HPL_T_ORDER PMAPPIN, int NPQS, int P, int Q, int NPFS, HPL_T_FACT PF, int NBMS, int NBM, int NDVS, int NDV, int NRFS, HPL_T_FACT RF, int NTPS, HPL_T_TOP TP, int NDHS, int DH, HPL_T_SWAP FSWAP, int TSWAP, int L1NOTRAN, int UNOTRAN, int EQUIL, int ALIGN, MPI_Comm comm) { int nb = 80; double memFactor = 0.8; NS = NBS = NPQS = NPFS = NBMS = NDVS = NRFS = NTPS = NDHS = 1; TEST->thrsh = 16.0; NB = nb; PMAPPIN = HPL_COLUMN_MAJOR; HPCC_ProcessGrid( P, Q, comm ); N = (int)sqrt( memFactor (double)(P Q) (double)(HPCC_Memory( comm ) / sizeof(double)) ) / (2 * nb); N = 2nb; / make N multiple of 2nb so both HPL and PTRANS see matrix dimension divisible by nb / PF = HPL_RIGHT_LOOKING; NBM = 4; NDV = 2; RF = HPL_CROUT; TP = HPL_1RING_M; DH = 1; FSWAP = HPL_SW_MIX; TSWAP = 64; L1NOTRAN = 0; UNOTRAN = 0; EQUIL = 1; ALIGN = 8; return 0; } #ifdef XERBLA_MISSING #ifdef Add_ #define F77xerbla xerbla_ #endif #ifdef Add__ #define F77xerbla xerbla__ #endif #ifdef NoChange #define F77xerbla xerbla #endif #ifdef UpCase #define F77xerbla XERBLA #endif #ifdef f77IsF2C #define F77xerbla xerbla_ #endif void F77xerbla(char srname, F77_INTEGER info, long srname_len) { /* int i; char Cname[7]; for (i = 0; i < 6; i++) Cname[i] = srname[i]; Cname[6] = 0; printf("xerbla(%d)\n", info); / printf("xerbla()\n"); fflush(stdout); } #endif #ifdef HPCC_MEMALLCTR #define MEM_MAXCNT 7 typedef double Mem_t; static Mem_t Mem_base; static size_t Mem_dsize; / Each entry can be in one of three states: 1. Full (holds a block of allocated memory) if: ptr != NULL; size > 0; free == 0 2. Free (holds block of unallocated memory) if: ptr != NULL; free = 1 3 Empty (doesn't hold a block of memory) if: ptr == NULL; free = 1 / typedef struct { Mem_t Mem_ptr; size_t Mem_size; int Mem_free; } Mem_entry_t; static Mem_entry_t Mem_blocks[MEM_MAXCNT]; static void HPCC_alloc_set_empty(int idx) { int i, n0, n; if (MEM_MAXCNT == idx) { n0 = 0; n = idx; } else { n0 = idx; n = idx + 1; } /* initialize all blocks to empty / for (i = n0; i < n; ++i) { Mem_blocks[i].Mem_ptr = (Mem_t )(NULL); Mem_blocks[i].Mem_size = 0; Mem_blocks[i].Mem_free = 1; } } static void HPCC_alloc_set_free(int idx, Mem_t dptr, size_t size) { Mem_blocks[idx].Mem_ptr = dptr; Mem_blocks[idx].Mem_size = size; Mem_blocks[idx].Mem_free = 1; } int HPCC_alloc_init(size_t total_size) { size_t dsize; Mem_dsize = dsize = Mceil( total_size, sizeof(Mem_t) ); Mem_base = (Mem_t )malloc( dsize * sizeof(Mem_t) ); HPCC_alloc_set_empty( MEM_MAXCNT ); if (Mem_base) { HPCC_alloc_set_free( 0, Mem_base, dsize ); return 0; } return -1; } int HPCC_alloc_finalize() { free( Mem_base ); HPCC_alloc_set_empty( MEM_MAXCNT ); return 0; } void * HPCC_malloc(size_t size) { size_t dsize, diff_size, cur_diff_size; int i, cur_best, cur_free; dsize = Mceil( size, sizeof(Mem_t) ); cur_diff_size = Mem_dsize + 1; cur_free = cur_best = MEM_MAXCNT; for (i = 0; i < MEM_MAXCNT; ++i) { /* skip full spots / if (! Mem_blocks[i].Mem_free) continue; / find empty spot / if (! Mem_blocks[i].Mem_ptr) { cur_free = i; continue; } diff_size = Mem_blocks[i].Mem_size - dsize; if (Mem_blocks[i].Mem_size >= dsize && diff_size < cur_diff_size) { / a match that's the best (so far) was found / cur_diff_size = diff_size; cur_best = i; } } / found a match / if (cur_best < MEM_MAXCNT) { if (cur_free < MEM_MAXCNT && cur_diff_size > 0) { / create a new free block / HPCC_alloc_set_free( cur_free, Mem_blocks[cur_best].Mem_ptr + dsize, cur_diff_size ); Mem_blocks[cur_best].Mem_size = dsize; / shrink the best match / } Mem_blocks[cur_best].Mem_free = 0; return (void )(Mem_blocks[cur_best].Mem_ptr); } return NULL; } void HPCC_free(void ptr) { Mem_t dptr = (Mem_t )ptr; int cur_blk = MEM_MAXCNT, made_changes, i, j; / look for the block being freed / for (i = 0; i < MEM_MAXCNT; ++i) { if (Mem_blocks[i].Mem_free) continue; if (Mem_blocks[i].Mem_ptr == dptr) { cur_blk = i; break; } } / not finding the pointer (including NULL) causes abort / if (MEM_MAXCNT == cur_blk) { HPL_pabort( __LINE__, "HPCC_free", "Unknown pointer in HPCC_free()." ); } / double-free causes abort / if (1 == Mem_blocks[cur_blk].Mem_free) { HPL_pabort( __LINE__, "HPCC_free", "Second call to HPCC_free() with the same pointer." ); } Mem_blocks[cur_blk].Mem_free = 1; / merge as many blocks as possible / for (made_changes = 1; made_changes;) { made_changes = 0; for (i = 0; i < MEM_MAXCNT; ++i) { / empty or full blocks can't be merged / if (! Mem_blocks[i].Mem_free \|\| ! Mem_blocks[i].Mem_ptr) continue; for (j = 0; j < MEM_MAXCNT; ++j) { / empty or occupied blocks can't be merged */ if (! Mem_blocks[j].Mem_free \|\| ! Mem_blocks[j].Mem_ptr) continue; if (Mem_blocks[i].Mem_ptr + Mem_blocks[i].Mem_size == Mem_blocks[j].Mem_ptr) { Mem_blocks[i].Mem_size += Mem_blocks[j].Mem_size; HPCC_alloc_set_empty( j ); made_changes = 1; } } } } } #endif
graph.h	// copyright (c) 2015, The Regents of the University of California (Regents) // See LICENSE.txt for license details #ifndef GRAPH_H_ #define GRAPH_H_ #include <stdio.h> #include <cinttypes> #include <iostream> #include <type_traits> #include <map> #include "pvector.h" #include "util.h" #include "segmentgraph.h" /* GAP Benchmark Suite Class: CSRGraph Author: Scott Beamer Simple container for graph in CSR format - Intended to be constructed by a Builder - To make weighted, set DestID_ template type to NodeWeight - MakeInverse parameter controls whether graph stores its inverse / // Used to hold node & weight, with another node it makes a weighted edge template <typename NodeID_=int32_t, typename WeightT_=int32_t> struct NodeWeight { NodeID_ v; WeightT_ w; NodeWeight() {} NodeWeight(NodeID_ v) : v(v), w(1) {} NodeWeight(NodeID_ v, WeightT_ w) : v(v), w(w) {} bool operator< (const NodeWeight& rhs) const { return v == rhs.v ? w < rhs.w : v < rhs.v; } // doesn't check WeightT_s, needed to remove duplicate edges bool operator== (const NodeWeight& rhs) const { return v == rhs.v; } // doesn't check WeightT_s, needed to remove self edges bool operator== (const NodeID_& rhs) const { return v == rhs; } operator NodeID_() { return v; } }; template <typename NodeID_, typename WeightT_> std::ostream& operator<<(std::ostream& os, const NodeWeight<NodeID_, WeightT_>& nw) { os << nw.v << " " << nw.w; return os; } template <typename NodeID_, typename WeightT_> std::istream& operator>>(std::istream& is, NodeWeight<NodeID_, WeightT_>& nw) { is >> nw.v >> nw.w; return is; } // Syntatic sugar for an edge template <typename SrcT, typename DstT = SrcT> struct EdgePair { SrcT u; DstT v; EdgePair() {} EdgePair(SrcT u, DstT v) : u(u), v(v) {} }; // SG = serialized graph, these types are for writing graph to file typedef int32_t SGID; typedef EdgePair<SGID> SGEdge; typedef int64_t SGOffset; template <class NodeID_, class DestID_ = NodeID_, bool MakeInverse = true> class CSRGraph { // Used to access neighbors of vertex, basically sugar for iterators class Neighborhood { NodeID_ n_; DestID_* g_index_; public: Neighborhood(NodeID_ n, DestID_** g_index) : n_(n), g_index_(g_index) {} typedef DestID_* iterator; iterator begin() { return g_index_[n_]; } iterator end() { return g_index_[n_+1]; } }; void ReleaseResources() { //added a second condition to prevent double free (transpose graphs) if (out_index_ != nullptr) delete[] out_index_; if (out_neighbors_ != nullptr) delete[] out_neighbors_; if (directed_) { if (in_index_ != nullptr) delete[] in_index_; if (in_neighbors_ != nullptr) delete[] in_neighbors_; } if (flags_ != nullptr) delete[] flags_; for (auto iter = label_to_segment.begin(); iter != label_to_segment.end(); iter++) { delete ((iter).second); } } public: CSRGraph() : directed_(false), num_nodes_(-1), num_edges_(-1), out_index_(nullptr), out_neighbors_(nullptr), in_index_(nullptr), in_neighbors_(nullptr), flags_(nullptr), is_transpose_(false) {} CSRGraph(int64_t num_nodes, DestID_* index, DestID_* neighs) : directed_(false), num_nodes_(num_nodes), out_index_(index), out_neighbors_(neighs), in_index_(index), in_neighbors_(neighs) { num_edges_ = (out_index_[num_nodes_] - out_index_[0]) / 2; //adding flags used for deduplication flags_ = new int[num_nodes_]; //adding offsets for load balacne scheme SetUpOffsets(true); } CSRGraph(int64_t num_nodes, DestID_** out_index, DestID_* out_neighs, DestID_** in_index, DestID_* in_neighs) : directed_(true), num_nodes_(num_nodes), out_index_(out_index), out_neighbors_(out_neighs), in_index_(in_index), in_neighbors_(in_neighs), is_transpose_(false) { num_edges_ = out_index_[num_nodes_] - out_index_[0]; flags_ = new int[num_nodes_]; SetUpOffsets(true); } CSRGraph(int64_t num_nodes, DestID_** out_index, DestID_* out_neighs, DestID_** in_index, DestID_* in_neighs, bool is_transpose) : directed_(true), num_nodes_(num_nodes), out_index_(out_index), out_neighbors_(out_neighs), in_index_(in_index), in_neighbors_(in_neighs) , is_transpose_(is_transpose){ num_edges_ = out_index_[num_nodes_] - out_index_[0]; flags_ = new int[num_nodes_]; SetUpOffsets(true); } CSRGraph(CSRGraph&& other) : directed_(other.directed_), num_nodes_(other.num_nodes_), num_edges_(other.num_edges_), out_index_(other.out_index_), out_neighbors_(other.out_neighbors_), in_index_(other.in_index_), in_neighbors_(other.in_neighbors_), is_transpose_(false) { other.num_edges_ = -1; other.num_nodes_ = -1; other.out_index_ = nullptr; other.out_neighbors_ = nullptr; other.in_index_ = nullptr; other.in_neighbors_ = nullptr; other.flags_ = nullptr; other.offsets_ = nullptr; } ~CSRGraph() { if (!is_transpose_) ReleaseResources(); } CSRGraph& operator=(CSRGraph&& other) { if (this != &other) { if (!is_transpose_) ReleaseResources(); directed_ = other.directed_; num_edges_ = other.num_edges_; num_nodes_ = other.num_nodes_; out_index_ = other.out_index_; out_neighbors_ = other.out_neighbors_; in_index_ = other.in_index_; in_neighbors_ = other.in_neighbors_; other.num_edges_ = -1; other.num_nodes_ = -1; other.out_index_ = nullptr; other.out_neighbors_ = nullptr; other.in_index_ = nullptr; other.in_neighbors_ = nullptr; other.flags_ = nullptr; other.offsets_ = nullptr; } return this; } bool directed() const { return directed_; } int64_t num_nodes() const { return num_nodes_; } int64_t num_edges() const { return num_edges_; } int64_t num_edges_directed() const { return directed_ ? num_edges_ : 2num_edges_; } int64_t out_degree(NodeID_ v) const { return out_index_[v+1] - out_index_[v]; } int64_t in_degree(NodeID_ v) const { static_assert(MakeInverse, "Graph inversion disabled but reading inverse"); return in_index_[v+1] - in_index_[v]; } Neighborhood out_neigh(NodeID_ n) const { return Neighborhood(n, out_index_); } Neighborhood in_neigh(NodeID_ n) const { static_assert(MakeInverse, "Graph inversion disabled but reading inverse"); return Neighborhood(n, in_index_); } void PrintStats() const { std::cout << "Graph has " << num_nodes_ << " nodes and " << num_edges_ << " "; if (!directed_) std::cout << "un"; std::cout << "directed edges for degree: "; std::cout << num_edges_/num_nodes_ << std::endl; } void PrintTopology() const { for (NodeID_ i=0; i < num_nodes_; i++) { std::cout << i << ": "; for (DestID_ j : out_neigh(i)) { std::cout << j << " "; } std::cout << std::endl; } } static DestID_** GenIndex(const pvector<SGOffset> &offsets, DestID_* neighs) { NodeID_ length = offsets.size(); DestID_** index = new DestID_[length]; #pragma omp parallel for for (NodeID_ n=0; n < length; n++) index[n] = neighs + offsets[n]; return index; } pvector<SGOffset> VertexOffsets(bool in_graph = false) const { pvector<SGOffset> offsets(num_nodes_+1); for (NodeID_ n=0; n < num_nodes_+1; n++) if (in_graph) offsets[n] = in_index_[n] - in_index_[0]; else offsets[n] = out_index_[n] - out_index_[0]; return offsets; } void SetUpOffsets(bool in_graph = false) { offsets_ = new SGOffset[num_nodes_+1]; for (NodeID_ n=0; n < num_nodes_+1; n++) if (in_graph) offsets_[n] = in_index_[n] - in_index_[0]; else offsets_[n] = out_index_[n] - out_index_[0]; } Range<NodeID_> vertices() const { return Range<NodeID_>(num_nodes()); } SegmentedGraph<DestID_, NodeID_> getSegmentedGraph(std::string label, int id) { return label_to_segment[label]->getSegmentedGraph(id); } int getNumSegments(std::string label) { return label_to_segment[label]->numSegments; } void buildPullSegmentedGraphs(std::string label, int numSegments, bool numa_aware=false, std::string path="") { auto graphSegments = new GraphSegments<DestID_,NodeID_>(numSegments, numa_aware); label_to_segment[label] = graphSegments; #ifdef LOADSEG cout << "loading segmented graph from " << path << endl; #pragma omp parallel for num_threads(numSegments) for (int i = 0; i < numSegments; i++) { FILE in; in = fopen((path + "/" + std::to_string(i)).c_str(), "r"); auto sg = graphSegments->getSegmentedGraph(i); fread((void ) &sg->numVertices, sizeof(sg->numVertices), 1, in); fread((void ) &sg->numEdges, sizeof(sg->numEdges), 1, in); sg->allocate(i); fread((void ) sg->graphId, sizeof(sg->graphId), sg->numVertices, in); fread((void ) sg->edgeArray, sizeof(sg->edgeArray), sg->numEdges, in); fread((void ) sg->vertexArray, sizeof(sg->vertexArray), sg->numVertices + 1, in); fclose(in); } return; #endif int segmentRange = (num_nodes() + numSegments - 1) / numSegments; //Go through the original graph and count the number of target vertices and edges for each segment for (auto d : vertices()){ for (auto s : in_neigh(d)){ int segment_id; if (std::is_same<DestID_, NodeWeight<>>::value) segment_id = static_cast<NodeWeight<>>(s).v/segmentRange; else segment_id = s/segmentRange; graphSegments->getSegmentedGraph(segment_id)->countEdge(d); } } //Allocate each segment graphSegments->allocate(); //Add the edges for each segment for (auto d : vertices()){ for (auto s : in_neigh(d)){ int segment_id; if (std::is_same<DestID_, NodeWeight<>>::value) segment_id = static_cast<NodeWeight<>>(s).v/segmentRange; else segment_id = s/segmentRange; graphSegments->getSegmentedGraph(segment_id)->addEdge(d, s); } } #ifdef STORESEG cout << "output serialized graph segments to " << path << endl; #pragma omp parallel for num_threads(numSegments) for(int i = 0; i < numSegments; i++) { FILE out = fopen((path + "/" + std::to_string(i)).c_str(), "w"); auto sg = graphSegments->getSegmentedGraph(i); fwrite((void ) &sg->numVertices, sizeof(sg->numVertices), 1, out); fwrite((void ) &sg->numEdges, sizeof(sg->numEdges), 1, out); fwrite((void ) sg->graphId, sizeof(sg->graphId), sg->numVertices, out); fwrite((void ) sg->edgeArray, sizeof(sg->edgeArray), sg->numEdges, out); fwrite((void ) sg->vertexArray, sizeof(sg->vertexArray), sg->numVertices + 1, out); fclose(out); } #endif } //useful for deduplication int* flags_; SGOffset * offsets_; // private: bool is_transpose_; bool directed_; int64_t num_nodes_; int64_t num_edges_; DestID_** out_index_; DestID_* out_neighbors_; DestID_** in_index_; DestID_* in_neighbors_; std::map<std::string, GraphSegments<DestID_,NodeID_>*> label_to_segment; }; #endif // GRAPH_H_
openmp.c	/* * Copyright (c) 2003, 2007-14 Matteo Frigo * Copyright (c) 2003, 2007-14 Massachusetts Institute of Technology * * This program is free software; you can redistribute it and/or modify * it under the terms of the GNU General Public License as published by * the Free Software Foundation; either version 2 of the License, or * (at your option) any later version. * * This program is distributed in the hope that it will be useful, * but WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the * GNU General Public License for more details. * * You should have received a copy of the GNU General Public License * along with this program; if not, write to the Free Software * Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA * / / openmp.c: thread spawning via OpenMP / #include "threads/threads.h" #if !defined(_OPENMP) #error OpenMP enabled but not using an OpenMP compiler #endif int X(ithreads_init)(void) { return 0; / no error / } / Distribute a loop from 0 to loopmax-1 over nthreads threads. proc(d) is called to execute a block of iterations from d->min to d->max-1. d->thr_num indicate the number of the thread that is executing proc (from 0 to nthreads-1), and d->data is the same as the data parameter passed to X(spawn_loop). This function returns only after all the threads have completed. / void X(spawn_loop)(int loopmax, int nthr, spawn_function proc, void data) { int block_size; spawn_data d; int i; A(loopmax >= 0); A(nthr > 0); A(proc); if (!loopmax) return; /* Choose the block size and number of threads in order to (1) minimize the critical path and (2) use the fewest threads that achieve the same critical path (to minimize overhead). e.g. if loopmax is 5 and nthr is 4, we should use only 3 threads with block sizes of 2, 2, and 1. / block_size = (loopmax + nthr - 1) / nthr; nthr = (loopmax + block_size - 1) / block_size; if (X(spawnloop_callback)) { / user-defined spawnloop backend / spawn_data sdata; STACK_MALLOC(spawn_data , sdata, sizeof(spawn_data) nthr); for (i = 0; i < nthr; ++i) { spawn_data d = &sdata[i]; d->max = (d->min = i block_size) + block_size; if (d->max > loopmax) d->max = loopmax; d->thr_num = i; d->data = data; } X(spawnloop_callback)(proc, sdata, sizeof(spawn_data), nthr, X(spawnloop_callback_data)); STACK_FREE(sdata); return; } #pragma omp parallel for private(d) for (i = 0; i < nthr; ++i) { d.max = (d.min = i * block_size) + block_size; if (d.max > loopmax) d.max = loopmax; d.thr_num = i; d.data = data; proc(&d); } } void X(threads_cleanup)(void) { } /* FIXME [Matteo Frigo 2015-05-25] What does "thread-safe" mean for openmp? */ void X(threads_register_planner_hooks)(void) { }
gp.h	#include <iostream> #include <armadillo> #include <omp.h> using namespace std; using namespace arma; //const double pi = M_PI; dmat calc_covariance_matrix(dmat X,float bandwidth=0.01) { bandwidth = 1.0 / (2.0 * pow(bandwidth,2)); int n = X.n_cols; dmat K(n,n,fill::eye); #pragma omp parallel { #pragma omp for for(int i=0;i<n;i++) for(int j=i+1;j<n;j++) { vec diff = X.col(i) - X.col(j); double mean_diff = mean(diff % diff); K(i,j) = exp(-mean_diffbandwidth); K(j,i) = K(i,j); } } return K; } double probit_log_likelihood(vec latent_variables, vec class_labels) { return accu(log(normcdf(latent_variables % class_labels))); } dmat elliptical_slice_sampling(dmat K,vec y,int N_mcmc=100000,int burn_in=1000,int seed=-1,bool verbose=true) { dmat samples; int n = K.n_rows; int N = y.n_elem; if (seed == -1) arma_rng::set_seed_random(); else arma_rng::set_seed(seed); dmat mcmc_samples(burn_in+N_mcmc,N,fill::zeros); dvec mean(n,fill::zeros); dmat norm_samples = mvnrnd(mean,K,burn_in+N_mcmc).t(); dvec unif_samples = randu<dvec>(burn_in+N_mcmc); dvec theta = randu<dvec>(burn_in+N_mcmc)(2.0pi); dvec theta_min = theta - (2.0 pi); dvec theta_max = theta + (2.0 * pi); for(int i=1;i<burn_in+N_mcmc;i++) { if (i < burn_in) { cout << "Burning in...\r"; cout << flush; } else { cout << "Elliptical slice sampling Step " << (i-burn_in+1) << "...\r"; cout << flush; } dvec f = conv_to<dvec>::from(mcmc_samples.row(i-1)); double llh_thresh = probit_log_likelihood(f,y) + log(unif_samples(i)); dvec f_star = f * cos(theta(i)) + norm_samples.row(i).t(); while(probit_log_likelihood(f_star,y) < llh_thresh) { if (theta(i) < 0) theta_min(i) = theta(i); else theta_max(i) = theta(i); theta(i) = randu<double>() * (theta_max(i)-theta_min(i)) + theta_min(i); f_star = f * cos(theta(i)) + norm_samples.row(i).t() * sin(theta(i)); } mcmc_samples.row(i) = f_star.t(); } cout << '\n'; return mcmc_samples.rows(burn_in,burn_in+N_mcmc-1); } dmat sherman_r(dmat A, dvec u, dvec v) { dmat x = v.t() * A * u; dmat B = A * u * v.t() * A; double c = 1.0 / (x(0) + 1.0); return A - B * c; } dvec calc_rate(dmat X, dmat f_draws, bool verbose=true) { dmat beta_draws = (pinv(X) * f_draws.t()).t(); dmat V = cov(beta_draws); dmat D = pinv(V); dmat D_U, D_V; dvec D_s; svd(D_U,D_s,D_V,D); uvec ind = find(D_s > 1e-10); D_U = D_U.cols(ind); dmat U = D_U.each_row() % sqrt(D_s.elem(ind)).t(); dvec mu = conv_to<dvec>::from(mean(beta_draws,0)); mu = abs(mu); dmat Lambda = U * U.t(); dvec kld(mu.n_elem,fill::zeros); for(int q=0;q<mu.n_elem;q++) { if (verbose) cout << "Calculating KLD(" << q << ")...\r"; dvec Vq = conv_to<dvec>::from(V.col(q)); dmat U_Lambda_sub = sherman_r(Lambda,Vq,Vq); dmat U_no_q = U_Lambda_sub; U_no_q.shed_row(q); dmat U_no_qq = U_no_q; U_no_qq.shed_col(q); dvec U_no_q_q = conv_to<dvec>::from(U_no_q.col(q)); dvec alpha = U_no_q_q.t() * U_no_qq * U_no_q_q; kld(q) = pow(mu(q),2.0) * alpha(0) * 0.5; } kld.save("kld.txt",raw_ascii); if (verbose) cout << "KLD calculation Completed.\n"; // Compute the corresponding “RelATive cEntrality” (RATE) measure dvec rates = kld / sum(kld); /// Find the entropic deviation from a uniform distribution //delta = np.sum(ratesnp.log(len(mu)rates)) // Calibrate Delta via the effective sample size (ESS) measures from importance sampling ### // (Gruber and West, 2016, 2017) //eff_samp_size = 1./(1.+delta)*100. return rates; } dmat find_rate_variables_with_other_sampling_methods(dmat X,vec y,float bandwidth = 0.01, string sampling_method = "ESS", int size = 100000, int N_mcmc = 100000, int burn_in = 1000, bool probit = true, int seed = -1) { int n_fils = X.n_cols; uvec nonzero_col = find(any(X,0)); nonzero_col.print(); X = conv_to<dmat>::from(X.cols(nonzero_col)); cout << "X " << X.n_rows << ' ' << X.n_cols << endl; dmat X_colmean = mean(X,0); dmat X_colstd = stddev(X,0,0); X.each_row() -= X_colmean; X.each_row() /= X_colstd; cout << X.n_rows << ' ' << X.n_cols << endl; dmat K = calc_covariance_matrix(X.t(),bandwidth); //K.save("K.bin",arma_binary); dmat samples; //if (not sampling_method.compare("ESS")) samples = elliptical_slice_sampling(K,y,N_mcmc,burn_in,seed,true); //samples.save("ESS.bin",arma_binary); //samples.load("ESS.bin",arma_binary); dvec rates_nv = calc_rate(X,samples); dvec rates(n_fils,fill::zeros); for(int i=0;i<nonzero_col.n_elem;i++) rates(nonzero_col(i)) = rates_nv(i); return rates; }
draw.c	/* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % DDDD RRRR AAA W W % % D D R R A A W W % % D D RRRR AAAAA W W W % % D D R RN A A WW WW % % DDDD R R A A W W % % % % % % MagickCore Image Drawing Methods % % % % % % Software Design % % Cristy % % July 1998 % % % % % % Copyright 1999-2019 ImageMagick Studio LLC, a non-profit organization % % dedicated to making software imaging solutions freely available. % % % % You may not use this file except in compliance with the License. You may % % obtain a copy of the License at % % % % https://imagemagick.org/script/license.php % % % % Unless required by applicable law or agreed to in writing, software % % distributed under the License is distributed on an "AS IS" BASIS, % % WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. % % See the License for the specific language governing permissions and % % limitations under the License. % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % Bill Radcliffe of Corbis (www.corbis.com) contributed the polygon % rendering code based on Paul Heckbert's "Concave Polygon Scan Conversion", % Graphics Gems, 1990. Leonard Rosenthal and David Harr of Appligent % (www.appligent.com) contributed the dash pattern, linecap stroking % algorithm, and minor rendering improvements. % / / Include declarations. / #include "MagickCore/studio.h" #include "MagickCore/annotate.h" #include "MagickCore/artifact.h" #include "MagickCore/blob.h" #include "MagickCore/cache.h" #include "MagickCore/cache-private.h" #include "MagickCore/cache-view.h" #include "MagickCore/channel.h" #include "MagickCore/color.h" #include "MagickCore/colorspace-private.h" #include "MagickCore/composite.h" #include "MagickCore/composite-private.h" #include "MagickCore/constitute.h" #include "MagickCore/draw.h" #include "MagickCore/draw-private.h" #include "MagickCore/enhance.h" #include "MagickCore/exception.h" #include "MagickCore/exception-private.h" #include "MagickCore/gem.h" #include "MagickCore/geometry.h" #include "MagickCore/image-private.h" #include "MagickCore/list.h" #include "MagickCore/log.h" #include "MagickCore/memory-private.h" #include "MagickCore/monitor.h" #include "MagickCore/monitor-private.h" #include "MagickCore/option.h" #include "MagickCore/paint.h" #include "MagickCore/pixel-accessor.h" #include "MagickCore/pixel-private.h" #include "MagickCore/property.h" #include "MagickCore/resample.h" #include "MagickCore/resample-private.h" #include "MagickCore/resource_.h" #include "MagickCore/splay-tree.h" #include "MagickCore/string_.h" #include "MagickCore/string-private.h" #include "MagickCore/thread-private.h" #include "MagickCore/token.h" #include "MagickCore/transform-private.h" #include "MagickCore/utility.h" / Define declarations. / #define BezierQuantum 200 #define PrimitiveExtentPad 2048 #define MaxBezierCoordinates 4194304 #define ThrowPointExpectedException(token,exception) \ { \ (void) ThrowMagickException(exception,GetMagickModule(),DrawError, \ "NonconformingDrawingPrimitiveDefinition","`%s'",token); \ status=MagickFalse; \ break; \ } / Typedef declarations. / typedef struct _EdgeInfo { SegmentInfo bounds; double scanline; PointInfo points; size_t number_points; ssize_t direction; MagickBooleanType ghostline; size_t highwater; } EdgeInfo; typedef struct _ElementInfo { double cx, cy, major, minor, angle; } ElementInfo; typedef struct _MVGInfo { PrimitiveInfo *primitive_info; size_t extent; ssize_t offset; PointInfo point; ExceptionInfo exception; } MVGInfo; typedef struct _PolygonInfo { EdgeInfo edges; size_t number_edges; } PolygonInfo; typedef enum { MoveToCode, OpenCode, GhostlineCode, LineToCode, EndCode } PathInfoCode; typedef struct _PathInfo { PointInfo point; PathInfoCode code; } PathInfo; /* Forward declarations. / static Image DrawClippingMask(Image ,const DrawInfo ,const char ,const char , ExceptionInfo ); static MagickBooleanType DrawStrokePolygon(Image ,const DrawInfo ,const PrimitiveInfo , ExceptionInfo ), RenderMVGContent(Image ,const DrawInfo ,const size_t,ExceptionInfo ), TraceArc(MVGInfo ,const PointInfo,const PointInfo,const PointInfo), TraceArcPath(MVGInfo ,const PointInfo,const PointInfo,const PointInfo, const double,const MagickBooleanType,const MagickBooleanType), TraceBezier(MVGInfo ,const size_t), TraceCircle(MVGInfo ,const PointInfo,const PointInfo), TraceEllipse(MVGInfo ,const PointInfo,const PointInfo,const PointInfo), TraceLine(PrimitiveInfo ,const PointInfo,const PointInfo), TraceRectangle(PrimitiveInfo ,const PointInfo,const PointInfo), TraceRoundRectangle(MVGInfo ,const PointInfo,const PointInfo,PointInfo), TraceSquareLinecap(PrimitiveInfo ,const size_t,const double); static PrimitiveInfo TraceStrokePolygon(const Image ,const DrawInfo ,const PrimitiveInfo ); static size_t TracePath(MVGInfo ,const char ,ExceptionInfo ); /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % A c q u i r e D r a w I n f o % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % AcquireDrawInfo() returns a DrawInfo structure properly initialized. % % The format of the AcquireDrawInfo method is: % % DrawInfo AcquireDrawInfo(void) % / MagickExport DrawInfo AcquireDrawInfo(void) { DrawInfo draw_info; draw_info=(DrawInfo ) AcquireCriticalMemory(sizeof(draw_info)); GetDrawInfo((ImageInfo ) NULL,draw_info); return(draw_info); } / %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % C l o n e D r a w I n f o % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % CloneDrawInfo() makes a copy of the given draw_info structure. If NULL % is specified, a new DrawInfo structure is created initialized to default % values. % % The format of the CloneDrawInfo method is: % % DrawInfo CloneDrawInfo(const ImageInfo image_info, % const DrawInfo draw_info) % % A description of each parameter follows: % % o image_info: the image info. % % o draw_info: the draw info. % / MagickExport DrawInfo CloneDrawInfo(const ImageInfo image_info, const DrawInfo draw_info) { DrawInfo clone_info; ExceptionInfo exception; clone_info=(DrawInfo ) AcquireCriticalMemory(sizeof(clone_info)); GetDrawInfo(image_info,clone_info); if (draw_info == (DrawInfo ) NULL) return(clone_info); exception=AcquireExceptionInfo(); if (draw_info->id != (char ) NULL) (void) CloneString(&clone_info->id,draw_info->id); if (draw_info->primitive != (char ) NULL) (void) CloneString(&clone_info->primitive,draw_info->primitive); if (draw_info->geometry != (char ) NULL) (void) CloneString(&clone_info->geometry,draw_info->geometry); clone_info->compliance=draw_info->compliance; clone_info->viewbox=draw_info->viewbox; clone_info->affine=draw_info->affine; clone_info->gravity=draw_info->gravity; clone_info->fill=draw_info->fill; clone_info->stroke=draw_info->stroke; clone_info->stroke_width=draw_info->stroke_width; if (draw_info->fill_pattern != (Image ) NULL) clone_info->fill_pattern=CloneImage(draw_info->fill_pattern,0,0,MagickTrue, exception); if (draw_info->stroke_pattern != (Image ) NULL) clone_info->stroke_pattern=CloneImage(draw_info->stroke_pattern,0,0, MagickTrue,exception); clone_info->stroke_antialias=draw_info->stroke_antialias; clone_info->text_antialias=draw_info->text_antialias; clone_info->fill_rule=draw_info->fill_rule; clone_info->linecap=draw_info->linecap; clone_info->linejoin=draw_info->linejoin; clone_info->miterlimit=draw_info->miterlimit; clone_info->dash_offset=draw_info->dash_offset; clone_info->decorate=draw_info->decorate; clone_info->compose=draw_info->compose; if (draw_info->text != (char ) NULL) (void) CloneString(&clone_info->text,draw_info->text); if (draw_info->font != (char ) NULL) (void) CloneString(&clone_info->font,draw_info->font); if (draw_info->metrics != (char ) NULL) (void) CloneString(&clone_info->metrics,draw_info->metrics); if (draw_info->family != (char ) NULL) (void) CloneString(&clone_info->family,draw_info->family); clone_info->style=draw_info->style; clone_info->stretch=draw_info->stretch; clone_info->weight=draw_info->weight; if (draw_info->encoding != (char ) NULL) (void) CloneString(&clone_info->encoding,draw_info->encoding); clone_info->pointsize=draw_info->pointsize; clone_info->kerning=draw_info->kerning; clone_info->interline_spacing=draw_info->interline_spacing; clone_info->interword_spacing=draw_info->interword_spacing; clone_info->direction=draw_info->direction; if (draw_info->density != (char ) NULL) (void) CloneString(&clone_info->density,draw_info->density); clone_info->align=draw_info->align; clone_info->undercolor=draw_info->undercolor; clone_info->border_color=draw_info->border_color; if (draw_info->server_name != (char ) NULL) (void) CloneString(&clone_info->server_name,draw_info->server_name); if (draw_info->dash_pattern != (double ) NULL) { register ssize_t x; for (x=0; fabs(draw_info->dash_pattern[x]) >= MagickEpsilon; x++) ; clone_info->dash_pattern=(double ) AcquireQuantumMemory((size_t) (2x+2), sizeof(clone_info->dash_pattern)); if (clone_info->dash_pattern == (double ) NULL) ThrowFatalException(ResourceLimitFatalError, "UnableToAllocateDashPattern"); (void) memset(clone_info->dash_pattern,0,(size_t) (2x+2)* sizeof(clone_info->dash_pattern)); (void) memcpy(clone_info->dash_pattern,draw_info->dash_pattern,(size_t) (x+1)sizeof(clone_info->dash_pattern)); } clone_info->gradient=draw_info->gradient; if (draw_info->gradient.stops != (StopInfo ) NULL) { size_t number_stops; number_stops=clone_info->gradient.number_stops; clone_info->gradient.stops=(StopInfo ) AcquireQuantumMemory((size_t) number_stops,sizeof(clone_info->gradient.stops)); if (clone_info->gradient.stops == (StopInfo ) NULL) ThrowFatalException(ResourceLimitFatalError, "UnableToAllocateDashPattern"); (void) memcpy(clone_info->gradient.stops,draw_info->gradient.stops, (size_t) number_stopssizeof(clone_info->gradient.stops)); } clone_info->bounds=draw_info->bounds; clone_info->fill_alpha=draw_info->fill_alpha; clone_info->stroke_alpha=draw_info->stroke_alpha; clone_info->element_reference=draw_info->element_reference; clone_info->clip_path=draw_info->clip_path; clone_info->clip_units=draw_info->clip_units; if (draw_info->clip_mask != (char ) NULL) (void) CloneString(&clone_info->clip_mask,draw_info->clip_mask); if (draw_info->clipping_mask != (Image ) NULL) clone_info->clipping_mask=CloneImage(draw_info->clipping_mask,0,0, MagickTrue,exception); if (draw_info->composite_mask != (Image ) NULL) clone_info->composite_mask=CloneImage(draw_info->composite_mask,0,0, MagickTrue,exception); clone_info->render=draw_info->render; clone_info->debug=IsEventLogging(); exception=DestroyExceptionInfo(exception); return(clone_info); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % + C o n v e r t P a t h T o P o l y g o n % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % ConvertPathToPolygon() converts a path to the more efficient sorted % rendering form. % % The format of the ConvertPathToPolygon method is: % % PolygonInfo ConvertPathToPolygon(const PathInfo path_info) % % A description of each parameter follows: % % o Method ConvertPathToPolygon returns the path in a more efficient sorted % rendering form of type PolygonInfo. % % o draw_info: Specifies a pointer to an DrawInfo structure. % % o path_info: Specifies a pointer to an PathInfo structure. % % / #if defined(__cplusplus) \|\| defined(c_plusplus) extern "C" { #endif static int DrawCompareEdges(const void p_edge,const void q_edge) { #define DrawCompareEdge(p,q) \ { \ if (((p)-(q)) < 0.0) \ return(-1); \ if (((p)-(q)) > 0.0) \ return(1); \ } register const PointInfo p, q; / Edge sorting for right-handed coordinate system. / p=((const EdgeInfo ) p_edge)->points; q=((const EdgeInfo ) q_edge)->points; DrawCompareEdge(p[0].y,q[0].y); DrawCompareEdge(p[0].x,q[0].x); DrawCompareEdge((p[1].x-p[0].x)(q[1].y-q[0].y),(p[1].y-p[0].y)* (q[1].x-q[0].x)); DrawCompareEdge(p[1].y,q[1].y); DrawCompareEdge(p[1].x,q[1].x); return(0); } #if defined(__cplusplus) \|\| defined(c_plusplus) } #endif static void LogPolygonInfo(const PolygonInfo polygon_info) { register EdgeInfo p; register ssize_t i, j; (void) LogMagickEvent(DrawEvent,GetMagickModule()," begin active-edge"); p=polygon_info->edges; for (i=0; i < (ssize_t) polygon_info->number_edges; i++) { (void) LogMagickEvent(DrawEvent,GetMagickModule()," edge %.20g:", (double) i); (void) LogMagickEvent(DrawEvent,GetMagickModule()," direction: %s", p->direction != MagickFalse ? "down" : "up"); (void) LogMagickEvent(DrawEvent,GetMagickModule()," ghostline: %s", p->ghostline != MagickFalse ? "transparent" : "opaque"); (void) LogMagickEvent(DrawEvent,GetMagickModule(), " bounds: %g,%g - %g,%g",p->bounds.x1,p->bounds.y1, p->bounds.x2,p->bounds.y2); for (j=0; j < (ssize_t) p->number_points; j++) (void) LogMagickEvent(DrawEvent,GetMagickModule()," %g,%g", p->points[j].x,p->points[j].y); p++; } (void) LogMagickEvent(DrawEvent,GetMagickModule()," end active-edge"); } static void ReversePoints(PointInfo points,const size_t number_points) { PointInfo point; register ssize_t i; for (i=0; i < (ssize_t) (number_points >> 1); i++) { point=points[i]; points[i]=points[number_points-(i+1)]; points[number_points-(i+1)]=point; } } static PolygonInfo ConvertPathToPolygon(const PathInfo path_info) { long direction, next_direction; PointInfo point, points; PolygonInfo polygon_info; SegmentInfo bounds; register ssize_t i, n; MagickBooleanType ghostline; size_t edge, number_edges, number_points; / Convert a path to the more efficient sorted rendering form. / polygon_info=(PolygonInfo ) AcquireMagickMemory(sizeof(polygon_info)); if (polygon_info == (PolygonInfo ) NULL) return((PolygonInfo ) NULL); number_edges=16; polygon_info->edges=(EdgeInfo ) AcquireQuantumMemory(number_edges, sizeof(polygon_info->edges)); if (polygon_info->edges == (EdgeInfo ) NULL) return((PolygonInfo ) NULL); (void) memset(polygon_info->edges,0,number_edges sizeof(polygon_info->edges)); direction=0; edge=0; ghostline=MagickFalse; n=0; number_points=0; points=(PointInfo ) NULL; (void) memset(&point,0,sizeof(point)); (void) memset(&bounds,0,sizeof(bounds)); polygon_info->edges[edge].number_points=(size_t) n; polygon_info->edges[edge].scanline=0.0; polygon_info->edges[edge].highwater=0; polygon_info->edges[edge].ghostline=ghostline; polygon_info->edges[edge].direction=(ssize_t) direction; polygon_info->edges[edge].points=points; polygon_info->edges[edge].bounds=bounds; polygon_info->number_edges=0; for (i=0; path_info[i].code != EndCode; i++) { if ((path_info[i].code == MoveToCode) \|\| (path_info[i].code == OpenCode) \|\| (path_info[i].code == GhostlineCode)) { /* Move to. / if ((points != (PointInfo ) NULL) && (n >= 2)) { if (edge == number_edges) { number_edges<<=1; polygon_info->edges=(EdgeInfo ) ResizeQuantumMemory( polygon_info->edges,(size_t) number_edges, sizeof(polygon_info->edges)); if (polygon_info->edges == (EdgeInfo ) NULL) return((PolygonInfo ) NULL); } polygon_info->edges[edge].number_points=(size_t) n; polygon_info->edges[edge].scanline=(-1.0); polygon_info->edges[edge].highwater=0; polygon_info->edges[edge].ghostline=ghostline; polygon_info->edges[edge].direction=(ssize_t) (direction > 0); if (direction < 0) ReversePoints(points,(size_t) n); polygon_info->edges[edge].points=points; polygon_info->edges[edge].bounds=bounds; polygon_info->edges[edge].bounds.y1=points[0].y; polygon_info->edges[edge].bounds.y2=points[n-1].y; points=(PointInfo ) NULL; ghostline=MagickFalse; edge++; } if (points == (PointInfo ) NULL) { number_points=16; points=(PointInfo ) AcquireQuantumMemory((size_t) number_points, sizeof(points)); if (points == (PointInfo ) NULL) return((PolygonInfo ) NULL); } ghostline=path_info[i].code == GhostlineCode ? MagickTrue : MagickFalse; point=path_info[i].point; points[0]=point; bounds.x1=point.x; bounds.x2=point.x; direction=0; n=1; continue; } /* Line to. / next_direction=((path_info[i].point.y > point.y) \|\| ((fabs(path_info[i].point.y-point.y) < MagickEpsilon) && (path_info[i].point.x > point.x))) ? 1 : -1; if ((points != (PointInfo ) NULL) && (direction != 0) && (direction != next_direction)) { /* New edge. / point=points[n-1]; if (edge == number_edges) { number_edges<<=1; polygon_info->edges=(EdgeInfo ) ResizeQuantumMemory( polygon_info->edges,(size_t) number_edges, sizeof(polygon_info->edges)); if (polygon_info->edges == (EdgeInfo ) NULL) return((PolygonInfo ) NULL); } polygon_info->edges[edge].number_points=(size_t) n; polygon_info->edges[edge].scanline=(-1.0); polygon_info->edges[edge].highwater=0; polygon_info->edges[edge].ghostline=ghostline; polygon_info->edges[edge].direction=(ssize_t) (direction > 0); if (direction < 0) ReversePoints(points,(size_t) n); polygon_info->edges[edge].points=points; polygon_info->edges[edge].bounds=bounds; polygon_info->edges[edge].bounds.y1=points[0].y; polygon_info->edges[edge].bounds.y2=points[n-1].y; number_points=16; points=(PointInfo ) AcquireQuantumMemory((size_t) number_points, sizeof(points)); if (points == (PointInfo ) NULL) return((PolygonInfo ) NULL); n=1; ghostline=MagickFalse; points[0]=point; bounds.x1=point.x; bounds.x2=point.x; edge++; } direction=next_direction; if (points == (PointInfo ) NULL) continue; if (n == (ssize_t) number_points) { number_points<<=1; points=(PointInfo ) ResizeQuantumMemory(points,(size_t) number_points, sizeof(points)); if (points == (PointInfo ) NULL) return((PolygonInfo ) NULL); } point=path_info[i].point; points[n]=point; if (point.x < bounds.x1) bounds.x1=point.x; if (point.x > bounds.x2) bounds.x2=point.x; n++; } if (points != (PointInfo ) NULL) { if (n < 2) points=(PointInfo ) RelinquishMagickMemory(points); else { if (edge == number_edges) { number_edges<<=1; polygon_info->edges=(EdgeInfo ) ResizeQuantumMemory( polygon_info->edges,(size_t) number_edges, sizeof(polygon_info->edges)); if (polygon_info->edges == (EdgeInfo ) NULL) return((PolygonInfo ) NULL); } polygon_info->edges[edge].number_points=(size_t) n; polygon_info->edges[edge].scanline=(-1.0); polygon_info->edges[edge].highwater=0; polygon_info->edges[edge].ghostline=ghostline; polygon_info->edges[edge].direction=(ssize_t) (direction > 0); if (direction < 0) ReversePoints(points,(size_t) n); polygon_info->edges[edge].points=points; polygon_info->edges[edge].bounds=bounds; polygon_info->edges[edge].bounds.y1=points[0].y; polygon_info->edges[edge].bounds.y2=points[n-1].y; ghostline=MagickFalse; edge++; } } polygon_info->number_edges=edge; qsort(polygon_info->edges,(size_t) polygon_info->number_edges, sizeof(polygon_info->edges),DrawCompareEdges); if (IsEventLogging() != MagickFalse) LogPolygonInfo(polygon_info); return(polygon_info); } / %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % + C o n v e r t P r i m i t i v e T o P a t h % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % ConvertPrimitiveToPath() converts a PrimitiveInfo structure into a vector % path structure. % % The format of the ConvertPrimitiveToPath method is: % % PathInfo ConvertPrimitiveToPath(const DrawInfo draw_info, % const PrimitiveInfo primitive_info) % % A description of each parameter follows: % % o Method ConvertPrimitiveToPath returns a vector path structure of type % PathInfo. % % o draw_info: a structure of type DrawInfo. % % o primitive_info: Specifies a pointer to an PrimitiveInfo structure. % % / static void LogPathInfo(const PathInfo path_info) { register const PathInfo p; (void) LogMagickEvent(DrawEvent,GetMagickModule()," begin vector-path"); for (p=path_info; p->code != EndCode; p++) (void) LogMagickEvent(DrawEvent,GetMagickModule(), " %g,%g %s",p->point.x,p->point.y,p->code == GhostlineCode ? "moveto ghostline" : p->code == OpenCode ? "moveto open" : p->code == MoveToCode ? "moveto" : p->code == LineToCode ? "lineto" : "?"); (void) LogMagickEvent(DrawEvent,GetMagickModule()," end vector-path"); } static PathInfo ConvertPrimitiveToPath(const PrimitiveInfo primitive_info) { MagickBooleanType closed_subpath; PathInfo path_info; PathInfoCode code; PointInfo p, q; register ssize_t i, n; ssize_t coordinates, start; / Converts a PrimitiveInfo structure into a vector path structure. / switch (primitive_info->primitive) { case AlphaPrimitive: case ColorPrimitive: case ImagePrimitive: case PointPrimitive: case TextPrimitive: return((PathInfo ) NULL); default: break; } for (i=0; primitive_info[i].primitive != UndefinedPrimitive; i++) ; path_info=(PathInfo ) AcquireQuantumMemory((size_t) (3ULi+1UL), sizeof(path_info)); if (path_info == (PathInfo ) NULL) return((PathInfo ) NULL); coordinates=0; closed_subpath=MagickFalse; n=0; p.x=(-1.0); p.y=(-1.0); q.x=(-1.0); q.y=(-1.0); start=0; for (i=0; primitive_info[i].primitive != UndefinedPrimitive; i++) { code=LineToCode; if (coordinates <= 0) { / New subpath. / coordinates=(ssize_t) primitive_info[i].coordinates; p=primitive_info[i].point; start=n; code=MoveToCode; closed_subpath=primitive_info[i].closed_subpath; } coordinates--; if ((code == MoveToCode) \|\| (coordinates <= 0) \|\| (fabs(q.x-primitive_info[i].point.x) >= MagickEpsilon) \|\| (fabs(q.y-primitive_info[i].point.y) >= MagickEpsilon)) { / Eliminate duplicate points. / path_info[n].code=code; path_info[n].point=primitive_info[i].point; q=primitive_info[i].point; n++; } if (coordinates > 0) continue; / next point in current subpath / if (closed_subpath != MagickFalse) { closed_subpath=MagickFalse; continue; } / Mark the p point as open if the subpath is not closed. / path_info[start].code=OpenCode; path_info[n].code=GhostlineCode; path_info[n].point=primitive_info[i].point; n++; path_info[n].code=LineToCode; path_info[n].point=p; n++; } path_info[n].code=EndCode; path_info[n].point.x=0.0; path_info[n].point.y=0.0; if (IsEventLogging() != MagickFalse) LogPathInfo(path_info); path_info=(PathInfo ) ResizeQuantumMemory(path_info,(size_t) (n+1), sizeof(path_info)); return(path_info); } / %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % D e s t r o y D r a w I n f o % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % DestroyDrawInfo() deallocates memory associated with an DrawInfo structure. % % The format of the DestroyDrawInfo method is: % % DrawInfo DestroyDrawInfo(DrawInfo draw_info) % % A description of each parameter follows: % % o draw_info: the draw info. % / MagickExport DrawInfo DestroyDrawInfo(DrawInfo draw_info) { assert(draw_info != (DrawInfo ) NULL); if (draw_info->debug != MagickFalse) (void) LogMagickEvent(TraceEvent,GetMagickModule(),"..."); assert(draw_info->signature == MagickCoreSignature); if (draw_info->id != (char ) NULL) draw_info->id=DestroyString(draw_info->id); if (draw_info->primitive != (char ) NULL) draw_info->primitive=DestroyString(draw_info->primitive); if (draw_info->text != (char ) NULL) draw_info->text=DestroyString(draw_info->text); if (draw_info->geometry != (char ) NULL) draw_info->geometry=DestroyString(draw_info->geometry); if (draw_info->fill_pattern != (Image ) NULL) draw_info->fill_pattern=DestroyImage(draw_info->fill_pattern); if (draw_info->stroke_pattern != (Image ) NULL) draw_info->stroke_pattern=DestroyImage(draw_info->stroke_pattern); if (draw_info->font != (char ) NULL) draw_info->font=DestroyString(draw_info->font); if (draw_info->metrics != (char ) NULL) draw_info->metrics=DestroyString(draw_info->metrics); if (draw_info->family != (char ) NULL) draw_info->family=DestroyString(draw_info->family); if (draw_info->encoding != (char ) NULL) draw_info->encoding=DestroyString(draw_info->encoding); if (draw_info->density != (char ) NULL) draw_info->density=DestroyString(draw_info->density); if (draw_info->server_name != (char ) NULL) draw_info->server_name=(char ) RelinquishMagickMemory(draw_info->server_name); if (draw_info->dash_pattern != (double ) NULL) draw_info->dash_pattern=(double ) RelinquishMagickMemory( draw_info->dash_pattern); if (draw_info->gradient.stops != (StopInfo ) NULL) draw_info->gradient.stops=(StopInfo ) RelinquishMagickMemory( draw_info->gradient.stops); if (draw_info->clip_mask != (char ) NULL) draw_info->clip_mask=DestroyString(draw_info->clip_mask); if (draw_info->clipping_mask != (Image ) NULL) draw_info->clipping_mask=DestroyImage(draw_info->clipping_mask); if (draw_info->composite_mask != (Image ) NULL) draw_info->composite_mask=DestroyImage(draw_info->composite_mask); draw_info->signature=(~MagickCoreSignature); draw_info=(DrawInfo ) RelinquishMagickMemory(draw_info); return(draw_info); } / %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % + D e s t r o y E d g e % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % DestroyEdge() destroys the specified polygon edge. % % The format of the DestroyEdge method is: % % ssize_t DestroyEdge(PolygonInfo polygon_info,const int edge) % % A description of each parameter follows: % % o polygon_info: Specifies a pointer to an PolygonInfo structure. % % o edge: the polygon edge number to destroy. % / static size_t DestroyEdge(PolygonInfo polygon_info, const size_t edge) { assert(edge < polygon_info->number_edges); polygon_info->edges[edge].points=(PointInfo ) RelinquishMagickMemory( polygon_info->edges[edge].points); polygon_info->number_edges--; if (edge < polygon_info->number_edges) (void) memmove(polygon_info->edges+edge,polygon_info->edges+edge+1, (size_t) (polygon_info->number_edges-edge)sizeof(polygon_info->edges)); return(polygon_info->number_edges); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % + D e s t r o y P o l y g o n I n f o % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % DestroyPolygonInfo() destroys the PolygonInfo data structure. % % The format of the DestroyPolygonInfo method is: % % PolygonInfo DestroyPolygonInfo(PolygonInfo polygon_info) % % A description of each parameter follows: % % o polygon_info: Specifies a pointer to an PolygonInfo structure. % / static PolygonInfo DestroyPolygonInfo(PolygonInfo polygon_info) { register ssize_t i; for (i=0; i < (ssize_t) polygon_info->number_edges; i++) polygon_info->edges[i].points=(PointInfo ) RelinquishMagickMemory(polygon_info->edges[i].points); polygon_info->edges=(EdgeInfo ) RelinquishMagickMemory(polygon_info->edges); return((PolygonInfo ) RelinquishMagickMemory(polygon_info)); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % D r a w A f f i n e I m a g e % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % DrawAffineImage() composites the source over the destination image as % dictated by the affine transform. % % The format of the DrawAffineImage method is: % % MagickBooleanType DrawAffineImage(Image image,const Image source, % const AffineMatrix affine,ExceptionInfo exception) % % A description of each parameter follows: % % o image: the image. % % o source: the source image. % % o affine: the affine transform. % % o exception: return any errors or warnings in this structure. % / static SegmentInfo AffineEdge(const Image image,const AffineMatrix affine, const double y,const SegmentInfo edge) { double intercept, z; register double x; SegmentInfo inverse_edge; /* Determine left and right edges. / inverse_edge.x1=edge->x1; inverse_edge.y1=edge->y1; inverse_edge.x2=edge->x2; inverse_edge.y2=edge->y2; z=affine->ryy+affine->tx; if (affine->sx >= MagickEpsilon) { intercept=(-z/affine->sx); x=intercept; if (x > inverse_edge.x1) inverse_edge.x1=x; intercept=(-z+(double) image->columns)/affine->sx; x=intercept; if (x < inverse_edge.x2) inverse_edge.x2=x; } else if (affine->sx < -MagickEpsilon) { intercept=(-z+(double) image->columns)/affine->sx; x=intercept; if (x > inverse_edge.x1) inverse_edge.x1=x; intercept=(-z/affine->sx); x=intercept; if (x < inverse_edge.x2) inverse_edge.x2=x; } else if ((z < 0.0) \|\| ((size_t) floor(z+0.5) >= image->columns)) { inverse_edge.x2=edge->x1; return(inverse_edge); } /* Determine top and bottom edges. / z=affine->syy+affine->ty; if (affine->rx >= MagickEpsilon) { intercept=(-z/affine->rx); x=intercept; if (x > inverse_edge.x1) inverse_edge.x1=x; intercept=(-z+(double) image->rows)/affine->rx; x=intercept; if (x < inverse_edge.x2) inverse_edge.x2=x; } else if (affine->rx < -MagickEpsilon) { intercept=(-z+(double) image->rows)/affine->rx; x=intercept; if (x > inverse_edge.x1) inverse_edge.x1=x; intercept=(-z/affine->rx); x=intercept; if (x < inverse_edge.x2) inverse_edge.x2=x; } else if ((z < 0.0) \|\| ((size_t) floor(z+0.5) >= image->rows)) { inverse_edge.x2=edge->x2; return(inverse_edge); } return(inverse_edge); } static AffineMatrix InverseAffineMatrix(const AffineMatrix affine) { AffineMatrix inverse_affine; double determinant; determinant=PerceptibleReciprocal(affine->sxaffine->sy-affine->rx* affine->ry); inverse_affine.sx=determinantaffine->sy; inverse_affine.rx=determinant(-affine->rx); inverse_affine.ry=determinant(-affine->ry); inverse_affine.sy=determinantaffine->sx; inverse_affine.tx=(-affine->tx)inverse_affine.sx-affine->ty inverse_affine.ry; inverse_affine.ty=(-affine->tx)inverse_affine.rx-affine->ty inverse_affine.sy; return(inverse_affine); } MagickExport MagickBooleanType DrawAffineImage(Image image, const Image source,const AffineMatrix affine,ExceptionInfo exception) { AffineMatrix inverse_affine; CacheView image_view, source_view; MagickBooleanType status; PixelInfo zero; PointInfo extent[4], min, max; register ssize_t i; SegmentInfo edge; ssize_t start, stop, y; /* Determine bounding box. / assert(image != (Image ) NULL); assert(image->signature == MagickCoreSignature); if (image->debug != MagickFalse) (void) LogMagickEvent(TraceEvent,GetMagickModule(),"%s",image->filename); assert(source != (const Image ) NULL); assert(source->signature == MagickCoreSignature); assert(affine != (AffineMatrix ) NULL); extent[0].x=0.0; extent[0].y=0.0; extent[1].x=(double) source->columns-1.0; extent[1].y=0.0; extent[2].x=(double) source->columns-1.0; extent[2].y=(double) source->rows-1.0; extent[3].x=0.0; extent[3].y=(double) source->rows-1.0; for (i=0; i < 4; i++) { PointInfo point; point=extent[i]; extent[i].x=point.xaffine->sx+point.yaffine->ry+affine->tx; extent[i].y=point.xaffine->rx+point.yaffine->sy+affine->ty; } min=extent[0]; max=extent[0]; for (i=1; i < 4; i++) { if (min.x > extent[i].x) min.x=extent[i].x; if (min.y > extent[i].y) min.y=extent[i].y; if (max.x < extent[i].x) max.x=extent[i].x; if (max.y < extent[i].y) max.y=extent[i].y; } /* Affine transform image. / if (SetImageStorageClass(image,DirectClass,exception) == MagickFalse) return(MagickFalse); status=MagickTrue; edge.x1=MagickMax(min.x,0.0); edge.y1=MagickMax(min.y,0.0); edge.x2=MagickMin(max.x,(double) image->columns-1.0); edge.y2=MagickMin(max.y,(double) image->rows-1.0); inverse_affine=InverseAffineMatrix(affine); GetPixelInfo(image,&zero); start=(ssize_t) ceil(edge.y1-0.5); stop=(ssize_t) floor(edge.y2+0.5); source_view=AcquireVirtualCacheView(source,exception); image_view=AcquireAuthenticCacheView(image,exception); #if defined(MAGICKCORE_OPENMP_SUPPORT) #pragma omp parallel for schedule(static) shared(status) \ magick_number_threads(source,image,stop-start,1) #endif for (y=start; y <= stop; y++) { PixelInfo composite, pixel; PointInfo point; register ssize_t x; register Quantum magick_restrict q; SegmentInfo inverse_edge; ssize_t x_offset; inverse_edge=AffineEdge(source,&inverse_affine,(double) y,&edge); if (inverse_edge.x2 < inverse_edge.x1) continue; q=GetCacheViewAuthenticPixels(image_view,(ssize_t) ceil(inverse_edge.x1- 0.5),y,(size_t) (floor(inverse_edge.x2+0.5)-ceil(inverse_edge.x1-0.5)+1), 1,exception); if (q == (Quantum ) NULL) continue; pixel=zero; composite=zero; x_offset=0; for (x=(ssize_t) ceil(inverse_edge.x1-0.5); x <= (ssize_t) floor(inverse_edge.x2+0.5); x++) { point.x=(double) xinverse_affine.sx+yinverse_affine.ry+ inverse_affine.tx; point.y=(double) xinverse_affine.rx+yinverse_affine.sy+ inverse_affine.ty; status=InterpolatePixelInfo(source,source_view,UndefinedInterpolatePixel, point.x,point.y,&pixel,exception); if (status == MagickFalse) break; GetPixelInfoPixel(image,q,&composite); CompositePixelInfoOver(&pixel,pixel.alpha,&composite,composite.alpha, &composite); SetPixelViaPixelInfo(image,&composite,q); x_offset++; q+=GetPixelChannels(image); } if (SyncCacheViewAuthenticPixels(image_view,exception) == MagickFalse) status=MagickFalse; } source_view=DestroyCacheView(source_view); image_view=DestroyCacheView(image_view); return(status); } / %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % + D r a w B o u n d i n g R e c t a n g l e s % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % DrawBoundingRectangles() draws the bounding rectangles on the image. This % is only useful for developers debugging the rendering algorithm. % % The format of the DrawBoundingRectangles method is: % % MagickBooleanType DrawBoundingRectangles(Image image, % const DrawInfo draw_info,PolygonInfo polygon_info, % ExceptionInfo exception) % % A description of each parameter follows: % % o image: the image. % % o draw_info: the draw info. % % o polygon_info: Specifies a pointer to a PolygonInfo structure. % % o exception: return any errors or warnings in this structure. % / static inline double SaneStrokeWidth(const Image image, const DrawInfo draw_info) { return(MagickMin((double) draw_info->stroke_width, (2.0sqrt(2.0)+MagickEpsilon)MagickMax(image->columns,image->rows))); } static MagickBooleanType DrawBoundingRectangles(Image image, const DrawInfo draw_info,const PolygonInfo polygon_info, ExceptionInfo exception) { double mid; DrawInfo clone_info; MagickStatusType status; PointInfo end, resolution, start; PrimitiveInfo primitive_info[6]; register ssize_t i; SegmentInfo bounds; ssize_t coordinates; (void) memset(primitive_info,0,sizeof(primitive_info)); clone_info=CloneDrawInfo((ImageInfo ) NULL,draw_info); status=QueryColorCompliance("#000F",AllCompliance,&clone_info->fill, exception); if (status == MagickFalse) { clone_info=DestroyDrawInfo(clone_info); return(MagickFalse); } resolution.x=96.0; resolution.y=96.0; if (clone_info->density != (char ) NULL) { GeometryInfo geometry_info; MagickStatusType flags; flags=ParseGeometry(clone_info->density,&geometry_info); resolution.x=geometry_info.rho; resolution.y=geometry_info.sigma; if ((flags & SigmaValue) == MagickFalse) resolution.y=resolution.x; } mid=(resolution.x/96.0)ExpandAffine(&clone_info->affine) SaneStrokeWidth(image,clone_info)/2.0; bounds.x1=0.0; bounds.y1=0.0; bounds.x2=0.0; bounds.y2=0.0; if (polygon_info != (PolygonInfo ) NULL) { bounds=polygon_info->edges[0].bounds; for (i=1; i < (ssize_t) polygon_info->number_edges; i++) { if (polygon_info->edges[i].bounds.x1 < (double) bounds.x1) bounds.x1=polygon_info->edges[i].bounds.x1; if (polygon_info->edges[i].bounds.y1 < (double) bounds.y1) bounds.y1=polygon_info->edges[i].bounds.y1; if (polygon_info->edges[i].bounds.x2 > (double) bounds.x2) bounds.x2=polygon_info->edges[i].bounds.x2; if (polygon_info->edges[i].bounds.y2 > (double) bounds.y2) bounds.y2=polygon_info->edges[i].bounds.y2; } bounds.x1-=mid; bounds.x1=bounds.x1 < 0.0 ? 0.0 : bounds.x1 >= (double) image->columns ? (double) image->columns-1 : bounds.x1; bounds.y1-=mid; bounds.y1=bounds.y1 < 0.0 ? 0.0 : bounds.y1 >= (double) image->rows ? (double) image->rows-1 : bounds.y1; bounds.x2+=mid; bounds.x2=bounds.x2 < 0.0 ? 0.0 : bounds.x2 >= (double) image->columns ? (double) image->columns-1 : bounds.x2; bounds.y2+=mid; bounds.y2=bounds.y2 < 0.0 ? 0.0 : bounds.y2 >= (double) image->rows ? (double) image->rows-1 : bounds.y2; for (i=0; i < (ssize_t) polygon_info->number_edges; i++) { if (polygon_info->edges[i].direction != 0) status=QueryColorCompliance("#f00",AllCompliance,&clone_info->stroke, exception); else status=QueryColorCompliance("#0f0",AllCompliance,&clone_info->stroke, exception); if (status == MagickFalse) break; start.x=(double) (polygon_info->edges[i].bounds.x1-mid); start.y=(double) (polygon_info->edges[i].bounds.y1-mid); end.x=(double) (polygon_info->edges[i].bounds.x2+mid); end.y=(double) (polygon_info->edges[i].bounds.y2+mid); primitive_info[0].primitive=RectanglePrimitive; status&=TraceRectangle(primitive_info,start,end); primitive_info[0].method=ReplaceMethod; coordinates=(ssize_t) primitive_info[0].coordinates; primitive_info[coordinates].primitive=UndefinedPrimitive; status=DrawPrimitive(image,clone_info,primitive_info,exception); if (status == MagickFalse) break; } if (i < (ssize_t) polygon_info->number_edges) { clone_info=DestroyDrawInfo(clone_info); return(status == 0 ? MagickFalse : MagickTrue); } } status=QueryColorCompliance("#00f",AllCompliance,&clone_info->stroke, exception); if (status == MagickFalse) { clone_info=DestroyDrawInfo(clone_info); return(MagickFalse); } start.x=(double) (bounds.x1-mid); start.y=(double) (bounds.y1-mid); end.x=(double) (bounds.x2+mid); end.y=(double) (bounds.y2+mid); primitive_info[0].primitive=RectanglePrimitive; status&=TraceRectangle(primitive_info,start,end); primitive_info[0].method=ReplaceMethod; coordinates=(ssize_t) primitive_info[0].coordinates; primitive_info[coordinates].primitive=UndefinedPrimitive; status=DrawPrimitive(image,clone_info,primitive_info,exception); clone_info=DestroyDrawInfo(clone_info); return(status == 0 ? MagickFalse : MagickTrue); } / %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % D r a w C l i p P a t h % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % DrawClipPath() draws the clip path on the image mask. % % The format of the DrawClipPath method is: % % MagickBooleanType DrawClipPath(Image image,const DrawInfo draw_info, % const char id,ExceptionInfo exception) % % A description of each parameter follows: % % o image: the image. % % o draw_info: the draw info. % % o id: the clip path id. % % o exception: return any errors or warnings in this structure. % / MagickExport MagickBooleanType DrawClipPath(Image image, const DrawInfo draw_info,const char id,ExceptionInfo exception) { const char clip_path; Image clipping_mask; MagickBooleanType status; clip_path=GetImageArtifact(image,id); if (clip_path == (const char ) NULL) return(MagickFalse); clipping_mask=DrawClippingMask(image,draw_info,draw_info->clip_mask,clip_path, exception); if (clipping_mask == (Image ) NULL) return(MagickFalse); status=SetImageMask(image,WritePixelMask,clipping_mask,exception); clipping_mask=DestroyImage(clipping_mask); return(status); } / %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % D r a w C l i p p i n g M a s k % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % DrawClippingMask() draws the clip path and returns it as an image clipping % mask. % % The format of the DrawClippingMask method is: % % Image DrawClippingMask(Image image,const DrawInfo draw_info, % const char id,const char clip_path,ExceptionInfo exception) % % A description of each parameter follows: % % o image: the image. % % o draw_info: the draw info. % % o id: the clip path id. % % o clip_path: the clip path. % % o exception: return any errors or warnings in this structure. % / static Image DrawClippingMask(Image image,const DrawInfo draw_info, const char id,const char clip_path,ExceptionInfo exception) { DrawInfo clone_info; Image clip_mask, separate_mask; MagickStatusType status; /* Draw a clip path. / assert(image != (Image ) NULL); assert(image->signature == MagickCoreSignature); if (image->debug != MagickFalse) (void) LogMagickEvent(TraceEvent,GetMagickModule(),"%s",image->filename); assert(draw_info != (const DrawInfo ) NULL); clip_mask=AcquireImage((const ImageInfo ) NULL,exception); status=SetImageExtent(clip_mask,image->columns,image->rows,exception); if (status == MagickFalse) return(DestroyImage(clip_mask)); status=SetImageMask(clip_mask,WritePixelMask,(Image ) NULL,exception); status=QueryColorCompliance("#0000",AllCompliance, &clip_mask->background_color,exception); clip_mask->background_color.alpha=(MagickRealType) TransparentAlpha; clip_mask->background_color.alpha_trait=BlendPixelTrait; status=SetImageBackgroundColor(clip_mask,exception); if (image->debug != MagickFalse) (void) LogMagickEvent(DrawEvent,GetMagickModule(),"\nbegin clip-path %s", id); clone_info=CloneDrawInfo((ImageInfo ) NULL,draw_info); (void) CloneString(&clone_info->primitive,clip_path); status=QueryColorCompliance("#ffffff",AllCompliance,&clone_info->fill, exception); if (clone_info->clip_mask != (char ) NULL) clone_info->clip_mask=DestroyString(clone_info->clip_mask); status=QueryColorCompliance("#00000000",AllCompliance,&clone_info->stroke, exception); clone_info->stroke_width=0.0; clone_info->alpha=OpaqueAlpha; clone_info->clip_path=MagickTrue; status=RenderMVGContent(clip_mask,clone_info,0,exception); clone_info=DestroyDrawInfo(clone_info); separate_mask=SeparateImage(clip_mask,AlphaChannel,exception); if (separate_mask != (Image ) NULL) { clip_mask=DestroyImage(clip_mask); clip_mask=separate_mask; status=NegateImage(clip_mask,MagickFalse,exception); if (status == MagickFalse) clip_mask=DestroyImage(clip_mask); } if (image->debug != MagickFalse) (void) LogMagickEvent(DrawEvent,GetMagickModule(),"end clip-path"); return(clip_mask); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % D r a w C o m p o s i t e M a s k % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % DrawCompositeMask() draws the mask path and returns it as an image mask. % % The format of the DrawCompositeMask method is: % % Image DrawCompositeMask(Image image,const DrawInfo draw_info, % const char id,const char mask_path,ExceptionInfo exception) % % A description of each parameter follows: % % o image: the image. % % o draw_info: the draw info. % % o id: the mask path id. % % o mask_path: the mask path. % % o exception: return any errors or warnings in this structure. % / static Image DrawCompositeMask(Image image,const DrawInfo draw_info, const char id,const char mask_path,ExceptionInfo exception) { Image composite_mask, separate_mask; DrawInfo clone_info; MagickStatusType status; /* Draw a mask path. / assert(image != (Image ) NULL); assert(image->signature == MagickCoreSignature); if (image->debug != MagickFalse) (void) LogMagickEvent(TraceEvent,GetMagickModule(),"%s",image->filename); assert(draw_info != (const DrawInfo ) NULL); composite_mask=AcquireImage((const ImageInfo ) NULL,exception); status=SetImageExtent(composite_mask,image->columns,image->rows,exception); if (status == MagickFalse) return(DestroyImage(composite_mask)); status=SetImageMask(composite_mask,CompositePixelMask,(Image ) NULL, exception); status=QueryColorCompliance("#0000",AllCompliance, &composite_mask->background_color,exception); composite_mask->background_color.alpha=(MagickRealType) TransparentAlpha; composite_mask->background_color.alpha_trait=BlendPixelTrait; (void) SetImageBackgroundColor(composite_mask,exception); if (image->debug != MagickFalse) (void) LogMagickEvent(DrawEvent,GetMagickModule(),"\nbegin mask-path %s", id); clone_info=CloneDrawInfo((ImageInfo ) NULL,draw_info); (void) CloneString(&clone_info->primitive,mask_path); status=QueryColorCompliance("#ffffff",AllCompliance,&clone_info->fill, exception); status=QueryColorCompliance("#00000000",AllCompliance,&clone_info->stroke, exception); clone_info->stroke_width=0.0; clone_info->alpha=OpaqueAlpha; status=RenderMVGContent(composite_mask,clone_info,0,exception); clone_info=DestroyDrawInfo(clone_info); separate_mask=SeparateImage(composite_mask,AlphaChannel,exception); if (separate_mask != (Image ) NULL) { composite_mask=DestroyImage(composite_mask); composite_mask=separate_mask; status=NegateImage(composite_mask,MagickFalse,exception); if (status == MagickFalse) composite_mask=DestroyImage(composite_mask); } if (image->debug != MagickFalse) (void) LogMagickEvent(DrawEvent,GetMagickModule(),"end mask-path"); return(composite_mask); } / %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % + D r a w D a s h P o l y g o n % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % DrawDashPolygon() draws a dashed polygon (line, rectangle, ellipse) on the % image while respecting the dash offset and dash pattern attributes. % % The format of the DrawDashPolygon method is: % % MagickBooleanType DrawDashPolygon(const DrawInfo draw_info, % const PrimitiveInfo primitive_info,Image image, % ExceptionInfo exception) % % A description of each parameter follows: % % o draw_info: the draw info. % % o primitive_info: Specifies a pointer to a PrimitiveInfo structure. % % o image: the image. % % o exception: return any errors or warnings in this structure. % / static MagickBooleanType DrawDashPolygon(const DrawInfo draw_info, const PrimitiveInfo primitive_info,Image image,ExceptionInfo exception) { double length, maximum_length, offset, scale, total_length; DrawInfo clone_info; MagickStatusType status; PrimitiveInfo dash_polygon; register double dx, dy; register ssize_t i; size_t number_vertices; ssize_t j, n; assert(draw_info != (const DrawInfo ) NULL); if (image->debug != MagickFalse) (void) LogMagickEvent(DrawEvent,GetMagickModule()," begin draw-dash"); for (i=0; primitive_info[i].primitive != UndefinedPrimitive; i++) ; number_vertices=(size_t) i; dash_polygon=(PrimitiveInfo ) AcquireQuantumMemory((size_t) (2ULnumber_vertices+32UL),sizeof(dash_polygon)); if (dash_polygon == (PrimitiveInfo ) NULL) return(MagickFalse); (void) memset(dash_polygon,0,(2ULnumber_vertices+32UL) sizeof(dash_polygon)); clone_info=CloneDrawInfo((ImageInfo ) NULL,draw_info); clone_info->miterlimit=0; dash_polygon[0]=primitive_info[0]; scale=ExpandAffine(&draw_info->affine); length=scaledraw_info->dash_pattern[0]; offset=fabs(draw_info->dash_offset) >= MagickEpsilon ? scaledraw_info->dash_offset : 0.0; j=1; for (n=0; offset > 0.0; j=0) { if (draw_info->dash_pattern[n] <= 0.0) break; length=scale(draw_info->dash_pattern[n]+(n == 0 ? -0.5 : 0.5)); if (offset > length) { offset-=length; n++; length=scaledraw_info->dash_pattern[n]; continue; } if (offset < length) { length-=offset; offset=0.0; break; } offset=0.0; n++; } status=MagickTrue; maximum_length=0.0; total_length=0.0; for (i=1; (i < (ssize_t) number_vertices) && (length >= 0.0); i++) { dx=primitive_info[i].point.x-primitive_info[i-1].point.x; dy=primitive_info[i].point.y-primitive_info[i-1].point.y; maximum_length=hypot(dx,dy); if (maximum_length > MaxBezierCoordinates) break; if (fabs(length) < MagickEpsilon) { if (fabs(draw_info->dash_pattern[n]) >= MagickEpsilon) n++; if (fabs(draw_info->dash_pattern[n]) < MagickEpsilon) n=0; length=scaledraw_info->dash_pattern[n]; } for (total_length=0.0; (length >= 0.0) && (maximum_length >= (total_length+length)); ) { total_length+=length; if ((n & 0x01) != 0) { dash_polygon[0]=primitive_info[0]; dash_polygon[0].point.x=(double) (primitive_info[i-1].point.x+dx total_lengthPerceptibleReciprocal(maximum_length)); dash_polygon[0].point.y=(double) (primitive_info[i-1].point.y+dy total_lengthPerceptibleReciprocal(maximum_length)); j=1; } else { if ((j+1) > (ssize_t) number_vertices) break; dash_polygon[j]=primitive_info[i-1]; dash_polygon[j].point.x=(double) (primitive_info[i-1].point.x+dx total_lengthPerceptibleReciprocal(maximum_length)); dash_polygon[j].point.y=(double) (primitive_info[i-1].point.y+dy total_lengthPerceptibleReciprocal(maximum_length)); dash_polygon[j].coordinates=1; j++; dash_polygon[0].coordinates=(size_t) j; dash_polygon[j].primitive=UndefinedPrimitive; status&=DrawStrokePolygon(image,clone_info,dash_polygon,exception); if (status == MagickFalse) break; } if (fabs(draw_info->dash_pattern[n]) >= MagickEpsilon) n++; if (fabs(draw_info->dash_pattern[n]) < MagickEpsilon) n=0; length=scaledraw_info->dash_pattern[n]; } length-=(maximum_length-total_length); if ((n & 0x01) != 0) continue; dash_polygon[j]=primitive_info[i]; dash_polygon[j].coordinates=1; j++; } if ((status != MagickFalse) && (total_length < maximum_length) && ((n & 0x01) == 0) && (j > 1)) { dash_polygon[j]=primitive_info[i-1]; dash_polygon[j].point.x+=MagickEpsilon; dash_polygon[j].point.y+=MagickEpsilon; dash_polygon[j].coordinates=1; j++; dash_polygon[0].coordinates=(size_t) j; dash_polygon[j].primitive=UndefinedPrimitive; status&=DrawStrokePolygon(image,clone_info,dash_polygon,exception); } dash_polygon=(PrimitiveInfo ) RelinquishMagickMemory(dash_polygon); clone_info=DestroyDrawInfo(clone_info); if (image->debug != MagickFalse) (void) LogMagickEvent(DrawEvent,GetMagickModule()," end draw-dash"); return(status != 0 ? MagickTrue : MagickFalse); } / %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % D r a w G r a d i e n t I m a g e % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % DrawGradientImage() draws a linear gradient on the image. % % The format of the DrawGradientImage method is: % % MagickBooleanType DrawGradientImage(Image image, % const DrawInfo draw_info,ExceptionInfo exception) % % A description of each parameter follows: % % o image: the image. % % o draw_info: the draw info. % % o exception: return any errors or warnings in this structure. % / static inline double GetStopColorOffset(const GradientInfo gradient, const ssize_t x,const ssize_t y) { switch (gradient->type) { case UndefinedGradient: case LinearGradient: { double gamma, length, offset, scale; PointInfo p, q; const SegmentInfo gradient_vector; gradient_vector=(&gradient->gradient_vector); p.x=gradient_vector->x2-gradient_vector->x1; p.y=gradient_vector->y2-gradient_vector->y1; q.x=(double) x-gradient_vector->x1; q.y=(double) y-gradient_vector->y1; length=sqrt(q.xq.x+q.yq.y); gamma=sqrt(p.xp.x+p.yp.y)length; gamma=PerceptibleReciprocal(gamma); scale=p.xq.x+p.yq.y; offset=gammascalelength; return(offset); } case RadialGradient: { PointInfo v; if (gradient->spread == RepeatSpread) { v.x=(double) x-gradient->center.x; v.y=(double) y-gradient->center.y; return(sqrt(v.xv.x+v.yv.y)); } v.x=(double) (((x-gradient->center.x)cos(DegreesToRadians( gradient->angle)))+((y-gradient->center.y)sin(DegreesToRadians( gradient->angle))))PerceptibleReciprocal(gradient->radii.x); v.y=(double) (((x-gradient->center.x)sin(DegreesToRadians( gradient->angle)))-((y-gradient->center.y)cos(DegreesToRadians( gradient->angle))))PerceptibleReciprocal(gradient->radii.y); return(sqrt(v.xv.x+v.yv.y)); } } return(0.0); } static int StopInfoCompare(const void x,const void y) { StopInfo stop_1, stop_2; stop_1=(StopInfo ) x; stop_2=(StopInfo ) y; if (stop_1->offset > stop_2->offset) return(1); if (fabs(stop_1->offset-stop_2->offset) <= MagickEpsilon) return(0); return(-1); } MagickExport MagickBooleanType DrawGradientImage(Image image, const DrawInfo draw_info,ExceptionInfo exception) { CacheView image_view; const GradientInfo gradient; const SegmentInfo gradient_vector; double length; MagickBooleanType status; PixelInfo zero; PointInfo point; RectangleInfo bounding_box; ssize_t y; / Draw linear or radial gradient on image. / assert(image != (Image ) NULL); assert(image->signature == MagickCoreSignature); if (image->debug != MagickFalse) (void) LogMagickEvent(TraceEvent,GetMagickModule(),"%s",image->filename); assert(draw_info != (const DrawInfo ) NULL); gradient=(&draw_info->gradient); qsort(gradient->stops,gradient->number_stops,sizeof(StopInfo), StopInfoCompare); gradient_vector=(&gradient->gradient_vector); point.x=gradient_vector->x2-gradient_vector->x1; point.y=gradient_vector->y2-gradient_vector->y1; length=sqrt(point.xpoint.x+point.ypoint.y); bounding_box=gradient->bounding_box; status=MagickTrue; GetPixelInfo(image,&zero); image_view=AcquireAuthenticCacheView(image,exception); #if defined(MAGICKCORE_OPENMP_SUPPORT) #pragma omp parallel for schedule(static) shared(status) \ magick_number_threads(image,image,bounding_box.height-bounding_box.y,1) #endif for (y=bounding_box.y; y < (ssize_t) bounding_box.height; y++) { PixelInfo composite, pixel; double alpha, offset; register Quantum magick_restrict q; register ssize_t i, x; ssize_t j; if (status == MagickFalse) continue; q=GetCacheViewAuthenticPixels(image_view,0,y,image->columns,1,exception); if (q == (Quantum ) NULL) { status=MagickFalse; continue; } pixel=zero; composite=zero; offset=GetStopColorOffset(gradient,0,y); if (gradient->type != RadialGradient) offset=PerceptibleReciprocal(length); for (x=bounding_box.x; x < (ssize_t) bounding_box.width; x++) { GetPixelInfoPixel(image,q,&pixel); switch (gradient->spread) { case UndefinedSpread: case PadSpread: { if ((x != (ssize_t) ceil(gradient_vector->x1-0.5)) \|\| (y != (ssize_t) ceil(gradient_vector->y1-0.5))) { offset=GetStopColorOffset(gradient,x,y); if (gradient->type != RadialGradient) offset=PerceptibleReciprocal(length); } for (i=0; i < (ssize_t) gradient->number_stops; i++) if (offset < gradient->stops[i].offset) break; if ((offset < 0.0) \|\| (i == 0)) composite=gradient->stops[0].color; else if ((offset > 1.0) \|\| (i == (ssize_t) gradient->number_stops)) composite=gradient->stops[gradient->number_stops-1].color; else { j=i; i--; alpha=(offset-gradient->stops[i].offset)/ (gradient->stops[j].offset-gradient->stops[i].offset); CompositePixelInfoBlend(&gradient->stops[i].color,1.0-alpha, &gradient->stops[j].color,alpha,&composite); } break; } case ReflectSpread: { if ((x != (ssize_t) ceil(gradient_vector->x1-0.5)) \|\| (y != (ssize_t) ceil(gradient_vector->y1-0.5))) { offset=GetStopColorOffset(gradient,x,y); if (gradient->type != RadialGradient) offset=PerceptibleReciprocal(length); } if (offset < 0.0) offset=(-offset); if ((ssize_t) fmod(offset,2.0) == 0) offset=fmod(offset,1.0); else offset=1.0-fmod(offset,1.0); for (i=0; i < (ssize_t) gradient->number_stops; i++) if (offset < gradient->stops[i].offset) break; if (i == 0) composite=gradient->stops[0].color; else if (i == (ssize_t) gradient->number_stops) composite=gradient->stops[gradient->number_stops-1].color; else { j=i; i--; alpha=(offset-gradient->stops[i].offset)/ (gradient->stops[j].offset-gradient->stops[i].offset); CompositePixelInfoBlend(&gradient->stops[i].color,1.0-alpha, &gradient->stops[j].color,alpha,&composite); } break; } case RepeatSpread: { MagickBooleanType antialias; double repeat; antialias=MagickFalse; repeat=0.0; if ((x != (ssize_t) ceil(gradient_vector->x1-0.5)) \|\| (y != (ssize_t) ceil(gradient_vector->y1-0.5))) { offset=GetStopColorOffset(gradient,x,y); if (gradient->type == LinearGradient) { repeat=fmod(offset,length); if (repeat < 0.0) repeat=length-fmod(-repeat,length); else repeat=fmod(offset,length); antialias=(repeat < length) && ((repeat+1.0) > length) ? MagickTrue : MagickFalse; offset=PerceptibleReciprocal(length)repeat; } else { repeat=fmod(offset,gradient->radius); if (repeat < 0.0) repeat=gradient->radius-fmod(-repeat,gradient->radius); else repeat=fmod(offset,gradient->radius); antialias=repeat+1.0 > gradient->radius ? MagickTrue : MagickFalse; offset=repeat/gradient->radius; } } for (i=0; i < (ssize_t) gradient->number_stops; i++) if (offset < gradient->stops[i].offset) break; if (i == 0) composite=gradient->stops[0].color; else if (i == (ssize_t) gradient->number_stops) composite=gradient->stops[gradient->number_stops-1].color; else { j=i; i--; alpha=(offset-gradient->stops[i].offset)/ (gradient->stops[j].offset-gradient->stops[i].offset); if (antialias != MagickFalse) { if (gradient->type == LinearGradient) alpha=length-repeat; else alpha=gradient->radius-repeat; i=0; j=(ssize_t) gradient->number_stops-1L; } CompositePixelInfoBlend(&gradient->stops[i].color,1.0-alpha, &gradient->stops[j].color,alpha,&composite); } break; } } CompositePixelInfoOver(&composite,composite.alpha,&pixel,pixel.alpha, &pixel); SetPixelViaPixelInfo(image,&pixel,q); q+=GetPixelChannels(image); } if (SyncCacheViewAuthenticPixels(image_view,exception) == MagickFalse) status=MagickFalse; } image_view=DestroyCacheView(image_view); return(status); } / %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % D r a w I m a g e % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % DrawImage() draws a graphic primitive on your image. The primitive % may be represented as a string or filename. Precede the filename with an % "at" sign (@) and the contents of the file are drawn on the image. You % can affect how text is drawn by setting one or more members of the draw % info structure. % % The format of the DrawImage method is: % % MagickBooleanType DrawImage(Image image,const DrawInfo draw_info, % ExceptionInfo exception) % % A description of each parameter follows: % % o image: the image. % % o draw_info: the draw info. % % o exception: return any errors or warnings in this structure. % / static MagickBooleanType CheckPrimitiveExtent(MVGInfo mvg_info, const size_t pad) { double extent; size_t quantum; / Check if there is enough storage for drawing pimitives. / extent=(double) mvg_info->offset+pad+PrimitiveExtentPad; quantum=sizeof(mvg_info->primitive_info); if (((extentquantum) < (double) SSIZE_MAX) && ((extentquantum) < (double) GetMaxMemoryRequest())) { if (extent <= (double) mvg_info->extent) return(MagickTrue); mvg_info->primitive_info=(PrimitiveInfo ) ResizeQuantumMemory( mvg_info->primitive_info,(size_t) extent,quantum); if (mvg_info->primitive_info != (PrimitiveInfo ) NULL) { register ssize_t i; mvg_info->extent=(size_t) extent; for (i=mvg_info->offset+1; i < (ssize_t) extent; i++) (mvg_info->primitive_info)[i].primitive=UndefinedPrimitive; return(MagickTrue); } } / Reallocation failed, allocate a primitive to facilitate unwinding. / (void) ThrowMagickException(mvg_info->exception,GetMagickModule(), ResourceLimitError,"MemoryAllocationFailed","`%s'",""); if (mvg_info->primitive_info != (PrimitiveInfo ) NULL) mvg_info->primitive_info=(PrimitiveInfo ) RelinquishMagickMemory( mvg_info->primitive_info); mvg_info->primitive_info=(PrimitiveInfo ) AcquireCriticalMemory( PrimitiveExtentPadquantum); (void) memset(mvg_info->primitive_info,0,PrimitiveExtentPadquantum); mvg_info->extent=1; return(MagickFalse); } MagickExport int MVGMacroCompare(const void target,const void source) { const char p, q; p=(const char ) target; q=(const char ) source; return(strcmp(p,q)); } static SplayTreeInfo GetMVGMacros(const char primitive) { char macro, token; const char q; size_t extent; SplayTreeInfo macros; /* Scan graphic primitives for definitions and classes. / if (primitive == (const char ) NULL) return((SplayTreeInfo ) NULL); macros=NewSplayTree(MVGMacroCompare,RelinquishMagickMemory, RelinquishMagickMemory); macro=AcquireString(primitive); token=AcquireString(primitive); extent=strlen(token)+MagickPathExtent; for (q=primitive; q != '\0'; ) { if (GetNextToken(q,&q,extent,token) < 1) break; if (token == '\0') break; if (LocaleCompare("push",token) == 0) { register const char end, start; (void) GetNextToken(q,&q,extent,token); if (q == '"') { char name[MagickPathExtent]; const char p; ssize_t n; / Named macro (e.g. push graphic-context "wheel"). / (void) GetNextToken(q,&q,extent,token); start=q; end=q; (void) CopyMagickString(name,token,MagickPathExtent); n=1; for (p=q; p != '\0'; ) { if (GetNextToken(p,&p,extent,token) < 1) break; if (token == '\0') break; if (LocaleCompare(token,"pop") == 0) { end=p-strlen(token)-1; n--; } if (LocaleCompare(token,"push") == 0) n++; if ((n == 0) && (end > start)) { / Extract macro. / (void) GetNextToken(p,&p,extent,token); (void) CopyMagickString(macro,start,(size_t) (end-start)); (void) AddValueToSplayTree(macros,ConstantString(name), ConstantString(macro)); break; } } } } } token=DestroyString(token); macro=DestroyString(macro); return(macros); } static inline MagickBooleanType IsPoint(const char point) { char p; double value; value=StringToDouble(point,&p); return((fabs(value) < MagickEpsilon) && (p == point) ? MagickFalse : MagickTrue); } static inline MagickBooleanType TracePoint(PrimitiveInfo primitive_info, const PointInfo point) { primitive_info->coordinates=1; primitive_info->closed_subpath=MagickFalse; primitive_info->point=point; return(MagickTrue); } static MagickBooleanType RenderMVGContent(Image image, const DrawInfo draw_info,const size_t depth,ExceptionInfo exception) { #define RenderImageTag "Render/Image" AffineMatrix affine, current; char keyword[MagickPathExtent], geometry[MagickPathExtent], next_token, pattern[MagickPathExtent], primitive, token; const char q; double angle, coordinates, cursor, factor, primitive_extent; DrawInfo clone_info, *graphic_context; MagickBooleanType proceed; MagickStatusType status; MVGInfo mvg_info; PointInfo point; PrimitiveInfo primitive_info; PrimitiveType primitive_type; register const char p; register ssize_t i, x; SegmentInfo bounds; size_t extent, number_points, number_stops; SplayTreeInfo macros; ssize_t defsDepth, j, k, n, symbolDepth; StopInfo stops; TypeMetric metrics; assert(image != (Image ) NULL); assert(image->signature == MagickCoreSignature); if (image->debug != MagickFalse) (void) LogMagickEvent(TraceEvent,GetMagickModule(),"%s",image->filename); assert(draw_info != (DrawInfo ) NULL); assert(draw_info->signature == MagickCoreSignature); if (image->debug != MagickFalse) (void) LogMagickEvent(TraceEvent,GetMagickModule(),"..."); if (depth > MagickMaxRecursionDepth) ThrowBinaryException(DrawError,"VectorGraphicsNestedTooDeeply", image->filename); if ((draw_info->primitive == (char ) NULL) \|\| (draw_info->primitive == '\0')) return(MagickFalse); if (image->debug != MagickFalse) (void) LogMagickEvent(DrawEvent,GetMagickModule(),"begin draw-image"); if (SetImageStorageClass(image,DirectClass,exception) == MagickFalse) return(MagickFalse); if (image->alpha_trait == UndefinedPixelTrait) { status=SetImageAlphaChannel(image,OpaqueAlphaChannel,exception); if (status == MagickFalse) return(MagickFalse); } if ((draw_info->primitive == '@') && (strlen(draw_info->primitive) > 1) && ((draw_info->primitive+1) != '-') && (depth == 0)) primitive=FileToString(draw_info->primitive+1,~0UL,exception); else primitive=AcquireString(draw_info->primitive); if (primitive == (char ) NULL) return(MagickFalse); primitive_extent=(double) strlen(primitive); (void) SetImageArtifact(image,"mvg:vector-graphics",primitive); n=0; number_stops=0; stops=(StopInfo ) NULL; / Allocate primitive info memory. / graphic_context=(DrawInfo ) AcquireMagickMemory(sizeof(graphic_context)); if (graphic_context == (DrawInfo *) NULL) { primitive=DestroyString(primitive); ThrowBinaryException(ResourceLimitError,"MemoryAllocationFailed", image->filename); } number_points=PrimitiveExtentPad; primitive_info=(PrimitiveInfo ) AcquireQuantumMemory((size_t) number_points, sizeof(primitive_info)); if (primitive_info == (PrimitiveInfo ) NULL) { primitive=DestroyString(primitive); for ( ; n >= 0; n--) graphic_context[n]=DestroyDrawInfo(graphic_context[n]); graphic_context=(DrawInfo *) RelinquishMagickMemory(graphic_context); ThrowBinaryException(ResourceLimitError,"MemoryAllocationFailed", image->filename); } (void) memset(primitive_info,0,(size_t) number_points sizeof(primitive_info)); (void) memset(&mvg_info,0,sizeof(mvg_info)); mvg_info.primitive_info=(&primitive_info); mvg_info.extent=(&number_points); mvg_info.exception=exception; graphic_context[n]=CloneDrawInfo((ImageInfo ) NULL,draw_info); graphic_context[n]->viewbox=image->page; if ((image->page.width == 0) \|\| (image->page.height == 0)) { graphic_context[n]->viewbox.width=image->columns; graphic_context[n]->viewbox.height=image->rows; } token=AcquireString(primitive); extent=strlen(token)+MagickPathExtent; defsDepth=0; symbolDepth=0; cursor=0.0; macros=GetMVGMacros(primitive); status=MagickTrue; for (q=primitive; q != '\0'; ) { / Interpret graphic primitive. / if (GetNextToken(q,&q,MagickPathExtent,keyword) < 1) break; if (keyword == '\0') break; if (keyword == '#') { / Comment. / while ((q != '\n') && (q != '\0')) q++; continue; } p=q-strlen(keyword)-1; primitive_type=UndefinedPrimitive; current=graphic_context[n]->affine; GetAffineMatrix(&affine); token='\0'; switch (keyword) { case ';': break; case 'a': case 'A': { if (LocaleCompare("affine",keyword) == 0) { (void) GetNextToken(q,&q,extent,token); affine.sx=StringToDouble(token,&next_token); if (token == next_token) ThrowPointExpectedException(token,exception); (void) GetNextToken(q,&q,extent,token); if (token == ',') (void) GetNextToken(q,&q,extent,token); affine.rx=StringToDouble(token,&next_token); if (token == next_token) ThrowPointExpectedException(token,exception); (void) GetNextToken(q,&q,extent,token); if (token == ',') (void) GetNextToken(q,&q,extent,token); affine.ry=StringToDouble(token,&next_token); if (token == next_token) ThrowPointExpectedException(token,exception); (void) GetNextToken(q,&q,extent,token); if (token == ',') (void) GetNextToken(q,&q,extent,token); affine.sy=StringToDouble(token,&next_token); if (token == next_token) ThrowPointExpectedException(token,exception); (void) GetNextToken(q,&q,extent,token); if (token == ',') (void) GetNextToken(q,&q,extent,token); affine.tx=StringToDouble(token,&next_token); if (token == next_token) ThrowPointExpectedException(token,exception); (void) GetNextToken(q,&q,extent,token); if (token == ',') (void) GetNextToken(q,&q,extent,token); affine.ty=StringToDouble(token,&next_token); if (token == next_token) ThrowPointExpectedException(token,exception); break; } if (LocaleCompare("alpha",keyword) == 0) { primitive_type=AlphaPrimitive; break; } if (LocaleCompare("arc",keyword) == 0) { primitive_type=ArcPrimitive; break; } status=MagickFalse; break; } case 'b': case 'B': { if (LocaleCompare("bezier",keyword) == 0) { primitive_type=BezierPrimitive; break; } if (LocaleCompare("border-color",keyword) == 0) { (void) GetNextToken(q,&q,extent,token); status&=QueryColorCompliance(token,AllCompliance, &graphic_context[n]->border_color,exception); break; } status=MagickFalse; break; } case 'c': case 'C': { if (LocaleCompare("class",keyword) == 0) { const char mvg_class; (void) GetNextToken(q,&q,extent,token); if (token == '\0') { status=MagickFalse; break; } if (LocaleCompare(token,graphic_context[n]->id) == 0) break; mvg_class=(const char ) GetValueFromSplayTree(macros,token); if (mvg_class != (const char ) NULL) { char elements; ssize_t offset; / Inject class elements in stream. / offset=(ssize_t) (p-primitive); elements=AcquireString(primitive); elements[offset]='\0'; (void) ConcatenateString(&elements,mvg_class); (void) ConcatenateString(&elements,"\n"); (void) ConcatenateString(&elements,q); primitive=DestroyString(primitive); primitive=elements; q=primitive+offset; } break; } if (LocaleCompare("clip-path",keyword) == 0) { const char clip_path; /* Take a node from within the MVG document, and duplicate it here. / (void) GetNextToken(q,&q,extent,token); if (token == '\0') { status=MagickFalse; break; } (void) CloneString(&graphic_context[n]->clip_mask,token); clip_path=(const char ) GetValueFromSplayTree(macros,token); if (clip_path != (const char ) NULL) { if (graphic_context[n]->clipping_mask != (Image ) NULL) graphic_context[n]->clipping_mask= DestroyImage(graphic_context[n]->clipping_mask); graphic_context[n]->clipping_mask=DrawClippingMask(image, graphic_context[n],token,clip_path,exception); if (graphic_context[n]->compliance != SVGCompliance) { clip_path=(const char ) GetValueFromSplayTree(macros, graphic_context[n]->clip_mask); if (clip_path != (const char ) NULL) (void) SetImageArtifact(image, graphic_context[n]->clip_mask,clip_path); status&=DrawClipPath(image,graphic_context[n], graphic_context[n]->clip_mask,exception); } } break; } if (LocaleCompare("clip-rule",keyword) == 0) { ssize_t fill_rule; (void) GetNextToken(q,&q,extent,token); fill_rule=ParseCommandOption(MagickFillRuleOptions,MagickFalse, token); if (fill_rule == -1) { status=MagickFalse; break; } graphic_context[n]->fill_rule=(FillRule) fill_rule; break; } if (LocaleCompare("clip-units",keyword) == 0) { ssize_t clip_units; (void) GetNextToken(q,&q,extent,token); clip_units=ParseCommandOption(MagickClipPathOptions,MagickFalse, token); if (clip_units == -1) { status=MagickFalse; break; } graphic_context[n]->clip_units=(ClipPathUnits) clip_units; if (clip_units == ObjectBoundingBox) { GetAffineMatrix(&current); affine.sx=draw_info->bounds.x2; affine.sy=draw_info->bounds.y2; affine.tx=draw_info->bounds.x1; affine.ty=draw_info->bounds.y1; break; } break; } if (LocaleCompare("circle",keyword) == 0) { primitive_type=CirclePrimitive; break; } if (LocaleCompare("color",keyword) == 0) { primitive_type=ColorPrimitive; break; } if (LocaleCompare("compliance",keyword) == 0) { / MVG compliance associates a clipping mask with an image; SVG compliance associates a clipping mask with a graphics context. / (void) GetNextToken(q,&q,extent,token); graphic_context[n]->compliance=(ComplianceType) ParseCommandOption( MagickComplianceOptions,MagickFalse,token); break; } status=MagickFalse; break; } case 'd': case 'D': { if (LocaleCompare("decorate",keyword) == 0) { ssize_t decorate; (void) GetNextToken(q,&q,extent,token); decorate=ParseCommandOption(MagickDecorateOptions,MagickFalse, token); if (decorate == -1) { status=MagickFalse; break; } graphic_context[n]->decorate=(DecorationType) decorate; break; } if (LocaleCompare("density",keyword) == 0) { (void) GetNextToken(q,&q,extent,token); (void) CloneString(&graphic_context[n]->density,token); break; } if (LocaleCompare("direction",keyword) == 0) { ssize_t direction; (void) GetNextToken(q,&q,extent,token); direction=ParseCommandOption(MagickDirectionOptions,MagickFalse, token); if (direction == -1) status=MagickFalse; else graphic_context[n]->direction=(DirectionType) direction; break; } status=MagickFalse; break; } case 'e': case 'E': { if (LocaleCompare("ellipse",keyword) == 0) { primitive_type=EllipsePrimitive; break; } if (LocaleCompare("encoding",keyword) == 0) { (void) GetNextToken(q,&q,extent,token); (void) CloneString(&graphic_context[n]->encoding,token); break; } status=MagickFalse; break; } case 'f': case 'F': { if (LocaleCompare("fill",keyword) == 0) { (void) GetNextToken(q,&q,extent,token); if (graphic_context[n]->clip_path != MagickFalse) break; (void) FormatLocaleString(pattern,MagickPathExtent,"%s",token); if (GetImageArtifact(image,pattern) != (const char ) NULL) (void) DrawPatternPath(image,draw_info,token, &graphic_context[n]->fill_pattern,exception); else { status&=QueryColorCompliance(token,AllCompliance, &graphic_context[n]->fill,exception); if (graphic_context[n]->fill_alpha != OpaqueAlpha) graphic_context[n]->fill.alpha=graphic_context[n]->fill_alpha; } break; } if (LocaleCompare("fill-opacity",keyword) == 0) { double opacity; (void) GetNextToken(q,&q,extent,token); if (graphic_context[n]->clip_path != MagickFalse) break; factor=strchr(token,'%') != (char ) NULL ? 0.01 : 1.0; opacity=MagickMin(MagickMax(factor StringToDouble(token,&next_token),0.0),1.0); if (token == next_token) ThrowPointExpectedException(token,exception); graphic_context[n]->fill_alpha=opacity; if (graphic_context[n]->fill.alpha != TransparentAlpha) graphic_context[n]->fill.alpha=graphic_context[n]->fill_alpha; else graphic_context[n]->fill.alpha=(MagickRealType) ClampToQuantum(QuantumRange(1.0-opacity)); break; } if (LocaleCompare("fill-rule",keyword) == 0) { ssize_t fill_rule; (void) GetNextToken(q,&q,extent,token); fill_rule=ParseCommandOption(MagickFillRuleOptions,MagickFalse, token); if (fill_rule == -1) { status=MagickFalse; break; } graphic_context[n]->fill_rule=(FillRule) fill_rule; break; } if (LocaleCompare("font",keyword) == 0) { (void) GetNextToken(q,&q,extent,token); (void) CloneString(&graphic_context[n]->font,token); if (LocaleCompare("none",token) == 0) graphic_context[n]->font=(char ) RelinquishMagickMemory( graphic_context[n]->font); break; } if (LocaleCompare("font-family",keyword) == 0) { (void) GetNextToken(q,&q,extent,token); (void) CloneString(&graphic_context[n]->family,token); break; } if (LocaleCompare("font-size",keyword) == 0) { (void) GetNextToken(q,&q,extent,token); graphic_context[n]->pointsize=StringToDouble(token,&next_token); if (token == next_token) ThrowPointExpectedException(token,exception); break; } if (LocaleCompare("font-stretch",keyword) == 0) { ssize_t stretch; (void) GetNextToken(q,&q,extent,token); stretch=ParseCommandOption(MagickStretchOptions,MagickFalse,token); if (stretch == -1) { status=MagickFalse; break; } graphic_context[n]->stretch=(StretchType) stretch; break; } if (LocaleCompare("font-style",keyword) == 0) { ssize_t style; (void) GetNextToken(q,&q,extent,token); style=ParseCommandOption(MagickStyleOptions,MagickFalse,token); if (style == -1) { status=MagickFalse; break; } graphic_context[n]->style=(StyleType) style; break; } if (LocaleCompare("font-weight",keyword) == 0) { ssize_t weight; (void) GetNextToken(q,&q,extent,token); weight=ParseCommandOption(MagickWeightOptions,MagickFalse,token); if (weight == -1) weight=(ssize_t) StringToUnsignedLong(token); graphic_context[n]->weight=(size_t) weight; break; } status=MagickFalse; break; } case 'g': case 'G': { if (LocaleCompare("gradient-units",keyword) == 0) { (void) GetNextToken(q,&q,extent,token); break; } if (LocaleCompare("gravity",keyword) == 0) { ssize_t gravity; (void) GetNextToken(q,&q,extent,token); gravity=ParseCommandOption(MagickGravityOptions,MagickFalse,token); if (gravity == -1) { status=MagickFalse; break; } graphic_context[n]->gravity=(GravityType) gravity; break; } status=MagickFalse; break; } case 'i': case 'I': { if (LocaleCompare("image",keyword) == 0) { ssize_t compose; primitive_type=ImagePrimitive; (void) GetNextToken(q,&q,extent,token); compose=ParseCommandOption(MagickComposeOptions,MagickFalse,token); if (compose == -1) { status=MagickFalse; break; } graphic_context[n]->compose=(CompositeOperator) compose; break; } if (LocaleCompare("interline-spacing",keyword) == 0) { (void) GetNextToken(q,&q,extent,token); graphic_context[n]->interline_spacing=StringToDouble(token, &next_token); if (token == next_token) ThrowPointExpectedException(token,exception); break; } if (LocaleCompare("interword-spacing",keyword) == 0) { (void) GetNextToken(q,&q,extent,token); graphic_context[n]->interword_spacing=StringToDouble(token, &next_token); if (token == next_token) ThrowPointExpectedException(token,exception); break; } status=MagickFalse; break; } case 'k': case 'K': { if (LocaleCompare("kerning",keyword) == 0) { (void) GetNextToken(q,&q,extent,token); graphic_context[n]->kerning=StringToDouble(token,&next_token); if (token == next_token) ThrowPointExpectedException(token,exception); break; } status=MagickFalse; break; } case 'l': case 'L': { if (LocaleCompare("letter-spacing",keyword) == 0) { (void) GetNextToken(q,&q,extent,token); clone_info=CloneDrawInfo((ImageInfo ) NULL,graphic_context[n]); clone_info->text=AcquireString(" "); status&=GetTypeMetrics(image,clone_info,&metrics,exception); graphic_context[n]->kerning=metrics.width* StringToDouble(token,&next_token); clone_info=DestroyDrawInfo(clone_info); if (token == next_token) ThrowPointExpectedException(token,exception); break; } if (LocaleCompare("line",keyword) == 0) { primitive_type=LinePrimitive; break; } status=MagickFalse; break; } case 'm': case 'M': { if (LocaleCompare("mask",keyword) == 0) { const char mask_path; / Take a node from within the MVG document, and duplicate it here. / (void) GetNextToken(q,&q,extent,token); mask_path=(const char ) GetValueFromSplayTree(macros,token); if (mask_path != (const char ) NULL) { if (graphic_context[n]->composite_mask != (Image ) NULL) graphic_context[n]->composite_mask= DestroyImage(graphic_context[n]->composite_mask); graphic_context[n]->composite_mask=DrawCompositeMask(image, graphic_context[n],token,mask_path,exception); if (graphic_context[n]->compliance != SVGCompliance) status=SetImageMask(image,CompositePixelMask, graphic_context[n]->composite_mask,exception); } break; } break; } case 'o': case 'O': { if (LocaleCompare("offset",keyword) == 0) { (void) GetNextToken(q,&q,extent,token); break; } if (LocaleCompare("opacity",keyword) == 0) { double opacity; (void) GetNextToken(q,&q,extent,token); if (graphic_context[n]->clip_path != MagickFalse) break; factor=strchr(token,'%') != (char ) NULL ? 0.01 : 1.0; opacity=MagickMin(MagickMax(factor StringToDouble(token,&next_token),0.0),1.0); if (token == next_token) ThrowPointExpectedException(token,exception); graphic_context[n]->fill_alpha=opacity; graphic_context[n]->stroke_alpha=opacity; break; } status=MagickFalse; break; } case 'p': case 'P': { if (LocaleCompare("path",keyword) == 0) { primitive_type=PathPrimitive; break; } if (LocaleCompare("point",keyword) == 0) { primitive_type=PointPrimitive; break; } if (LocaleCompare("polyline",keyword) == 0) { primitive_type=PolylinePrimitive; break; } if (LocaleCompare("polygon",keyword) == 0) { primitive_type=PolygonPrimitive; break; } if (LocaleCompare("pop",keyword) == 0) { if (GetNextToken(q,&q,extent,token) < 1) break; if (LocaleCompare("class",token) == 0) break; if (LocaleCompare("clip-path",token) == 0) break; if (LocaleCompare("defs",token) == 0) { defsDepth--; graphic_context[n]->render=defsDepth > 0 ? MagickFalse : MagickTrue; break; } if (LocaleCompare("gradient",token) == 0) break; if (LocaleCompare("graphic-context",token) == 0) { if (n <= 0) { (void) ThrowMagickException(exception,GetMagickModule(), DrawError,"UnbalancedGraphicContextPushPop","`%s'",token); status=MagickFalse; n=0; break; } if ((graphic_context[n]->clip_mask != (char ) NULL) && (graphic_context[n]->compliance != SVGCompliance)) if (LocaleCompare(graphic_context[n]->clip_mask, graphic_context[n-1]->clip_mask) != 0) status=SetImageMask(image,WritePixelMask,(Image ) NULL, exception); graphic_context[n]=DestroyDrawInfo(graphic_context[n]); n--; break; } if (LocaleCompare("mask",token) == 0) break; if (LocaleCompare("pattern",token) == 0) break; if (LocaleCompare("symbol",token) == 0) { symbolDepth--; graphic_context[n]->render=symbolDepth > 0 ? MagickFalse : MagickTrue; break; } status=MagickFalse; break; } if (LocaleCompare("push",keyword) == 0) { if (GetNextToken(q,&q,extent,token) < 1) break; if (LocaleCompare("class",token) == 0) { /* Class context. / for (p=q; q != '\0'; ) { if (GetNextToken(q,&q,extent,token) < 1) break; if (LocaleCompare(token,"pop") != 0) continue; (void) GetNextToken(q,(const char *) NULL,extent,token); if (LocaleCompare(token,"class") != 0) continue; break; } (void) GetNextToken(q,&q,extent,token); break; } if (LocaleCompare("clip-path",token) == 0) { (void) GetNextToken(q,&q,extent,token); for (p=q; q != '\0'; ) { if (GetNextToken(q,&q,extent,token) < 1) break; if (LocaleCompare(token,"pop") != 0) continue; (void) GetNextToken(q,(const char *) NULL,extent,token); if (LocaleCompare(token,"clip-path") != 0) continue; break; } if ((q == (char ) NULL) \|\| (p == (char ) NULL) \|\| ((q-4) < p)) { status=MagickFalse; break; } (void) GetNextToken(q,&q,extent,token); break; } if (LocaleCompare("defs",token) == 0) { defsDepth++; graphic_context[n]->render=defsDepth > 0 ? MagickFalse : MagickTrue; break; } if (LocaleCompare("gradient",token) == 0) { char key[2MagickPathExtent], name[MagickPathExtent], type[MagickPathExtent]; SegmentInfo segment; (void) GetNextToken(q,&q,extent,token); (void) CopyMagickString(name,token,MagickPathExtent); (void) GetNextToken(q,&q,extent,token); (void) CopyMagickString(type,token,MagickPathExtent); (void) GetNextToken(q,&q,extent,token); segment.x1=StringToDouble(token,&next_token); if (token == next_token) ThrowPointExpectedException(token,exception); (void) GetNextToken(q,&q,extent,token); if (token == ',') (void) GetNextToken(q,&q,extent,token); segment.y1=StringToDouble(token,&next_token); if (token == next_token) ThrowPointExpectedException(token,exception); (void) GetNextToken(q,&q,extent,token); if (token == ',') (void) GetNextToken(q,&q,extent,token); segment.x2=StringToDouble(token,&next_token); if (token == next_token) ThrowPointExpectedException(token,exception); (void) GetNextToken(q,&q,extent,token); if (token == ',') (void) GetNextToken(q,&q,extent,token); segment.y2=StringToDouble(token,&next_token); if (token == next_token) ThrowPointExpectedException(token,exception); if (LocaleCompare(type,"radial") == 0) { (void) GetNextToken(q,&q,extent,token); if (token == ',') (void) GetNextToken(q,&q,extent,token); } for (p=q; q != '\0'; ) { if (GetNextToken(q,&q,extent,token) < 1) break; if (LocaleCompare(token,"pop") != 0) continue; (void) GetNextToken(q,(const char ) NULL,extent,token); if (LocaleCompare(token,"gradient") != 0) continue; break; } if ((q == (char ) NULL) \|\| (p == (char ) NULL) \|\| ((q-4) < p)) { status=MagickFalse; break; } (void) CopyMagickString(token,p,(size_t) (q-p-4+1)); bounds.x1=graphic_context[n]->affine.sxsegment.x1+ graphic_context[n]->affine.rysegment.y1+ graphic_context[n]->affine.tx; bounds.y1=graphic_context[n]->affine.rxsegment.x1+ graphic_context[n]->affine.sysegment.y1+ graphic_context[n]->affine.ty; bounds.x2=graphic_context[n]->affine.sxsegment.x2+ graphic_context[n]->affine.rysegment.y2+ graphic_context[n]->affine.tx; bounds.y2=graphic_context[n]->affine.rxsegment.x2+ graphic_context[n]->affine.sysegment.y2+ graphic_context[n]->affine.ty; (void) FormatLocaleString(key,MagickPathExtent,"%s",name); (void) SetImageArtifact(image,key,token); (void) FormatLocaleString(key,MagickPathExtent,"%s-type",name); (void) SetImageArtifact(image,key,type); (void) FormatLocaleString(key,MagickPathExtent,"%s-geometry", name); (void) FormatLocaleString(geometry,MagickPathExtent, "%gx%g%+.15g%+.15g", MagickMax(fabs(bounds.x2-bounds.x1+1.0),1.0), MagickMax(fabs(bounds.y2-bounds.y1+1.0),1.0), bounds.x1,bounds.y1); (void) SetImageArtifact(image,key,geometry); (void) GetNextToken(q,&q,extent,token); break; } if (LocaleCompare("graphic-context",token) == 0) { n++; graphic_context=(DrawInfo ) ResizeQuantumMemory( graphic_context,(size_t) (n+1),sizeof(graphic_context)); if (graphic_context == (DrawInfo *) NULL) { (void) ThrowMagickException(exception,GetMagickModule(), ResourceLimitError,"MemoryAllocationFailed","`%s'", image->filename); break; } graphic_context[n]=CloneDrawInfo((ImageInfo ) NULL, graphic_context[n-1]); if (q == '"') { (void) GetNextToken(q,&q,extent,token); (void) CloneString(&graphic_context[n]->id,token); } break; } if (LocaleCompare("mask",token) == 0) { (void) GetNextToken(q,&q,extent,token); break; } if (LocaleCompare("pattern",token) == 0) { char key[2MagickPathExtent], name[MagickPathExtent]; RectangleInfo bounds; (void) GetNextToken(q,&q,extent,token); (void) CopyMagickString(name,token,MagickPathExtent); (void) GetNextToken(q,&q,extent,token); bounds.x=(ssize_t) ceil(StringToDouble(token,&next_token)-0.5); if (token == next_token) ThrowPointExpectedException(token,exception); (void) GetNextToken(q,&q,extent,token); if (token == ',') (void) GetNextToken(q,&q,extent,token); bounds.y=(ssize_t) ceil(StringToDouble(token,&next_token)-0.5); if (token == next_token) ThrowPointExpectedException(token,exception); (void) GetNextToken(q,&q,extent,token); if (token == ',') (void) GetNextToken(q,&q,extent,token); bounds.width=(size_t) floor(StringToDouble(token,&next_token)+ 0.5); if (token == next_token) ThrowPointExpectedException(token,exception); (void) GetNextToken(q,&q,extent,token); if (token == ',') (void) GetNextToken(q,&q,extent,token); bounds.height=(size_t) floor(StringToDouble(token,&next_token)+ 0.5); if (token == next_token) ThrowPointExpectedException(token,exception); for (p=q; q != '\0'; ) { if (GetNextToken(q,&q,extent,token) < 1) break; if (LocaleCompare(token,"pop") != 0) continue; (void) GetNextToken(q,(const char *) NULL,extent,token); if (LocaleCompare(token,"pattern") != 0) continue; break; } if ((q == (char ) NULL) \|\| (p == (char ) NULL) \|\| ((q-4) < p)) { status=MagickFalse; break; } (void) CopyMagickString(token,p,(size_t) (q-p-4+1)); (void) FormatLocaleString(key,MagickPathExtent,"%s",name); (void) SetImageArtifact(image,key,token); (void) FormatLocaleString(key,MagickPathExtent,"%s-geometry", name); (void) FormatLocaleString(geometry,MagickPathExtent, "%.20gx%.20g%+.20g%+.20g",(double) bounds.width,(double) bounds.height,(double) bounds.x,(double) bounds.y); (void) SetImageArtifact(image,key,geometry); (void) GetNextToken(q,&q,extent,token); break; } if (LocaleCompare("symbol",token) == 0) { symbolDepth++; graphic_context[n]->render=symbolDepth > 0 ? MagickFalse : MagickTrue; break; } status=MagickFalse; break; } status=MagickFalse; break; } case 'r': case 'R': { if (LocaleCompare("rectangle",keyword) == 0) { primitive_type=RectanglePrimitive; break; } if (LocaleCompare("rotate",keyword) == 0) { (void) GetNextToken(q,&q,extent,token); angle=StringToDouble(token,&next_token); if (token == next_token) ThrowPointExpectedException(token,exception); affine.sx=cos(DegreesToRadians(fmod((double) angle,360.0))); affine.rx=sin(DegreesToRadians(fmod((double) angle,360.0))); affine.ry=(-sin(DegreesToRadians(fmod((double) angle,360.0)))); affine.sy=cos(DegreesToRadians(fmod((double) angle,360.0))); break; } if (LocaleCompare("roundRectangle",keyword) == 0) { primitive_type=RoundRectanglePrimitive; break; } status=MagickFalse; break; } case 's': case 'S': { if (LocaleCompare("scale",keyword) == 0) { (void) GetNextToken(q,&q,extent,token); affine.sx=StringToDouble(token,&next_token); if (token == next_token) ThrowPointExpectedException(token,exception); (void) GetNextToken(q,&q,extent,token); if (token == ',') (void) GetNextToken(q,&q,extent,token); affine.sy=StringToDouble(token,&next_token); if (token == next_token) ThrowPointExpectedException(token,exception); break; } if (LocaleCompare("skewX",keyword) == 0) { (void) GetNextToken(q,&q,extent,token); angle=StringToDouble(token,&next_token); if (token == next_token) ThrowPointExpectedException(token,exception); affine.ry=sin(DegreesToRadians(angle)); break; } if (LocaleCompare("skewY",keyword) == 0) { (void) GetNextToken(q,&q,extent,token); angle=StringToDouble(token,&next_token); if (token == next_token) ThrowPointExpectedException(token,exception); affine.rx=(-tan(DegreesToRadians(angle)/2.0)); break; } if (LocaleCompare("stop-color",keyword) == 0) { PixelInfo stop_color; number_stops++; if (number_stops == 1) stops=(StopInfo ) AcquireQuantumMemory(2,sizeof(stops)); else if (number_stops > 2) stops=(StopInfo ) ResizeQuantumMemory(stops,number_stops, sizeof(stops)); if (stops == (StopInfo ) NULL) { (void) ThrowMagickException(exception,GetMagickModule(), ResourceLimitError,"MemoryAllocationFailed","`%s'", image->filename); break; } (void) GetNextToken(q,&q,extent,token); status&=QueryColorCompliance(token,AllCompliance,&stop_color, exception); stops[number_stops-1].color=stop_color; (void) GetNextToken(q,&q,extent,token); factor=strchr(token,'%') != (char ) NULL ? 0.01 : 1.0; stops[number_stops-1].offset=factorStringToDouble(token, &next_token); if (token == next_token) ThrowPointExpectedException(token,exception); break; } if (LocaleCompare("stroke",keyword) == 0) { (void) GetNextToken(q,&q,extent,token); if (graphic_context[n]->clip_path != MagickFalse) break; (void) FormatLocaleString(pattern,MagickPathExtent,"%s",token); if (GetImageArtifact(image,pattern) != (const char ) NULL) (void) DrawPatternPath(image,draw_info,token, &graphic_context[n]->stroke_pattern,exception); else { status&=QueryColorCompliance(token,AllCompliance, &graphic_context[n]->stroke,exception); if (graphic_context[n]->stroke_alpha != OpaqueAlpha) graphic_context[n]->stroke.alpha= graphic_context[n]->stroke_alpha; } break; } if (LocaleCompare("stroke-antialias",keyword) == 0) { (void) GetNextToken(q,&q,extent,token); graphic_context[n]->stroke_antialias=StringToLong(token) != 0 ? MagickTrue : MagickFalse; break; } if (LocaleCompare("stroke-dasharray",keyword) == 0) { if (graphic_context[n]->dash_pattern != (double ) NULL) graphic_context[n]->dash_pattern=(double ) RelinquishMagickMemory(graphic_context[n]->dash_pattern); if (IsPoint(q) != MagickFalse) { const char r; r=q; (void) GetNextToken(r,&r,extent,token); if (token == ',') (void) GetNextToken(r,&r,extent,token); for (x=0; IsPoint(token) != MagickFalse; x++) { (void) GetNextToken(r,&r,extent,token); if (token == ',') (void) GetNextToken(r,&r,extent,token); } graphic_context[n]->dash_pattern=(double ) AcquireQuantumMemory((size_t) (2x+2), sizeof(graphic_context[n]->dash_pattern)); if (graphic_context[n]->dash_pattern == (double ) NULL) { (void) ThrowMagickException(exception,GetMagickModule(), ResourceLimitError,"MemoryAllocationFailed","`%s'", image->filename); status=MagickFalse; break; } (void) memset(graphic_context[n]->dash_pattern,0,(size_t) (2x+2)sizeof(graphic_context[n]->dash_pattern)); for (j=0; j < x; j++) { (void) GetNextToken(q,&q,extent,token); if (token == ',') (void) GetNextToken(q,&q,extent,token); graphic_context[n]->dash_pattern[j]=StringToDouble(token, &next_token); if (token == next_token) ThrowPointExpectedException(token,exception); if (graphic_context[n]->dash_pattern[j] < 0.0) status=MagickFalse; } if ((x & 0x01) != 0) for ( ; j < (2x); j++) graphic_context[n]->dash_pattern[j]= graphic_context[n]->dash_pattern[j-x]; graphic_context[n]->dash_pattern[j]=0.0; break; } (void) GetNextToken(q,&q,extent,token); break; } if (LocaleCompare("stroke-dashoffset",keyword) == 0) { (void) GetNextToken(q,&q,extent,token); graphic_context[n]->dash_offset=StringToDouble(token,&next_token); if (token == next_token) ThrowPointExpectedException(token,exception); break; } if (LocaleCompare("stroke-linecap",keyword) == 0) { ssize_t linecap; (void) GetNextToken(q,&q,extent,token); linecap=ParseCommandOption(MagickLineCapOptions,MagickFalse,token); if (linecap == -1) { status=MagickFalse; break; } graphic_context[n]->linecap=(LineCap) linecap; break; } if (LocaleCompare("stroke-linejoin",keyword) == 0) { ssize_t linejoin; (void) GetNextToken(q,&q,extent,token); linejoin=ParseCommandOption(MagickLineJoinOptions,MagickFalse, token); if (linejoin == -1) { status=MagickFalse; break; } graphic_context[n]->linejoin=(LineJoin) linejoin; break; } if (LocaleCompare("stroke-miterlimit",keyword) == 0) { (void) GetNextToken(q,&q,extent,token); graphic_context[n]->miterlimit=StringToUnsignedLong(token); break; } if (LocaleCompare("stroke-opacity",keyword) == 0) { double opacity; (void) GetNextToken(q,&q,extent,token); if (graphic_context[n]->clip_path != MagickFalse) break; factor=strchr(token,'%') != (char ) NULL ? 0.01 : 1.0; opacity=MagickMin(MagickMax(factor StringToDouble(token,&next_token),0.0),1.0); if (token == next_token) ThrowPointExpectedException(token,exception); graphic_context[n]->stroke_alpha=opacity; if (graphic_context[n]->stroke.alpha != TransparentAlpha) graphic_context[n]->stroke.alpha=graphic_context[n]->stroke_alpha; else graphic_context[n]->stroke.alpha=(MagickRealType) ClampToQuantum(QuantumRange(1.0-opacity)); break; } if (LocaleCompare("stroke-width",keyword) == 0) { (void) GetNextToken(q,&q,extent,token); if (graphic_context[n]->clip_path != MagickFalse) break; graphic_context[n]->stroke_width=StringToDouble(token,&next_token); if (token == next_token) ThrowPointExpectedException(token,exception); break; } status=MagickFalse; break; } case 't': case 'T': { if (LocaleCompare("text",keyword) == 0) { primitive_type=TextPrimitive; break; } if (LocaleCompare("text-align",keyword) == 0) { ssize_t align; (void) GetNextToken(q,&q,extent,token); align=ParseCommandOption(MagickAlignOptions,MagickFalse,token); if (align == -1) { status=MagickFalse; break; } graphic_context[n]->align=(AlignType) align; break; } if (LocaleCompare("text-anchor",keyword) == 0) { ssize_t align; (void) GetNextToken(q,&q,extent,token); align=ParseCommandOption(MagickAlignOptions,MagickFalse,token); if (align == -1) { status=MagickFalse; break; } graphic_context[n]->align=(AlignType) align; break; } if (LocaleCompare("text-antialias",keyword) == 0) { (void) GetNextToken(q,&q,extent,token); graphic_context[n]->text_antialias=StringToLong(token) != 0 ? MagickTrue : MagickFalse; break; } if (LocaleCompare("text-undercolor",keyword) == 0) { (void) GetNextToken(q,&q,extent,token); status&=QueryColorCompliance(token,AllCompliance, &graphic_context[n]->undercolor,exception); break; } if (LocaleCompare("translate",keyword) == 0) { (void) GetNextToken(q,&q,extent,token); affine.tx=StringToDouble(token,&next_token); if (token == next_token) ThrowPointExpectedException(token,exception); (void) GetNextToken(q,&q,extent,token); if (token == ',') (void) GetNextToken(q,&q,extent,token); affine.ty=StringToDouble(token,&next_token); if (token == next_token) ThrowPointExpectedException(token,exception); cursor=0.0; break; } status=MagickFalse; break; } case 'u': case 'U': { if (LocaleCompare("use",keyword) == 0) { const char use; /* Get a macro from the MVG document, and "use" it here. / (void) GetNextToken(q,&q,extent,token); use=(const char ) GetValueFromSplayTree(macros,token); if (use != (const char ) NULL) { clone_info=CloneDrawInfo((ImageInfo ) NULL,graphic_context[n]); (void) CloneString(&clone_info->primitive,use); status=RenderMVGContent(image,clone_info,depth+1,exception); clone_info=DestroyDrawInfo(clone_info); } break; } break; } case 'v': case 'V': { if (LocaleCompare("viewbox",keyword) == 0) { (void) GetNextToken(q,&q,extent,token); graphic_context[n]->viewbox.x=(ssize_t) ceil(StringToDouble(token, &next_token)-0.5); if (token == next_token) ThrowPointExpectedException(token,exception); (void) GetNextToken(q,&q,extent,token); if (token == ',') (void) GetNextToken(q,&q,extent,token); graphic_context[n]->viewbox.y=(ssize_t) ceil(StringToDouble(token, &next_token)-0.5); if (token == next_token) ThrowPointExpectedException(token,exception); (void) GetNextToken(q,&q,extent,token); if (token == ',') (void) GetNextToken(q,&q,extent,token); graphic_context[n]->viewbox.width=(size_t) floor(StringToDouble( token,&next_token)+0.5); if (token == next_token) ThrowPointExpectedException(token,exception); (void) GetNextToken(q,&q,extent,token); if (token == ',') (void) GetNextToken(q,&q,extent,token); graphic_context[n]->viewbox.height=(size_t) floor(StringToDouble( token,&next_token)+0.5); if (token == next_token) ThrowPointExpectedException(token,exception); break; } status=MagickFalse; break; } case 'w': case 'W': { if (LocaleCompare("word-spacing",keyword) == 0) { (void) GetNextToken(q,&q,extent,token); graphic_context[n]->interword_spacing=StringToDouble(token, &next_token); if (token == next_token) ThrowPointExpectedException(token,exception); break; } status=MagickFalse; break; } default: { status=MagickFalse; break; } } if (status == MagickFalse) break; if ((fabs(affine.sx-1.0) >= MagickEpsilon) \|\| (fabs(affine.rx) >= MagickEpsilon) \|\| (fabs(affine.ry) >= MagickEpsilon) \|\| (fabs(affine.sy-1.0) >= MagickEpsilon) \|\| (fabs(affine.tx) >= MagickEpsilon) \|\| (fabs(affine.ty) >= MagickEpsilon)) { graphic_context[n]->affine.sx=current.sxaffine.sx+current.ryaffine.rx; graphic_context[n]->affine.rx=current.rxaffine.sx+current.syaffine.rx; graphic_context[n]->affine.ry=current.sxaffine.ry+current.ryaffine.sy; graphic_context[n]->affine.sy=current.rxaffine.ry+current.syaffine.sy; graphic_context[n]->affine.tx=current.sxaffine.tx+current.ryaffine.ty+ current.tx; graphic_context[n]->affine.ty=current.rxaffine.tx+current.syaffine.ty+ current.ty; } if (primitive_type == UndefinedPrimitive) { if (q == '\0') { if (number_stops > 1) { GradientType type; type=LinearGradient; if (draw_info->gradient.type == RadialGradient) type=RadialGradient; (void) GradientImage(image,type,PadSpread,stops,number_stops, exception); } if (number_stops > 0) stops=(StopInfo ) RelinquishMagickMemory(stops); } if ((image->debug != MagickFalse) && (q > p)) (void) LogMagickEvent(DrawEvent,GetMagickModule()," %.s",(int) (q-p-1),p); continue; } /* Parse the primitive attributes. / for (i=0; primitive_info[i].primitive != UndefinedPrimitive; i++) if ((primitive_info[i].primitive == TextPrimitive) \|\| (primitive_info[i].primitive == ImagePrimitive)) if (primitive_info[i].text != (char ) NULL) primitive_info[i].text=DestroyString(primitive_info[i].text); i=0; mvg_info.offset=i; j=0; primitive_info[0].point.x=0.0; primitive_info[0].point.y=0.0; primitive_info[0].coordinates=0; primitive_info[0].method=FloodfillMethod; primitive_info[0].closed_subpath=MagickFalse; for (x=0; q != '\0'; x++) { / Define points. / if (IsPoint(q) == MagickFalse) break; (void) GetNextToken(q,&q,extent,token); point.x=StringToDouble(token,&next_token); if (token == next_token) ThrowPointExpectedException(token,exception); (void) GetNextToken(q,&q,extent,token); if (token == ',') (void) GetNextToken(q,&q,extent,token); point.y=StringToDouble(token,&next_token); if (token == next_token) ThrowPointExpectedException(token,exception); (void) GetNextToken(q,(const char *) NULL,extent,token); if (token == ',') (void) GetNextToken(q,&q,extent,token); primitive_info[i].primitive=primitive_type; primitive_info[i].point=point; primitive_info[i].coordinates=0; primitive_info[i].method=FloodfillMethod; primitive_info[i].closed_subpath=MagickFalse; i++; mvg_info.offset=i; if (i < (ssize_t) number_points) continue; status&=CheckPrimitiveExtent(&mvg_info,number_points); } if (status == MagickFalse) break; if ((primitive_info[j].primitive == TextPrimitive) \|\| (primitive_info[j].primitive == ImagePrimitive)) if (primitive_info[j].text != (char ) NULL) primitive_info[j].text=DestroyString(primitive_info[j].text); primitive_info[j].primitive=primitive_type; primitive_info[j].coordinates=(size_t) x; primitive_info[j].method=FloodfillMethod; primitive_info[j].closed_subpath=MagickFalse; / Circumscribe primitive within a circle. / bounds.x1=primitive_info[j].point.x; bounds.y1=primitive_info[j].point.y; bounds.x2=primitive_info[j].point.x; bounds.y2=primitive_info[j].point.y; for (k=1; k < (ssize_t) primitive_info[j].coordinates; k++) { point=primitive_info[j+k].point; if (point.x < bounds.x1) bounds.x1=point.x; if (point.y < bounds.y1) bounds.y1=point.y; if (point.x > bounds.x2) bounds.x2=point.x; if (point.y > bounds.y2) bounds.y2=point.y; } / Speculate how many points our primitive might consume. / coordinates=(double) primitive_info[j].coordinates; switch (primitive_type) { case RectanglePrimitive: { coordinates=5.0; break; } case RoundRectanglePrimitive: { double alpha, beta, radius; alpha=bounds.x2-bounds.x1; beta=bounds.y2-bounds.y1; radius=hypot((double) alpha,(double) beta); coordinates=5.0; coordinates+=2.0((size_t) ceil((double) MagickPIradius))+6.0 BezierQuantum+360.0; break; } case BezierPrimitive: { coordinates=(double) (BezierQuantumprimitive_info[j].coordinates); if (primitive_info[j].coordinates > (107BezierQuantum)) { (void) ThrowMagickException(exception,GetMagickModule(),DrawError, "TooManyBezierCoordinates","`%s'",token); status=MagickFalse; break; } break; } case PathPrimitive: { char s, t; (void) GetNextToken(q,&q,extent,token); coordinates=1.0; t=token; for (s=token; s != '\0'; s=t) { double value; value=StringToDouble(s,&t); (void) value; if (s == t) { t++; continue; } coordinates++; } for (s=token; s != '\0'; s++) if (strspn(s,"AaCcQqSsTt") != 0) coordinates+=(20.0BezierQuantum)+360.0; break; } case CirclePrimitive: case ArcPrimitive: case EllipsePrimitive: { double alpha, beta, radius; alpha=bounds.x2-bounds.x1; beta=bounds.y2-bounds.y1; radius=hypot(alpha,beta); coordinates=2.0(ceil(MagickPIradius))+6.0BezierQuantum+360.0; break; } default: break; } if (coordinates > MaxBezierCoordinates) { (void) ThrowMagickException(exception,GetMagickModule(), ResourceLimitError,"TooManyBezierCoordinates","`%s'",token); status=MagickFalse; } if (status == MagickFalse) break; if (((size_t) (i+coordinates)) >= number_points) { /* Resize based on speculative points required by primitive. / number_points+=coordinates+1; if (number_points < (size_t) coordinates) { (void) ThrowMagickException(exception,GetMagickModule(), ResourceLimitError,"MemoryAllocationFailed","`%s'", image->filename); break; } mvg_info.offset=i; status&=CheckPrimitiveExtent(&mvg_info,number_points); } status&=CheckPrimitiveExtent(&mvg_info,PrimitiveExtentPad); if (status == MagickFalse) break; mvg_info.offset=j; switch (primitive_type) { case PointPrimitive: default: { if (primitive_info[j].coordinates != 1) { status=MagickFalse; break; } status&=TracePoint(primitive_info+j,primitive_info[j].point); i=(ssize_t) (j+primitive_info[j].coordinates); break; } case LinePrimitive: { if (primitive_info[j].coordinates != 2) { status=MagickFalse; break; } status&=TraceLine(primitive_info+j,primitive_info[j].point, primitive_info[j+1].point); i=(ssize_t) (j+primitive_info[j].coordinates); break; } case RectanglePrimitive: { if (primitive_info[j].coordinates != 2) { status=MagickFalse; break; } status&=TraceRectangle(primitive_info+j,primitive_info[j].point, primitive_info[j+1].point); i=(ssize_t) (j+primitive_info[j].coordinates); break; } case RoundRectanglePrimitive: { if (primitive_info[j].coordinates != 3) { status=MagickFalse; break; } if ((primitive_info[j+2].point.x < 0.0) \|\| (primitive_info[j+2].point.y < 0.0)) { status=MagickFalse; break; } if ((primitive_info[j+1].point.x-primitive_info[j].point.x) < 0.0) { status=MagickFalse; break; } if ((primitive_info[j+1].point.y-primitive_info[j].point.y) < 0.0) { status=MagickFalse; break; } status&=TraceRoundRectangle(&mvg_info,primitive_info[j].point, primitive_info[j+1].point,primitive_info[j+2].point); i=(ssize_t) (j+primitive_info[j].coordinates); break; } case ArcPrimitive: { if (primitive_info[j].coordinates != 3) { primitive_type=UndefinedPrimitive; break; } status&=TraceArc(&mvg_info,primitive_info[j].point, primitive_info[j+1].point,primitive_info[j+2].point); i=(ssize_t) (j+primitive_info[j].coordinates); break; } case EllipsePrimitive: { if (primitive_info[j].coordinates != 3) { status=MagickFalse; break; } if ((primitive_info[j+1].point.x < 0.0) \|\| (primitive_info[j+1].point.y < 0.0)) { status=MagickFalse; break; } status&=TraceEllipse(&mvg_info,primitive_info[j].point, primitive_info[j+1].point,primitive_info[j+2].point); i=(ssize_t) (j+primitive_info[j].coordinates); break; } case CirclePrimitive: { if (primitive_info[j].coordinates != 2) { status=MagickFalse; break; } status&=TraceCircle(&mvg_info,primitive_info[j].point, primitive_info[j+1].point); i=(ssize_t) (j+primitive_info[j].coordinates); break; } case PolylinePrimitive: { if (primitive_info[j].coordinates < 1) { status=MagickFalse; break; } break; } case PolygonPrimitive: { if (primitive_info[j].coordinates < 3) { status=MagickFalse; break; } primitive_info[i]=primitive_info[j]; primitive_info[i].coordinates=0; primitive_info[j].coordinates++; primitive_info[j].closed_subpath=MagickTrue; i++; break; } case BezierPrimitive: { if (primitive_info[j].coordinates < 3) { status=MagickFalse; break; } status&=TraceBezier(&mvg_info,primitive_info[j].coordinates); i=(ssize_t) (j+primitive_info[j].coordinates); break; } case PathPrimitive: { coordinates=(double) TracePath(&mvg_info,token,exception); if (coordinates == 0.0) { status=MagickFalse; break; } i=(ssize_t) (j+coordinates); break; } case AlphaPrimitive: case ColorPrimitive: { ssize_t method; if (primitive_info[j].coordinates != 1) { status=MagickFalse; break; } (void) GetNextToken(q,&q,extent,token); method=ParseCommandOption(MagickMethodOptions,MagickFalse,token); if (method == -1) { status=MagickFalse; break; } primitive_info[j].method=(PaintMethod) method; break; } case TextPrimitive: { char geometry[MagickPathExtent]; if (primitive_info[j].coordinates != 1) { status=MagickFalse; break; } if (token != ',') (void) GetNextToken(q,&q,extent,token); (void) CloneString(&primitive_info[j].text,token); /* Compute text cursor offset. / clone_info=CloneDrawInfo((ImageInfo ) NULL,graphic_context[n]); if ((fabs(mvg_info.point.x-primitive_info->point.x) < MagickEpsilon) && (fabs(mvg_info.point.y-primitive_info->point.y) < MagickEpsilon)) { mvg_info.point=primitive_info->point; primitive_info->point.x+=cursor; } else { mvg_info.point=primitive_info->point; cursor=0.0; } (void) FormatLocaleString(geometry,MagickPathExtent,"%+f%+f", primitive_info->point.x,primitive_info->point.y); clone_info->render=MagickFalse; clone_info->text=AcquireString(token); status&=GetTypeMetrics(image,clone_info,&metrics,exception); clone_info=DestroyDrawInfo(clone_info); cursor+=metrics.width; if (graphic_context[n]->compliance != SVGCompliance) cursor=0.0; break; } case ImagePrimitive: { if (primitive_info[j].coordinates != 2) { status=MagickFalse; break; } (void) GetNextToken(q,&q,extent,token); (void) CloneString(&primitive_info[j].text,token); break; } } mvg_info.offset=i; if ((image->debug != MagickFalse) && (q > p)) (void) LogMagickEvent(DrawEvent,GetMagickModule()," %.s",(int) (q-p-1), p); if (status == MagickFalse) break; primitive_info[i].primitive=UndefinedPrimitive; if (i == 0) continue; / Transform points. / for (i=0; primitive_info[i].primitive != UndefinedPrimitive; i++) { point=primitive_info[i].point; primitive_info[i].point.x=graphic_context[n]->affine.sxpoint.x+ graphic_context[n]->affine.rypoint.y+graphic_context[n]->affine.tx; primitive_info[i].point.y=graphic_context[n]->affine.rxpoint.x+ graphic_context[n]->affine.sypoint.y+graphic_context[n]->affine.ty; point=primitive_info[i].point; if (point.x < graphic_context[n]->bounds.x1) graphic_context[n]->bounds.x1=point.x; if (point.y < graphic_context[n]->bounds.y1) graphic_context[n]->bounds.y1=point.y; if (point.x > graphic_context[n]->bounds.x2) graphic_context[n]->bounds.x2=point.x; if (point.y > graphic_context[n]->bounds.y2) graphic_context[n]->bounds.y2=point.y; if (primitive_info[i].primitive == ImagePrimitive) break; if (i >= (ssize_t) number_points) ThrowFatalException(ResourceLimitFatalError,"MemoryAllocationFailed"); } if (graphic_context[n]->render != MagickFalse) { if ((n != 0) && (graphic_context[n]->compliance != SVGCompliance) && (graphic_context[n]->clip_mask != (char ) NULL) && (LocaleCompare(graphic_context[n]->clip_mask, graphic_context[n-1]->clip_mask) != 0)) { const char clip_path; clip_path=(const char ) GetValueFromSplayTree(macros, graphic_context[n]->clip_mask); if (clip_path != (const char ) NULL) (void) SetImageArtifact(image,graphic_context[n]->clip_mask, clip_path); status&=DrawClipPath(image,graphic_context[n], graphic_context[n]->clip_mask,exception); } status&=DrawPrimitive(image,graphic_context[n],primitive_info, exception); } proceed=SetImageProgress(image,RenderImageTag,q-primitive,(MagickSizeType) primitive_extent); if (proceed == MagickFalse) break; if (status == 0) break; } if (image->debug != MagickFalse) (void) LogMagickEvent(DrawEvent,GetMagickModule(),"end draw-image"); / Relinquish resources. / macros=DestroySplayTree(macros); token=DestroyString(token); if (primitive_info != (PrimitiveInfo ) NULL) { for (i=0; primitive_info[i].primitive != UndefinedPrimitive; i++) if ((primitive_info[i].primitive == TextPrimitive) \|\| (primitive_info[i].primitive == ImagePrimitive)) if (primitive_info[i].text != (char ) NULL) primitive_info[i].text=DestroyString(primitive_info[i].text); primitive_info=(PrimitiveInfo ) RelinquishMagickMemory(primitive_info); } primitive=DestroyString(primitive); if (stops != (StopInfo ) NULL) stops=(StopInfo ) RelinquishMagickMemory(stops); for ( ; n >= 0; n--) graphic_context[n]=DestroyDrawInfo(graphic_context[n]); graphic_context=(DrawInfo *) RelinquishMagickMemory(graphic_context); if (status == MagickFalse) ThrowBinaryException(DrawError,"NonconformingDrawingPrimitiveDefinition", keyword); return(status != 0 ? MagickTrue : MagickFalse); } MagickExport MagickBooleanType DrawImage(Image image,const DrawInfo draw_info, ExceptionInfo exception) { return(RenderMVGContent(image,draw_info,0,exception)); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % D r a w P a t t e r n P a t h % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % DrawPatternPath() draws a pattern. % % The format of the DrawPatternPath method is: % % MagickBooleanType DrawPatternPath(Image image,const DrawInfo draw_info, % const char name,Image pattern,ExceptionInfo exception) % % A description of each parameter follows: % % o image: the image. % % o draw_info: the draw info. % % o name: the pattern name. % % o image: the image. % % o exception: return any errors or warnings in this structure. % / MagickExport MagickBooleanType DrawPatternPath(Image image, const DrawInfo draw_info,const char name,Image *pattern, ExceptionInfo exception) { char property[MagickPathExtent]; const char geometry, path, type; DrawInfo clone_info; ImageInfo image_info; MagickBooleanType status; assert(image != (Image ) NULL); assert(image->signature == MagickCoreSignature); if (image->debug != MagickFalse) (void) LogMagickEvent(TraceEvent,GetMagickModule(),"%s",image->filename); assert(draw_info != (const DrawInfo ) NULL); assert(name != (const char ) NULL); (void) FormatLocaleString(property,MagickPathExtent,"%s",name); path=GetImageArtifact(image,property); if (path == (const char ) NULL) return(MagickFalse); (void) FormatLocaleString(property,MagickPathExtent,"%s-geometry",name); geometry=GetImageArtifact(image,property); if (geometry == (const char ) NULL) return(MagickFalse); if ((pattern) != (Image ) NULL) pattern=DestroyImage(pattern); image_info=AcquireImageInfo(); image_info->size=AcquireString(geometry); pattern=AcquireImage(image_info,exception); image_info=DestroyImageInfo(image_info); (void) QueryColorCompliance("#000000ff",AllCompliance, &(pattern)->background_color,exception); (void) SetImageBackgroundColor(pattern,exception); if (image->debug != MagickFalse) (void) LogMagickEvent(DrawEvent,GetMagickModule(), "begin pattern-path %s %s",name,geometry); clone_info=CloneDrawInfo((ImageInfo ) NULL,draw_info); clone_info->fill_pattern=NewImageList(); clone_info->stroke_pattern=NewImageList(); (void) FormatLocaleString(property,MagickPathExtent,"%s-type",name); type=GetImageArtifact(image,property); if (type != (const char ) NULL) clone_info->gradient.type=(GradientType) ParseCommandOption( MagickGradientOptions,MagickFalse,type); (void) CloneString(&clone_info->primitive,path); status=RenderMVGContent(pattern,clone_info,0,exception); clone_info=DestroyDrawInfo(clone_info); if (image->debug != MagickFalse) (void) LogMagickEvent(DrawEvent,GetMagickModule(),"end pattern-path"); return(status); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % + D r a w P o l y g o n P r i m i t i v e % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % DrawPolygonPrimitive() draws a polygon on the image. % % The format of the DrawPolygonPrimitive method is: % % MagickBooleanType DrawPolygonPrimitive(Image image, % const DrawInfo draw_info,const PrimitiveInfo primitive_info, % ExceptionInfo exception) % % A description of each parameter follows: % % o image: the image. % % o draw_info: the draw info. % % o primitive_info: Specifies a pointer to a PrimitiveInfo structure. % % o exception: return any errors or warnings in this structure. % / static PolygonInfo DestroyPolygonThreadSet(PolygonInfo polygon_info) { register ssize_t i; assert(polygon_info != (PolygonInfo ) NULL); for (i=0; i < (ssize_t) GetMagickResourceLimit(ThreadResource); i++) if (polygon_info[i] != (PolygonInfo ) NULL) polygon_info[i]=DestroyPolygonInfo(polygon_info[i]); polygon_info=(PolygonInfo ) RelinquishMagickMemory(polygon_info); return(polygon_info); } static PolygonInfo AcquirePolygonThreadSet( const PrimitiveInfo primitive_info) { PathInfo magick_restrict path_info; PolygonInfo polygon_info; register ssize_t i; size_t number_threads; number_threads=(size_t) GetMagickResourceLimit(ThreadResource); polygon_info=(PolygonInfo ) AcquireQuantumMemory(number_threads, sizeof(polygon_info)); if (polygon_info == (PolygonInfo ) NULL) return((PolygonInfo ) NULL); (void) memset(polygon_info,0,number_threadssizeof(polygon_info)); path_info=ConvertPrimitiveToPath(primitive_info); if (path_info == (PathInfo ) NULL) return(DestroyPolygonThreadSet(polygon_info)); for (i=0; i < (ssize_t) number_threads; i++) { polygon_info[i]=ConvertPathToPolygon(path_info); if (polygon_info[i] == (PolygonInfo ) NULL) return(DestroyPolygonThreadSet(polygon_info)); } path_info=(PathInfo ) RelinquishMagickMemory(path_info); return(polygon_info); } static double GetFillAlpha(PolygonInfo polygon_info,const double mid, const MagickBooleanType fill,const FillRule fill_rule,const ssize_t x, const ssize_t y,double stroke_alpha) { double alpha, beta, distance, subpath_alpha; PointInfo delta; register const PointInfo q; register EdgeInfo p; register ssize_t i; ssize_t j, winding_number; /* Compute fill & stroke opacity for this (x,y) point. / stroke_alpha=0.0; subpath_alpha=0.0; p=polygon_info->edges; for (j=0; j < (ssize_t) polygon_info->number_edges; j++, p++) { if ((double) y <= (p->bounds.y1-mid-0.5)) break; if ((double) y > (p->bounds.y2+mid+0.5)) { (void) DestroyEdge(polygon_info,(size_t) j); continue; } if (((double) x <= (p->bounds.x1-mid-0.5)) \|\| ((double) x > (p->bounds.x2+mid+0.5))) continue; i=(ssize_t) MagickMax((double) p->highwater,1.0); for ( ; i < (ssize_t) p->number_points; i++) { if ((double) y <= (p->points[i-1].y-mid-0.5)) break; if ((double) y > (p->points[i].y+mid+0.5)) continue; if (p->scanline != (double) y) { p->scanline=(double) y; p->highwater=(size_t) i; } /* Compute distance between a point and an edge. / q=p->points+i-1; delta.x=(q+1)->x-q->x; delta.y=(q+1)->y-q->y; beta=delta.x(x-q->x)+delta.y(y-q->y); if (beta <= 0.0) { delta.x=(double) x-q->x; delta.y=(double) y-q->y; distance=delta.xdelta.x+delta.ydelta.y; } else { alpha=delta.xdelta.x+delta.ydelta.y; if (beta >= alpha) { delta.x=(double) x-(q+1)->x; delta.y=(double) y-(q+1)->y; distance=delta.xdelta.x+delta.ydelta.y; } else { alpha=PerceptibleReciprocal(alpha); beta=delta.x(y-q->y)-delta.y(x-q->x); distance=alphabetabeta; } } / Compute stroke & subpath opacity. / beta=0.0; if (p->ghostline == MagickFalse) { alpha=mid+0.5; if ((stroke_alpha < 1.0) && (distance <= ((alpha+0.25)(alpha+0.25)))) { alpha=mid-0.5; if (distance <= ((alpha+0.25)(alpha+0.25))) stroke_alpha=1.0; else { beta=1.0; if (fabs(distance-1.0) >= MagickEpsilon) beta=sqrt((double) distance); alpha=beta-mid-0.5; if (stroke_alpha < ((alpha-0.25)(alpha-0.25))) stroke_alpha=(alpha-0.25)(alpha-0.25); } } } if ((fill == MagickFalse) \|\| (distance > 1.0) \|\| (subpath_alpha >= 1.0)) continue; if (distance <= 0.0) { subpath_alpha=1.0; continue; } if (distance > 1.0) continue; if (fabs(beta) < MagickEpsilon) { beta=1.0; if (fabs(distance-1.0) >= MagickEpsilon) beta=sqrt(distance); } alpha=beta-1.0; if (subpath_alpha < (alphaalpha)) subpath_alpha=alphaalpha; } } / Compute fill opacity. / if (fill == MagickFalse) return(0.0); if (subpath_alpha >= 1.0) return(1.0); / Determine winding number. / winding_number=0; p=polygon_info->edges; for (j=0; j < (ssize_t) polygon_info->number_edges; j++, p++) { if ((double) y <= p->bounds.y1) break; if (((double) y > p->bounds.y2) \|\| ((double) x <= p->bounds.x1)) continue; if ((double) x > p->bounds.x2) { winding_number+=p->direction ? 1 : -1; continue; } i=(ssize_t) MagickMax((double) p->highwater,1.0); for ( ; i < (ssize_t) (p->number_points-1); i++) if ((double) y <= p->points[i].y) break; q=p->points+i-1; if ((((q+1)->x-q->x)(y-q->y)) <= (((q+1)->y-q->y)(x-q->x))) winding_number+=p->direction ? 1 : -1; } if (fill_rule != NonZeroRule) { if ((MagickAbsoluteValue(winding_number) & 0x01) != 0) return(1.0); } else if (MagickAbsoluteValue(winding_number) != 0) return(1.0); return(subpath_alpha); } static MagickBooleanType DrawPolygonPrimitive(Image image, const DrawInfo draw_info,const PrimitiveInfo primitive_info, ExceptionInfo exception) { CacheView image_view; MagickBooleanType fill, status; double mid; PolygonInfo *magick_restrict polygon_info; register EdgeInfo p; register ssize_t i; SegmentInfo bounds; ssize_t start_y, stop_y, y; assert(image != (Image ) NULL); assert(image->signature == MagickCoreSignature); if (image->debug != MagickFalse) (void) LogMagickEvent(TraceEvent,GetMagickModule(),"%s",image->filename); assert(draw_info != (DrawInfo ) NULL); assert(draw_info->signature == MagickCoreSignature); assert(primitive_info != (PrimitiveInfo ) NULL); if (primitive_info->coordinates <= 1) return(MagickTrue); / Compute bounding box. / polygon_info=AcquirePolygonThreadSet(primitive_info); if (polygon_info == (PolygonInfo ) NULL) return(MagickFalse); DisableMSCWarning(4127) if (0) { status=DrawBoundingRectangles(image,draw_info,polygon_info[0],exception); if (status == MagickFalse) { polygon_info=DestroyPolygonThreadSet(polygon_info); return(status); } } RestoreMSCWarning if (image->debug != MagickFalse) (void) LogMagickEvent(DrawEvent,GetMagickModule()," begin draw-polygon"); fill=(primitive_info->method == FillToBorderMethod) \|\| (primitive_info->method == FloodfillMethod) ? MagickTrue : MagickFalse; mid=ExpandAffine(&draw_info->affine)SaneStrokeWidth(image,draw_info)/2.0; bounds=polygon_info[0]->edges[0].bounds; for (i=1; i < (ssize_t) polygon_info[0]->number_edges; i++) { p=polygon_info[0]->edges+i; if (p->bounds.x1 < bounds.x1) bounds.x1=p->bounds.x1; if (p->bounds.y1 < bounds.y1) bounds.y1=p->bounds.y1; if (p->bounds.x2 > bounds.x2) bounds.x2=p->bounds.x2; if (p->bounds.y2 > bounds.y2) bounds.y2=p->bounds.y2; } bounds.x1-=(mid+1.0); bounds.y1-=(mid+1.0); bounds.x2+=(mid+1.0); bounds.y2+=(mid+1.0); if ((bounds.x1 >= (double) image->columns) \|\| (bounds.y1 >= (double) image->rows) \|\| (bounds.x2 <= 0.0) \|\| (bounds.y2 <= 0.0)) { polygon_info=DestroyPolygonThreadSet(polygon_info); return(MagickTrue); /* virtual polygon / } bounds.x1=bounds.x1 < 0.0 ? 0.0 : bounds.x1 >= (double) image->columns-1.0 ? (double) image->columns-1.0 : bounds.x1; bounds.y1=bounds.y1 < 0.0 ? 0.0 : bounds.y1 >= (double) image->rows-1.0 ? (double) image->rows-1.0 : bounds.y1; bounds.x2=bounds.x2 < 0.0 ? 0.0 : bounds.x2 >= (double) image->columns-1.0 ? (double) image->columns-1.0 : bounds.x2; bounds.y2=bounds.y2 < 0.0 ? 0.0 : bounds.y2 >= (double) image->rows-1.0 ? (double) image->rows-1.0 : bounds.y2; status=MagickTrue; image_view=AcquireAuthenticCacheView(image,exception); if ((primitive_info->coordinates == 1) \|\| (polygon_info[0]->number_edges == 0)) { / Draw point. / start_y=(ssize_t) ceil(bounds.y1-0.5); stop_y=(ssize_t) floor(bounds.y2+0.5); #if defined(MAGICKCORE_OPENMP_SUPPORT) #pragma omp parallel for schedule(static) shared(status) \ magick_number_threads(image,image,stop_y-start_y+1,1) #endif for (y=start_y; y <= stop_y; y++) { MagickBooleanType sync; PixelInfo pixel; register ssize_t x; register Quantum magick_restrict q; ssize_t start_x, stop_x; if (status == MagickFalse) continue; start_x=(ssize_t) ceil(bounds.x1-0.5); stop_x=(ssize_t) floor(bounds.x2+0.5); x=start_x; q=GetCacheViewAuthenticPixels(image_view,x,y,(size_t) (stop_x-x+1),1, exception); if (q == (Quantum ) NULL) { status=MagickFalse; continue; } GetPixelInfo(image,&pixel); for ( ; x <= stop_x; x++) { if ((x == (ssize_t) ceil(primitive_info->point.x-0.5)) && (y == (ssize_t) ceil(primitive_info->point.y-0.5))) { GetFillColor(draw_info,x-start_x,y-start_y,&pixel,exception); SetPixelViaPixelInfo(image,&pixel,q); } q+=GetPixelChannels(image); } sync=SyncCacheViewAuthenticPixels(image_view,exception); if (sync == MagickFalse) status=MagickFalse; } image_view=DestroyCacheView(image_view); polygon_info=DestroyPolygonThreadSet(polygon_info); if (image->debug != MagickFalse) (void) LogMagickEvent(DrawEvent,GetMagickModule(), " end draw-polygon"); return(status); } / Draw polygon or line. / start_y=(ssize_t) ceil(bounds.y1-0.5); stop_y=(ssize_t) floor(bounds.y2+0.5); #if defined(MAGICKCORE_OPENMP_SUPPORT) #pragma omp parallel for schedule(static) shared(status) \ magick_number_threads(image,image,stop_y-start_y+1,1) #endif for (y=start_y; y <= stop_y; y++) { const int id = GetOpenMPThreadId(); register Quantum magick_restrict q; register ssize_t x; ssize_t start_x, stop_x; if (status == MagickFalse) continue; start_x=(ssize_t) ceil(bounds.x1-0.5); stop_x=(ssize_t) floor(bounds.x2+0.5); q=GetCacheViewAuthenticPixels(image_view,start_x,y,(size_t) (stop_x-start_x+ 1),1,exception); if (q == (Quantum ) NULL) { status=MagickFalse; continue; } for (x=start_x; x <= stop_x; x++) { double fill_alpha, stroke_alpha; PixelInfo fill_color, stroke_color; / Fill and/or stroke. / fill_alpha=GetFillAlpha(polygon_info[id],mid,fill,draw_info->fill_rule, x,y,&stroke_alpha); if (draw_info->stroke_antialias == MagickFalse) { fill_alpha=fill_alpha > 0.25 ? 1.0 : 0.0; stroke_alpha=stroke_alpha > 0.25 ? 1.0 : 0.0; } GetFillColor(draw_info,x-start_x,y-start_y,&fill_color,exception); CompositePixelOver(image,&fill_color,fill_alphafill_color.alpha,q, (double) GetPixelAlpha(image,q),q); GetStrokeColor(draw_info,x-start_x,y-start_y,&stroke_color,exception); CompositePixelOver(image,&stroke_color,stroke_alphastroke_color.alpha,q, (double) GetPixelAlpha(image,q),q); q+=GetPixelChannels(image); } if (SyncCacheViewAuthenticPixels(image_view,exception) == MagickFalse) status=MagickFalse; } image_view=DestroyCacheView(image_view); polygon_info=DestroyPolygonThreadSet(polygon_info); if (image->debug != MagickFalse) (void) LogMagickEvent(DrawEvent,GetMagickModule()," end draw-polygon"); return(status); } / %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % D r a w P r i m i t i v e % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % DrawPrimitive() draws a primitive (line, rectangle, ellipse) on the image. % % The format of the DrawPrimitive method is: % % MagickBooleanType DrawPrimitive(Image image,const DrawInfo draw_info, % PrimitiveInfo primitive_info,ExceptionInfo exception) % % A description of each parameter follows: % % o image: the image. % % o draw_info: the draw info. % % o primitive_info: Specifies a pointer to a PrimitiveInfo structure. % % o exception: return any errors or warnings in this structure. % / static inline double ConstrainCoordinate(double x) { if (x < (double) -(SSIZE_MAX-512)) return((double) -(SSIZE_MAX-512)); if (x > (double) (SSIZE_MAX-512)) return((double) (SSIZE_MAX-512)); return(x); } static void LogPrimitiveInfo(const PrimitiveInfo primitive_info) { const char methods[] = { "point", "replace", "floodfill", "filltoborder", "reset", "?" }; PointInfo p, point, q; register ssize_t i, x; ssize_t coordinates, y; x=(ssize_t) ceil(primitive_info->point.x-0.5); y=(ssize_t) ceil(primitive_info->point.y-0.5); switch (primitive_info->primitive) { case AlphaPrimitive: { (void) LogMagickEvent(DrawEvent,GetMagickModule(), "AlphaPrimitive %.20g,%.20g %s",(double) x,(double) y, methods[primitive_info->method]); return; } case ColorPrimitive: { (void) LogMagickEvent(DrawEvent,GetMagickModule(), "ColorPrimitive %.20g,%.20g %s",(double) x,(double) y, methods[primitive_info->method]); return; } case ImagePrimitive: { (void) LogMagickEvent(DrawEvent,GetMagickModule(), "ImagePrimitive %.20g,%.20g",(double) x,(double) y); return; } case PointPrimitive: { (void) LogMagickEvent(DrawEvent,GetMagickModule(), "PointPrimitive %.20g,%.20g %s",(double) x,(double) y, methods[primitive_info->method]); return; } case TextPrimitive: { (void) LogMagickEvent(DrawEvent,GetMagickModule(), "TextPrimitive %.20g,%.20g",(double) x,(double) y); return; } default: break; } coordinates=0; p=primitive_info[0].point; q.x=(-1.0); q.y=(-1.0); for (i=0; primitive_info[i].primitive != UndefinedPrimitive; i++) { point=primitive_info[i].point; if (coordinates <= 0) { coordinates=(ssize_t) primitive_info[i].coordinates; (void) LogMagickEvent(DrawEvent,GetMagickModule(), " begin open (%.20g)",(double) coordinates); p=point; } point=primitive_info[i].point; if ((fabs(q.x-point.x) >= MagickEpsilon) \|\| (fabs(q.y-point.y) >= MagickEpsilon)) (void) LogMagickEvent(DrawEvent,GetMagickModule(), " %.20g: %.18g,%.18g",(double) coordinates,point.x,point.y); else (void) LogMagickEvent(DrawEvent,GetMagickModule(), " %.20g: %g %g (duplicate)",(double) coordinates,point.x,point.y); q=point; coordinates--; if (coordinates > 0) continue; if ((fabs(p.x-point.x) >= MagickEpsilon) \|\| (fabs(p.y-point.y) >= MagickEpsilon)) (void) LogMagickEvent(DrawEvent,GetMagickModule()," end last (%.20g)", (double) coordinates); else (void) LogMagickEvent(DrawEvent,GetMagickModule()," end open (%.20g)", (double) coordinates); } } MagickExport MagickBooleanType DrawPrimitive(Image image, const DrawInfo draw_info,const PrimitiveInfo primitive_info, ExceptionInfo exception) { CacheView image_view; MagickStatusType status; register ssize_t i, x; ssize_t y; if (image->debug != MagickFalse) { (void) LogMagickEvent(DrawEvent,GetMagickModule(), " begin draw-primitive"); (void) LogMagickEvent(DrawEvent,GetMagickModule(), " affine: %g,%g,%g,%g,%g,%g",draw_info->affine.sx, draw_info->affine.rx,draw_info->affine.ry,draw_info->affine.sy, draw_info->affine.tx,draw_info->affine.ty); } status=MagickTrue; if ((IsGrayColorspace(image->colorspace) != MagickFalse) && ((IsPixelInfoGray(&draw_info->fill) == MagickFalse) \|\| (IsPixelInfoGray(&draw_info->stroke) == MagickFalse))) status=SetImageColorspace(image,sRGBColorspace,exception); if (draw_info->compliance == SVGCompliance) { status&=SetImageMask(image,WritePixelMask,draw_info->clipping_mask, exception); status&=SetImageMask(image,CompositePixelMask,draw_info->composite_mask, exception); } x=(ssize_t) ceil(ConstrainCoordinate(primitive_info->point.x-0.5)); y=(ssize_t) ceil(ConstrainCoordinate(primitive_info->point.y-0.5)); image_view=AcquireAuthenticCacheView(image,exception); switch (primitive_info->primitive) { case AlphaPrimitive: { if (image->alpha_trait == UndefinedPixelTrait) (void) SetImageAlphaChannel(image,OpaqueAlphaChannel,exception); switch (primitive_info->method) { case PointMethod: default: { PixelInfo pixel; register Quantum q; q=GetCacheViewAuthenticPixels(image_view,x,y,1,1,exception); if (q == (Quantum ) NULL) break; GetFillColor(draw_info,x,y,&pixel,exception); SetPixelAlpha(image,ClampToQuantum(pixel.alpha),q); (void) SyncCacheViewAuthenticPixels(image_view,exception); break; } case ReplaceMethod: { MagickBooleanType sync; PixelInfo pixel, target; (void) GetOneCacheViewVirtualPixelInfo(image_view,x,y,&target, exception); GetPixelInfo(image,&pixel); for (y=0; y < (ssize_t) image->rows; y++) { register Quantum magick_restrict q; q=GetCacheViewAuthenticPixels(image_view,0,y,image->columns,1, exception); if (q == (Quantum ) NULL) break; for (x=0; x < (ssize_t) image->columns; x++) { GetPixelInfoPixel(image,q,&pixel); if (IsFuzzyEquivalencePixelInfo(&pixel,&target) == MagickFalse) { q+=GetPixelChannels(image); continue; } GetFillColor(draw_info,x,y,&pixel,exception); SetPixelAlpha(image,ClampToQuantum(pixel.alpha),q); q+=GetPixelChannels(image); } sync=SyncCacheViewAuthenticPixels(image_view,exception); if (sync == MagickFalse) break; } break; } case FloodfillMethod: case FillToBorderMethod: { ChannelType channel_mask; PixelInfo target; (void) GetOneVirtualPixelInfo(image,TileVirtualPixelMethod,x,y, &target,exception); if (primitive_info->method == FillToBorderMethod) { target.red=(double) draw_info->border_color.red; target.green=(double) draw_info->border_color.green; target.blue=(double) draw_info->border_color.blue; } channel_mask=SetImageChannelMask(image,AlphaChannel); status&=FloodfillPaintImage(image,draw_info,&target,x,y, primitive_info->method == FloodfillMethod ? MagickFalse : MagickTrue,exception); (void) SetImageChannelMask(image,channel_mask); break; } case ResetMethod: { MagickBooleanType sync; PixelInfo pixel; for (y=0; y < (ssize_t) image->rows; y++) { register Quantum magick_restrict q; q=GetCacheViewAuthenticPixels(image_view,0,y,image->columns,1, exception); if (q == (Quantum ) NULL) break; for (x=0; x < (ssize_t) image->columns; x++) { GetFillColor(draw_info,x,y,&pixel,exception); SetPixelAlpha(image,ClampToQuantum(pixel.alpha),q); q+=GetPixelChannels(image); } sync=SyncCacheViewAuthenticPixels(image_view,exception); if (sync == MagickFalse) break; } break; } } break; } case ColorPrimitive: { switch (primitive_info->method) { case PointMethod: default: { PixelInfo pixel; register Quantum q; q=GetCacheViewAuthenticPixels(image_view,x,y,1,1,exception); if (q == (Quantum ) NULL) break; GetPixelInfo(image,&pixel); GetFillColor(draw_info,x,y,&pixel,exception); SetPixelViaPixelInfo(image,&pixel,q); (void) SyncCacheViewAuthenticPixels(image_view,exception); break; } case ReplaceMethod: { MagickBooleanType sync; PixelInfo pixel, target; (void) GetOneCacheViewVirtualPixelInfo(image_view,x,y,&target, exception); for (y=0; y < (ssize_t) image->rows; y++) { register Quantum magick_restrict q; q=GetCacheViewAuthenticPixels(image_view,0,y,image->columns,1, exception); if (q == (Quantum ) NULL) break; for (x=0; x < (ssize_t) image->columns; x++) { GetPixelInfoPixel(image,q,&pixel); if (IsFuzzyEquivalencePixelInfo(&pixel,&target) == MagickFalse) { q+=GetPixelChannels(image); continue; } GetFillColor(draw_info,x,y,&pixel,exception); SetPixelViaPixelInfo(image,&pixel,q); q+=GetPixelChannels(image); } sync=SyncCacheViewAuthenticPixels(image_view,exception); if (sync == MagickFalse) break; } break; } case FloodfillMethod: case FillToBorderMethod: { PixelInfo target; (void) GetOneVirtualPixelInfo(image,TileVirtualPixelMethod,x,y, &target,exception); if (primitive_info->method == FillToBorderMethod) { target.red=(double) draw_info->border_color.red; target.green=(double) draw_info->border_color.green; target.blue=(double) draw_info->border_color.blue; } status&=FloodfillPaintImage(image,draw_info,&target,x,y, primitive_info->method == FloodfillMethod ? MagickFalse : MagickTrue,exception); break; } case ResetMethod: { MagickBooleanType sync; PixelInfo pixel; GetPixelInfo(image,&pixel); for (y=0; y < (ssize_t) image->rows; y++) { register Quantum magick_restrict q; q=GetCacheViewAuthenticPixels(image_view,0,y,image->columns,1, exception); if (q == (Quantum ) NULL) break; for (x=0; x < (ssize_t) image->columns; x++) { GetFillColor(draw_info,x,y,&pixel,exception); SetPixelViaPixelInfo(image,&pixel,q); q+=GetPixelChannels(image); } sync=SyncCacheViewAuthenticPixels(image_view,exception); if (sync == MagickFalse) break; } break; } } break; } case ImagePrimitive: { AffineMatrix affine; char composite_geometry[MagickPathExtent]; Image composite_image, composite_images; ImageInfo clone_info; RectangleInfo geometry; ssize_t x1, y1; if (primitive_info->text == (char ) NULL) break; clone_info=AcquireImageInfo(); composite_images=(Image ) NULL; if (LocaleNCompare(primitive_info->text,"data:",5) == 0) composite_images=ReadInlineImage(clone_info,primitive_info->text, exception); else if (primitive_info->text != '\0') { (void) CopyMagickString(clone_info->filename,primitive_info->text, MagickPathExtent); composite_images=ReadImage(clone_info,exception); } clone_info=DestroyImageInfo(clone_info); if (composite_images == (Image ) NULL) { status=0; break; } composite_image=RemoveFirstImageFromList(&composite_images); composite_images=DestroyImageList(composite_images); (void) SetImageProgressMonitor(composite_image,(MagickProgressMonitor) NULL,(void ) NULL); x1=(ssize_t) ceil(primitive_info[1].point.x-0.5); y1=(ssize_t) ceil(primitive_info[1].point.y-0.5); if (((x1 != 0L) && (x1 != (ssize_t) composite_image->columns)) \|\| ((y1 != 0L) && (y1 != (ssize_t) composite_image->rows))) { /* Resize image. / (void) FormatLocaleString(composite_geometry,MagickPathExtent, "%gx%g!",primitive_info[1].point.x,primitive_info[1].point.y); composite_image->filter=image->filter; (void) TransformImage(&composite_image,(char ) NULL, composite_geometry,exception); } if (composite_image->alpha_trait == UndefinedPixelTrait) (void) SetImageAlphaChannel(composite_image,OpaqueAlphaChannel, exception); if (draw_info->alpha != OpaqueAlpha) (void) SetImageAlpha(composite_image,draw_info->alpha,exception); SetGeometry(image,&geometry); image->gravity=draw_info->gravity; geometry.x=x; geometry.y=y; (void) FormatLocaleString(composite_geometry,MagickPathExtent, "%.20gx%.20g%+.20g%+.20g",(double) composite_image->columns,(double) composite_image->rows,(double) geometry.x,(double) geometry.y); (void) ParseGravityGeometry(image,composite_geometry,&geometry,exception); affine=draw_info->affine; affine.tx=(double) geometry.x; affine.ty=(double) geometry.y; composite_image->interpolate=image->interpolate; if ((draw_info->compose == OverCompositeOp) \|\| (draw_info->compose == SrcOverCompositeOp)) (void) DrawAffineImage(image,composite_image,&affine,exception); else (void) CompositeImage(image,composite_image,draw_info->compose, MagickTrue,geometry.x,geometry.y,exception); composite_image=DestroyImage(composite_image); break; } case PointPrimitive: { PixelInfo fill_color; register Quantum q; if ((y < 0) \|\| (y >= (ssize_t) image->rows)) break; if ((x < 0) \|\| (x >= (ssize_t) image->columns)) break; q=GetCacheViewAuthenticPixels(image_view,x,y,1,1,exception); if (q == (Quantum ) NULL) break; GetFillColor(draw_info,x,y,&fill_color,exception); CompositePixelOver(image,&fill_color,(double) fill_color.alpha,q, (double) GetPixelAlpha(image,q),q); (void) SyncCacheViewAuthenticPixels(image_view,exception); break; } case TextPrimitive: { char geometry[MagickPathExtent]; DrawInfo clone_info; if (primitive_info->text == (char ) NULL) break; clone_info=CloneDrawInfo((ImageInfo ) NULL,draw_info); (void) CloneString(&clone_info->text,primitive_info->text); (void) FormatLocaleString(geometry,MagickPathExtent,"%+f%+f", primitive_info->point.x,primitive_info->point.y); (void) CloneString(&clone_info->geometry,geometry); status&=AnnotateImage(image,clone_info,exception); clone_info=DestroyDrawInfo(clone_info); break; } default: { double mid, scale; DrawInfo clone_info; if (IsEventLogging() != MagickFalse) LogPrimitiveInfo(primitive_info); scale=ExpandAffine(&draw_info->affine); if ((draw_info->dash_pattern != (double ) NULL) && (fabs(draw_info->dash_pattern[0]) >= MagickEpsilon) && (fabs(scaledraw_info->stroke_width) >= MagickEpsilon) && (draw_info->stroke.alpha != (Quantum) TransparentAlpha)) { /* Draw dash polygon. / clone_info=CloneDrawInfo((ImageInfo ) NULL,draw_info); clone_info->stroke_width=0.0; clone_info->stroke.alpha=(MagickRealType) TransparentAlpha; status&=DrawPolygonPrimitive(image,clone_info,primitive_info, exception); clone_info=DestroyDrawInfo(clone_info); status=DrawDashPolygon(draw_info,primitive_info,image,exception); break; } mid=ExpandAffine(&draw_info->affine)SaneStrokeWidth(image,draw_info)/2.0; if ((mid > 1.0) && ((draw_info->stroke.alpha != (Quantum) TransparentAlpha) \|\| (draw_info->stroke_pattern != (Image ) NULL))) { double x, y; MagickBooleanType closed_path; /* Draw strokes while respecting line cap/join attributes. / closed_path=primitive_info[0].closed_subpath; i=(ssize_t) primitive_info[0].coordinates; x=fabs(primitive_info[i-1].point.x-primitive_info[0].point.x); y=fabs(primitive_info[i-1].point.y-primitive_info[0].point.y); if ((x < MagickEpsilon) && (y < MagickEpsilon)) closed_path=MagickTrue; if ((((draw_info->linecap == RoundCap) \|\| (closed_path != MagickFalse)) && (draw_info->linejoin == RoundJoin)) \|\| (primitive_info[i].primitive != UndefinedPrimitive)) { status=DrawPolygonPrimitive(image,draw_info,primitive_info, exception); break; } clone_info=CloneDrawInfo((ImageInfo ) NULL,draw_info); clone_info->stroke_width=0.0; clone_info->stroke.alpha=(MagickRealType) TransparentAlpha; status&=DrawPolygonPrimitive(image,clone_info,primitive_info, exception); clone_info=DestroyDrawInfo(clone_info); status&=DrawStrokePolygon(image,draw_info,primitive_info,exception); break; } status&=DrawPolygonPrimitive(image,draw_info,primitive_info,exception); break; } } image_view=DestroyCacheView(image_view); if (draw_info->compliance == SVGCompliance) { status&=SetImageMask(image,WritePixelMask,(Image ) NULL,exception); status&=SetImageMask(image,CompositePixelMask,(Image ) NULL,exception); } if (image->debug != MagickFalse) (void) LogMagickEvent(DrawEvent,GetMagickModule()," end draw-primitive"); return(status != 0 ? MagickTrue : MagickFalse); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % + D r a w S t r o k e P o l y g o n % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % DrawStrokePolygon() draws a stroked polygon (line, rectangle, ellipse) on % the image while respecting the line cap and join attributes. % % The format of the DrawStrokePolygon method is: % % MagickBooleanType DrawStrokePolygon(Image image, % const DrawInfo draw_info,const PrimitiveInfo primitive_info) % % A description of each parameter follows: % % o image: the image. % % o draw_info: the draw info. % % o primitive_info: Specifies a pointer to a PrimitiveInfo structure. % % / static MagickBooleanType DrawRoundLinecap(Image image, const DrawInfo draw_info,const PrimitiveInfo primitive_info, ExceptionInfo exception) { PrimitiveInfo linecap[5]; register ssize_t i; for (i=0; i < 4; i++) linecap[i]=(primitive_info); linecap[0].coordinates=4; linecap[1].point.x+=2.0MagickEpsilon; linecap[2].point.x+=2.0MagickEpsilon; linecap[2].point.y+=2.0MagickEpsilon; linecap[3].point.y+=2.0MagickEpsilon; linecap[4].primitive=UndefinedPrimitive; return(DrawPolygonPrimitive(image,draw_info,linecap,exception)); } static MagickBooleanType DrawStrokePolygon(Image image, const DrawInfo draw_info,const PrimitiveInfo primitive_info, ExceptionInfo exception) { DrawInfo clone_info; MagickBooleanType closed_path; MagickStatusType status; PrimitiveInfo stroke_polygon; register const PrimitiveInfo p, q; / Draw stroked polygon. / if (image->debug != MagickFalse) (void) LogMagickEvent(DrawEvent,GetMagickModule(), " begin draw-stroke-polygon"); clone_info=CloneDrawInfo((ImageInfo ) NULL,draw_info); clone_info->fill=draw_info->stroke; if (clone_info->fill_pattern != (Image ) NULL) clone_info->fill_pattern=DestroyImage(clone_info->fill_pattern); if (clone_info->stroke_pattern != (Image ) NULL) clone_info->fill_pattern=CloneImage(clone_info->stroke_pattern,0,0, MagickTrue,exception); clone_info->stroke.alpha=(MagickRealType) TransparentAlpha; clone_info->stroke_width=0.0; clone_info->fill_rule=NonZeroRule; status=MagickTrue; for (p=primitive_info; p->primitive != UndefinedPrimitive; p+=p->coordinates) { if (p->coordinates == 1) continue; stroke_polygon=TraceStrokePolygon(image,draw_info,p); if (stroke_polygon == (PrimitiveInfo ) NULL) { status=0; break; } status&=DrawPolygonPrimitive(image,clone_info,stroke_polygon,exception); stroke_polygon=(PrimitiveInfo ) RelinquishMagickMemory(stroke_polygon); if (status == 0) break; q=p+p->coordinates-1; closed_path=p->closed_subpath; if ((draw_info->linecap == RoundCap) && (closed_path == MagickFalse)) { status&=DrawRoundLinecap(image,draw_info,p,exception); status&=DrawRoundLinecap(image,draw_info,q,exception); } } clone_info=DestroyDrawInfo(clone_info); if (image->debug != MagickFalse) (void) LogMagickEvent(DrawEvent,GetMagickModule(), " end draw-stroke-polygon"); return(status != 0 ? MagickTrue : MagickFalse); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % G e t A f f i n e M a t r i x % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % GetAffineMatrix() returns an AffineMatrix initialized to the identity % matrix. % % The format of the GetAffineMatrix method is: % % void GetAffineMatrix(AffineMatrix affine_matrix) % % A description of each parameter follows: % % o affine_matrix: the affine matrix. % / MagickExport void GetAffineMatrix(AffineMatrix affine_matrix) { (void) LogMagickEvent(TraceEvent,GetMagickModule(),"..."); assert(affine_matrix != (AffineMatrix ) NULL); (void) memset(affine_matrix,0,sizeof(affine_matrix)); affine_matrix->sx=1.0; affine_matrix->sy=1.0; } / %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % + G e t D r a w I n f o % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % GetDrawInfo() initializes draw_info to default values from image_info. % % The format of the GetDrawInfo method is: % % void GetDrawInfo(const ImageInfo image_info,DrawInfo draw_info) % % A description of each parameter follows: % % o image_info: the image info.. % % o draw_info: the draw info. % / MagickExport void GetDrawInfo(const ImageInfo image_info,DrawInfo draw_info) { char next_token; const char option; ExceptionInfo exception; ImageInfo clone_info; / Initialize draw attributes. / (void) LogMagickEvent(TraceEvent,GetMagickModule(),"..."); assert(draw_info != (DrawInfo ) NULL); (void) memset(draw_info,0,sizeof(draw_info)); clone_info=CloneImageInfo(image_info); GetAffineMatrix(&draw_info->affine); exception=AcquireExceptionInfo(); (void) QueryColorCompliance("#000F",AllCompliance,&draw_info->fill, exception); (void) QueryColorCompliance("#FFF0",AllCompliance,&draw_info->stroke, exception); draw_info->stroke_antialias=clone_info->antialias; draw_info->stroke_width=1.0; draw_info->fill_rule=EvenOddRule; draw_info->alpha=OpaqueAlpha; draw_info->fill_alpha=OpaqueAlpha; draw_info->stroke_alpha=OpaqueAlpha; draw_info->linecap=ButtCap; draw_info->linejoin=MiterJoin; draw_info->miterlimit=10; draw_info->decorate=NoDecoration; draw_info->pointsize=12.0; draw_info->undercolor.alpha=(MagickRealType) TransparentAlpha; draw_info->compose=OverCompositeOp; draw_info->render=MagickTrue; draw_info->clip_path=MagickFalse; draw_info->debug=IsEventLogging(); if (clone_info->font != (char ) NULL) draw_info->font=AcquireString(clone_info->font); if (clone_info->density != (char ) NULL) draw_info->density=AcquireString(clone_info->density); draw_info->text_antialias=clone_info->antialias; if (fabs(clone_info->pointsize) >= MagickEpsilon) draw_info->pointsize=clone_info->pointsize; draw_info->border_color=clone_info->border_color; if (clone_info->server_name != (char ) NULL) draw_info->server_name=AcquireString(clone_info->server_name); option=GetImageOption(clone_info,"direction"); if (option != (const char ) NULL) draw_info->direction=(DirectionType) ParseCommandOption( MagickDirectionOptions,MagickFalse,option); else draw_info->direction=UndefinedDirection; option=GetImageOption(clone_info,"encoding"); if (option != (const char ) NULL) (void) CloneString(&draw_info->encoding,option); option=GetImageOption(clone_info,"family"); if (option != (const char ) NULL) (void) CloneString(&draw_info->family,option); option=GetImageOption(clone_info,"fill"); if (option != (const char ) NULL) (void) QueryColorCompliance(option,AllCompliance,&draw_info->fill, exception); option=GetImageOption(clone_info,"gravity"); if (option != (const char ) NULL) draw_info->gravity=(GravityType) ParseCommandOption(MagickGravityOptions, MagickFalse,option); option=GetImageOption(clone_info,"interline-spacing"); if (option != (const char ) NULL) draw_info->interline_spacing=StringToDouble(option,&next_token); option=GetImageOption(clone_info,"interword-spacing"); if (option != (const char ) NULL) draw_info->interword_spacing=StringToDouble(option,&next_token); option=GetImageOption(clone_info,"kerning"); if (option != (const char ) NULL) draw_info->kerning=StringToDouble(option,&next_token); option=GetImageOption(clone_info,"stroke"); if (option != (const char ) NULL) (void) QueryColorCompliance(option,AllCompliance,&draw_info->stroke, exception); option=GetImageOption(clone_info,"strokewidth"); if (option != (const char ) NULL) draw_info->stroke_width=StringToDouble(option,&next_token); option=GetImageOption(clone_info,"style"); if (option != (const char ) NULL) draw_info->style=(StyleType) ParseCommandOption(MagickStyleOptions, MagickFalse,option); option=GetImageOption(clone_info,"undercolor"); if (option != (const char ) NULL) (void) QueryColorCompliance(option,AllCompliance,&draw_info->undercolor, exception); option=GetImageOption(clone_info,"weight"); if (option != (const char ) NULL) { ssize_t weight; weight=ParseCommandOption(MagickWeightOptions,MagickFalse,option); if (weight == -1) weight=(ssize_t) StringToUnsignedLong(option); draw_info->weight=(size_t) weight; } exception=DestroyExceptionInfo(exception); draw_info->signature=MagickCoreSignature; clone_info=DestroyImageInfo(clone_info); } / %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % + P e r m u t a t e % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % Permutate() returns the permuation of the (n,k). % % The format of the Permutate method is: % % void Permutate(ssize_t n,ssize_t k) % % A description of each parameter follows: % % o n: % % o k: % % / static inline double Permutate(const ssize_t n,const ssize_t k) { double r; register ssize_t i; r=1.0; for (i=k+1; i <= n; i++) r=i; for (i=1; i <= (n-k); i++) r/=i; return(r); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % + T r a c e P r i m i t i v e % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % TracePrimitive is a collection of methods for generating graphic % primitives such as arcs, ellipses, paths, etc. % / static MagickBooleanType TraceArc(MVGInfo mvg_info,const PointInfo start, const PointInfo end,const PointInfo degrees) { PointInfo center, radius; center.x=0.5(end.x+start.x); center.y=0.5(end.y+start.y); radius.x=fabs(center.x-start.x); radius.y=fabs(center.y-start.y); return(TraceEllipse(mvg_info,center,radius,degrees)); } static MagickBooleanType TraceArcPath(MVGInfo mvg_info,const PointInfo start, const PointInfo end,const PointInfo arc,const double angle, const MagickBooleanType large_arc,const MagickBooleanType sweep) { double alpha, beta, delta, factor, gamma, theta; MagickStatusType status; PointInfo center, points[3], radii; register double cosine, sine; PrimitiveInfo primitive_info; register PrimitiveInfo p; register ssize_t i; size_t arc_segments; ssize_t offset; offset=mvg_info->offset; primitive_info=(mvg_info->primitive_info)+mvg_info->offset; primitive_info->coordinates=0; if ((fabs(start.x-end.x) < MagickEpsilon) && (fabs(start.y-end.y) < MagickEpsilon)) return(TracePoint(primitive_info,end)); radii.x=fabs(arc.x); radii.y=fabs(arc.y); if ((radii.x < MagickEpsilon) \|\| (radii.y < MagickEpsilon)) return(TraceLine(primitive_info,start,end)); cosine=cos(DegreesToRadians(fmod((double) angle,360.0))); sine=sin(DegreesToRadians(fmod((double) angle,360.0))); center.x=(double) (cosine(end.x-start.x)/2+sine(end.y-start.y)/2); center.y=(double) (cosine(end.y-start.y)/2-sine(end.x-start.x)/2); delta=(center.xcenter.x)/(radii.xradii.x)+(center.ycenter.y)/ (radii.yradii.y); if (delta < MagickEpsilon) return(TraceLine(primitive_info,start,end)); if (delta > 1.0) { radii.x=sqrt((double) delta); radii.y=sqrt((double) delta); } points[0].x=(double) (cosinestart.x/radii.x+sinestart.y/radii.x); points[0].y=(double) (cosinestart.y/radii.y-sinestart.x/radii.y); points[1].x=(double) (cosineend.x/radii.x+sineend.y/radii.x); points[1].y=(double) (cosineend.y/radii.y-sineend.x/radii.y); alpha=points[1].x-points[0].x; beta=points[1].y-points[0].y; if (fabs(alphaalpha+betabeta) < MagickEpsilon) return(TraceLine(primitive_info,start,end)); factor=PerceptibleReciprocal(alphaalpha+betabeta)-0.25; if (factor <= 0.0) factor=0.0; else { factor=sqrt((double) factor); if (sweep == large_arc) factor=(-factor); } center.x=(double) ((points[0].x+points[1].x)/2-factorbeta); center.y=(double) ((points[0].y+points[1].y)/2+factoralpha); alpha=atan2(points[0].y-center.y,points[0].x-center.x); theta=atan2(points[1].y-center.y,points[1].x-center.x)-alpha; if ((theta < 0.0) && (sweep != MagickFalse)) theta+=2.0MagickPI; else if ((theta > 0.0) && (sweep == MagickFalse)) theta-=2.0MagickPI; arc_segments=(size_t) ceil(fabs((double) (theta/(0.5MagickPI+ MagickEpsilon)))); status=MagickTrue; p=primitive_info; for (i=0; i < (ssize_t) arc_segments; i++) { beta=0.5((alpha+(i+1)theta/arc_segments)-(alpha+itheta/arc_segments)); gamma=(8.0/3.0)sin(fmod((double) (0.5beta),DegreesToRadians(360.0)))* sin(fmod((double) (0.5beta),DegreesToRadians(360.0)))/ sin(fmod((double) beta,DegreesToRadians(360.0))); points[0].x=(double) (center.x+cos(fmod((double) (alpha+(double) itheta/ arc_segments),DegreesToRadians(360.0)))-gammasin(fmod((double) (alpha+ (double) itheta/arc_segments),DegreesToRadians(360.0)))); points[0].y=(double) (center.y+sin(fmod((double) (alpha+(double) itheta/ arc_segments),DegreesToRadians(360.0)))+gammacos(fmod((double) (alpha+ (double) itheta/arc_segments),DegreesToRadians(360.0)))); points[2].x=(double) (center.x+cos(fmod((double) (alpha+(double) (i+1) theta/arc_segments),DegreesToRadians(360.0)))); points[2].y=(double) (center.y+sin(fmod((double) (alpha+(double) (i+1)* theta/arc_segments),DegreesToRadians(360.0)))); points[1].x=(double) (points[2].x+gammasin(fmod((double) (alpha+(double) (i+1)theta/arc_segments),DegreesToRadians(360.0)))); points[1].y=(double) (points[2].y-gammacos(fmod((double) (alpha+(double) (i+1)theta/arc_segments),DegreesToRadians(360.0)))); p->point.x=(p == primitive_info) ? start.x : (p-1)->point.x; p->point.y=(p == primitive_info) ? start.y : (p-1)->point.y; (p+1)->point.x=(double) (cosineradii.xpoints[0].x-sineradii.y points[0].y); (p+1)->point.y=(double) (sineradii.xpoints[0].x+cosineradii.y points[0].y); (p+2)->point.x=(double) (cosineradii.xpoints[1].x-sineradii.y points[1].y); (p+2)->point.y=(double) (sineradii.xpoints[1].x+cosineradii.y points[1].y); (p+3)->point.x=(double) (cosineradii.xpoints[2].x-sineradii.y points[2].y); (p+3)->point.y=(double) (sineradii.xpoints[2].x+cosineradii.y points[2].y); if (i == (ssize_t) (arc_segments-1)) (p+3)->point=end; status&=TraceBezier(mvg_info,4); if (status == 0) break; p=(mvg_info->primitive_info)+mvg_info->offset; mvg_info->offset+=p->coordinates; p+=p->coordinates; } if (status == 0) return(MagickFalse); mvg_info->offset=offset; primitive_info=(mvg_info->primitive_info)+mvg_info->offset; primitive_info->coordinates=(size_t) (p-primitive_info); primitive_info->closed_subpath=MagickFalse; for (i=0; i < (ssize_t) primitive_info->coordinates; i++) { p->primitive=primitive_info->primitive; p--; } return(MagickTrue); } static MagickBooleanType TraceBezier(MVGInfo mvg_info, const size_t number_coordinates) { double alpha, coefficients, weight; PointInfo end, point, points; PrimitiveInfo primitive_info; register PrimitiveInfo p; register ssize_t i, j; size_t control_points, quantum; / Allocate coefficients. / primitive_info=(mvg_info->primitive_info)+mvg_info->offset; quantum=number_coordinates; for (i=0; i < (ssize_t) number_coordinates; i++) { for (j=i+1; j < (ssize_t) number_coordinates; j++) { alpha=fabs(primitive_info[j].point.x-primitive_info[i].point.x); if (alpha > (double) SSIZE_MAX) { (void) ThrowMagickException(mvg_info->exception,GetMagickModule(), ResourceLimitError,"MemoryAllocationFailed","`%s'",""); return(MagickFalse); } if (alpha > (double) quantum) quantum=(size_t) alpha; alpha=fabs(primitive_info[j].point.y-primitive_info[i].point.y); if (alpha > (double) SSIZE_MAX) { (void) ThrowMagickException(mvg_info->exception,GetMagickModule(), ResourceLimitError,"MemoryAllocationFailed","`%s'",""); return(MagickFalse); } if (alpha > (double) quantum) quantum=(size_t) alpha; } } primitive_info=(mvg_info->primitive_info)+mvg_info->offset; quantum=MagickMin(quantum/number_coordinates,BezierQuantum); coefficients=(double ) AcquireQuantumMemory(number_coordinates, sizeof(coefficients)); points=(PointInfo ) AcquireQuantumMemory(quantum,number_coordinates* sizeof(points)); if ((coefficients == (double ) NULL) \|\| (points == (PointInfo ) NULL)) { if (points != (PointInfo ) NULL) points=(PointInfo ) RelinquishMagickMemory(points); if (coefficients != (double ) NULL) coefficients=(double ) RelinquishMagickMemory(coefficients); (void) ThrowMagickException(mvg_info->exception,GetMagickModule(), ResourceLimitError,"MemoryAllocationFailed","`%s'",""); return(MagickFalse); } control_points=quantumnumber_coordinates; if (CheckPrimitiveExtent(mvg_info,control_points+1) == MagickFalse) { points=(PointInfo ) RelinquishMagickMemory(points); coefficients=(double ) RelinquishMagickMemory(coefficients); return(MagickFalse); } primitive_info=(mvg_info->primitive_info)+mvg_info->offset; / Compute bezier points. / end=primitive_info[number_coordinates-1].point; for (i=0; i < (ssize_t) number_coordinates; i++) coefficients[i]=Permutate((ssize_t) number_coordinates-1,i); weight=0.0; for (i=0; i < (ssize_t) control_points; i++) { p=primitive_info; point.x=0.0; point.y=0.0; alpha=pow((double) (1.0-weight),(double) number_coordinates-1.0); for (j=0; j < (ssize_t) number_coordinates; j++) { point.x+=alphacoefficients[j]p->point.x; point.y+=alphacoefficients[j]p->point.y; alpha=weight/(1.0-weight); p++; } points[i]=point; weight+=1.0/control_points; } /* Bezier curves are just short segmented polys. / p=primitive_info; for (i=0; i < (ssize_t) control_points; i++) { if (TracePoint(p,points[i]) == MagickFalse) { points=(PointInfo ) RelinquishMagickMemory(points); coefficients=(double ) RelinquishMagickMemory(coefficients); return(MagickFalse); } p+=p->coordinates; } if (TracePoint(p,end) == MagickFalse) { points=(PointInfo ) RelinquishMagickMemory(points); coefficients=(double ) RelinquishMagickMemory(coefficients); return(MagickFalse); } p+=p->coordinates; primitive_info->coordinates=(size_t) (p-primitive_info); primitive_info->closed_subpath=MagickFalse; for (i=0; i < (ssize_t) primitive_info->coordinates; i++) { p->primitive=primitive_info->primitive; p--; } points=(PointInfo ) RelinquishMagickMemory(points); coefficients=(double ) RelinquishMagickMemory(coefficients); return(MagickTrue); } static MagickBooleanType TraceCircle(MVGInfo mvg_info,const PointInfo start, const PointInfo end) { double alpha, beta, radius; PointInfo offset, degrees; alpha=end.x-start.x; beta=end.y-start.y; radius=hypot((double) alpha,(double) beta); offset.x=(double) radius; offset.y=(double) radius; degrees.x=0.0; degrees.y=360.0; return(TraceEllipse(mvg_info,start,offset,degrees)); } static MagickBooleanType TraceEllipse(MVGInfo mvg_info,const PointInfo center, const PointInfo radii,const PointInfo arc) { double coordinates, delta, step, x, y; PointInfo angle, point; PrimitiveInfo primitive_info; register PrimitiveInfo p; register ssize_t i; / Ellipses are just short segmented polys. / primitive_info=(mvg_info->primitive_info)+mvg_info->offset; primitive_info->coordinates=0; if ((fabs(radii.x) < MagickEpsilon) \|\| (fabs(radii.y) < MagickEpsilon)) return(MagickTrue); delta=2.0PerceptibleReciprocal(MagickMax(radii.x,radii.y)); step=MagickPI/8.0; if ((delta >= 0.0) && (delta < (MagickPI/8.0))) step=MagickPI/4.0/(MagickPIPerceptibleReciprocal(delta)/2.0); angle.x=DegreesToRadians(arc.x); y=arc.y; while (y < arc.x) y+=360.0; angle.y=DegreesToRadians(y); coordinates=ceil((angle.y-angle.x)/step+1.0); if (coordinates > (double) SSIZE_MAX) { (void) ThrowMagickException(mvg_info->exception,GetMagickModule(), ResourceLimitError,"MemoryAllocationFailed","`%s'",""); return(MagickFalse); } if (CheckPrimitiveExtent(mvg_info,(size_t) coordinates) == MagickFalse) return(MagickFalse); primitive_info=(mvg_info->primitive_info)+mvg_info->offset; for (p=primitive_info; angle.x < angle.y; angle.x+=step) { point.x=cos(fmod(angle.x,DegreesToRadians(360.0)))radii.x+center.x; point.y=sin(fmod(angle.x,DegreesToRadians(360.0)))radii.y+center.y; if (TracePoint(p,point) == MagickFalse) return(MagickFalse); p+=p->coordinates; } point.x=cos(fmod(angle.y,DegreesToRadians(360.0)))radii.x+center.x; point.y=sin(fmod(angle.y,DegreesToRadians(360.0)))radii.y+center.y; if (TracePoint(p,point) == MagickFalse) return(MagickFalse); p+=p->coordinates; primitive_info->coordinates=(size_t) (p-primitive_info); primitive_info->closed_subpath=MagickFalse; x=fabs(primitive_info[0].point.x- primitive_info[primitive_info->coordinates-1].point.x); y=fabs(primitive_info[0].point.y- primitive_info[primitive_info->coordinates-1].point.y); if ((x < MagickEpsilon) && (y < MagickEpsilon)) primitive_info->closed_subpath=MagickTrue; for (i=0; i < (ssize_t) primitive_info->coordinates; i++) { p->primitive=primitive_info->primitive; p--; } return(MagickTrue); } static MagickBooleanType TraceLine(PrimitiveInfo primitive_info, const PointInfo start,const PointInfo end) { if (TracePoint(primitive_info,start) == MagickFalse) return(MagickFalse); if ((fabs(start.x-end.x) < MagickEpsilon) && (fabs(start.y-end.y) < MagickEpsilon)) { primitive_info->primitive=PointPrimitive; primitive_info->coordinates=1; return(MagickTrue); } if (TracePoint(primitive_info+1,end) == MagickFalse) return(MagickFalse); (primitive_info+1)->primitive=primitive_info->primitive; primitive_info->coordinates=2; primitive_info->closed_subpath=MagickFalse; return(MagickTrue); } static size_t TracePath(MVGInfo mvg_info,const char path, ExceptionInfo exception) { char next_token, token[MagickPathExtent]; const char p; double x, y; int attribute, last_attribute; MagickBooleanType status; PointInfo end = {0.0, 0.0}, points[4] = { {0.0, 0.0}, {0.0, 0.0}, {0.0, 0.0}, {0.0, 0.0} }, point = {0.0, 0.0}, start = {0.0, 0.0}; PrimitiveInfo primitive_info; PrimitiveType primitive_type; register PrimitiveInfo q; register ssize_t i; size_t number_coordinates, z_count; ssize_t subpath_offset; subpath_offset=mvg_info->offset; primitive_info=(mvg_info->primitive_info)+mvg_info->offset; status=MagickTrue; attribute=0; number_coordinates=0; z_count=0; primitive_type=primitive_info->primitive; q=primitive_info; for (p=path; p != '\0'; ) { if (status == MagickFalse) break; while (isspace((int) ((unsigned char) p)) != 0) p++; if (p == '\0') break; last_attribute=attribute; attribute=(int) (p++); switch (attribute) { case 'a': case 'A': { double angle = 0.0; MagickBooleanType large_arc = MagickFalse, sweep = MagickFalse; PointInfo arc = {0.0, 0.0}; /* Elliptical arc. / do { (void) GetNextToken(p,&p,MagickPathExtent,token); if (token == ',') (void) GetNextToken(p,&p,MagickPathExtent,token); arc.x=StringToDouble(token,&next_token); if (token == next_token) ThrowPointExpectedException(token,exception); (void) GetNextToken(p,&p,MagickPathExtent,token); if (token == ',') (void) GetNextToken(p,&p,MagickPathExtent,token); arc.y=StringToDouble(token,&next_token); if (token == next_token) ThrowPointExpectedException(token,exception); (void) GetNextToken(p,&p,MagickPathExtent,token); if (token == ',') (void) GetNextToken(p,&p,MagickPathExtent,token); angle=StringToDouble(token,&next_token); if (token == next_token) ThrowPointExpectedException(token,exception); (void) GetNextToken(p,&p,MagickPathExtent,token); if (token == ',') (void) GetNextToken(p,&p,MagickPathExtent,token); large_arc=StringToLong(token) != 0 ? MagickTrue : MagickFalse; (void) GetNextToken(p,&p,MagickPathExtent,token); if (token == ',') (void) GetNextToken(p,&p,MagickPathExtent,token); sweep=StringToLong(token) != 0 ? MagickTrue : MagickFalse; if (token == ',') (void) GetNextToken(p,&p,MagickPathExtent,token); (void) GetNextToken(p,&p,MagickPathExtent,token); if (token == ',') (void) GetNextToken(p,&p,MagickPathExtent,token); x=StringToDouble(token,&next_token); if (token == next_token) ThrowPointExpectedException(token,exception); (void) GetNextToken(p,&p,MagickPathExtent,token); if (token == ',') (void) GetNextToken(p,&p,MagickPathExtent,token); y=StringToDouble(token,&next_token); if (token == next_token) ThrowPointExpectedException(token,exception); end.x=(double) (attribute == (int) 'A' ? x : point.x+x); end.y=(double) (attribute == (int) 'A' ? y : point.y+y); if (TraceArcPath(mvg_info,point,end,arc,angle,large_arc,sweep) == MagickFalse) return(0); q=(mvg_info->primitive_info)+mvg_info->offset; mvg_info->offset+=q->coordinates; q+=q->coordinates; point=end; while (isspace((int) ((unsigned char) p)) != 0) p++; if (p == ',') p++; } while (IsPoint(p) != MagickFalse); break; } case 'c': case 'C': { /* Cubic Bézier curve. / do { points[0]=point; for (i=1; i < 4; i++) { (void) GetNextToken(p,&p,MagickPathExtent,token); if (token == ',') (void) GetNextToken(p,&p,MagickPathExtent,token); x=StringToDouble(token,&next_token); if (token == next_token) ThrowPointExpectedException(token,exception); (void) GetNextToken(p,&p,MagickPathExtent,token); if (token == ',') (void) GetNextToken(p,&p,MagickPathExtent,token); y=StringToDouble(token,&next_token); if (token == next_token) ThrowPointExpectedException(token,exception); end.x=(double) (attribute == (int) 'C' ? x : point.x+x); end.y=(double) (attribute == (int) 'C' ? y : point.y+y); points[i]=end; } for (i=0; i < 4; i++) (q+i)->point=points[i]; if (TraceBezier(mvg_info,4) == MagickFalse) return(0); q=(mvg_info->primitive_info)+mvg_info->offset; mvg_info->offset+=q->coordinates; q+=q->coordinates; point=end; while (isspace((int) ((unsigned char) p)) != 0) p++; if (p == ',') p++; } while (IsPoint(p) != MagickFalse); break; } case 'H': case 'h': { do { (void) GetNextToken(p,&p,MagickPathExtent,token); if (token == ',') (void) GetNextToken(p,&p,MagickPathExtent,token); x=StringToDouble(token,&next_token); if (token == next_token) ThrowPointExpectedException(token,exception); point.x=(double) (attribute == (int) 'H' ? x: point.x+x); if (CheckPrimitiveExtent(mvg_info,PrimitiveExtentPad) == MagickFalse) return(0); q=(mvg_info->primitive_info)+mvg_info->offset; if (TracePoint(q,point) == MagickFalse) return(0); mvg_info->offset+=q->coordinates; q+=q->coordinates; while (isspace((int) ((unsigned char) p)) != 0) p++; if (p == ',') p++; } while (IsPoint(p) != MagickFalse); break; } case 'l': case 'L': { /* Line to. / do { (void) GetNextToken(p,&p,MagickPathExtent,token); if (token == ',') (void) GetNextToken(p,&p,MagickPathExtent,token); x=StringToDouble(token,&next_token); if (token == next_token) ThrowPointExpectedException(token,exception); (void) GetNextToken(p,&p,MagickPathExtent,token); if (token == ',') (void) GetNextToken(p,&p,MagickPathExtent,token); y=StringToDouble(token,&next_token); if (token == next_token) ThrowPointExpectedException(token,exception); point.x=(double) (attribute == (int) 'L' ? x : point.x+x); point.y=(double) (attribute == (int) 'L' ? y : point.y+y); if (CheckPrimitiveExtent(mvg_info,PrimitiveExtentPad) == MagickFalse) return(0); q=(mvg_info->primitive_info)+mvg_info->offset; if (TracePoint(q,point) == MagickFalse) return(0); mvg_info->offset+=q->coordinates; q+=q->coordinates; while (isspace((int) ((unsigned char) p)) != 0) p++; if (p == ',') p++; } while (IsPoint(p) != MagickFalse); break; } case 'M': case 'm': { /* Move to. / if (mvg_info->offset != subpath_offset) { primitive_info=(mvg_info->primitive_info)+subpath_offset; primitive_info->coordinates=(size_t) (q-primitive_info); number_coordinates+=primitive_info->coordinates; primitive_info=q; subpath_offset=mvg_info->offset; } i=0; do { (void) GetNextToken(p,&p,MagickPathExtent,token); if (token == ',') (void) GetNextToken(p,&p,MagickPathExtent,token); x=StringToDouble(token,&next_token); if (token == next_token) ThrowPointExpectedException(token,exception); (void) GetNextToken(p,&p,MagickPathExtent,token); if (token == ',') (void) GetNextToken(p,&p,MagickPathExtent,token); y=StringToDouble(token,&next_token); if (token == next_token) ThrowPointExpectedException(token,exception); point.x=(double) (attribute == (int) 'M' ? x : point.x+x); point.y=(double) (attribute == (int) 'M' ? y : point.y+y); if (i == 0) start=point; i++; if (CheckPrimitiveExtent(mvg_info,PrimitiveExtentPad) == MagickFalse) return(0); q=(mvg_info->primitive_info)+mvg_info->offset; if (TracePoint(q,point) == MagickFalse) return(0); mvg_info->offset+=q->coordinates; q+=q->coordinates; while (isspace((int) ((unsigned char) p)) != 0) p++; if (p == ',') p++; } while (IsPoint(p) != MagickFalse); break; } case 'q': case 'Q': { / Quadratic Bézier curve. / do { points[0]=point; for (i=1; i < 3; i++) { (void) GetNextToken(p,&p,MagickPathExtent,token); if (token == ',') (void) GetNextToken(p,&p,MagickPathExtent,token); x=StringToDouble(token,&next_token); if (token == next_token) ThrowPointExpectedException(token,exception); (void) GetNextToken(p,&p,MagickPathExtent,token); if (token == ',') (void) GetNextToken(p,&p,MagickPathExtent,token); y=StringToDouble(token,&next_token); if (token == next_token) ThrowPointExpectedException(token,exception); if (p == ',') p++; end.x=(double) (attribute == (int) 'Q' ? x : point.x+x); end.y=(double) (attribute == (int) 'Q' ? y : point.y+y); points[i]=end; } for (i=0; i < 3; i++) (q+i)->point=points[i]; if (TraceBezier(mvg_info,3) == MagickFalse) return(0); q=(mvg_info->primitive_info)+mvg_info->offset; mvg_info->offset+=q->coordinates; q+=q->coordinates; point=end; while (isspace((int) ((unsigned char) p)) != 0) p++; if (p == ',') p++; } while (IsPoint(p) != MagickFalse); break; } case 's': case 'S': { / Cubic Bézier curve. / do { points[0]=points[3]; points[1].x=2.0points[3].x-points[2].x; points[1].y=2.0points[3].y-points[2].y; for (i=2; i < 4; i++) { (void) GetNextToken(p,&p,MagickPathExtent,token); if (token == ',') (void) GetNextToken(p,&p,MagickPathExtent,token); x=StringToDouble(token,&next_token); if (token == next_token) ThrowPointExpectedException(token,exception); (void) GetNextToken(p,&p,MagickPathExtent,token); if (token == ',') (void) GetNextToken(p,&p,MagickPathExtent,token); y=StringToDouble(token,&next_token); if (token == next_token) ThrowPointExpectedException(token,exception); if (p == ',') p++; end.x=(double) (attribute == (int) 'S' ? x : point.x+x); end.y=(double) (attribute == (int) 'S' ? y : point.y+y); points[i]=end; } if (strchr("CcSs",last_attribute) == (char ) NULL) { points[0]=point; points[1]=point; } for (i=0; i < 4; i++) (q+i)->point=points[i]; if (TraceBezier(mvg_info,4) == MagickFalse) return(0); q=(mvg_info->primitive_info)+mvg_info->offset; mvg_info->offset+=q->coordinates; q+=q->coordinates; point=end; last_attribute=attribute; while (isspace((int) ((unsigned char) p)) != 0) p++; if (p == ',') p++; } while (IsPoint(p) != MagickFalse); break; } case 't': case 'T': { /* Quadratic Bézier curve. / do { points[0]=points[2]; points[1].x=2.0points[2].x-points[1].x; points[1].y=2.0points[2].y-points[1].y; for (i=2; i < 3; i++) { (void) GetNextToken(p,&p,MagickPathExtent,token); if (token == ',') (void) GetNextToken(p,&p,MagickPathExtent,token); x=StringToDouble(token,&next_token); if (token == next_token) ThrowPointExpectedException(token,exception); (void) GetNextToken(p,&p,MagickPathExtent,token); if (token == ',') (void) GetNextToken(p,&p,MagickPathExtent,token); y=StringToDouble(token,&next_token); if (token == next_token) ThrowPointExpectedException(token,exception); end.x=(double) (attribute == (int) 'T' ? x : point.x+x); end.y=(double) (attribute == (int) 'T' ? y : point.y+y); points[i]=end; } if (status == MagickFalse) break; if (strchr("QqTt",last_attribute) == (char ) NULL) { points[0]=point; points[1]=point; } for (i=0; i < 3; i++) (q+i)->point=points[i]; if (TraceBezier(mvg_info,3) == MagickFalse) return(0); q=(mvg_info->primitive_info)+mvg_info->offset; mvg_info->offset+=q->coordinates; q+=q->coordinates; point=end; last_attribute=attribute; while (isspace((int) ((unsigned char) p)) != 0) p++; if (p == ',') p++; } while (IsPoint(p) != MagickFalse); break; } case 'v': case 'V': { / Line to. / do { (void) GetNextToken(p,&p,MagickPathExtent,token); if (token == ',') (void) GetNextToken(p,&p,MagickPathExtent,token); y=StringToDouble(token,&next_token); if (token == next_token) ThrowPointExpectedException(token,exception); point.y=(double) (attribute == (int) 'V' ? y : point.y+y); if (CheckPrimitiveExtent(mvg_info,PrimitiveExtentPad) == MagickFalse) return(0); q=(mvg_info->primitive_info)+mvg_info->offset; if (TracePoint(q,point) == MagickFalse) return(0); mvg_info->offset+=q->coordinates; q+=q->coordinates; while (isspace((int) ((unsigned char) p)) != 0) p++; if (p == ',') p++; } while (IsPoint(p) != MagickFalse); break; } case 'z': case 'Z': { / Close path. / point=start; if (CheckPrimitiveExtent(mvg_info,PrimitiveExtentPad) == MagickFalse) return(0); q=(mvg_info->primitive_info)+mvg_info->offset; if (TracePoint(q,point) == MagickFalse) return(0); mvg_info->offset+=q->coordinates; q+=q->coordinates; primitive_info=(mvg_info->primitive_info)+subpath_offset; primitive_info->coordinates=(size_t) (q-primitive_info); primitive_info->closed_subpath=MagickTrue; number_coordinates+=primitive_info->coordinates; primitive_info=q; subpath_offset=mvg_info->offset; z_count++; break; } default: { ThrowPointExpectedException(token,exception); break; } } } if (status == MagickFalse) return(0); primitive_info=(mvg_info->primitive_info)+subpath_offset; primitive_info->coordinates=(size_t) (q-primitive_info); number_coordinates+=primitive_info->coordinates; for (i=0; i < (ssize_t) number_coordinates; i++) { q--; q->primitive=primitive_type; if (z_count > 1) q->method=FillToBorderMethod; } q=primitive_info; return(number_coordinates); } static MagickBooleanType TraceRectangle(PrimitiveInfo primitive_info, const PointInfo start,const PointInfo end) { PointInfo point; register PrimitiveInfo p; register ssize_t i; p=primitive_info; if (TracePoint(p,start) == MagickFalse) return(MagickFalse); p+=p->coordinates; point.x=start.x; point.y=end.y; if (TracePoint(p,point) == MagickFalse) return(MagickFalse); p+=p->coordinates; if (TracePoint(p,end) == MagickFalse) return(MagickFalse); p+=p->coordinates; point.x=end.x; point.y=start.y; if (TracePoint(p,point) == MagickFalse) return(MagickFalse); p+=p->coordinates; if (TracePoint(p,start) == MagickFalse) return(MagickFalse); p+=p->coordinates; primitive_info->coordinates=(size_t) (p-primitive_info); primitive_info->closed_subpath=MagickTrue; for (i=0; i < (ssize_t) primitive_info->coordinates; i++) { p->primitive=primitive_info->primitive; p--; } return(MagickTrue); } static MagickBooleanType TraceRoundRectangle(MVGInfo mvg_info, const PointInfo start,const PointInfo end,PointInfo arc) { PointInfo degrees, point, segment; PrimitiveInfo primitive_info; register PrimitiveInfo p; register ssize_t i; ssize_t offset; offset=mvg_info->offset; segment.x=fabs(end.x-start.x); segment.y=fabs(end.y-start.y); if ((segment.x < MagickEpsilon) \|\| (segment.y < MagickEpsilon)) { (mvg_info->primitive_info+mvg_info->offset)->coordinates=0; return(MagickTrue); } if (arc.x > (0.5segment.x)) arc.x=0.5segment.x; if (arc.y > (0.5segment.y)) arc.y=0.5segment.y; point.x=start.x+segment.x-arc.x; point.y=start.y+arc.y; degrees.x=270.0; degrees.y=360.0; if (TraceEllipse(mvg_info,point,arc,degrees) == MagickFalse) return(MagickFalse); p=(mvg_info->primitive_info)+mvg_info->offset; mvg_info->offset+=p->coordinates; point.x=start.x+segment.x-arc.x; point.y=start.y+segment.y-arc.y; degrees.x=0.0; degrees.y=90.0; if (TraceEllipse(mvg_info,point,arc,degrees) == MagickFalse) return(MagickFalse); p=(mvg_info->primitive_info)+mvg_info->offset; mvg_info->offset+=p->coordinates; point.x=start.x+arc.x; point.y=start.y+segment.y-arc.y; degrees.x=90.0; degrees.y=180.0; if (TraceEllipse(mvg_info,point,arc,degrees) == MagickFalse) return(MagickFalse); p=(mvg_info->primitive_info)+mvg_info->offset; mvg_info->offset+=p->coordinates; point.x=start.x+arc.x; point.y=start.y+arc.y; degrees.x=180.0; degrees.y=270.0; if (TraceEllipse(mvg_info,point,arc,degrees) == MagickFalse) return(MagickFalse); p=(mvg_info->primitive_info)+mvg_info->offset; mvg_info->offset+=p->coordinates; if (CheckPrimitiveExtent(mvg_info,PrimitiveExtentPad) == MagickFalse) return(MagickFalse); p=(mvg_info->primitive_info)+mvg_info->offset; if (TracePoint(p,(mvg_info->primitive_info+offset)->point) == MagickFalse) return(MagickFalse); p+=p->coordinates; mvg_info->offset=offset; primitive_info=(mvg_info->primitive_info)+offset; primitive_info->coordinates=(size_t) (p-primitive_info); primitive_info->closed_subpath=MagickTrue; for (i=0; i < (ssize_t) primitive_info->coordinates; i++) { p->primitive=primitive_info->primitive; p--; } return(MagickTrue); } static MagickBooleanType TraceSquareLinecap(PrimitiveInfo primitive_info, const size_t number_vertices,const double offset) { double distance; register double dx, dy; register ssize_t i; ssize_t j; dx=0.0; dy=0.0; for (i=1; i < (ssize_t) number_vertices; i++) { dx=primitive_info[0].point.x-primitive_info[i].point.x; dy=primitive_info[0].point.y-primitive_info[i].point.y; if ((fabs((double) dx) >= MagickEpsilon) \|\| (fabs((double) dy) >= MagickEpsilon)) break; } if (i == (ssize_t) number_vertices) i=(ssize_t) number_vertices-1L; distance=hypot((double) dx,(double) dy); primitive_info[0].point.x=(double) (primitive_info[i].point.x+ dx(distance+offset)/distance); primitive_info[0].point.y=(double) (primitive_info[i].point.y+ dy(distance+offset)/distance); for (j=(ssize_t) number_vertices-2; j >= 0; j--) { dx=primitive_info[number_vertices-1].point.x-primitive_info[j].point.x; dy=primitive_info[number_vertices-1].point.y-primitive_info[j].point.y; if ((fabs((double) dx) >= MagickEpsilon) \|\| (fabs((double) dy) >= MagickEpsilon)) break; } distance=hypot((double) dx,(double) dy); primitive_info[number_vertices-1].point.x=(double) (primitive_info[j].point.x+ dx(distance+offset)/distance); primitive_info[number_vertices-1].point.y=(double) (primitive_info[j].point.y+ dy(distance+offset)/distance); return(MagickTrue); } static PrimitiveInfo TraceStrokePolygon(const Image image, const DrawInfo draw_info,const PrimitiveInfo primitive_info) { #define CheckPathExtent(pad) \ if ((ssize_t) (q+(pad)) >= (ssize_t) max_strokes) \ { \ if (~max_strokes < (pad)) \ { \ path_p=(PointInfo ) RelinquishMagickMemory(path_p); \ path_q=(PointInfo ) RelinquishMagickMemory(path_q); \ } \ else \ { \ max_strokes+=(pad); \ path_p=(PointInfo ) ResizeQuantumMemory(path_p,max_strokes, \ sizeof(path_p)); \ path_q=(PointInfo ) ResizeQuantumMemory(path_q,max_strokes, \ sizeof(path_q)); \ } \ if ((path_p == (PointInfo ) NULL) \|\| (path_q == (PointInfo ) NULL)) \ { \ if (path_p != (PointInfo ) NULL) \ path_p=(PointInfo ) RelinquishMagickMemory(path_p); \ if (path_q != (PointInfo ) NULL) \ path_q=(PointInfo ) RelinquishMagickMemory(path_q); \ polygon_primitive=(PrimitiveInfo ) \ RelinquishMagickMemory(polygon_primitive); \ return((PrimitiveInfo ) NULL); \ } \ } typedef struct _LineSegment { double p, q; } LineSegment; double delta_theta, dot_product, mid, miterlimit; LineSegment dx = {0,0}, dy = {0,0}, inverse_slope = {0,0}, slope = {0,0}, theta = {0,0}; MagickBooleanType closed_path; PointInfo box_p[5], box_q[5], center, offset, path_p, path_q; PrimitiveInfo polygon_primitive, stroke_polygon; register ssize_t i; size_t arc_segments, max_strokes, number_vertices; ssize_t j, n, p, q; /* Allocate paths. / number_vertices=primitive_info->coordinates; max_strokes=2number_vertices+6BezierQuantum+360; polygon_primitive=(PrimitiveInfo ) AcquireQuantumMemory((size_t) number_vertices+2UL,sizeof(polygon_primitive)); if (polygon_primitive == (PrimitiveInfo ) NULL) return((PrimitiveInfo ) NULL); (void) memcpy(polygon_primitive,primitive_info,(size_t) number_vertices sizeof(polygon_primitive)); closed_path=primitive_info[0].closed_subpath; if (((draw_info->linejoin == RoundJoin) \|\| (draw_info->linejoin == MiterJoin)) && (closed_path != MagickFalse)) { polygon_primitive[number_vertices]=primitive_info[1]; number_vertices++; } polygon_primitive[number_vertices].primitive=UndefinedPrimitive; / Compute the slope for the first line segment, p. / dx.p=0.0; dy.p=0.0; for (n=1; n < (ssize_t) number_vertices; n++) { dx.p=polygon_primitive[n].point.x-polygon_primitive[0].point.x; dy.p=polygon_primitive[n].point.y-polygon_primitive[0].point.y; if ((fabs(dx.p) >= MagickEpsilon) \|\| (fabs(dy.p) >= MagickEpsilon)) break; } if (n == (ssize_t) number_vertices) { if ((draw_info->linecap != RoundCap) \|\| (closed_path != MagickFalse)) { / Zero length subpath. / stroke_polygon=(PrimitiveInfo ) AcquireCriticalMemory( sizeof(stroke_polygon)); stroke_polygon[0]=polygon_primitive[0]; stroke_polygon[0].coordinates=0; polygon_primitive=(PrimitiveInfo ) RelinquishMagickMemory( polygon_primitive); return(stroke_polygon); } n=(ssize_t) number_vertices-1L; } path_p=(PointInfo ) AcquireQuantumMemory((size_t) max_strokes, sizeof(path_p)); if (path_p == (PointInfo ) NULL) { polygon_primitive=(PrimitiveInfo ) RelinquishMagickMemory( polygon_primitive); return((PrimitiveInfo ) NULL); } path_q=(PointInfo ) AcquireQuantumMemory((size_t) max_strokes, sizeof(path_q)); if (path_q == (PointInfo ) NULL) { path_p=(PointInfo ) RelinquishMagickMemory(path_p); polygon_primitive=(PrimitiveInfo ) RelinquishMagickMemory( polygon_primitive); return((PrimitiveInfo ) NULL); } slope.p=0.0; inverse_slope.p=0.0; if (fabs(dx.p) < MagickEpsilon) { if (dx.p >= 0.0) slope.p=dy.p < 0.0 ? -1.0/MagickEpsilon : 1.0/MagickEpsilon; else slope.p=dy.p < 0.0 ? 1.0/MagickEpsilon : -1.0/MagickEpsilon; } else if (fabs(dy.p) < MagickEpsilon) { if (dy.p >= 0.0) inverse_slope.p=dx.p < 0.0 ? -1.0/MagickEpsilon : 1.0/MagickEpsilon; else inverse_slope.p=dx.p < 0.0 ? 1.0/MagickEpsilon : -1.0/MagickEpsilon; } else { slope.p=dy.p/dx.p; inverse_slope.p=(-1.0/slope.p); } mid=ExpandAffine(&draw_info->affine)SaneStrokeWidth(image,draw_info)/2.0; miterlimit=(double) (draw_info->miterlimitdraw_info->miterlimitmidmid); if ((draw_info->linecap == SquareCap) && (closed_path == MagickFalse)) (void) TraceSquareLinecap(polygon_primitive,number_vertices,mid); offset.x=sqrt((double) (midmid/(inverse_slope.pinverse_slope.p+1.0))); offset.y=(double) (offset.xinverse_slope.p); if ((dy.poffset.x-dx.poffset.y) > 0.0) { box_p[0].x=polygon_primitive[0].point.x-offset.x; box_p[0].y=polygon_primitive[0].point.y-offset.xinverse_slope.p; box_p[1].x=polygon_primitive[n].point.x-offset.x; box_p[1].y=polygon_primitive[n].point.y-offset.xinverse_slope.p; box_q[0].x=polygon_primitive[0].point.x+offset.x; box_q[0].y=polygon_primitive[0].point.y+offset.xinverse_slope.p; box_q[1].x=polygon_primitive[n].point.x+offset.x; box_q[1].y=polygon_primitive[n].point.y+offset.xinverse_slope.p; } else { box_p[0].x=polygon_primitive[0].point.x+offset.x; box_p[0].y=polygon_primitive[0].point.y+offset.y; box_p[1].x=polygon_primitive[n].point.x+offset.x; box_p[1].y=polygon_primitive[n].point.y+offset.y; box_q[0].x=polygon_primitive[0].point.x-offset.x; box_q[0].y=polygon_primitive[0].point.y-offset.y; box_q[1].x=polygon_primitive[n].point.x-offset.x; box_q[1].y=polygon_primitive[n].point.y-offset.y; } /* Create strokes for the line join attribute: bevel, miter, round. / p=0; q=0; path_q[p++]=box_q[0]; path_p[q++]=box_p[0]; for (i=(ssize_t) n+1; i < (ssize_t) number_vertices; i++) { / Compute the slope for this line segment, q. / dx.q=polygon_primitive[i].point.x-polygon_primitive[n].point.x; dy.q=polygon_primitive[i].point.y-polygon_primitive[n].point.y; dot_product=dx.qdx.q+dy.qdy.q; if (dot_product < 0.25) continue; slope.q=0.0; inverse_slope.q=0.0; if (fabs(dx.q) < MagickEpsilon) { if (dx.q >= 0.0) slope.q=dy.q < 0.0 ? -1.0/MagickEpsilon : 1.0/MagickEpsilon; else slope.q=dy.q < 0.0 ? 1.0/MagickEpsilon : -1.0/MagickEpsilon; } else if (fabs(dy.q) < MagickEpsilon) { if (dy.q >= 0.0) inverse_slope.q=dx.q < 0.0 ? -1.0/MagickEpsilon : 1.0/MagickEpsilon; else inverse_slope.q=dx.q < 0.0 ? 1.0/MagickEpsilon : -1.0/MagickEpsilon; } else { slope.q=dy.q/dx.q; inverse_slope.q=(-1.0/slope.q); } offset.x=sqrt((double) (midmid/(inverse_slope.qinverse_slope.q+1.0))); offset.y=(double) (offset.xinverse_slope.q); dot_product=dy.qoffset.x-dx.qoffset.y; if (dot_product > 0.0) { box_p[2].x=polygon_primitive[n].point.x-offset.x; box_p[2].y=polygon_primitive[n].point.y-offset.y; box_p[3].x=polygon_primitive[i].point.x-offset.x; box_p[3].y=polygon_primitive[i].point.y-offset.y; box_q[2].x=polygon_primitive[n].point.x+offset.x; box_q[2].y=polygon_primitive[n].point.y+offset.y; box_q[3].x=polygon_primitive[i].point.x+offset.x; box_q[3].y=polygon_primitive[i].point.y+offset.y; } else { box_p[2].x=polygon_primitive[n].point.x+offset.x; box_p[2].y=polygon_primitive[n].point.y+offset.y; box_p[3].x=polygon_primitive[i].point.x+offset.x; box_p[3].y=polygon_primitive[i].point.y+offset.y; box_q[2].x=polygon_primitive[n].point.x-offset.x; box_q[2].y=polygon_primitive[n].point.y-offset.y; box_q[3].x=polygon_primitive[i].point.x-offset.x; box_q[3].y=polygon_primitive[i].point.y-offset.y; } if (fabs((double) (slope.p-slope.q)) < MagickEpsilon) { box_p[4]=box_p[1]; box_q[4]=box_q[1]; } else { box_p[4].x=(double) ((slope.pbox_p[0].x-box_p[0].y-slope.qbox_p[3].x+ box_p[3].y)/(slope.p-slope.q)); box_p[4].y=(double) (slope.p(box_p[4].x-box_p[0].x)+box_p[0].y); box_q[4].x=(double) ((slope.pbox_q[0].x-box_q[0].y-slope.qbox_q[3].x+ box_q[3].y)/(slope.p-slope.q)); box_q[4].y=(double) (slope.p(box_q[4].x-box_q[0].x)+box_q[0].y); } CheckPathExtent(6BezierQuantum+360); dot_product=dx.qdy.p-dx.pdy.q; if (dot_product <= 0.0) switch (draw_info->linejoin) { case BevelJoin: { path_q[q++]=box_q[1]; path_q[q++]=box_q[2]; dot_product=(box_q[4].x-box_p[4].x)(box_q[4].x-box_p[4].x)+ (box_q[4].y-box_p[4].y)(box_q[4].y-box_p[4].y); if (dot_product <= miterlimit) path_p[p++]=box_p[4]; else { path_p[p++]=box_p[1]; path_p[p++]=box_p[2]; } break; } case MiterJoin: { dot_product=(box_q[4].x-box_p[4].x)(box_q[4].x-box_p[4].x)+ (box_q[4].y-box_p[4].y)(box_q[4].y-box_p[4].y); if (dot_product <= miterlimit) { path_q[q++]=box_q[4]; path_p[p++]=box_p[4]; } else { path_q[q++]=box_q[1]; path_q[q++]=box_q[2]; path_p[p++]=box_p[1]; path_p[p++]=box_p[2]; } break; } case RoundJoin: { dot_product=(box_q[4].x-box_p[4].x)(box_q[4].x-box_p[4].x)+ (box_q[4].y-box_p[4].y)(box_q[4].y-box_p[4].y); if (dot_product <= miterlimit) path_p[p++]=box_p[4]; else { path_p[p++]=box_p[1]; path_p[p++]=box_p[2]; } center=polygon_primitive[n].point; theta.p=atan2(box_q[1].y-center.y,box_q[1].x-center.x); theta.q=atan2(box_q[2].y-center.y,box_q[2].x-center.x); if (theta.q < theta.p) theta.q+=2.0MagickPI; arc_segments=(size_t) ceil((double) ((theta.q-theta.p)/ (2.0sqrt((double) (1.0/mid))))); CheckPathExtent(arc_segments+6BezierQuantum+360); path_q[q].x=box_q[1].x; path_q[q].y=box_q[1].y; q++; for (j=1; j < (ssize_t) arc_segments; j++) { delta_theta=(double) (j(theta.q-theta.p)/arc_segments); path_q[q].x=(double) (center.x+midcos(fmod((double) (theta.p+delta_theta),DegreesToRadians(360.0)))); path_q[q].y=(double) (center.y+midsin(fmod((double) (theta.p+delta_theta),DegreesToRadians(360.0)))); q++; } path_q[q++]=box_q[2]; break; } default: break; } else switch (draw_info->linejoin) { case BevelJoin: { path_p[p++]=box_p[1]; path_p[p++]=box_p[2]; dot_product=(box_q[4].x-box_p[4].x)(box_q[4].x-box_p[4].x)+ (box_q[4].y-box_p[4].y)(box_q[4].y-box_p[4].y); if (dot_product <= miterlimit) path_q[q++]=box_q[4]; else { path_q[q++]=box_q[1]; path_q[q++]=box_q[2]; } break; } case MiterJoin: { dot_product=(box_q[4].x-box_p[4].x)(box_q[4].x-box_p[4].x)+ (box_q[4].y-box_p[4].y)(box_q[4].y-box_p[4].y); if (dot_product <= miterlimit) { path_q[q++]=box_q[4]; path_p[p++]=box_p[4]; } else { path_q[q++]=box_q[1]; path_q[q++]=box_q[2]; path_p[p++]=box_p[1]; path_p[p++]=box_p[2]; } break; } case RoundJoin: { dot_product=(box_q[4].x-box_p[4].x)(box_q[4].x-box_p[4].x)+ (box_q[4].y-box_p[4].y)(box_q[4].y-box_p[4].y); if (dot_product <= miterlimit) path_q[q++]=box_q[4]; else { path_q[q++]=box_q[1]; path_q[q++]=box_q[2]; } center=polygon_primitive[n].point; theta.p=atan2(box_p[1].y-center.y,box_p[1].x-center.x); theta.q=atan2(box_p[2].y-center.y,box_p[2].x-center.x); if (theta.p < theta.q) theta.p+=2.0MagickPI; arc_segments=(size_t) ceil((double) ((theta.p-theta.q)/ (2.0sqrt((double) (1.0/mid))))); CheckPathExtent(arc_segments+6BezierQuantum+360); path_p[p++]=box_p[1]; for (j=1; j < (ssize_t) arc_segments; j++) { delta_theta=(double) (j(theta.q-theta.p)/arc_segments); path_p[p].x=(double) (center.x+midcos(fmod((double) (theta.p+delta_theta),DegreesToRadians(360.0)))); path_p[p].y=(double) (center.y+midsin(fmod((double) (theta.p+delta_theta),DegreesToRadians(360.0)))); p++; } path_p[p++]=box_p[2]; break; } default: break; } slope.p=slope.q; inverse_slope.p=inverse_slope.q; box_p[0]=box_p[2]; box_p[1]=box_p[3]; box_q[0]=box_q[2]; box_q[1]=box_q[3]; dx.p=dx.q; dy.p=dy.q; n=i; } path_p[p++]=box_p[1]; path_q[q++]=box_q[1]; / Trace stroked polygon. / stroke_polygon=(PrimitiveInfo ) AcquireQuantumMemory((size_t) (p+q+2ULclosed_path+2UL),sizeof(stroke_polygon)); if (stroke_polygon != (PrimitiveInfo ) NULL) { for (i=0; i < (ssize_t) p; i++) { stroke_polygon[i]=polygon_primitive[0]; stroke_polygon[i].point=path_p[i]; } if (closed_path != MagickFalse) { stroke_polygon[i]=polygon_primitive[0]; stroke_polygon[i].point=stroke_polygon[0].point; i++; } for ( ; i < (ssize_t) (p+q+closed_path); i++) { stroke_polygon[i]=polygon_primitive[0]; stroke_polygon[i].point=path_q[p+q+closed_path-(i+1)]; } if (closed_path != MagickFalse) { stroke_polygon[i]=polygon_primitive[0]; stroke_polygon[i].point=stroke_polygon[p+closed_path].point; i++; } stroke_polygon[i]=polygon_primitive[0]; stroke_polygon[i].point=stroke_polygon[0].point; i++; stroke_polygon[i].primitive=UndefinedPrimitive; stroke_polygon[0].coordinates=(size_t) (p+q+2closed_path+1); } path_p=(PointInfo ) RelinquishMagickMemory(path_p); path_q=(PointInfo ) RelinquishMagickMemory(path_q); polygon_primitive=(PrimitiveInfo *) RelinquishMagickMemory(polygon_primitive); return(stroke_polygon); }
program_evaluator.h	// Ceres Solver - A fast non-linear least squares minimizer // Copyright 2015 Google Inc. All rights reserved. // http://ceres-solver.org/ // // Redistribution and use in source and binary forms, with or without // modification, are permitted provided that the following conditions are met: // // * Redistributions of source code must retain the above copyright notice, // this list of conditions and the following disclaimer. // * Redistributions in binary form must reproduce the above copyright notice, // this list of conditions and the following disclaimer in the documentation // and/or other materials provided with the distribution. // * Neither the name of Google Inc. nor the names of its contributors may be // used to endorse or promote products derived from this software without // specific prior written permission. // // THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" // AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE // IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE // ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR CONTRIBUTORS BE // LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR // CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF // SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS // INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN // CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) // ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE // POSSIBILITY OF SUCH DAMAGE. // // Author: keir@google.com (Keir Mierle) // // The ProgramEvaluator runs the cost functions contained in each residual block // and stores the result into a jacobian. The particular type of jacobian is // abstracted out using two template parameters: // // - An "EvaluatePreparer" that is responsible for creating the array with // pointers to the jacobian blocks where the cost function evaluates to. // - A "JacobianWriter" that is responsible for storing the resulting // jacobian blocks in the passed sparse matrix. // // This abstraction affords an efficient evaluator implementation while still // supporting writing to multiple sparse matrix formats. For example, when the // ProgramEvaluator is parameterized for writing to block sparse matrices, the // residual jacobians are written directly into their final position in the // block sparse matrix by the user's CostFunction; there is no copying. // // The evaluation is threaded with OpenMP or TBB. // // The EvaluatePreparer and JacobianWriter interfaces are as follows: // // class EvaluatePreparer { // // Prepare the jacobians array for use as the destination of a call to // // a cost function's evaluate method. // void Prepare(const ResidualBlock* residual_block, // int residual_block_index, // SparseMatrix* jacobian, // double** jacobians); // } // // class JacobianWriter { // // Create a jacobian that this writer can write. Same as // // Evaluator::CreateJacobian. // SparseMatrix* CreateJacobian() const; // // // Create num_threads evaluate preparers. Caller owns result which must // // be freed with delete[]. Resulting preparers are valid while this is. // EvaluatePreparer CreateEvaluatePreparers(int num_threads); // // // Write the block jacobians from a residual block evaluation to the // // larger sparse jacobian. // void Write(int residual_id, // int residual_offset, // double** jacobians, // SparseMatrix* jacobian); // } // // Note: The ProgramEvaluator is not thread safe, since internally it maintains // some per-thread scratch space. #ifndef CERES_INTERNAL_PROGRAM_EVALUATOR_H_ #define CERES_INTERNAL_PROGRAM_EVALUATOR_H_ // This include must come before any #ifndef check on Ceres compile options. #include "ceres/internal/port.h" #include <map> #include <string> #include <vector> #include "ceres/execution_summary.h" #include "ceres/internal/eigen.h" #include "ceres/internal/scoped_ptr.h" #include "ceres/parameter_block.h" #include "ceres/program.h" #include "ceres/residual_block.h" #include "ceres/scoped_thread_token.h" #include "ceres/small_blas.h" #include "ceres/thread_token_provider.h" #ifdef CERES_USE_TBB #include <atomic> #include <tbb/parallel_for.h> #include <tbb/task_scheduler_init.h> #endif namespace ceres { namespace internal { struct NullJacobianFinalizer { void operator()(SparseMatrix* jacobian, int num_parameters) {} }; template<typename EvaluatePreparer, typename JacobianWriter, typename JacobianFinalizer = NullJacobianFinalizer> class ProgramEvaluator : public Evaluator { public: ProgramEvaluator(const Evaluator::Options &options, Program* program) : options_(options), program_(program), jacobian_writer_(options, program), evaluate_preparers_( jacobian_writer_.CreateEvaluatePreparers(options.num_threads)) { #ifdef CERES_NO_THREADS if (options_.num_threads > 1) { LOG(WARNING) << "Neither OpenMP nor TBB support is compiled into this binary; " << "only options.num_threads = 1 is supported. Switching " << "to single threaded mode."; options_.num_threads = 1; } #endif // CERES_NO_THREADS BuildResidualLayout(program, &residual_layout_); evaluate_scratch_.reset(CreateEvaluatorScratch(program, options.num_threads)); } // Implementation of Evaluator interface. SparseMatrix* CreateJacobian() const { return jacobian_writer_.CreateJacobian(); } bool Evaluate(const Evaluator::EvaluateOptions& evaluate_options, const double* state, double* cost, double* residuals, double* gradient, SparseMatrix* jacobian) { ScopedExecutionTimer total_timer("Evaluator::Total", &execution_summary_); ScopedExecutionTimer call_type_timer(gradient == NULL && jacobian == NULL ? "Evaluator::Residual" : "Evaluator::Jacobian", &execution_summary_); // The parameters are stateful, so set the state before evaluating. if (!program_->StateVectorToParameterBlocks(state)) { return false; } if (residuals != NULL) { VectorRef(residuals, program_->NumResiduals()).setZero(); } if (jacobian != NULL) { jacobian->SetZero(); } // Each thread gets it's own cost and evaluate scratch space. for (int i = 0; i < options_.num_threads; ++i) { evaluate_scratch_[i].cost = 0.0; if (gradient != NULL) { VectorRef(evaluate_scratch_[i].gradient.get(), program_->NumEffectiveParameters()).setZero(); } } const int num_residual_blocks = program_->NumResidualBlocks(); ThreadTokenProvider thread_token_provider(options_.num_threads); #ifdef CERES_USE_OPENMP // This bool is used to disable the loop if an error is encountered // without breaking out of it. The remaining loop iterations are still run, // but with an empty body, and so will finish quickly. bool abort = false; #pragma omp parallel for num_threads(options_.num_threads) for (int i = 0; i < num_residual_blocks; ++i) { // Disable the loop instead of breaking, as required by OpenMP. #pragma omp flush(abort) #endif // CERES_USE_OPENMP #ifdef CERES_NO_THREADS bool abort = false; for (int i = 0; i < num_residual_blocks; ++i) { #endif // CERES_NO_THREADS #ifdef CERES_USE_TBB std::atomic_bool abort(false); tbb::task_scheduler_init tbb_task_scheduler_init(options_.num_threads); tbb::parallel_for(0, num_residual_blocks, [&](int i) { #endif // CERES_USE_TBB if (abort) { #ifndef CERES_USE_TBB continue; #else return; #endif // !CERES_USE_TBB } const ScopedThreadToken scoped_thread_token(&thread_token_provider); const int thread_id = scoped_thread_token.token(); EvaluatePreparer* preparer = &evaluate_preparers_[thread_id]; EvaluateScratch* scratch = &evaluate_scratch_[thread_id]; // Prepare block residuals if requested. const ResidualBlock* residual_block = program_->residual_blocks()[i]; double* block_residuals = NULL; if (residuals != NULL) { block_residuals = residuals + residual_layout_[i]; } else if (gradient != NULL) { block_residuals = scratch->residual_block_residuals.get(); } // Prepare block jacobians if requested. double** block_jacobians = NULL; if (jacobian != NULL \|\| gradient != NULL) { preparer->Prepare(residual_block, i, jacobian, scratch->jacobian_block_ptrs.get()); block_jacobians = scratch->jacobian_block_ptrs.get(); } // Evaluate the cost, residuals, and jacobians. double block_cost; if (!residual_block->Evaluate( evaluate_options.apply_loss_function, &block_cost, block_residuals, block_jacobians, scratch->residual_block_evaluate_scratch.get())) { abort = true; #ifdef CERES_USE_OPENMP // This ensures that the OpenMP threads have a consistent view of 'abort'. Do // the flush inside the failure case so that there is usually only one // synchronization point per loop iteration instead of two. #pragma omp flush(abort) #endif // CERES_USE_OPENMP #ifndef CERES_USE_TBB continue; #else return; #endif // !CERES_USE_TBB } scratch->cost += block_cost; // Store the jacobians, if they were requested. if (jacobian != NULL) { jacobian_writer_.Write(i, residual_layout_[i], block_jacobians, jacobian); } // Compute and store the gradient, if it was requested. if (gradient != NULL) { int num_residuals = residual_block->NumResiduals(); int num_parameter_blocks = residual_block->NumParameterBlocks(); for (int j = 0; j < num_parameter_blocks; ++j) { const ParameterBlock* parameter_block = residual_block->parameter_blocks()[j]; if (parameter_block->IsConstant()) { continue; } MatrixTransposeVectorMultiply<Eigen::Dynamic, Eigen::Dynamic, 1>( block_jacobians[j], num_residuals, parameter_block->LocalSize(), block_residuals, scratch->gradient.get() + parameter_block->delta_offset()); } } } #ifdef CERES_USE_TBB ); #endif // CERES_USE_TBB if (!abort) { const int num_parameters = program_->NumEffectiveParameters(); // Sum the cost and gradient (if requested) from each thread. (cost) = 0.0; if (gradient != NULL) { VectorRef(gradient, num_parameters).setZero(); } for (int i = 0; i < options_.num_threads; ++i) { (cost) += evaluate_scratch_[i].cost; if (gradient != NULL) { VectorRef(gradient, num_parameters) += VectorRef(evaluate_scratch_[i].gradient.get(), num_parameters); } } // Finalize the Jacobian if it is available. // `num_parameters` is passed to the finalizer so that additional // storage can be reserved for additional diagonal elements if // necessary. if (jacobian != NULL) { JacobianFinalizer f; f(jacobian, num_parameters); } } return !abort; } bool Plus(const double* state, const double* delta, double* state_plus_delta) const { return program_->Plus(state, delta, state_plus_delta); } int NumParameters() const { return program_->NumParameters(); } int NumEffectiveParameters() const { return program_->NumEffectiveParameters(); } int NumResiduals() const { return program_->NumResiduals(); } virtual std::map<std::string, int> CallStatistics() const { return execution_summary_.calls(); } virtual std::map<std::string, double> TimeStatistics() const { return execution_summary_.times(); } private: // Per-thread scratch space needed to evaluate and store each residual block. struct EvaluateScratch { void Init(int max_parameters_per_residual_block, int max_scratch_doubles_needed_for_evaluate, int max_residuals_per_residual_block, int num_parameters) { residual_block_evaluate_scratch.reset( new double[max_scratch_doubles_needed_for_evaluate]); gradient.reset(new double[num_parameters]); VectorRef(gradient.get(), num_parameters).setZero(); residual_block_residuals.reset( new double[max_residuals_per_residual_block]); jacobian_block_ptrs.reset( new double[max_parameters_per_residual_block]); } double cost; scoped_array<double> residual_block_evaluate_scratch; // The gradient in the local parameterization. scoped_array<double> gradient; // Enough space to store the residual for the largest residual block. scoped_array<double> residual_block_residuals; scoped_array<double> jacobian_block_ptrs; }; static void BuildResidualLayout(const Program& program, std::vector<int>* residual_layout) { const std::vector<ResidualBlock>& residual_blocks = program.residual_blocks(); residual_layout->resize(program.NumResidualBlocks()); int residual_pos = 0; for (int i = 0; i < residual_blocks.size(); ++i) { const int num_residuals = residual_blocks[i]->NumResiduals(); (residual_layout)[i] = residual_pos; residual_pos += num_residuals; } } // Create scratch space for each thread evaluating the program. static EvaluateScratch* CreateEvaluatorScratch(const Program& program, int num_threads) { int max_parameters_per_residual_block = program.MaxParametersPerResidualBlock(); int max_scratch_doubles_needed_for_evaluate = program.MaxScratchDoublesNeededForEvaluate(); int max_residuals_per_residual_block = program.MaxResidualsPerResidualBlock(); int num_parameters = program.NumEffectiveParameters(); EvaluateScratch* evaluate_scratch = new EvaluateScratch[num_threads]; for (int i = 0; i < num_threads; i++) { evaluate_scratch[i].Init(max_parameters_per_residual_block, max_scratch_doubles_needed_for_evaluate, max_residuals_per_residual_block, num_parameters); } return evaluate_scratch; } Evaluator::Options options_; Program* program_; JacobianWriter jacobian_writer_; scoped_array<EvaluatePreparer> evaluate_preparers_; scoped_array<EvaluateScratch> evaluate_scratch_; std::vector<int> residual_layout_; ::ceres::internal::ExecutionSummary execution_summary_; }; } // namespace internal } // namespace ceres #endif // CERES_INTERNAL_PROGRAM_EVALUATOR_H_
CLHelper.h	//------------------------------------------ //--cambine:helper function for OpenCL //--programmer: Jianbin Fang //--date: 27/12/2010 //------------------------------------------ #ifndef _CL_HELPER_ #define _CL_HELPER_ #include <CL/cl.h> #include <vector> #include <iostream> #include <fstream> #include <string> using std::string; using std::ifstream; using std::cerr; using std::endl; using std::cout; //#pragma OPENCL EXTENSION cl_nv_compiler_options:enable #define WORK_DIM 2 //work-items dimensions struct oclHandleStruct { cl_context context; cl_device_id devices; cl_command_queue queue; cl_program program; cl_int cl_status; std::string error_str; std::vector<cl_kernel> kernel; }; struct oclHandleStruct oclHandles; char kernel_file[100] = "Kernels.cl"; int total_kernels = 2; string kernel_names[2] = {"BFS_1", "BFS_2"}; int work_group_size = 512; int device_id_inused = 0; //deviced id used (default : 0) / * Converts the contents of a file into a string / string FileToString(const string fileName) { ifstream f(fileName.c_str(), ifstream::in \| ifstream::binary); try { size_t size; char str; string s; if(f.is_open()) { size_t fileSize; f.seekg(0, ifstream::end); size = fileSize = f.tellg(); f.seekg(0, ifstream::beg); str = new char[size+1]; if (!str) throw(string("Could not allocate memory")); f.read(str, fileSize); f.close(); str[size] = '\0'; s = str; delete [] str; return s; } } catch(std::string msg) { cerr << "Exception caught in FileToString(): " << msg << endl; if(f.is_open()) f.close(); } catch(...) { cerr << "Exception caught in FileToString()" << endl; if(f.is_open()) f.close(); } string errorMsg = "FileToString()::Error: Unable to open file " + fileName; throw(errorMsg); } //--------------------------------------- //Read command line parameters // void _clCmdParams(int argc, char* argv[]){ for (int i =0; i < argc; ++i) { switch (argv[i][1]) { case 'g': //--g stands for size of work group if (++i < argc) { sscanf(argv[i], "%u", &work_group_size); } else { std::cerr << "Could not read argument after option " << argv[i-1] << std::endl; throw; } break; case 'd': //--d stands for device id used in computaion if (++i < argc) { sscanf(argv[i], "%u", &device_id_inused); } else { std::cerr << "Could not read argument after option " << argv[i-1] << std::endl; throw; } break; default: ; } } } //--------------------------------------- //Initlize CL objects //--description: there are 5 steps to initialize all the OpenCL objects needed //--revised on 04/01/2011: get the number of devices and // devices have no relationship with context void _clInit() { int DEVICE_ID_INUSED = device_id_inused; cl_int resultCL; oclHandles.context = NULL; oclHandles.devices = NULL; oclHandles.queue = NULL; oclHandles.program = NULL; cl_uint deviceListSize; //----------------------------------------------- //--cambine-1: find the available platforms and select one cl_uint numPlatforms; cl_platform_id targetPlatform = NULL; resultCL = clGetPlatformIDs(0, NULL, &numPlatforms); if (resultCL != CL_SUCCESS) throw (string("InitCL()::Error: Getting number of platforms (clGetPlatformIDs)")); //printf("number of platforms:%d\n",numPlatforms); //by cambine if (!(numPlatforms > 0)) throw (string("InitCL()::Error: No platforms found (clGetPlatformIDs)")); cl_platform_id* allPlatforms = (cl_platform_id) malloc(numPlatforms sizeof(cl_platform_id)); resultCL = clGetPlatformIDs(numPlatforms, allPlatforms, NULL); if (resultCL != CL_SUCCESS) throw (string("InitCL()::Error: Getting platform ids (clGetPlatformIDs)")); /* Select the target platform. Default: first platform / targetPlatform = allPlatforms[0]; for (int i = 0; i < numPlatforms; i++) { char pbuff[128]; resultCL = clGetPlatformInfo( allPlatforms[i], CL_PLATFORM_VENDOR, sizeof(pbuff), pbuff, NULL); if (resultCL != CL_SUCCESS) throw (string("InitCL()::Error: Getting platform info (clGetPlatformInfo)")); //printf("vedor is %s\n",pbuff); } free(allPlatforms); //----------------------------------------------- //--cambine-2: create an OpenCL context cl_context_properties cprops[3] = { CL_CONTEXT_PLATFORM, (cl_context_properties)targetPlatform, 0 }; oclHandles.context = clCreateContextFromType(cprops, CL_DEVICE_TYPE_GPU, NULL, NULL, &resultCL); if ((resultCL != CL_SUCCESS) \|\| (oclHandles.context == NULL)) throw (string("InitCL()::Error: Creating Context (clCreateContextFromType)")); //----------------------------------------------- //--cambine-3: detect OpenCL devices / First, get the size of device list / oclHandles.cl_status = clGetDeviceIDs(targetPlatform, CL_DEVICE_TYPE_GPU, 0, NULL, &deviceListSize); if(oclHandles.cl_status!=CL_SUCCESS){ throw(string("exception in _clInit -> clGetDeviceIDs")); } if (deviceListSize == 0) throw(string("InitCL()::Error: No devices found.")); //std::cout<<"device number:"<<deviceListSize<<std::endl; / Now, allocate the device list / oclHandles.devices = (cl_device_id )malloc(deviceListSize * sizeof(cl_device_id)); if (oclHandles.devices == 0) throw(string("InitCL()::Error: Could not allocate memory.")); /* Next, get the device list data / oclHandles.cl_status = clGetDeviceIDs(targetPlatform, CL_DEVICE_TYPE_GPU, deviceListSize, \ oclHandles.devices, NULL); if(oclHandles.cl_status!=CL_SUCCESS){ throw(string("exception in _clInit -> clGetDeviceIDs-2")); } //----------------------------------------------- //--cambine-4: Create an OpenCL command queue oclHandles.queue = clCreateCommandQueue(oclHandles.context, oclHandles.devices[DEVICE_ID_INUSED], 0, &resultCL); if ((resultCL != CL_SUCCESS) \|\| (oclHandles.queue == NULL)) throw(string("InitCL()::Creating Command Queue. (clCreateCommandQueue)")); //----------------------------------------------- //--cambine-5: Load CL file, build CL program object, create CL kernel object std::string source_str = FileToString(kernel_file); const char source = source_str.c_str(); size_t sourceSize[] = { source_str.length() }; oclHandles.program = clCreateProgramWithSource(oclHandles.context, 1, &source, sourceSize, &resultCL); if ((resultCL != CL_SUCCESS) \|\| (oclHandles.program == NULL)) throw(string("InitCL()::Error: Loading Binary into cl_program. (clCreateProgramWithBinary)")); //insert debug information //std::string options= "-cl-nv-verbose"; //Doesn't work on AMD machines //options += " -cl-nv-opt-level=3"; resultCL = clBuildProgram(oclHandles.program, deviceListSize, oclHandles.devices, NULL, NULL,NULL); if ((resultCL != CL_SUCCESS) \|\| (oclHandles.program == NULL)) { cerr << "InitCL()::Error: In clBuildProgram" << endl; size_t length; resultCL = clGetProgramBuildInfo(oclHandles.program, oclHandles.devices[DEVICE_ID_INUSED], CL_PROGRAM_BUILD_LOG, 0, NULL, &length); if(resultCL != CL_SUCCESS) throw(string("InitCL()::Error: Getting Program build info(clGetProgramBuildInfo)")); char* buffer = (char)malloc(length); resultCL = clGetProgramBuildInfo(oclHandles.program, oclHandles.devices[DEVICE_ID_INUSED], CL_PROGRAM_BUILD_LOG, length, buffer, NULL); if(resultCL != CL_SUCCESS) throw(string("InitCL()::Error: Getting Program build info(clGetProgramBuildInfo)")); cerr << buffer << endl; free(buffer); throw(string("InitCL()::Error: Building Program (clBuildProgram)")); } //get program information in intermediate representation #ifdef PTX_MSG size_t binary_sizes[deviceListSize]; char binaries[deviceListSize]; //figure out number of devices and the sizes of the binary for each device. oclHandles.cl_status = clGetProgramInfo(oclHandles.program, CL_PROGRAM_BINARY_SIZES, sizeof(size_t)deviceListSize, &binary_sizes, NULL ); if(oclHandles.cl_status!=CL_SUCCESS){ throw(string("--cambine:exception in _InitCL -> clGetProgramInfo-2")); } std::cout<<"--cambine:"<<binary_sizes<<std::endl; //copy over all of the generated binaries. for(int i=0;i<deviceListSize;i++) binaries[i] = (char )malloc( sizeof(char)(binary_sizes[i]+1)); oclHandles.cl_status = clGetProgramInfo(oclHandles.program, CL_PROGRAM_BINARIES, sizeof(char )deviceListSize, binaries, NULL ); if(oclHandles.cl_status!=CL_SUCCESS){ throw(string("--cambine:exception in _InitCL -> clGetProgramInfo-3")); } for(int i=0;i<deviceListSize;i++) binaries[i][binary_sizes[i]] = '\0'; std::cout<<"--cambine:writing ptd information..."<<std::endl; FILE ptx_file = fopen("cl.ptx","w"); if(ptx_file==NULL){ throw(string("exceptions in allocate ptx file.")); } fprintf(ptx_file,"%s",binaries[DEVICE_ID_INUSED]); fclose(ptx_file); std::cout<<"--cambine:writing ptd information done."<<std::endl; for(int i=0;i<deviceListSize;i++) free(binaries[i]); #endif for (int nKernel = 0; nKernel < total_kernels; nKernel++) { /* get a kernel object handle for a kernel with the given name / cl_kernel kernel = clCreateKernel(oclHandles.program, (kernel_names[nKernel]).c_str(), &resultCL); if ((resultCL != CL_SUCCESS) \|\| (kernel == NULL)) { string errorMsg = "InitCL()::Error: Creating Kernel (clCreateKernel) \"" + kernel_names[nKernel] + "\""; throw(errorMsg); } oclHandles.kernel.push_back(kernel); } //get resource alocation information #ifdef RES_MSG char build_log; size_t ret_val_size; oclHandles.cl_status = clGetProgramBuildInfo(oclHandles.program, oclHandles.devices[DEVICE_ID_INUSED], CL_PROGRAM_BUILD_LOG, 0, NULL, &ret_val_size); if(oclHandles.cl_status!=CL_SUCCESS){ throw(string("exceptions in _InitCL -> getting resource information")); } build_log = (char )malloc(ret_val_size+1); oclHandles.cl_status = clGetProgramBuildInfo(oclHandles.program, oclHandles.devices[DEVICE_ID_INUSED], CL_PROGRAM_BUILD_LOG, ret_val_size, build_log, NULL); if(oclHandles.cl_status!=CL_SUCCESS){ throw(string("exceptions in _InitCL -> getting resources allocation information-2")); } build_log[ret_val_size] = '\0'; std::cout<<"--cambine:"<<build_log<<std::endl; free(build_log); #endif } //--------------------------------------- //release CL objects void _clRelease() { char errorFlag = false; for (int nKernel = 0; nKernel < oclHandles.kernel.size(); nKernel++) { if (oclHandles.kernel[nKernel] != NULL) { cl_int resultCL = clReleaseKernel(oclHandles.kernel[nKernel]); if (resultCL != CL_SUCCESS) { cerr << "ReleaseCL()::Error: In clReleaseKernel" << endl; errorFlag = true; } oclHandles.kernel[nKernel] = NULL; } oclHandles.kernel.clear(); } if (oclHandles.program != NULL) { cl_int resultCL = clReleaseProgram(oclHandles.program); if (resultCL != CL_SUCCESS) { cerr << "ReleaseCL()::Error: In clReleaseProgram" << endl; errorFlag = true; } oclHandles.program = NULL; } if (oclHandles.queue != NULL) { cl_int resultCL = clReleaseCommandQueue(oclHandles.queue); if (resultCL != CL_SUCCESS) { cerr << "ReleaseCL()::Error: In clReleaseCommandQueue" << endl; errorFlag = true; } oclHandles.queue = NULL; } free(oclHandles.devices); if (oclHandles.context != NULL) { cl_int resultCL = clReleaseContext(oclHandles.context); if (resultCL != CL_SUCCESS) { cerr << "ReleaseCL()::Error: In clReleaseContext" << endl; errorFlag = true; } oclHandles.context = NULL; } if (errorFlag) throw(string("ReleaseCL()::Error encountered.")); } //-------------------------------------------------------- //--cambine:create buffer and then copy data from host to device cl_mem _clCreateAndCpyMem(int size, void h_mem_source) throw(string){ cl_mem d_mem; d_mem = clCreateBuffer(oclHandles.context, CL_MEM_READ_ONLY\|CL_MEM_COPY_HOST_PTR, \ size, h_mem_source, &oclHandles.cl_status); #ifdef ERRMSG if(oclHandles.cl_status != CL_SUCCESS) throw(string("excpetion in _clCreateAndCpyMem()")); #endif return d_mem; } //------------------------------------------------------- //--cambine: create read only buffer for devices //--date: 17/01/2011 cl_mem _clMallocRW(int size, void * h_mem_ptr) throw(string){ cl_mem d_mem; d_mem = clCreateBuffer(oclHandles.context, CL_MEM_READ_WRITE \| CL_MEM_COPY_HOST_PTR, size, h_mem_ptr, &oclHandles.cl_status); #ifdef ERRMSG if(oclHandles.cl_status != CL_SUCCESS) throw(string("excpetion in _clMallocRW")); #endif return d_mem; } //------------------------------------------------------- //--cambine: create read and write buffer for devices //--date: 17/01/2011 cl_mem _clMalloc(int size, void * h_mem_ptr) throw(string){ cl_mem d_mem; d_mem = clCreateBuffer(oclHandles.context, CL_MEM_WRITE_ONLY \| CL_MEM_COPY_HOST_PTR, size, h_mem_ptr, &oclHandles.cl_status); #ifdef ERRMSG if(oclHandles.cl_status != CL_SUCCESS) throw(string("excpetion in _clMalloc")); #endif return d_mem; } //------------------------------------------------------- //--cambine: transfer data from host to device //--date: 17/01/2011 void _clMemcpyH2D(cl_mem d_mem, int size, const void h_mem_ptr) throw(string){ oclHandles.cl_status = clEnqueueWriteBuffer(oclHandles.queue, d_mem, CL_TRUE, 0, size, h_mem_ptr, 0, NULL, NULL); #ifdef ERRMSG if(oclHandles.cl_status != CL_SUCCESS) throw(string("excpetion in _clMemcpyH2D")); #endif } //-------------------------------------------------------- //--cambine:create buffer and then copy data from host to device with pinned // memory cl_mem _clCreateAndCpyPinnedMem(int size, float h_mem_source) throw(string){ cl_mem d_mem, d_mem_pinned; float * h_mem_pinned = NULL; d_mem_pinned = clCreateBuffer(oclHandles.context, CL_MEM_READ_ONLY\|CL_MEM_ALLOC_HOST_PTR, \ size, NULL, &oclHandles.cl_status); #ifdef ERRMSG if(oclHandles.cl_status != CL_SUCCESS) throw(string("excpetion in _clCreateAndCpyMem()->d_mem_pinned")); #endif //------------ d_mem = clCreateBuffer(oclHandles.context, CL_MEM_READ_ONLY, \ size, NULL, &oclHandles.cl_status); #ifdef ERRMSG if(oclHandles.cl_status != CL_SUCCESS) throw(string("excpetion in _clCreateAndCpyMem() -> d_mem ")); #endif //---------- h_mem_pinned = (cl_float )clEnqueueMapBuffer(oclHandles.queue, d_mem_pinned, CL_TRUE, \ CL_MAP_WRITE, 0, size, 0, NULL, \ NULL, &oclHandles.cl_status); #ifdef ERRMSG if(oclHandles.cl_status != CL_SUCCESS) throw(string("excpetion in _clCreateAndCpyMem() -> clEnqueueMapBuffer")); #endif int element_number = size/sizeof(float); #pragma omp parallel for for(int i=0;i<element_number;i++){ h_mem_pinned[i] = h_mem_source[i]; } //---------- oclHandles.cl_status = clEnqueueWriteBuffer(oclHandles.queue, d_mem, \ CL_TRUE, 0, size, h_mem_pinned, \ 0, NULL, NULL); #ifdef ERRMSG if(oclHandles.cl_status != CL_SUCCESS) throw(string("excpetion in _clCreateAndCpyMem() -> clEnqueueWriteBuffer")); #endif return d_mem; } //-------------------------------------------------------- //--cambine:create write only buffer on device cl_mem _clMallocWO(int size) throw(string){ cl_mem d_mem; d_mem = clCreateBuffer(oclHandles.context, CL_MEM_WRITE_ONLY, size, 0, &oclHandles.cl_status); #ifdef ERRMSG if(oclHandles.cl_status != CL_SUCCESS) throw(string("excpetion in _clCreateMem()")); #endif return d_mem; } //-------------------------------------------------------- //transfer data from device to host void _clMemcpyD2H(cl_mem d_mem, int size, void h_mem) throw(string){ oclHandles.cl_status = clEnqueueReadBuffer(oclHandles.queue, d_mem, CL_TRUE, 0, size, h_mem, 0,0,0); #ifdef ERRMSG oclHandles.error_str = "excpetion in _clCpyMemD2H -> "; switch(oclHandles.cl_status){ case CL_INVALID_COMMAND_QUEUE: oclHandles.error_str += "CL_INVALID_COMMAND_QUEUE"; break; case CL_INVALID_CONTEXT: oclHandles.error_str += "CL_INVALID_CONTEXT"; break; case CL_INVALID_MEM_OBJECT: oclHandles.error_str += "CL_INVALID_MEM_OBJECT"; break; case CL_INVALID_VALUE: oclHandles.error_str += "CL_INVALID_VALUE"; break; case CL_INVALID_EVENT_WAIT_LIST: oclHandles.error_str += "CL_INVALID_EVENT_WAIT_LIST"; break; case CL_MEM_OBJECT_ALLOCATION_FAILURE: oclHandles.error_str += "CL_MEM_OBJECT_ALLOCATION_FAILURE"; break; case CL_OUT_OF_HOST_MEMORY: oclHandles.error_str += "CL_OUT_OF_HOST_MEMORY"; break; default: oclHandles.error_str += "Unknown reason"; break; } if(oclHandles.cl_status != CL_SUCCESS) throw(oclHandles.error_str); #endif } //-------------------------------------------------------- //set kernel arguments void _clSetArgs(int kernel_id, int arg_idx, void * d_mem, int size = 0) throw(string){ if(!size){ oclHandles.cl_status = clSetKernelArg(oclHandles.kernel[kernel_id], arg_idx, sizeof(d_mem), &d_mem); #ifdef ERRMSG oclHandles.error_str = "excpetion in _clSetKernelArg() "; switch(oclHandles.cl_status){ case CL_INVALID_KERNEL: oclHandles.error_str += "CL_INVALID_KERNEL"; break; case CL_INVALID_ARG_INDEX: oclHandles.error_str += "CL_INVALID_ARG_INDEX"; break; case CL_INVALID_ARG_VALUE: oclHandles.error_str += "CL_INVALID_ARG_VALUE"; break; case CL_INVALID_MEM_OBJECT: oclHandles.error_str += "CL_INVALID_MEM_OBJECT"; break; case CL_INVALID_SAMPLER: oclHandles.error_str += "CL_INVALID_SAMPLER"; break; case CL_INVALID_ARG_SIZE: oclHandles.error_str += "CL_INVALID_ARG_SIZE"; break; case CL_OUT_OF_RESOURCES: oclHandles.error_str += "CL_OUT_OF_RESOURCES"; break; case CL_OUT_OF_HOST_MEMORY: oclHandles.error_str += "CL_OUT_OF_HOST_MEMORY"; break; default: oclHandles.error_str += "Unknown reason"; break; } if(oclHandles.cl_status != CL_SUCCESS) throw(oclHandles.error_str); #endif } else{ oclHandles.cl_status = clSetKernelArg(oclHandles.kernel[kernel_id], arg_idx, size, d_mem); #ifdef ERRMSG oclHandles.error_str = "excpetion in _clSetKernelArg() "; switch(oclHandles.cl_status){ case CL_INVALID_KERNEL: oclHandles.error_str += "CL_INVALID_KERNEL"; break; case CL_INVALID_ARG_INDEX: oclHandles.error_str += "CL_INVALID_ARG_INDEX"; break; case CL_INVALID_ARG_VALUE: oclHandles.error_str += "CL_INVALID_ARG_VALUE"; break; case CL_INVALID_MEM_OBJECT: oclHandles.error_str += "CL_INVALID_MEM_OBJECT"; break; case CL_INVALID_SAMPLER: oclHandles.error_str += "CL_INVALID_SAMPLER"; break; case CL_INVALID_ARG_SIZE: oclHandles.error_str += "CL_INVALID_ARG_SIZE"; break; case CL_OUT_OF_RESOURCES: oclHandles.error_str += "CL_OUT_OF_RESOURCES"; break; case CL_OUT_OF_HOST_MEMORY: oclHandles.error_str += "CL_OUT_OF_HOST_MEMORY"; break; default: oclHandles.error_str += "Unknown reason"; break; } if(oclHandles.cl_status != CL_SUCCESS) throw(oclHandles.error_str); #endif } } void _clFinish() throw(string){ oclHandles.cl_status = clFinish(oclHandles.queue); #ifdef ERRMSG oclHandles.error_str = "excpetion in _clFinish"; switch(oclHandles.cl_status){ case CL_INVALID_COMMAND_QUEUE: oclHandles.error_str += "CL_INVALID_COMMAND_QUEUE"; break; case CL_OUT_OF_RESOURCES: oclHandles.error_str += "CL_OUT_OF_RESOURCES"; break; case CL_OUT_OF_HOST_MEMORY: oclHandles.error_str += "CL_OUT_OF_HOST_MEMORY"; break; default: oclHandles.error_str += "Unknown reasons"; break; } if(oclHandles.cl_status!=CL_SUCCESS){ throw(oclHandles.error_str); } #endif } //-------------------------------------------------------- //--cambine:enqueue kernel void _clInvokeKernel(int kernel_id, int work_items, int work_group_size) throw(string){ cl_uint work_dim = WORK_DIM; cl_event e[1]; if(work_items%work_group_size != 0) //process situations that work_items cannot be divided by work_group_size work_items = work_items + (work_group_size-(work_items%work_group_size)); size_t local_work_size[] = {work_group_size, 1}; size_t global_work_size[] = {work_items, 1}; oclHandles.cl_status = clEnqueueNDRangeKernel(oclHandles.queue, oclHandles.kernel[kernel_id], work_dim, 0, \ global_work_size, local_work_size, 0 , 0, &(e[0]) ); #ifdef ERRMSG oclHandles.error_str = "excpetion in _clInvokeKernel() -> "; switch(oclHandles.cl_status) { case CL_INVALID_PROGRAM_EXECUTABLE: oclHandles.error_str += "CL_INVALID_PROGRAM_EXECUTABLE"; break; case CL_INVALID_COMMAND_QUEUE: oclHandles.error_str += "CL_INVALID_COMMAND_QUEUE"; break; case CL_INVALID_KERNEL: oclHandles.error_str += "CL_INVALID_KERNEL"; break; case CL_INVALID_CONTEXT: oclHandles.error_str += "CL_INVALID_CONTEXT"; break; case CL_INVALID_KERNEL_ARGS: oclHandles.error_str += "CL_INVALID_KERNEL_ARGS"; break; case CL_INVALID_WORK_DIMENSION: oclHandles.error_str += "CL_INVALID_WORK_DIMENSION"; break; case CL_INVALID_GLOBAL_WORK_SIZE: oclHandles.error_str += "CL_INVALID_GLOBAL_WORK_SIZE"; break; case CL_INVALID_WORK_GROUP_SIZE: oclHandles.error_str += "CL_INVALID_WORK_GROUP_SIZE"; break; case CL_INVALID_WORK_ITEM_SIZE: oclHandles.error_str += "CL_INVALID_WORK_ITEM_SIZE"; break; case CL_INVALID_GLOBAL_OFFSET: oclHandles.error_str += "CL_INVALID_GLOBAL_OFFSET"; break; case CL_OUT_OF_RESOURCES: oclHandles.error_str += "CL_OUT_OF_RESOURCES"; break; case CL_MEM_OBJECT_ALLOCATION_FAILURE: oclHandles.error_str += "CL_MEM_OBJECT_ALLOCATION_FAILURE"; break; case CL_INVALID_EVENT_WAIT_LIST: oclHandles.error_str += "CL_INVALID_EVENT_WAIT_LIST"; break; case CL_OUT_OF_HOST_MEMORY: oclHandles.error_str += "CL_OUT_OF_HOST_MEMORY"; break; default: oclHandles.error_str += "Unkown reseason"; break; } if(oclHandles.cl_status != CL_SUCCESS) throw(oclHandles.error_str); #endif //_clFinish(); // oclHandles.cl_status = clWaitForEvents(1, &e[0]); // #ifdef ERRMSG // if (oclHandles.cl_status!= CL_SUCCESS) // throw(string("excpetion in _clEnqueueNDRange() -> clWaitForEvents")); // #endif } void _clInvokeKernel2D(int kernel_id, int range_x, int range_y, int group_x, int group_y) throw(string){ cl_uint work_dim = WORK_DIM; size_t local_work_size[] = {group_x, group_y}; size_t global_work_size[] = {range_x, range_y}; cl_event e[1]; /if(work_items%work_group_size != 0) //process situations that work_items cannot be divided by work_group_size work_items = work_items + (work_group_size-(work_items%work_group_size));/ oclHandles.cl_status = clEnqueueNDRangeKernel(oclHandles.queue, oclHandles.kernel[kernel_id], work_dim, 0, \ global_work_size, local_work_size, 0 , 0, &(e[0]) ); #ifdef ERRMSG oclHandles.error_str = "excpetion in _clInvokeKernel() -> "; switch(oclHandles.cl_status) { case CL_INVALID_PROGRAM_EXECUTABLE: oclHandles.error_str += "CL_INVALID_PROGRAM_EXECUTABLE"; break; case CL_INVALID_COMMAND_QUEUE: oclHandles.error_str += "CL_INVALID_COMMAND_QUEUE"; break; case CL_INVALID_KERNEL: oclHandles.error_str += "CL_INVALID_KERNEL"; break; case CL_INVALID_CONTEXT: oclHandles.error_str += "CL_INVALID_CONTEXT"; break; case CL_INVALID_KERNEL_ARGS: oclHandles.error_str += "CL_INVALID_KERNEL_ARGS"; break; case CL_INVALID_WORK_DIMENSION: oclHandles.error_str += "CL_INVALID_WORK_DIMENSION"; break; case CL_INVALID_GLOBAL_WORK_SIZE: oclHandles.error_str += "CL_INVALID_GLOBAL_WORK_SIZE"; break; case CL_INVALID_WORK_GROUP_SIZE: oclHandles.error_str += "CL_INVALID_WORK_GROUP_SIZE"; break; case CL_INVALID_WORK_ITEM_SIZE: oclHandles.error_str += "CL_INVALID_WORK_ITEM_SIZE"; break; case CL_INVALID_GLOBAL_OFFSET: oclHandles.error_str += "CL_INVALID_GLOBAL_OFFSET"; break; case CL_OUT_OF_RESOURCES: oclHandles.error_str += "CL_OUT_OF_RESOURCES"; break; case CL_MEM_OBJECT_ALLOCATION_FAILURE: oclHandles.error_str += "CL_MEM_OBJECT_ALLOCATION_FAILURE"; break; case CL_INVALID_EVENT_WAIT_LIST: oclHandles.error_str += "CL_INVALID_EVENT_WAIT_LIST"; break; case CL_OUT_OF_HOST_MEMORY: oclHandles.error_str += "CL_OUT_OF_HOST_MEMORY"; break; default: oclHandles.error_str += "Unkown reseason"; break; } if(oclHandles.cl_status != CL_SUCCESS) throw(oclHandles.error_str); #endif //_clFinish(); /oclHandles.cl_status = clWaitForEvents(1, &e[0]); #ifdef ERRMSG if (oclHandles.cl_status!= CL_SUCCESS) throw(string("excpetion in _clEnqueueNDRange() -> clWaitForEvents")); #endif/ } //-------------------------------------------------------- //release OpenCL objects void _clFree(cl_mem ob) throw(string){ if(ob!=NULL) oclHandles.cl_status = clReleaseMemObject(ob); #ifdef ERRMSG oclHandles.error_str = "excpetion in _clFree() ->"; switch(oclHandles.cl_status) { case CL_INVALID_MEM_OBJECT: oclHandles.error_str += "CL_INVALID_MEM_OBJECT"; break; case CL_OUT_OF_RESOURCES: oclHandles.error_str += "CL_OUT_OF_RESOURCES"; break; case CL_OUT_OF_HOST_MEMORY: oclHandles.error_str += "CL_OUT_OF_HOST_MEMORY"; break; default: oclHandles.error_str += "Unkown reseason"; break; } if (oclHandles.cl_status!= CL_SUCCESS) throw(oclHandles.error_str); #endif } #endif //_CL_HELPER_
mixed_tentusscher_myo_epi_2004_S1_3.c	// Scenario 1 - Mixed-Model TenTusscher 2004 (Myocardium + Epicardium) // (AP + max:dvdt) #include <stdio.h> #include "mixed_tentusscher_myo_epi_2004_S1_3.h" GET_CELL_MODEL_DATA(init_cell_model_data) { if(get_initial_v) cell_model->initial_v = INITIAL_V; if(get_neq) cell_model->number_of_ode_equations = NEQ; } SET_ODE_INITIAL_CONDITIONS_CPU(set_model_initial_conditions_cpu) { static bool first_call = true; if(first_call) { print_to_stdout_and_file("Using mixed version of TenTusscher 2004 myocardium + epicardium CPU model\n"); first_call = false; } // Get the mapping array uint32_t mapping = NULL; if(extra_data) { mapping = (uint32_t)extra_data; } else { print_to_stderr_and_file_and_exit("You need to specify a mask function when using a mixed model!\n"); } // Initial conditions for TenTusscher myocardium if (mapping[sv_id] == 0) { // Default initial conditions /* sv[0] = INITIAL_V; // V; millivolt sv[1] = 0.f; //M sv[2] = 0.75; //H sv[3] = 0.75f; //J sv[4] = 0.f; //Xr1 sv[5] = 1.f; //Xr2 sv[6] = 0.f; //Xs sv[7] = 1.f; //S sv[8] = 0.f; //R sv[9] = 0.f; //D sv[10] = 1.f; //F sv[11] = 1.f; //FCa sv[12] = 1.f; //G sv[13] = 0.0002; //Cai sv[14] = 0.2f; //CaSR sv[15] = 11.6f; //Nai sv[16] = 138.3f; //Ki / // Elnaz's steady-state initial conditions real sv_sst[]={-86.3965119057144,0.00133824305081220,0.775463576993407,0.775278393595599,0.000179499343643571,0.483303039835057,0.00297647859235379,0.999998290403642,1.98961879737287e-08,1.93486789479597e-05,0.999599147019885,1.00646342475688,0.999975178010127,5.97703651642618e-05,0.418325344820368,10.7429775420171,138.918155900633}; for (uint32_t i = 0; i < NEQ; i++) sv[i] = sv_sst[i]; } // Initial conditions for TenTusscher epicardium else { // Default initial conditions / sv[0] = INITIAL_V; // V; millivolt sv[1] = 0.f; //M sv[2] = 0.75; //H sv[3] = 0.75f; //J sv[4] = 0.f; //Xr1 sv[5] = 1.f; //Xr2 sv[6] = 0.f; //Xs sv[7] = 1.f; //S sv[8] = 0.f; //R sv[9] = 0.f; //D sv[10] = 1.f; //F sv[11] = 1.f; //FCa sv[12] = 1.f; //G sv[13] = 0.0002; //Cai sv[14] = 0.2f; //CaSR sv[15] = 11.6f; //Nai sv[16] = 138.3f; //Ki / // Elnaz's steady-state initial conditions real sv_sst[]={-86.7781728901090,0.00123349870343949,0.784809889318744,0.784547392738085,0.000169596490364688,0.487274781980815,0.00289668567203959,0.999998415889729,1.86706803556251e-08,1.83887682327320e-05,0.999777287266349,1.00756607610598,0.999999160062542,3.39867729896090e-05,0.592251587252171,9.37662819093271,140.159936788276}; for (uint32_t i = 0; i < NEQ; i++) sv[i] = sv_sst[i]; } } SOLVE_MODEL_ODES_CPU(solve_model_odes_cpu) { // Get the mapping array uint32_t mapping = NULL; if(extra_data) { mapping = (uint32_t)extra_data; } else { print_to_stderr_and_file_and_exit("You need to specify a mask function when using a mixed model!\n"); } uint32_t sv_id; int i; #pragma omp parallel for private(sv_id) for (i = 0; i < num_cells_to_solve; i++) { if(cells_to_solve) sv_id = cells_to_solve[i]; else sv_id = (uint32_t )i; for (int j = 0; j < num_steps; ++j) { if (mapping[i] == 0) solve_model_ode_cpu_myo(dt, sv + (sv_id NEQ), stim_currents[i]); else solve_model_ode_cpu_epi(dt, sv + (sv_id * NEQ), stim_currents[i]); } } } void solve_model_ode_cpu_myo (real dt, real sv, real stim_current) { real rY[NEQ], rDY[NEQ]; for(int i = 0; i < NEQ; i++) rY[i] = sv[i]; RHS_cpu_myo(rY, rDY, stim_current, dt); for(int i = 0; i < NEQ; i++) sv[i] = rDY[i]; } void RHS_cpu_myo(const real sv, real rDY_, real stim_current, real dt) { // State variables real svolt = sv[0]; real sm = sv[1]; real sh = sv[2]; real sj = sv[3]; real sxr1 = sv[4]; real sxr2 = sv[5]; real sxs = sv[6]; real ss = sv[7]; real sr = sv[8]; real sd = sv[9]; real sf = sv[10]; real sfca = sv[11]; real sg = sv[12]; real Cai = sv[13]; real CaSR = sv[14]; real Nai = sv[15]; real Ki = sv[16]; //External concentrations real Ko=5.4; real Cao=2.0; real Nao=140.0; //Intracellular volumes real Vc=0.016404; real Vsr=0.001094; //Calcium dynamics real Bufc=0.15f; real Kbufc=0.001f; real Bufsr=10.f; real Kbufsr=0.3f; real taufca=2.f; real taug=2.f; real Vmaxup=0.000425f; real Kup=0.00025f; //Constants const real R = 8314.472f; const real F = 96485.3415f; const real T =310.0f; real RTONF =(RT)/F; //Cellular capacitance real CAPACITANCE=0.185; //Parameters for currents //Parameters for IKr real Gkr=0.096; //Parameters for Iks real pKNa=0.03; // [!] Myocardium cell real Gks=0.062; //Parameters for Ik1 real GK1=5.405; //Parameters for Ito // [!] Myocardium cell real Gto=0.294; //Parameters for INa real GNa=14.838; //Parameters for IbNa real GbNa=0.00029; //Parameters for INaK real KmK=1.0; real KmNa=40.0; real knak=1.362; //Parameters for ICaL real GCaL=0.000175; //Parameters for IbCa real GbCa=0.000592; //Parameters for INaCa real knaca=1000; real KmNai=87.5; real KmCa=1.38; real ksat=0.1; real n=0.35; //Parameters for IpCa real GpCa=0.825; real KpCa=0.0005; //Parameters for IpK; real GpK=0.0146; real IKr; real IKs; real IK1; real Ito; real INa; real IbNa; real ICaL; real IbCa; real INaCa; real IpCa; real IpK; real INaK; real Irel; real Ileak; real dNai; real dKi; real dCai; real dCaSR; real A; // real BufferFactorc; // real BufferFactorsr; real SERCA; real Caisquare; real CaSRsquare; real CaCurrent; real CaSRCurrent; real fcaold; real gold; real Ek; real Ena; real Eks; real Eca; real CaCSQN; real bjsr; real cjsr; real CaBuf; real bc; real cc; real Ak1; real Bk1; real rec_iK1; real rec_ipK; real rec_iNaK; real AM; real BM; real AH_1; real BH_1; real AH_2; real BH_2; real AJ_1; real BJ_1; real AJ_2; real BJ_2; real M_INF; real H_INF; real J_INF; real TAU_M; real TAU_H; real TAU_J; real axr1; real bxr1; real axr2; real bxr2; real Xr1_INF; real Xr2_INF; real TAU_Xr1; real TAU_Xr2; real Axs; real Bxs; real Xs_INF; real TAU_Xs; real R_INF; real TAU_R; real S_INF; real TAU_S; real Ad; real Bd; real Cd; real TAU_D; real D_INF; real TAU_F; real F_INF; real FCa_INF; real G_INF; real inverseVcF2=1/(2VcF); real inverseVcF=1./(VcF); real Kupsquare=KupKup; // real BufcKbufc=BufcKbufc; // real Kbufcsquare=KbufcKbufc; // real Kbufc2=2Kbufc; // real BufsrKbufsr=BufsrKbufsr; // const real Kbufsrsquare=KbufsrKbufsr; // const real Kbufsr2=2Kbufsr; const real exptaufca=exp(-dt/taufca); const real exptaug=exp(-dt/taug); real sItot; //Needed to compute currents Ek=RTONF(log((Ko/Ki))); Ena=RTONF(log((Nao/Nai))); Eks=RTONF(log((Ko+pKNaNao)/(Ki+pKNaNai))); Eca=0.5RTONF(log((Cao/Cai))); Ak1=0.1/(1.+exp(0.06(svolt-Ek-200))); Bk1=(3.exp(0.0002(svolt-Ek+100))+ exp(0.1(svolt-Ek-10)))/(1.+exp(-0.5(svolt-Ek))); rec_iK1=Ak1/(Ak1+Bk1); rec_iNaK=(1./(1.+0.1245exp(-0.1svoltF/(RT))+0.0353exp(-svoltF/(RT)))); rec_ipK=1./(1.+exp((25-svolt)/5.98)); //Compute currents INa=GNasmsmsmshsj(svolt-Ena); ICaL=GCaLsdsfsfca4svolt(FF/(RT)) (exp(2svoltF/(RT))Cai-0.341Cao)/(exp(2svoltF/(RT))-1.); Ito=Gtosrss(svolt-Ek); IKr=Gkrsqrt(Ko/5.4)sxr1sxr2(svolt-Ek); IKs=Gkssxssxs(svolt-Eks); IK1=GK1rec_iK1(svolt-Ek); INaCa=knaca(1./(KmNaiKmNaiKmNai+NaoNaoNao))(1./(KmCa+Cao))* (1./(1+ksatexp((n-1)svoltF/(RT))))* (exp(nsvoltF/(RT))NaiNaiNaiCao- exp((n-1)svoltF/(RT))NaoNaoNaoCai2.5); INaK=knak(Ko/(Ko+KmK))(Nai/(Nai+KmNa))rec_iNaK; IpCa=GpCaCai/(KpCa+Cai); IpK=GpKrec_ipK(svolt-Ek); IbNa=GbNa(svolt-Ena); IbCa=GbCa(svolt-Eca); //Determine total current (sItot) = IKr + IKs + IK1 + Ito + INa + IbNa + ICaL + IbCa + INaK + INaCa + IpCa + IpK + stim_current; //update concentrations Caisquare=CaiCai; CaSRsquare=CaSRCaSR; CaCurrent=-(ICaL+IbCa+IpCa-2.0fINaCa)inverseVcF2CAPACITANCE; A=0.016464fCaSRsquare/(0.0625f+CaSRsquare)+0.008232f; Irel=Asdsg; Ileak=0.00008f(CaSR-Cai); SERCA=Vmaxup/(1.f+(Kupsquare/Caisquare)); CaSRCurrent=SERCA-Irel-Ileak; CaCSQN=BufsrCaSR/(CaSR+Kbufsr); dCaSR=dt(Vc/Vsr)CaSRCurrent; bjsr=Bufsr-CaCSQN-dCaSR-CaSR+Kbufsr; cjsr=Kbufsr(CaCSQN+dCaSR+CaSR); CaSR=(sqrt(bjsrbjsr+4.cjsr)-bjsr)/2.; CaBuf=BufcCai/(Cai+Kbufc); dCai=dt(CaCurrent-CaSRCurrent); bc=Bufc-CaBuf-dCai-Cai+Kbufc; cc=Kbufc(CaBuf+dCai+Cai); Cai=(sqrt(bcbc+4cc)-bc)/2; dNai=-(INa+IbNa+3INaK+3INaCa)inverseVcFCAPACITANCE; Nai+=dtdNai; dKi=-(stim_current+IK1+Ito+IKr+IKs-2INaK+IpK)inverseVcFCAPACITANCE; Ki+=dtdKi; //compute steady state values and time constants AM=1./(1.+exp((-60.-svolt)/5.)); BM=0.1/(1.+exp((svolt+35.)/5.))+0.10/(1.+exp((svolt-50.)/200.)); TAU_M=AMBM; M_INF=1./((1.+exp((-56.86-svolt)/9.03))(1.+exp((-56.86-svolt)/9.03))); if (svolt>=-40.) { AH_1=0.; BH_1=(0.77/(0.13(1.+exp(-(svolt+10.66)/11.1)))); TAU_H= 1.0/(AH_1+BH_1); } else { AH_2=(0.057exp(-(svolt+80.)/6.8)); BH_2=(2.7exp(0.079svolt)+(3.1e5)exp(0.3485svolt)); TAU_H=1.0/(AH_2+BH_2); } H_INF=1./((1.+exp((svolt+71.55)/7.43))(1.+exp((svolt+71.55)/7.43))); if(svolt>=-40.) { AJ_1=0.; BJ_1=(0.6exp((0.057)svolt)/(1.+exp(-0.1(svolt+32.)))); TAU_J= 1.0/(AJ_1+BJ_1); } else { AJ_2=(((-2.5428e4)exp(0.2444svolt)-(6.948e-6)* exp(-0.04391svolt))(svolt+37.78)/ (1.+exp(0.311(svolt+79.23)))); BJ_2=(0.02424exp(-0.01052svolt)/(1.+exp(-0.1378(svolt+40.14)))); TAU_J= 1.0/(AJ_2+BJ_2); } J_INF=H_INF; Xr1_INF=1./(1.+exp((-26.-svolt)/7.)); axr1=450./(1.+exp((-45.-svolt)/10.)); bxr1=6./(1.+exp((svolt-(-30.))/11.5)); TAU_Xr1=axr1bxr1; Xr2_INF=1./(1.+exp((svolt-(-88.))/24.)); axr2=3./(1.+exp((-60.-svolt)/20.)); bxr2=1.12/(1.+exp((svolt-60.)/20.)); TAU_Xr2=axr2bxr2; Xs_INF=1./(1.+exp((-5.-svolt)/14.)); Axs=1100./(sqrt(1.+exp((-10.-svolt)/6))); Bxs=1./(1.+exp((svolt-60.)/20.)); TAU_Xs=AxsBxs; // [!] Myocardium cell R_INF=1./(1.+exp((20-svolt)/6.)); S_INF=1./(1.+exp((svolt+20)/5.)); TAU_R=9.5exp(-(svolt+40.)(svolt+40.)/1800.)+0.8; TAU_S=85.exp(-(svolt+45.)(svolt+45.)/320.)+5./(1.+exp((svolt-20.)/5.))+3.; D_INF=1./(1.+exp((-5-svolt)/7.5)); Ad=1.4/(1.+exp((-35-svolt)/13))+0.25; Bd=1.4/(1.+exp((svolt+5)/5)); Cd=1./(1.+exp((50-svolt)/20)); TAU_D=AdBd+Cd; F_INF=1./(1.+exp((svolt+20)/7)); //TAU_F=1125exp(-(svolt+27)(svolt+27)/300)+80+165/(1.+exp((25-svolt)/10)); TAU_F=1125exp(-(svolt+27)(svolt+27)/240)+80+165/(1.+exp((25-svolt)/10)); // Updated from CellML FCa_INF=(1./(1.+pow((Cai/0.000325),8))+ 0.1/(1.+exp((Cai-0.0005)/0.0001))+ 0.20/(1.+exp((Cai-0.00075)/0.0008))+ 0.23 )/1.46; if(Cai<0.00035) G_INF=1./(1.+pow((Cai/0.00035),6)); else G_INF=1./(1.+pow((Cai/0.00035),16)); //Update gates rDY_[1] = M_INF-(M_INF-sm)exp(-dt/TAU_M); rDY_[2] = H_INF-(H_INF-sh)exp(-dt/TAU_H); rDY_[3] = J_INF-(J_INF-sj)exp(-dt/TAU_J); rDY_[4] = Xr1_INF-(Xr1_INF-sxr1)exp(-dt/TAU_Xr1); rDY_[5] = Xr2_INF-(Xr2_INF-sxr2)exp(-dt/TAU_Xr2); rDY_[6] = Xs_INF-(Xs_INF-sxs)exp(-dt/TAU_Xs); rDY_[7] = S_INF-(S_INF-ss)exp(-dt/TAU_S); rDY_[8] = R_INF-(R_INF-sr)exp(-dt/TAU_R); rDY_[9] = D_INF-(D_INF-sd)exp(-dt/TAU_D); rDY_[10] = F_INF-(F_INF-sf)exp(-dt/TAU_F); fcaold= sfca; sfca = FCa_INF-(FCa_INF-sfca)exptaufca; if(sfca>fcaold && (svolt)>-37.0) sfca = fcaold; gold = sg; sg = G_INF-(G_INF-sg)exptaug; if(sg>gold && (svolt)>-37.0) sg=gold; //update voltage rDY_[0] = svolt + dt(-sItot); rDY_[11] = sfca; rDY_[12] = sg; rDY_[13] = Cai; rDY_[14] = CaSR; rDY_[15] = Nai; rDY_[16] = Ki; } void solve_model_ode_cpu_epi (real dt, real sv, real stim_current) { real rY[NEQ], rDY[NEQ]; for(int i = 0; i < NEQ; i++) rY[i] = sv[i]; RHS_cpu_epi(rY, rDY, stim_current, dt); for(int i = 0; i < NEQ; i++) sv[i] = rDY[i]; } void RHS_cpu_epi(const real sv, real rDY_, real stim_current, real dt) { // State variables real svolt = sv[0]; real sm = sv[1]; real sh = sv[2]; real sj = sv[3]; real sxr1 = sv[4]; real sxr2 = sv[5]; real sxs = sv[6]; real ss = sv[7]; real sr = sv[8]; real sd = sv[9]; real sf = sv[10]; real sfca = sv[11]; real sg = sv[12]; real Cai = sv[13]; real CaSR = sv[14]; real Nai = sv[15]; real Ki = sv[16]; //External concentrations real Ko=5.4; real Cao=2.0; real Nao=140.0; //Intracellular volumes real Vc=0.016404; real Vsr=0.001094; //Calcium dynamics real Bufc=0.15f; real Kbufc=0.001f; real Bufsr=10.f; real Kbufsr=0.3f; real taufca=2.f; real taug=2.f; real Vmaxup=0.000425f; real Kup=0.00025f; //Constants const real R = 8314.472f; const real F = 96485.3415f; const real T =310.0f; real RTONF =(RT)/F; //Cellular capacitance real CAPACITANCE=0.185; //Parameters for currents //Parameters for IKr real Gkr=0.096; //Parameters for Iks real pKNa=0.03; // [!] Epicardium cell real Gks=0.245; //Parameters for Ik1 real GK1=5.405; //Parameters for Ito // [!] Epicardium cell real Gto=0.294; //Parameters for INa real GNa=14.838; //Parameters for IbNa real GbNa=0.00029; //Parameters for INaK real KmK=1.0; real KmNa=40.0; real knak=1.362; //Parameters for ICaL real GCaL=0.000175; //Parameters for IbCa real GbCa=0.000592; //Parameters for INaCa real knaca=1000; real KmNai=87.5; real KmCa=1.38; real ksat=0.1; real n=0.35; //Parameters for IpCa real GpCa=0.825; real KpCa=0.0005; //Parameters for IpK; real GpK=0.0146; real parameters []={13.8994716023310,0.000314898731878021,0.000156213524980972,0.000500074781915997,0.266864980659979,0.210551078794501,0.0657802089893208,2.85046969353601,0.0146506603832578,2.33945156719839,1099.72957852790,0.000431840298681176,0.479647775253583,0.0184750516443378,0.00580287376612870,1.67786611618970e-05}; GNa=parameters[0]; GbNa=parameters[1]; GCaL=parameters[2]; GbCa=parameters[3]; Gto=parameters[4]; Gkr=parameters[5]; Gks=parameters[6]; GK1=parameters[7]; GpK=parameters[8]; knak=parameters[9]; knaca=parameters[10]; Vmaxup=parameters[11]; GpCa=parameters[12]; real arel=parameters[13]; real crel=parameters[14]; real Vleak=parameters[15]; real IKr; real IKs; real IK1; real Ito; real INa; real IbNa; real ICaL; real IbCa; real INaCa; real IpCa; real IpK; real INaK; real Irel; real Ileak; real dNai; real dKi; real dCai; real dCaSR; real A; // real BufferFactorc; // real BufferFactorsr; real SERCA; real Caisquare; real CaSRsquare; real CaCurrent; real CaSRCurrent; real fcaold; real gold; real Ek; real Ena; real Eks; real Eca; real CaCSQN; real bjsr; real cjsr; real CaBuf; real bc; real cc; real Ak1; real Bk1; real rec_iK1; real rec_ipK; real rec_iNaK; real AM; real BM; real AH_1; real BH_1; real AH_2; real BH_2; real AJ_1; real BJ_1; real AJ_2; real BJ_2; real M_INF; real H_INF; real J_INF; real TAU_M; real TAU_H; real TAU_J; real axr1; real bxr1; real axr2; real bxr2; real Xr1_INF; real Xr2_INF; real TAU_Xr1; real TAU_Xr2; real Axs; real Bxs; real Xs_INF; real TAU_Xs; real R_INF; real TAU_R; real S_INF; real TAU_S; real Ad; real Bd; real Cd; real TAU_D; real D_INF; real TAU_F; real F_INF; real FCa_INF; real G_INF; real inverseVcF2=1/(2VcF); real inverseVcF=1./(VcF); real Kupsquare=KupKup; // real BufcKbufc=BufcKbufc; // real Kbufcsquare=KbufcKbufc; // real Kbufc2=2Kbufc; // real BufsrKbufsr=BufsrKbufsr; // const real Kbufsrsquare=KbufsrKbufsr; // const real Kbufsr2=2Kbufsr; const real exptaufca=exp(-dt/taufca); const real exptaug=exp(-dt/taug); real sItot; //Needed to compute currents Ek=RTONF(log((Ko/Ki))); Ena=RTONF(log((Nao/Nai))); Eks=RTONF(log((Ko+pKNaNao)/(Ki+pKNaNai))); Eca=0.5RTONF(log((Cao/Cai))); Ak1=0.1/(1.+exp(0.06(svolt-Ek-200))); Bk1=(3.exp(0.0002(svolt-Ek+100))+ exp(0.1(svolt-Ek-10)))/(1.+exp(-0.5(svolt-Ek))); rec_iK1=Ak1/(Ak1+Bk1); rec_iNaK=(1./(1.+0.1245exp(-0.1svoltF/(RT))+0.0353exp(-svoltF/(RT)))); rec_ipK=1./(1.+exp((25-svolt)/5.98)); //Compute currents INa=GNasmsmsmshsj(svolt-Ena); ICaL=GCaLsdsfsfca4svolt(FF/(RT))* (exp(2svoltF/(RT))Cai-0.341Cao)/(exp(2svoltF/(RT))-1.); Ito=Gtosrss(svolt-Ek); IKr=Gkrsqrt(Ko/5.4)sxr1sxr2(svolt-Ek); IKs=Gkssxssxs(svolt-Eks); IK1=GK1rec_iK1(svolt-Ek); INaCa=knaca(1./(KmNaiKmNaiKmNai+NaoNaoNao))(1./(KmCa+Cao))* (1./(1+ksatexp((n-1)svoltF/(RT))))* (exp(nsvoltF/(RT))NaiNaiNaiCao- exp((n-1)svoltF/(RT))NaoNaoNaoCai2.5); INaK=knak(Ko/(Ko+KmK))(Nai/(Nai+KmNa))rec_iNaK; IpCa=GpCaCai/(KpCa+Cai); IpK=GpKrec_ipK(svolt-Ek); IbNa=GbNa(svolt-Ena); IbCa=GbCa(svolt-Eca); //Determine total current (sItot) = IKr + IKs + IK1 + Ito + INa + IbNa + ICaL + IbCa + INaK + INaCa + IpCa + IpK + stim_current; //update concentrations Caisquare=CaiCai; CaSRsquare=CaSRCaSR; CaCurrent=-(ICaL+IbCa+IpCa-2.0fINaCa)inverseVcF2CAPACITANCE; A=arelCaSRsquare/(0.0625f+CaSRsquare)+crel; Irel=Asdsg; Ileak=Vleak(CaSR-Cai); SERCA=Vmaxup/(1.f+(Kupsquare/Caisquare)); CaSRCurrent=SERCA-Irel-Ileak; CaCSQN=BufsrCaSR/(CaSR+Kbufsr); dCaSR=dt(Vc/Vsr)CaSRCurrent; bjsr=Bufsr-CaCSQN-dCaSR-CaSR+Kbufsr; cjsr=Kbufsr(CaCSQN+dCaSR+CaSR); CaSR=(sqrt(bjsrbjsr+4.cjsr)-bjsr)/2.; CaBuf=BufcCai/(Cai+Kbufc); dCai=dt(CaCurrent-CaSRCurrent); bc=Bufc-CaBuf-dCai-Cai+Kbufc; cc=Kbufc(CaBuf+dCai+Cai); Cai=(sqrt(bcbc+4cc)-bc)/2; dNai=-(INa+IbNa+3INaK+3INaCa)inverseVcFCAPACITANCE; Nai+=dtdNai; dKi=-(stim_current+IK1+Ito+IKr+IKs-2INaK+IpK)inverseVcFCAPACITANCE; Ki+=dtdKi; //compute steady state values and time constants AM=1./(1.+exp((-60.-svolt)/5.)); BM=0.1/(1.+exp((svolt+35.)/5.))+0.10/(1.+exp((svolt-50.)/200.)); TAU_M=AMBM; M_INF=1./((1.+exp((-56.86-svolt)/9.03))(1.+exp((-56.86-svolt)/9.03))); if (svolt>=-40.) { AH_1=0.; BH_1=(0.77/(0.13(1.+exp(-(svolt+10.66)/11.1)))); TAU_H= 1.0/(AH_1+BH_1); } else { AH_2=(0.057exp(-(svolt+80.)/6.8)); BH_2=(2.7exp(0.079svolt)+(3.1e5)exp(0.3485svolt)); TAU_H=1.0/(AH_2+BH_2); } H_INF=1./((1.+exp((svolt+71.55)/7.43))(1.+exp((svolt+71.55)/7.43))); if(svolt>=-40.) { AJ_1=0.; BJ_1=(0.6exp((0.057)svolt)/(1.+exp(-0.1(svolt+32.)))); TAU_J= 1.0/(AJ_1+BJ_1); } else { AJ_2=(((-2.5428e4)exp(0.2444svolt)-(6.948e-6)* exp(-0.04391svolt))(svolt+37.78)/ (1.+exp(0.311(svolt+79.23)))); BJ_2=(0.02424exp(-0.01052svolt)/(1.+exp(-0.1378(svolt+40.14)))); TAU_J= 1.0/(AJ_2+BJ_2); } J_INF=H_INF; Xr1_INF=1./(1.+exp((-26.-svolt)/7.)); axr1=450./(1.+exp((-45.-svolt)/10.)); bxr1=6./(1.+exp((svolt-(-30.))/11.5)); TAU_Xr1=axr1bxr1; Xr2_INF=1./(1.+exp((svolt-(-88.))/24.)); axr2=3./(1.+exp((-60.-svolt)/20.)); bxr2=1.12/(1.+exp((svolt-60.)/20.)); TAU_Xr2=axr2bxr2; Xs_INF=1./(1.+exp((-5.-svolt)/14.)); Axs=1100./(sqrt(1.+exp((-10.-svolt)/6))); Bxs=1./(1.+exp((svolt-60.)/20.)); TAU_Xs=AxsBxs; R_INF=1./(1.+exp((20-svolt)/6.)); S_INF=1./(1.+exp((svolt+20)/5.)); TAU_R=9.5exp(-(svolt+40.)(svolt+40.)/1800.)+0.8; TAU_S=85.exp(-(svolt+45.)(svolt+45.)/320.)+5./(1.+exp((svolt-20.)/5.))+3.; D_INF=1./(1.+exp((-5-svolt)/7.5)); Ad=1.4/(1.+exp((-35-svolt)/13))+0.25; Bd=1.4/(1.+exp((svolt+5)/5)); Cd=1./(1.+exp((50-svolt)/20)); TAU_D=AdBd+Cd; F_INF=1./(1.+exp((svolt+20)/7)); //TAU_F=1125exp(-(svolt+27)(svolt+27)/300)+80+165/(1.+exp((25-svolt)/10)); TAU_F=1125exp(-(svolt+27)(svolt+27)/240)+80+165/(1.+exp((25-svolt)/10)); // Updated from CellML FCa_INF=(1./(1.+pow((Cai/0.000325),8))+ 0.1/(1.+exp((Cai-0.0005)/0.0001))+ 0.20/(1.+exp((Cai-0.00075)/0.0008))+ 0.23 )/1.46; if(Cai<0.00035) G_INF=1./(1.+pow((Cai/0.00035),6)); else G_INF=1./(1.+pow((Cai/0.00035),16)); //Update gates rDY_[1] = M_INF-(M_INF-sm)exp(-dt/TAU_M); rDY_[2] = H_INF-(H_INF-sh)exp(-dt/TAU_H); rDY_[3] = J_INF-(J_INF-sj)exp(-dt/TAU_J); rDY_[4] = Xr1_INF-(Xr1_INF-sxr1)exp(-dt/TAU_Xr1); rDY_[5] = Xr2_INF-(Xr2_INF-sxr2)exp(-dt/TAU_Xr2); rDY_[6] = Xs_INF-(Xs_INF-sxs)exp(-dt/TAU_Xs); rDY_[7] = S_INF-(S_INF-ss)exp(-dt/TAU_S); rDY_[8] = R_INF-(R_INF-sr)exp(-dt/TAU_R); rDY_[9] = D_INF-(D_INF-sd)exp(-dt/TAU_D); rDY_[10] = F_INF-(F_INF-sf)exp(-dt/TAU_F); fcaold= sfca; sfca = FCa_INF-(FCa_INF-sfca)exptaufca; if(sfca>fcaold && (svolt)>-37.0) sfca = fcaold; gold = sg; sg = G_INF-(G_INF-sg)exptaug; if(sg>gold && (svolt)>-37.0) sg=gold; //update voltage rDY_[0] = svolt + dt*(-sItot); rDY_[11] = sfca; rDY_[12] = sg; rDY_[13] = Cai; rDY_[14] = CaSR; rDY_[15] = Nai; rDY_[16] = Ki; }
private.c	#include "private.h" static timer linsysTimer; static pfloat totalSolveTime; char * getLinSysMethod(Data * d, Priv * p) { char * tmp = scs_malloc(sizeof(char) * 64); sprintf(tmp, "sparse-direct, nnz in A = %li", (long) d->A->p[d->n]); return tmp; } char * getLinSysSummary(Priv * p, Info * info) { char * str = scs_malloc(sizeof(char) * 64); idxint n = p->L->n; sprintf(str, "\tLin-sys: nnz in L factor: %li, avg solve time: %1.2es\n", (long ) (p->L->p[n] + n), totalSolveTime / (info->iter + 1) / 1e3); totalSolveTime = 0; return str; } void freePriv(Priv * p) { if (p) { if (p->L) cs_spfree(p->L); if (p->P) scs_free(p->P); if (p->D) scs_free(p->D); if (p->bp) scs_free(p->bp); scs_free(p); } } cs * formKKT(Data * d) { /* ONLY UPPER TRIANGULAR PART IS STUFFED * forms column compressed KKT matrix * assumes column compressed form A matrix * * forms upper triangular part of [I A'; A -I] / idxint j, k, kk; cs K_cs; AMatrix * A = d->A; /* I at top left / const idxint Anz = A->p[d->n]; const idxint Knzmax = d->n + d->m + Anz; cs K = cs_spalloc(d->m + d->n, d->m + d->n, Knzmax, 1, 1); #ifdef EXTRAVERBOSE scs_printf("forming KKT\n"); #endif if (!K) { return NULL; } kk = 0; for (k = 0; k < d->n; k++) { K->i[kk] = k; K->p[kk] = k; K->x[kk] = d->RHO_X; kk++; } /* A^T at top right : CCS: / for (j = 0; j < d->n; j++) { for (k = A->p[j]; k < A->p[j + 1]; k++) { K->p[kk] = A->i[k] + d->n; K->i[kk] = j; K->x[kk] = A->x[k]; kk++; } } / -I at bottom right / for (k = 0; k < d->m; k++) { K->i[kk] = k + d->n; K->p[kk] = k + d->n; K->x[kk] = -1; kk++; } / assert kk == Knzmax / K->nz = Knzmax; K_cs = cs_compress(K); cs_spfree(K); return (K_cs); } idxint LDLInit(cs A, idxint P[], pfloat *info) { info = (pfloat ) scs_malloc(AMD_INFO sizeof(pfloat)); #ifdef DLONG return(amd_l_order(A->n, A->p, A->i, P, (pfloat ) NULL, info)); #else return (amd_order(A->n, A->p, A->i, P, (pfloat ) NULL, info)); #endif } idxint LDLFactor(cs * A, idxint P[], idxint Pinv[], cs L, pfloat D) { idxint kk, n = A->n; idxint * Parent = scs_malloc(n * sizeof(idxint)); idxint * Lnz = scs_malloc(n * sizeof(idxint)); idxint * Flag = scs_malloc(n * sizeof(idxint)); idxint * Pattern = scs_malloc(n * sizeof(idxint)); pfloat * Y = scs_malloc(n * sizeof(pfloat)); (L)->p = (idxint ) scs_malloc((1 + n) * sizeof(idxint)); /idxint Parent[n], Lnz[n], Flag[n], Pattern[n]; / /pfloat Y[n]; / LDL_symbolic(n, A->p, A->i, (L)->p, Parent, Lnz, Flag, P, Pinv); (L)->nzmax = ((L)->p + n); (L)->x = (pfloat ) scs_malloc((L)->nzmax sizeof(pfloat)); (L)->i = (idxint ) scs_malloc((L)->nzmax sizeof(idxint)); D = (pfloat ) scs_malloc(n * sizeof(pfloat)); if (!(D) \|\| !(L)->i \|\| !(L)->x \|\| !Y \|\| !Pattern \|\| !Flag \|\| !Lnz \|\| !Parent) return -1; #ifdef EXTRAVERBOSE scs_printf("numeric factorization\n"); #endif kk = LDL_numeric(n, A->p, A->i, A->x, (L)->p, Parent, Lnz, (L)->i, (L)->x, D, Y, Pattern, Flag, P, Pinv); #ifdef EXTRAVERBOSE scs_printf("finished numeric factorization\n"); #endif scs_free(Parent); scs_free(Lnz); scs_free(Flag); scs_free(Pattern); scs_free(Y); return (n - kk); } void LDLSolve(pfloat x, pfloat b[], cs * L, pfloat D[], idxint P[], pfloat * bp) { /* solves PLDL'P' x = b for x / idxint n = L->n; if (P == NULL) { if (x != b) / if they're different addresses / memcpy(x, b, n sizeof(pfloat)); LDL_lsolve(n, x, L->p, L->i, L->x); LDL_dsolve(n, x, D); LDL_ltsolve(n, x, L->p, L->i, L->x); } else { LDL_perm(n, bp, b, P); LDL_lsolve(n, bp, L->p, L->i, L->x); LDL_dsolve(n, bp, D); LDL_ltsolve(n, bp, L->p, L->i, L->x); LDL_permt(n, x, bp, P); } } void _accumByAtrans(idxint n, pfloat * Ax, idxint * Ai, idxint * Ap, const pfloat x, pfloat y) { /* y = A'x A in column compressed format parallelizes over columns (rows of A') / idxint p, j; idxint c1, c2; pfloat yj; #ifdef OPENMP #pragma omp parallel for private(p,c1,c2,yj) #endif for (j = 0; j < n; j++) { yj = y[j]; c1 = Ap[j]; c2 = Ap[j + 1]; for (p = c1; p < c2; p++) { yj += Ax[p] * x[Ai[p]]; } y[j] = yj; } } void _accumByA(idxint n, pfloat * Ax, idxint * Ai, idxint * Ap, const pfloat x, pfloat y) { /y = Ax A in column compressed format this parallelizes over columns and uses pragma atomic to prevent concurrent writes to y / idxint p, j; idxint c1, c2; pfloat xj; /#pragma omp parallel for private(p,c1,c2,xj) / for (j = 0; j < n; j++) { xj = x[j]; c1 = Ap[j]; c2 = Ap[j + 1]; for (p = c1; p < c2; p++) { /#pragma omp atomic / y[Ai[p]] += Ax[p] xj; } } } void accumByAtrans(Data * d, Priv * p, const pfloat x, pfloat y) { AMatrix * A = d->A; _accumByAtrans(d->n, A->x, A->i, A->p, x, y); } void accumByA(Data * d, Priv * p, const pfloat x, pfloat y) { AMatrix * A = d->A; _accumByA(d->n, A->x, A->i, A->p, x, y); } idxint factorize(Data * d, Priv * p) { pfloat info; idxint Pinv, amd_status, ldl_status; cs C, K = formKKT(d); if (!K) { return -1; } amd_status = LDLInit(K, p->P, &info); if (amd_status < 0) return (amd_status); #ifdef EXTRAVERBOSE if(d->VERBOSE) { scs_printf("Matrix factorization info:\n"); #ifdef DLONG amd_l_info(info); #else amd_info(info); #endif } #endif Pinv = cs_pinv(p->P, d->n + d->m); C = cs_symperm(K, Pinv, 1); ldl_status = LDLFactor(C, NULL, NULL, &p->L, &p->D); cs_spfree(C); cs_spfree(K); scs_free(Pinv); scs_free(info); return (ldl_status); } Priv * initPriv(Data * d) { Priv * p = scs_calloc(1, sizeof(Priv)); idxint n_plus_m = d->n + d->m; p->P = scs_malloc(sizeof(idxint) * n_plus_m); p->L = scs_malloc(sizeof(cs)); p->bp = scs_malloc(n_plus_m * sizeof(pfloat)); p->L->m = n_plus_m; p->L->n = n_plus_m; p->L->nz = -1; if (factorize(d, p) < 0) { freePriv(p); return NULL; } totalSolveTime = 0.0; return p; } idxint solveLinSys(Data * d, Priv * p, pfloat * b, const pfloat * s, idxint iter) { /* returns solution to linear system / / Ax = b with solution stored in b */ tic(&linsysTimer); LDLSolve(b, b, p->L, p->D, p->P, p->bp); totalSolveTime += tocq(&linsysTimer); #ifdef EXTRAVERBOSE scs_printf("linsys solve time: %1.2es\n", tocq(&linsysTimer) / 1e3); #endif return 0; }
task_late_fulfill.c	// RUN: %libomp-compile -fopenmp-version=50 && env OMP_NUM_THREADS='3' \ // RUN: %libomp-run \| %sort-threads \| FileCheck %s // REQUIRES: ompt // Checked gcc 10.1 still does not support detach clause on task construct. // UNSUPPORTED: gcc-4, gcc-5, gcc-6, gcc-7, gcc-8, gcc-9, gcc-10 // clang supports detach clause since version 11. // UNSUPPORTED: clang-10, clang-9, clang-8, clang-7 // icc compiler does not support detach clause. // UNSUPPORTED: icc #include "callback.h" #include <omp.h> int main() { #pragma omp parallel #pragma omp master { omp_event_handle_t event; omp_event_handle_t f_event; #pragma omp task detach(event) depend(out : f_event) shared(f_event) if (0) { printf("task 1\n"); f_event = &event; } #pragma omp task depend(in : f_event) { printf("task 2\n"); } printf("calling omp_fulfill_event\n"); omp_fulfill_event(f_event); #pragma omp taskwait } return 0; } // Check if libomp supports the callbacks for this test. // CHECK-NOT: {{^}}0: Could not register callback 'ompt_callback_task_create' // CHECK-NOT: {{^}}0: Could not register callback 'ompt_callback_task_schedule' // CHECK-NOT: {{^}}0: Could not register callback 'ompt_callback_parallel_begin' // CHECK-NOT: {{^}}0: Could not register callback 'ompt_callback_parallel_end' // CHECK-NOT: {{^}}0: Could not register callback 'ompt_callback_implicit_task' // CHECK-NOT: {{^}}0: Could not register callback 'ompt_callback_mutex_acquire' // CHECK-NOT: {{^}}0: Could not register callback 'ompt_callback_mutex_acquired' // CHECK-NOT: {{^}}0: Could not register callback 'ompt_callback_mutex_released' // CHECK: {{^}}0: NULL_POINTER=[[NULL:.*$]] // CHECK: {{^}}[[MASTER_ID:[0-9]+]]: ompt_event_parallel_begin: // CHECK-SAME: parent_task_id=[[PARENT_TASK_ID:[0-9]+]], // CHECK-SAME: parent_task_frame.exit=[[NULL]], // CHECK-SAME: parent_task_frame.reenter=0x{{[0-f]+}}, // CHECK-SAME: parallel_id=[[PARALLEL_ID:[0-9]+]], // CHECK-SAME: requested_team_size=3, // CHECK: {{^}}[[MASTER_ID]]: ompt_event_implicit_task_begin: // CHECK-SAME: parallel_id=[[PARALLEL_ID]], // CHECK-SAME: task_id=[[IMPLICIT_TASK_ID:[0-9]+]] // The following is to match the taskwait task created in __kmpc_omp_wait_deps // this should go away, once codegen for "detached if(0)" is fixed // CHECK: {{^}}[[MASTER_ID]]: ompt_event_task_create: // CHECK-SAME: parent_task_id=[[IMPLICIT_TASK_ID]], // CHECK-SAME: has_dependences=yes // CHECK: {{^}}[[MASTER_ID]]: ompt_event_task_create: // CHECK-SAME: parent_task_id=[[IMPLICIT_TASK_ID]], // CHECK-SAME: parent_task_frame.exit=0x{{[0-f]+}}, // CHECK-SAME: parent_task_frame.reenter=0x{{[0-f]+}}, // CHECK-SAME: new_task_id=[[TASK_ID:[0-9]+]], // CHECK: {{^}}[[MASTER_ID:[0-9]+]]: ompt_event_task_schedule: // CHECK-SAME: first_task_id=[[IMPLICIT_TASK_ID]], // CHECK-SAME: second_task_id=[[TASK_ID]], // CHECK-SAME: prior_task_status=ompt_task_switch=7 // CHECK: {{^}}[[MASTER_ID:[0-9]+]]: ompt_event_task_schedule: // CHECK-SAME: first_task_id=[[TASK_ID]], // CHECK-SAME: second_task_id=[[IMPLICIT_TASK_ID]], // CHECK-SAME: prior_task_status=ompt_task_detach=4 // CHECK: {{^}}[[MASTER_ID:[0-9]+]]: ompt_event_task_schedule: // CHECK-SAME: first_task_id=[[TASK_ID]], // CHECK-SAME: second_task_id=18446744073709551615, // CHECK-SAME: prior_task_status=ompt_task_late_fulfill=6

threshold.c

/* Copyright 2014. The Regents of the University of California. * Copyright 2015-2017. Martin Uecker. * All rights reserved. Use of this source code is governed by * a BSD-style license which can be found in the LICENSE file. * * Authors: * 2013-2017 Martin Uecker <martin.uecker@med.uni-goettingen.de> * 2015-2016 Jon Tamir <jtamir@eecs.berkeley.edu> * 2015 Frank Ong <frankong@berkeley.edu> */ #include <stdbool.h> #include <complex.h> #include "num/flpmath.h" #include "num/multind.h" #include "num/init.h" #include "num/ops_p.h" #include "iter/prox.h" #include "iter/thresh.h" #include "misc/mmio.h" #include "misc/misc.h" #include "misc/debug.h" #include "misc/opts.h" #include "lowrank/lrthresh.h" #include "linops/waveop.h" #include "dfwavelet/prox_dfwavelet.h" // FIXME: lowrank interface should not be coupled to mri.h -- it should take D as an input #ifndef DIMS #define DIMS 16 #endif // FIXME: consider moving this to a more accessible location? static void wthresh(unsigned int D, const long dims[D], float lambda, unsigned int flags, complex float* out, const complex float* in) { long minsize[D]; md_singleton_dims(D, minsize); long course_scale[3] = MD_INIT_ARRAY(3, 16); md_copy_dims(3, minsize, course_scale); unsigned int wflags = 7; // FIXME for (unsigned int i = 0; i < 3; i++) if (dims[i] < minsize[i]) wflags = MD_CLEAR(wflags, i); long strs[D]; md_calc_strides(D, strs, dims, CFL_SIZE); const struct linop_s* w = linop_wavelet_create(D, wflags, dims, strs, minsize, false); const struct operator_p_s* p = prox_unithresh_create(D, w, lambda, flags); operator_p_apply(p, 1., D, dims, out, D, dims, in); operator_p_free(p); } static void lrthresh(unsigned int D, const long dims[D], int llrblk, float lambda, unsigned int flags, complex float* out, const complex float* in) { long blkdims[MAX_LEV][D]; int levels = llr_blkdims(blkdims, ~flags, dims, llrblk); UNUSED(levels); const struct operator_p_s* p = lrthresh_create(dims, false, ~flags, (const long (*)[])blkdims, lambda, false, false, false); operator_p_apply(p, 1., D, dims, out, D, dims, in); operator_p_free(p); } static void dfthresh(unsigned int D, const long dims[D], float lambda, complex float* out, const complex float* in) { long minsize[3]; md_singleton_dims(3, minsize); long coarse_scale[3] = MD_INIT_ARRAY(3, 16); md_min_dims(3, ~0u, minsize, dims, coarse_scale); complex float res[3]; res[0] = 1.; res[1] = 1.; res[2] = 1.; assert(3 == dims[TE_DIM]); const struct operator_p_s* p = prox_dfwavelet_create(dims, minsize, res, TE_DIM, lambda, false); operator_p_apply(p, 1., D, dims, out, D, dims, in); operator_p_free(p); } static void hard_thresh(unsigned int D, const long dims[D], float lambda, complex float* out, const complex float* in) { long size = md_calc_size(DIMS, dims); #pragma omp parallel for for (long i = 0; i < size; i++) out[i] = (cabsf(in[i]) > lambda) ? in[i] : 0.; } static void binary_thresh(unsigned int D, const long dims[D], float lambda, complex float* out, const complex float* in) { long size = md_calc_size(DIMS, dims); #pragma omp parallel for for (long i = 0; i < size; i++) out[i] = (cabsf(in[i]) > lambda) ? 1. : 0.; } static const char help_str[] = "Perform (soft) thresholding with parameter lambda."; int main_threshold(int argc, char* argv[argc]) { float lambda = 0.; const char* in_file = NULL; const char* out_file = NULL; struct arg_s args[] = { ARG_FLOAT(true, &lambda, "lambda"), ARG_INFILE(true, &in_file, "input"), ARG_OUTFILE(true, &out_file, "output"), }; unsigned int flags = 0; enum th_type { NONE, WAV, LLR, DFW, MPDFW, HARD, BINARY } th_type = NONE; int llrblk = 8; const struct opt_s opts[] = { OPT_SELECT('H', enum th_type, &th_type, HARD, "hard thresholding"), OPT_SELECT('W', enum th_type, &th_type, WAV, "daubechies wavelet soft-thresholding"), OPT_SELECT('L', enum th_type, &th_type, LLR, "locally low rank soft-thresholding"), OPT_SELECT('D', enum th_type, &th_type, DFW, "divergence-free wavelet soft-thresholding"), OPT_SELECT('B', enum th_type, &th_type, BINARY, "thresholding with binary output"), OPT_UINT('j', &flags, "bitmask", "joint soft-thresholding"), OPT_INT('b', &llrblk, "blocksize", "locally low rank block size"), }; cmdline(&argc, argv, ARRAY_SIZE(args), args, help_str, ARRAY_SIZE(opts), opts); num_init(); const int N = DIMS; long dims[N]; complex float* idata = load_cfl(in_file, N, dims); complex float* odata = create_cfl(out_file, N, dims); switch (th_type) { case WAV: wthresh(N, dims, lambda, flags, odata, idata); break; case LLR: lrthresh(N, dims, llrblk, lambda, flags, odata, idata); break; case DFW: dfthresh(N, dims, lambda, odata, idata); break; case HARD: hard_thresh(N, dims, lambda, odata, idata); break; case BINARY: binary_thresh(N, dims, lambda, odata, idata); break; default: md_zsoftthresh(N, dims, lambda, flags, odata, idata); } unmap_cfl(N, dims, idata); unmap_cfl(N, dims, odata); return 0; }

TSDFVoxelGridImpl.h

// ---------------------------------------------------------------------------- // - Open3D: www.open3d.org - // ---------------------------------------------------------------------------- // The MIT License (MIT) // // Copyright (c) 2018 www.open3d.org // // Permission is hereby granted, free of charge, to any person obtaining a copy // of this software and associated documentation files (the "Software"), to deal // in the Software without restriction, including without limitation the rights // to use, copy, modify, merge, publish, distribute, sublicense, and/or sell // copies of the Software, and to permit persons to whom the Software is // furnished to do so, subject to the following conditions: // // The above copyright notice and this permission notice shall be included in // all copies or substantial portions of the Software. // // THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR // IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, // FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE // AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER // LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING // FROM, OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS // IN THE SOFTWARE. // ---------------------------------------------------------------------------- #include <atomic> #include <cmath> #include "open3d/core/Dispatch.h" #include "open3d/core/Dtype.h" #include "open3d/core/MemoryManager.h" #include "open3d/core/SizeVector.h" #include "open3d/core/Tensor.h" #include "open3d/t/geometry/Utility.h" #include "open3d/t/geometry/kernel/GeometryIndexer.h" #include "open3d/t/geometry/kernel/GeometryMacros.h" #include "open3d/t/geometry/kernel/TSDFVoxel.h" #include "open3d/t/geometry/kernel/TSDFVoxelGrid.h" #include "open3d/utility/Console.h" #include "open3d/utility/Timer.h" namespace open3d { namespace t { namespace geometry { namespace kernel { namespace tsdf { #if defined(__CUDACC__) void IntegrateCUDA #else void IntegrateCPU #endif (const core::Tensor& depth, const core::Tensor& color, const core::Tensor& indices, const core::Tensor& block_keys, core::Tensor& block_values, // Transforms const core::Tensor& intrinsics, const core::Tensor& extrinsics, // Parameters int64_t resolution, float voxel_size, float sdf_trunc, float depth_scale, float depth_max) { // Parameters int64_t resolution3 = resolution * resolution * resolution; // Shape / transform indexers, no data involved NDArrayIndexer voxel_indexer({resolution, resolution, resolution}); TransformIndexer transform_indexer(intrinsics, extrinsics, voxel_size); // Real data indexer NDArrayIndexer depth_indexer(depth, 2); NDArrayIndexer block_keys_indexer(block_keys, 1); NDArrayIndexer voxel_block_buffer_indexer(block_values, 4); // Optional color integration NDArrayIndexer color_indexer; bool integrate_color = false; if (color.NumElements() != 0) { color_indexer = NDArrayIndexer(color, 2); integrate_color = true; } // Plain arrays that does not require indexers const int64_t* indices_ptr = static_cast<const int64_t*>(indices.GetDataPtr()); int64_t n = indices.GetLength() * resolution3; #if defined(__CUDACC__) core::kernel::CUDALauncher launcher; #else core::kernel::CPULauncher launcher; #endif DISPATCH_BYTESIZE_TO_VOXEL( voxel_block_buffer_indexer.ElementByteSize(), [&]() { launcher.LaunchGeneralKernel(n, [=] OPEN3D_DEVICE( int64_t workload_idx) { // Natural index (0, N) -> (block_idx, voxel_idx) int64_t block_idx = indices_ptr[workload_idx / resolution3]; int64_t voxel_idx = workload_idx % resolution3; /// Coordinate transform // block_idx -> (x_block, y_block, z_block) int* block_key_ptr = block_keys_indexer.GetDataPtrFromCoord<int>( block_idx); int64_t xb = static_cast<int64_t>(block_key_ptr[0]); int64_t yb = static_cast<int64_t>(block_key_ptr[1]); int64_t zb = static_cast<int64_t>(block_key_ptr[2]); // voxel_idx -> (x_voxel, y_voxel, z_voxel) int64_t xv, yv, zv; voxel_indexer.WorkloadToCoord(voxel_idx, &xv, &yv, &zv); // coordinate in world (in voxel) int64_t x = (xb * resolution + xv); int64_t y = (yb * resolution + yv); int64_t z = (zb * resolution + zv); // coordinate in camera (in voxel -> in meter) float xc, yc, zc, u, v; transform_indexer.RigidTransform( static_cast<float>(x), static_cast<float>(y), static_cast<float>(z), &xc, &yc, &zc); // coordinate in image (in pixel) transform_indexer.Project(xc, yc, zc, &u, &v); if (!depth_indexer.InBoundary(u, v)) { return; } // Associate image workload and compute SDF and TSDF. float depth = *depth_indexer.GetDataPtrFromCoord<float>( static_cast<int64_t>(u), static_cast<int64_t>(v)) / depth_scale; float sdf = (depth - zc); if (depth <= 0 || depth > depth_max || zc <= 0 || sdf < -sdf_trunc) { return; } sdf = sdf < sdf_trunc ? sdf : sdf_trunc; sdf /= sdf_trunc; // Associate voxel workload and update TSDF/Weights voxel_t* voxel_ptr = voxel_block_buffer_indexer .GetDataPtrFromCoord<voxel_t>( xv, yv, zv, block_idx); if (integrate_color) { float* color_ptr = color_indexer.GetDataPtrFromCoord<float>( static_cast<int64_t>(u), static_cast<int64_t>(v)); voxel_ptr->Integrate(sdf, color_ptr[0], color_ptr[1], color_ptr[2]); } else { voxel_ptr->Integrate(sdf); } }); }); #if defined(__CUDACC__) OPEN3D_CUDA_CHECK(cudaDeviceSynchronize()); #endif } #if defined(__CUDACC__) void ExtractSurfacePointsCUDA #else void ExtractSurfacePointsCPU #endif (const core::Tensor& indices, const core::Tensor& nb_indices, const core::Tensor& nb_masks, const core::Tensor& block_keys, const core::Tensor& block_values, core::Tensor& points, utility::optional<std::reference_wrapper<core::Tensor>> normals, utility::optional<std::reference_wrapper<core::Tensor>> colors, int64_t resolution, float voxel_size, float weight_threshold, int& valid_size) { // Parameters int64_t resolution3 = resolution * resolution * resolution; // Shape / transform indexers, no data involved NDArrayIndexer voxel_indexer({resolution, resolution, resolution}); // Real data indexer NDArrayIndexer voxel_block_buffer_indexer(block_values, 4); NDArrayIndexer block_keys_indexer(block_keys, 1); NDArrayIndexer nb_block_masks_indexer(nb_masks, 2); NDArrayIndexer nb_block_indices_indexer(nb_indices, 2); // Plain arrays that does not require indexers const int64_t* indices_ptr = static_cast<const int64_t*>(indices.GetDataPtr()); int64_t n_blocks = indices.GetLength(); int64_t n = n_blocks * resolution3; // Output #if defined(__CUDACC__) core::Tensor count(std::vector<int>{0}, {1}, core::Dtype::Int32, block_values.GetDevice()); int* count_ptr = count.GetDataPtr<int>(); #else std::atomic<int> count_atomic(0); std::atomic<int>* count_ptr = &count_atomic; #endif #if defined(__CUDACC__) core::kernel::CUDALauncher launcher; #else core::kernel::CPULauncher launcher; #endif if (valid_size < 0) { utility::LogWarning( "No estimated max point cloud size provided, using a 2-pass " "estimation. Surface extraction could be slow."); // This pass determines valid number of points. DISPATCH_BYTESIZE_TO_VOXEL( voxel_block_buffer_indexer.ElementByteSize(), [&]() { launcher.LaunchGeneralKernel( n, [=] OPEN3D_DEVICE(int64_t workload_idx) { auto GetVoxelAt = [&] OPEN3D_DEVICE( int xo, int yo, int zo, int curr_block_idx) -> voxel_t* { return DeviceGetVoxelAt<voxel_t>( xo, yo, zo, curr_block_idx, static_cast<int>(resolution), nb_block_masks_indexer, nb_block_indices_indexer, voxel_block_buffer_indexer); }; // Natural index (0, N) -> (block_idx, // voxel_idx) int64_t workload_block_idx = workload_idx / resolution3; int64_t block_idx = indices_ptr[workload_block_idx]; int64_t voxel_idx = workload_idx % resolution3; // voxel_idx -> (x_voxel, y_voxel, z_voxel) int64_t xv, yv, zv; voxel_indexer.WorkloadToCoord(voxel_idx, &xv, &yv, &zv); voxel_t* voxel_ptr = voxel_block_buffer_indexer .GetDataPtrFromCoord<voxel_t>( xv, yv, zv, block_idx); float tsdf_o = voxel_ptr->GetTSDF(); float weight_o = voxel_ptr->GetWeight(); if (weight_o <= weight_threshold) return; // Enumerate x-y-z directions for (int i = 0; i < 3; ++i) { voxel_t* ptr = GetVoxelAt( static_cast<int>(xv) + (i == 0), static_cast<int>(yv) + (i == 1), static_cast<int>(zv) + (i == 2), static_cast<int>( workload_block_idx)); if (ptr == nullptr) continue; float tsdf_i = ptr->GetTSDF(); float weight_i = ptr->GetWeight(); if (weight_i > weight_threshold && tsdf_i * tsdf_o < 0) { OPEN3D_ATOMIC_ADD(count_ptr, 1); } } }); }); #if defined(__CUDACC__) valid_size = count[0].Item<int>(); count[0] = 0; #else valid_size = (*count_ptr).load(); (*count_ptr) = 0; #endif } int max_count = valid_size; if (points.GetLength() == 0) { points = core::Tensor({max_count, 3}, core::Dtype::Float32, block_values.GetDevice()); } NDArrayIndexer point_indexer(points, 1); // Normals bool extract_normal = false; NDArrayIndexer normal_indexer; if (normals.has_value()) { extract_normal = true; if (normals.value().get().GetLength() == 0) { normals.value().get() = core::Tensor({max_count, 3}, core::Dtype::Float32, block_values.GetDevice()); } normal_indexer = NDArrayIndexer(normals.value().get(), 1); } // This pass extracts exact surface points. DISPATCH_BYTESIZE_TO_VOXEL( voxel_block_buffer_indexer.ElementByteSize(), [&]() { // Colors bool extract_color = false; NDArrayIndexer color_indexer; if (voxel_t::HasColor() && colors.has_value()) { extract_color = true; if (colors.value().get().GetLength() == 0) { colors.value().get() = core::Tensor( {max_count, 3}, core::Dtype::Float32, block_values.GetDevice()); } color_indexer = NDArrayIndexer(colors.value().get(), 1); } launcher.LaunchGeneralKernel(n, [=] OPEN3D_DEVICE( int64_t workload_idx) { auto GetVoxelAt = [&] OPEN3D_DEVICE( int xo, int yo, int zo, int curr_block_idx) -> voxel_t* { return DeviceGetVoxelAt<voxel_t>( xo, yo, zo, curr_block_idx, static_cast<int>(resolution), nb_block_masks_indexer, nb_block_indices_indexer, voxel_block_buffer_indexer); }; auto GetNormalAt = [&] OPEN3D_DEVICE(int xo, int yo, int zo, int curr_block_idx, float* n) { return DeviceGetNormalAt<voxel_t>( xo, yo, zo, curr_block_idx, n, static_cast<int>(resolution), voxel_size, nb_block_masks_indexer, nb_block_indices_indexer, voxel_block_buffer_indexer); }; // Natural index (0, N) -> (block_idx, voxel_idx) int64_t workload_block_idx = workload_idx / resolution3; int64_t block_idx = indices_ptr[workload_block_idx]; int64_t voxel_idx = workload_idx % resolution3; /// Coordinate transform // block_idx -> (x_block, y_block, z_block) int* block_key_ptr = block_keys_indexer.GetDataPtrFromCoord<int>( block_idx); int64_t xb = static_cast<int64_t>(block_key_ptr[0]); int64_t yb = static_cast<int64_t>(block_key_ptr[1]); int64_t zb = static_cast<int64_t>(block_key_ptr[2]); // voxel_idx -> (x_voxel, y_voxel, z_voxel) int64_t xv, yv, zv; voxel_indexer.WorkloadToCoord(voxel_idx, &xv, &yv, &zv); voxel_t* voxel_ptr = voxel_block_buffer_indexer .GetDataPtrFromCoord<voxel_t>( xv, yv, zv, block_idx); float tsdf_o = voxel_ptr->GetTSDF(); float weight_o = voxel_ptr->GetWeight(); if (weight_o <= weight_threshold) return; int64_t x = xb * resolution + xv; int64_t y = yb * resolution + yv; int64_t z = zb * resolution + zv; float no[3] = {0}, ni[3] = {0}; if (extract_normal) { GetNormalAt(static_cast<int>(xv), static_cast<int>(yv), static_cast<int>(zv), static_cast<int>(workload_block_idx), no); } // Enumerate x-y-z axis for (int i = 0; i < 3; ++i) { voxel_t* ptr = GetVoxelAt( static_cast<int>(xv) + (i == 0), static_cast<int>(yv) + (i == 1), static_cast<int>(zv) + (i == 2), static_cast<int>(workload_block_idx)); if (ptr == nullptr) continue; float tsdf_i = ptr->GetTSDF(); float weight_i = ptr->GetWeight(); if (weight_i > weight_threshold && tsdf_i * tsdf_o < 0) { float ratio = (0 - tsdf_o) / (tsdf_i - tsdf_o); int idx = OPEN3D_ATOMIC_ADD(count_ptr, 1); if (idx >= valid_size) { printf("Point cloud size larger than " "estimated, please increase the " "estimation!\n"); return; } float* point_ptr = point_indexer.GetDataPtrFromCoord<float>( idx); point_ptr[0] = voxel_size * (x + ratio * int(i == 0)); point_ptr[1] = voxel_size * (y + ratio * int(i == 1)); point_ptr[2] = voxel_size * (z + ratio * int(i == 2)); if (extract_color) { float* color_ptr = color_indexer .GetDataPtrFromCoord<float>( idx); float r_o = voxel_ptr->GetR(); float g_o = voxel_ptr->GetG(); float b_o = voxel_ptr->GetB(); float r_i = ptr->GetR(); float g_i = ptr->GetG(); float b_i = ptr->GetB(); color_ptr[0] = ((1 - ratio) * r_o + ratio * r_i) / 255.0f; color_ptr[1] = ((1 - ratio) * g_o + ratio * g_i) / 255.0f; color_ptr[2] = ((1 - ratio) * b_o + ratio * b_i) / 255.0f; } if (extract_normal) { GetNormalAt( static_cast<int>(xv) + (i == 0), static_cast<int>(yv) + (i == 1), static_cast<int>(zv) + (i == 2), static_cast<int>(workload_block_idx), ni); float* normal_ptr = normal_indexer .GetDataPtrFromCoord<float>( idx); float nx = (1 - ratio) * no[0] + ratio * ni[0]; float ny = (1 - ratio) * no[1] + ratio * ni[1]; float nz = (1 - ratio) * no[2] + ratio * ni[2]; float norm = static_cast<float>( sqrt(nx * nx + ny * ny + nz * nz) + 1e-5); normal_ptr[0] = nx / norm; normal_ptr[1] = ny / norm; normal_ptr[2] = nz / norm; } } } }); }); #if defined(__CUDACC__) int total_count = count.Item<int>(); #else int total_count = (*count_ptr).load(); #endif utility::LogDebug("{} vertices extracted", total_count); valid_size = total_count; #if defined(BUILD_CUDA_MODULE) && defined(__CUDACC__) OPEN3D_CUDA_CHECK(cudaDeviceSynchronize()); #endif } #if defined(__CUDACC__) void ExtractSurfaceMeshCUDA #else void ExtractSurfaceMeshCPU #endif (const core::Tensor& indices, const core::Tensor& inv_indices, const core::Tensor& nb_indices, const core::Tensor& nb_masks, const core::Tensor& block_keys, const core::Tensor& block_values, core::Tensor& vertices, core::Tensor& triangles, core::Tensor& normals, core::Tensor& colors, int64_t resolution, float voxel_size, float weight_threshold) { int64_t resolution3 = resolution * resolution * resolution; // Shape / transform indexers, no data involved NDArrayIndexer voxel_indexer({resolution, resolution, resolution}); // Output #if defined(__CUDACC__) core::CUDACachedMemoryManager::ReleaseCache(); #endif int n_blocks = static_cast<int>(indices.GetLength()); // Voxel-wise mesh info. 4 channels correspond to: // 3 edges' corresponding vertex index + 1 table index. core::Tensor mesh_structure; try { mesh_structure = core::Tensor::Zeros( {n_blocks, resolution, resolution, resolution, 4}, core::Dtype::Int32, block_keys.GetDevice()); } catch (const std::runtime_error&) { utility::LogError( "[MeshExtractionKernel] Unable to allocate assistance mesh " "structure for Marching " "Cubes with {} active voxel blocks. Please consider using a " "larger voxel size (currently {}) for TSDF " "integration, or using tsdf_volume.cpu() to perform mesh " "extraction on CPU.", n_blocks, voxel_size); } // Real data indexer NDArrayIndexer voxel_block_buffer_indexer(block_values, 4); NDArrayIndexer mesh_structure_indexer(mesh_structure, 4); NDArrayIndexer nb_block_masks_indexer(nb_masks, 2); NDArrayIndexer nb_block_indices_indexer(nb_indices, 2); // Plain arrays that does not require indexers const int64_t* indices_ptr = indices.GetDataPtr<int64_t>(); const int64_t* inv_indices_ptr = inv_indices.GetDataPtr<int64_t>(); int64_t n = n_blocks * resolution3; #if defined(__CUDACC__) core::kernel::CUDALauncher launcher; #else core::kernel::CPULauncher launcher; #endif // Pass 0: analyze mesh structure, set up one-on-one correspondences from // edges to vertices. DISPATCH_BYTESIZE_TO_VOXEL( voxel_block_buffer_indexer.ElementByteSize(), [&]() { launcher.LaunchGeneralKernel(n, [=] OPEN3D_DEVICE( int64_t workload_idx) { auto GetVoxelAt = [&] OPEN3D_DEVICE( int xo, int yo, int zo, int curr_block_idx) -> voxel_t* { return DeviceGetVoxelAt<voxel_t>( xo, yo, zo, curr_block_idx, static_cast<int>(resolution), nb_block_masks_indexer, nb_block_indices_indexer, voxel_block_buffer_indexer); }; // Natural index (0, N) -> (block_idx, voxel_idx) int64_t workload_block_idx = workload_idx / resolution3; int64_t voxel_idx = workload_idx % resolution3; // voxel_idx -> (x_voxel, y_voxel, z_voxel) int64_t xv, yv, zv; voxel_indexer.WorkloadToCoord(voxel_idx, &xv, &yv, &zv); // Check per-vertex sign in the cube to determine cube type int table_idx = 0; for (int i = 0; i < 8; ++i) { voxel_t* voxel_ptr_i = GetVoxelAt( static_cast<int>(xv) + vtx_shifts[i][0], static_cast<int>(yv) + vtx_shifts[i][1], static_cast<int>(zv) + vtx_shifts[i][2], static_cast<int>(workload_block_idx)); if (voxel_ptr_i == nullptr) return; float tsdf_i = voxel_ptr_i->GetTSDF(); float weight_i = voxel_ptr_i->GetWeight(); if (weight_i <= weight_threshold) return; table_idx |= ((tsdf_i < 0) ? (1 << i) : 0); } int* mesh_struct_ptr = mesh_structure_indexer.GetDataPtrFromCoord<int>( xv, yv, zv, workload_block_idx); mesh_struct_ptr[3] = table_idx; if (table_idx == 0 || table_idx == 255) return; // Check per-edge sign in the cube to determine cube type int edges_with_vertices = edge_table[table_idx]; for (int i = 0; i < 12; ++i) { if (edges_with_vertices & (1 << i)) { int64_t xv_i = xv + edge_shifts[i][0]; int64_t yv_i = yv + edge_shifts[i][1]; int64_t zv_i = zv + edge_shifts[i][2]; int edge_i = edge_shifts[i][3]; int dxb = static_cast<int>(xv_i / resolution); int dyb = static_cast<int>(yv_i / resolution); int dzb = static_cast<int>(zv_i / resolution); int nb_idx = (dxb + 1) + (dyb + 1) * 3 + (dzb + 1) * 9; int64_t block_idx_i = *nb_block_indices_indexer .GetDataPtrFromCoord<int64_t>( workload_block_idx, nb_idx); int* mesh_ptr_i = mesh_structure_indexer.GetDataPtrFromCoord< int>(xv_i - dxb * resolution, yv_i - dyb * resolution, zv_i - dzb * resolution, inv_indices_ptr[block_idx_i]); // Non-atomic write, but we are safe mesh_ptr_i[edge_i] = -1; } } }); }); // Pass 1: determine valid number of vertices. #if defined(__CUDACC__) core::Tensor vtx_count(std::vector<int>{0}, {}, core::Dtype::Int32, block_values.GetDevice()); int* vtx_count_ptr = vtx_count.GetDataPtr<int>(); #else std::atomic<int> vtx_count_atomic(0); std::atomic<int>* vtx_count_ptr = &vtx_count_atomic; #endif #if defined(__CUDACC__) core::kernel::CUDALauncher::LaunchGeneralKernel( n, [=] OPEN3D_DEVICE(int64_t workload_idx) { #else core::kernel::CPULauncher::LaunchGeneralKernel( n, [&](int64_t workload_idx) { #endif // Natural index (0, N) -> (block_idx, voxel_idx) int64_t workload_block_idx = workload_idx / resolution3; int64_t voxel_idx = workload_idx % resolution3; // voxel_idx -> (x_voxel, y_voxel, z_voxel) int64_t xv, yv, zv; voxel_indexer.WorkloadToCoord(voxel_idx, &xv, &yv, &zv); // Obtain voxel's mesh struct ptr int* mesh_struct_ptr = mesh_structure_indexer.GetDataPtrFromCoord<int>( xv, yv, zv, workload_block_idx); // Early quit -- no allocated vertex to compute if (mesh_struct_ptr[0] != -1 && mesh_struct_ptr[1] != -1 && mesh_struct_ptr[2] != -1) { return; } // Enumerate 3 edges in the voxel for (int e = 0; e < 3; ++e) { int vertex_idx = mesh_struct_ptr[e]; if (vertex_idx != -1) continue; OPEN3D_ATOMIC_ADD(vtx_count_ptr, 1); } }); // Reset count_ptr #if defined(__CUDACC__) int total_vtx_count = vtx_count.Item<int>(); vtx_count = core::Tensor(std::vector<int>{0}, {}, core::Dtype::Int32, block_values.GetDevice()); vtx_count_ptr = vtx_count.GetDataPtr<int>(); #else int total_vtx_count = (*vtx_count_ptr).load(); (*vtx_count_ptr) = 0; #endif utility::LogDebug("Total vertex count = {}", total_vtx_count); vertices = core::Tensor({total_vtx_count, 3}, core::Dtype::Float32, block_values.GetDevice()); normals = core::Tensor({total_vtx_count, 3}, core::Dtype::Float32, block_values.GetDevice()); NDArrayIndexer block_keys_indexer(block_keys, 1); NDArrayIndexer vertex_indexer(vertices, 1); NDArrayIndexer normal_indexer(normals, 1); // Pass 2: extract vertices. DISPATCH_BYTESIZE_TO_VOXEL( voxel_block_buffer_indexer.ElementByteSize(), [&]() { bool extract_color = false; NDArrayIndexer color_indexer; if (voxel_t::HasColor()) { extract_color = true; colors = core::Tensor({total_vtx_count, 3}, core::Dtype::Float32, block_values.GetDevice()); color_indexer = NDArrayIndexer(colors, 1); } launcher.LaunchGeneralKernel(n, [=] OPEN3D_DEVICE( int64_t workload_idx) { auto GetVoxelAt = [&] OPEN3D_DEVICE( int xo, int yo, int zo, int curr_block_idx) -> voxel_t* { return DeviceGetVoxelAt<voxel_t>( xo, yo, zo, curr_block_idx, static_cast<int>(resolution), nb_block_masks_indexer, nb_block_indices_indexer, voxel_block_buffer_indexer); }; auto GetNormalAt = [&] OPEN3D_DEVICE(int xo, int yo, int zo, int curr_block_idx, float* n) { return DeviceGetNormalAt<voxel_t>( xo, yo, zo, curr_block_idx, n, static_cast<int>(resolution), voxel_size, nb_block_masks_indexer, nb_block_indices_indexer, voxel_block_buffer_indexer); }; // Natural index (0, N) -> (block_idx, voxel_idx) int64_t workload_block_idx = workload_idx / resolution3; int64_t block_idx = indices_ptr[workload_block_idx]; int64_t voxel_idx = workload_idx % resolution3; // block_idx -> (x_block, y_block, z_block) int* block_key_ptr = block_keys_indexer.GetDataPtrFromCoord<int>( block_idx); int64_t xb = static_cast<int64_t>(block_key_ptr[0]); int64_t yb = static_cast<int64_t>(block_key_ptr[1]); int64_t zb = static_cast<int64_t>(block_key_ptr[2]); // voxel_idx -> (x_voxel, y_voxel, z_voxel) int64_t xv, yv, zv; voxel_indexer.WorkloadToCoord(voxel_idx, &xv, &yv, &zv); // global coordinate (in voxels) int64_t x = xb * resolution + xv; int64_t y = yb * resolution + yv; int64_t z = zb * resolution + zv; // Obtain voxel's mesh struct ptr int* mesh_struct_ptr = mesh_structure_indexer.GetDataPtrFromCoord<int>( xv, yv, zv, workload_block_idx); // Early quit -- no allocated vertex to compute if (mesh_struct_ptr[0] != -1 && mesh_struct_ptr[1] != -1 && mesh_struct_ptr[2] != -1) { return; } // Obtain voxel ptr voxel_t* voxel_ptr = voxel_block_buffer_indexer .GetDataPtrFromCoord<voxel_t>( xv, yv, zv, block_idx); float tsdf_o = voxel_ptr->GetTSDF(); float no[3] = {0}, ne[3] = {0}; GetNormalAt(static_cast<int>(xv), static_cast<int>(yv), static_cast<int>(zv), static_cast<int>(workload_block_idx), no); // Enumerate 3 edges in the voxel for (int e = 0; e < 3; ++e) { int vertex_idx = mesh_struct_ptr[e]; if (vertex_idx != -1) continue; voxel_t* voxel_ptr_e = GetVoxelAt( static_cast<int>(xv) + (e == 0), static_cast<int>(yv) + (e == 1), static_cast<int>(zv) + (e == 2), static_cast<int>(workload_block_idx)); float tsdf_e = voxel_ptr_e->GetTSDF(); float ratio = (0 - tsdf_o) / (tsdf_e - tsdf_o); int idx = OPEN3D_ATOMIC_ADD(vtx_count_ptr, 1); mesh_struct_ptr[e] = idx; float ratio_x = ratio * int(e == 0); float ratio_y = ratio * int(e == 1); float ratio_z = ratio * int(e == 2); float* vertex_ptr = vertex_indexer.GetDataPtrFromCoord<float>(idx); vertex_ptr[0] = voxel_size * (x + ratio_x); vertex_ptr[1] = voxel_size * (y + ratio_y); vertex_ptr[2] = voxel_size * (z + ratio_z); float* normal_ptr = normal_indexer.GetDataPtrFromCoord<float>(idx); GetNormalAt(static_cast<int>(xv) + (e == 0), static_cast<int>(yv) + (e == 1), static_cast<int>(zv) + (e == 2), static_cast<int>(workload_block_idx), ne); float nx = (1 - ratio) * no[0] + ratio * ne[0]; float ny = (1 - ratio) * no[1] + ratio * ne[1]; float nz = (1 - ratio) * no[2] + ratio * ne[2]; float norm = static_cast<float>( sqrt(nx * nx + ny * ny + nz * nz) + 1e-5); normal_ptr[0] = nx / norm; normal_ptr[1] = ny / norm; normal_ptr[2] = nz / norm; if (extract_color) { float* color_ptr = color_indexer.GetDataPtrFromCoord<float>( idx); float r_o = voxel_ptr->GetR(); float g_o = voxel_ptr->GetG(); float b_o = voxel_ptr->GetB(); float r_e = voxel_ptr_e->GetR(); float g_e = voxel_ptr_e->GetG(); float b_e = voxel_ptr_e->GetB(); color_ptr[0] = ((1 - ratio) * r_o + ratio * r_e) / 255.0f; color_ptr[1] = ((1 - ratio) * g_o + ratio * g_e) / 255.0f; color_ptr[2] = ((1 - ratio) * b_o + ratio * b_e) / 255.0f; } } }); }); // Pass 3: connect vertices and form triangles. #if defined(__CUDACC__) core::Tensor triangle_count(std::vector<int>{0}, {}, core::Dtype::Int32, block_values.GetDevice()); int* tri_count_ptr = triangle_count.GetDataPtr<int>(); #else std::atomic<int> tri_count_atomic(0); std::atomic<int>* tri_count_ptr = &tri_count_atomic; #endif triangles = core::Tensor({total_vtx_count * 3, 3}, core::Dtype::Int64, block_values.GetDevice()); NDArrayIndexer triangle_indexer(triangles, 1); #if defined(__CUDACC__) core::kernel::CUDALauncher::LaunchGeneralKernel( n, [=] OPEN3D_DEVICE(int64_t workload_idx) { #else core::kernel::CPULauncher::LaunchGeneralKernel( n, [&](int64_t workload_idx) { #endif // Natural index (0, N) -> (block_idx, // voxel_idx) int64_t workload_block_idx = workload_idx / resolution3; int64_t voxel_idx = workload_idx % resolution3; // voxel_idx -> (x_voxel, y_voxel, z_voxel) int64_t xv, yv, zv; voxel_indexer.WorkloadToCoord(voxel_idx, &xv, &yv, &zv); // Obtain voxel's mesh struct ptr int* mesh_struct_ptr = mesh_structure_indexer.GetDataPtrFromCoord<int>( xv, yv, zv, workload_block_idx); int table_idx = mesh_struct_ptr[3]; if (tri_count[table_idx] == 0) return; for (size_t tri = 0; tri < 16; tri += 3) { if (tri_table[table_idx][tri] == -1) return; int tri_idx = OPEN3D_ATOMIC_ADD(tri_count_ptr, 1); for (size_t vertex = 0; vertex < 3; ++vertex) { int edge = tri_table[table_idx][tri + vertex]; int64_t xv_i = xv + edge_shifts[edge][0]; int64_t yv_i = yv + edge_shifts[edge][1]; int64_t zv_i = zv + edge_shifts[edge][2]; int64_t edge_i = edge_shifts[edge][3]; int dxb = static_cast<int>(xv_i / resolution); int dyb = static_cast<int>(yv_i / resolution); int dzb = static_cast<int>(zv_i / resolution); int nb_idx = (dxb + 1) + (dyb + 1) * 3 + (dzb + 1) * 9; int64_t block_idx_i = *nb_block_indices_indexer .GetDataPtrFromCoord<int64_t>( workload_block_idx, nb_idx); int* mesh_struct_ptr_i = mesh_structure_indexer.GetDataPtrFromCoord<int>( xv_i - dxb * resolution, yv_i - dyb * resolution, zv_i - dzb * resolution, inv_indices_ptr[block_idx_i]); int64_t* triangle_ptr = triangle_indexer.GetDataPtrFromCoord<int64_t>( tri_idx); triangle_ptr[2 - vertex] = mesh_struct_ptr_i[edge_i]; } } }); #if defined(__CUDACC__) int total_tri_count = triangle_count.Item<int>(); #else int total_tri_count = (*tri_count_ptr).load(); #endif utility::LogDebug("Total triangle count = {}", total_tri_count); triangles = triangles.Slice(0, 0, total_tri_count); } #if defined(__CUDACC__) void EstimateRangeCUDA #else void EstimateRangeCPU #endif (const core::Tensor& block_keys, core::Tensor& range_minmax_map, const core::Tensor& intrinsics, const core::Tensor& extrinsics, int h, int w, int down_factor, int64_t block_resolution, float voxel_size, float depth_min, float depth_max) { // TODO(wei): reserve it in a reusable buffer // Every 2 channels: (min, max) int h_down = h / down_factor; int w_down = w / down_factor; range_minmax_map = core::Tensor({h_down, w_down, 2}, core::Dtype::Float32, block_keys.GetDevice()); NDArrayIndexer range_map_indexer(range_minmax_map, 2); // Every 6 channels: (v_min, u_min, v_max, u_max, z_min, z_max) const int fragment_size = 16; const int frag_buffer_size = 65535; // TODO(wei): explicit buffer core::Tensor fragment_buffer = core::Tensor({frag_buffer_size, 6}, core::Dtype::Float32, block_keys.GetDevice()); NDArrayIndexer frag_buffer_indexer(fragment_buffer, 1); NDArrayIndexer block_keys_indexer(block_keys, 1); TransformIndexer w2c_transform_indexer(intrinsics, extrinsics); #if defined(__CUDACC__) core::Tensor count(std::vector<int>{0}, {1}, core::Dtype::Int32, block_keys.GetDevice()); int* count_ptr = count.GetDataPtr<int>(); #else std::atomic<int> count_atomic(0); std::atomic<int>* count_ptr = &count_atomic; #endif #if defined(__CUDACC__) core::kernel::CUDALauncher launcher; #else core::kernel::CPULauncher launcher; using std::ceil; using std::floor; using std::max; using std::min; #endif // Pass 0: iterate over blocks, fill-in an rendering fragment array launcher.LaunchGeneralKernel( block_keys.GetLength(), [=] OPEN3D_DEVICE(int64_t workload_idx) { int* key = block_keys_indexer.GetDataPtrFromCoord<int>( workload_idx); int u_min = w_down - 1, v_min = h_down - 1, u_max = 0, v_max = 0; float z_min = depth_max, z_max = depth_min; float xc, yc, zc, u, v; // Project 8 corners to low-res image and form a rectangle for (int i = 0; i < 8; ++i) { float xw = (key[0] + ((i & 1) > 0)) * block_resolution * voxel_size; float yw = (key[1] + ((i & 2) > 0)) * block_resolution * voxel_size; float zw = (key[2] + ((i & 4) > 0)) * block_resolution * voxel_size; w2c_transform_indexer.RigidTransform(xw, yw, zw, &xc, &yc, &zc); if (zc <= 0) continue; // Project to the down sampled image buffer w2c_transform_indexer.Project(xc, yc, zc, &u, &v); u /= down_factor; v /= down_factor; v_min = min(static_cast<int>(floor(v)), v_min); v_max = max(static_cast<int>(ceil(v)), v_max); u_min = min(static_cast<int>(floor(u)), u_min); u_max = max(static_cast<int>(ceil(u)), u_max); z_min = min(z_min, zc); z_max = max(z_max, zc); } v_min = max(0, v_min); v_max = min(h_down - 1, v_max); u_min = max(0, u_min); u_max = min(w_down - 1, u_max); if (v_min >= v_max || u_min >= u_max || z_min >= z_max) return; // Divide the rectangle into small 16x16 fragments int frag_v_count = ceil(float(v_max - v_min + 1) / float(fragment_size)); int frag_u_count = ceil(float(u_max - u_min + 1) / float(fragment_size)); int frag_count = frag_v_count * frag_u_count; int frag_count_start = OPEN3D_ATOMIC_ADD(count_ptr, 1); int frag_count_end = frag_count_start + frag_count; if (frag_count_end >= frag_buffer_size) { printf("Fragment count exceeding buffer size, abort!\n"); } int offset = 0; for (int frag_v = 0; frag_v < frag_v_count; ++frag_v) { for (int frag_u = 0; frag_u < frag_u_count; ++frag_u, ++offset) { float* frag_ptr = frag_buffer_indexer.GetDataPtrFromCoord<float>( frag_count_start + offset); // zmin, zmax frag_ptr[0] = z_min; frag_ptr[1] = z_max; // vmin, umin frag_ptr[2] = v_min + frag_v * fragment_size; frag_ptr[3] = u_min + frag_u * fragment_size; // vmax, umax frag_ptr[4] = min(frag_ptr[2] + fragment_size - 1, static_cast<float>(v_max)); frag_ptr[5] = min(frag_ptr[3] + fragment_size - 1, static_cast<float>(u_max)); } } }); #if defined(__CUDACC__) int frag_count = count[0].Item<int>(); #else int frag_count = (*count_ptr).load(); #endif // Pass 0.5: Fill in range map to prepare for atomic min/max launcher.LaunchGeneralKernel( h_down * w_down, [=] OPEN3D_DEVICE(int64_t workload_idx) { int v = workload_idx / w_down; int u = workload_idx % w_down; float* range_ptr = range_map_indexer.GetDataPtrFromCoord<float>(u, v); range_ptr[0] = depth_max; range_ptr[1] = depth_min; }); // Pass 1: iterate over rendering fragment array, fill-in range launcher.LaunchGeneralKernel( frag_count * fragment_size * fragment_size, [=] OPEN3D_DEVICE(int64_t workload_idx) { int frag_idx = workload_idx / (fragment_size * fragment_size); int local_idx = workload_idx % (fragment_size * fragment_size); int dv = local_idx / fragment_size; int du = local_idx % fragment_size; float* frag_ptr = frag_buffer_indexer.GetDataPtrFromCoord<float>( frag_idx); int v_min = static_cast<int>(frag_ptr[2]); int u_min = static_cast<int>(frag_ptr[3]); int v_max = static_cast<int>(frag_ptr[4]); int u_max = static_cast<int>(frag_ptr[5]); int v = v_min + dv; int u = u_min + du; if (v > v_max || u > u_max) return; float z_min = frag_ptr[0]; float z_max = frag_ptr[1]; float* range_ptr = range_map_indexer.GetDataPtrFromCoord<float>(u, v); #ifdef __CUDACC__ atomicMinf(&(range_ptr[0]), z_min); atomicMaxf(&(range_ptr[1]), z_max); #else #pragma omp critical { range_ptr[0] = min(z_min, range_ptr[0]); range_ptr[1] = max(z_max, range_ptr[1]); } #endif }); #if defined(__CUDACC__) OPEN3D_CUDA_CHECK(cudaDeviceSynchronize()); #endif } struct BlockCache { int x; int y; int z; int block_idx; inline int OPEN3D_DEVICE Check(int xin, int yin, int zin) { return (xin == x && yin == y && zin == z) ? block_idx : -1; } inline void OPEN3D_DEVICE Update(int xin, int yin, int zin, int block_idx_in) { x = xin; y = yin; z = zin; block_idx = block_idx_in; } }; #if defined(__CUDACC__) void RayCastCUDA #else void RayCastCPU #endif (std::shared_ptr<core::DeviceHashmap>& hashmap, const core::Tensor& block_values, const core::Tensor& range_map, core::Tensor& vertex_map, core::Tensor& depth_map, core::Tensor& color_map, core::Tensor& normal_map, const core::Tensor& intrinsics, const core::Tensor& extrinsics, int h, int w, int64_t block_resolution, float voxel_size, float sdf_trunc, float depth_scale, float depth_min, float depth_max, float weight_threshold) { using Key = core::Block<int, 3>; using Hash = core::BlockHash<int, 3>; #if defined(BUILD_CUDA_MODULE) && defined(__CUDACC__) auto cuda_hashmap = std::dynamic_pointer_cast<core::StdGPUHashmap<Key, Hash>>(hashmap); if (cuda_hashmap == nullptr) { utility::LogError( "Unsupported backend: CUDA raycasting only supports STDGPU."); } auto hashmap_impl = cuda_hashmap->GetImpl(); #else auto cpu_hashmap = std::dynamic_pointer_cast<core::TBBHashmap<Key, Hash>>(hashmap); auto hashmap_impl = *cpu_hashmap->GetImpl(); #endif NDArrayIndexer voxel_block_buffer_indexer(block_values, 4); NDArrayIndexer range_map_indexer(range_map, 2); NDArrayIndexer vertex_map_indexer; NDArrayIndexer depth_map_indexer; NDArrayIndexer color_map_indexer; NDArrayIndexer normal_map_indexer; bool enable_vertex = (vertex_map.GetLength() != 0); bool enable_depth = (depth_map.GetLength() != 0); bool enable_color = (color_map.GetLength() != 0); bool enable_normal = (normal_map.GetLength() != 0); if (!enable_vertex && !enable_depth && !enable_color && !enable_normal) { utility::LogWarning("No output specified for ray casting, exit."); return; } if (enable_vertex) { vertex_map_indexer = NDArrayIndexer(vertex_map, 2); } if (enable_depth) { depth_map_indexer = NDArrayIndexer(depth_map, 2); } if (enable_color) { color_map_indexer = NDArrayIndexer(color_map, 2); } if (enable_normal) { normal_map_indexer = NDArrayIndexer(normal_map, 2); } TransformIndexer c2w_transform_indexer( intrinsics, t::geometry::InverseTransformation(extrinsics)); TransformIndexer w2c_transform_indexer(intrinsics, extrinsics); int64_t rows = h; int64_t cols = w; float block_size = voxel_size * block_resolution; #if defined(BUILD_CUDA_MODULE) && defined(__CUDACC__) core::kernel::CUDALauncher launcher; #else core::kernel::CPULauncher launcher; using std::max; #endif DISPATCH_BYTESIZE_TO_VOXEL(voxel_block_buffer_indexer.ElementByteSize(), [&]() { launcher.LaunchGeneralKernel( rows * cols, [=] OPEN3D_DEVICE(int64_t workload_idx) { auto GetVoxelAtP = [&] OPEN3D_DEVICE( int x_b, int y_b, int z_b, int x_v, int y_v, int z_v, core::addr_t block_addr, BlockCache& cache) -> voxel_t* { int x_vn = (x_v + block_resolution) % block_resolution; int y_vn = (y_v + block_resolution) % block_resolution; int z_vn = (z_v + block_resolution) % block_resolution; int dx_b = sign(x_v - x_vn); int dy_b = sign(y_v - y_vn); int dz_b = sign(z_v - z_vn); if (dx_b == 0 && dy_b == 0 && dz_b == 0) { return voxel_block_buffer_indexer .GetDataPtrFromCoord<voxel_t>(x_v, y_v, z_v, block_addr); } else { Key key; key(0) = x_b + dx_b; key(1) = y_b + dy_b; key(2) = z_b + dz_b; int block_addr = cache.Check(key(0), key(1), key(2)); if (block_addr < 0) { auto iter = hashmap_impl.find(key); if (iter == hashmap_impl.end()) return nullptr; block_addr = iter->second; cache.Update(key(0), key(1), key(2), block_addr); } return voxel_block_buffer_indexer .GetDataPtrFromCoord<voxel_t>( x_vn, y_vn, z_vn, block_addr); } }; auto GetVoxelAtT = [&] OPEN3D_DEVICE( float x_o, float y_o, float z_o, float x_d, float y_d, float z_d, float t, BlockCache& cache) -> voxel_t* { float x_g = x_o + t * x_d; float y_g = y_o + t * y_d; float z_g = z_o + t * z_d; // Block coordinate and look up int x_b = static_cast<int>(floor(x_g / block_size)); int y_b = static_cast<int>(floor(y_g / block_size)); int z_b = static_cast<int>(floor(z_g / block_size)); Key key; key(0) = x_b; key(1) = y_b; key(2) = z_b; int block_addr = cache.Check(x_b, y_b, z_b); if (block_addr < 0) { auto iter = hashmap_impl.find(key); if (iter == hashmap_impl.end()) return nullptr; block_addr = iter->second; cache.Update(x_b, y_b, z_b, block_addr); } // Voxel coordinate and look up int x_v = int((x_g - x_b * block_size) / voxel_size); int y_v = int((y_g - y_b * block_size) / voxel_size); int z_v = int((z_g - z_b * block_size) / voxel_size); return voxel_block_buffer_indexer .GetDataPtrFromCoord<voxel_t>(x_v, y_v, z_v, block_addr); }; int64_t y = workload_idx / cols; int64_t x = workload_idx % cols; float *depth_ptr = nullptr, *vertex_ptr = nullptr, *normal_ptr = nullptr, *color_ptr = nullptr; if (enable_depth) { depth_ptr = depth_map_indexer.GetDataPtrFromCoord<float>(x, y); *depth_ptr = 0; } if (enable_vertex) { vertex_ptr = vertex_map_indexer.GetDataPtrFromCoord<float>( x, y); vertex_ptr[0] = 0; vertex_ptr[1] = 0; vertex_ptr[2] = 0; } if (enable_color) { color_ptr = color_map_indexer.GetDataPtrFromCoord<float>(x, y); color_ptr[0] = 0; color_ptr[1] = 0; color_ptr[2] = 0; } if (enable_normal) { normal_ptr = normal_map_indexer.GetDataPtrFromCoord<float>( x, y); normal_ptr[0] = 0; normal_ptr[1] = 0; normal_ptr[2] = 0; } const float* range = range_map_indexer.GetDataPtrFromCoord<float>(x / 8, y / 8); float t = range[0]; const float t_max = range[1]; if (t >= t_max) return; // Coordinates in camera and global float x_c = 0, y_c = 0, z_c = 0; float x_g = 0, y_g = 0, z_g = 0; float x_o = 0, y_o = 0, z_o = 0; // Iterative ray intersection check float t_prev = t; float tsdf_prev = -1.0f; float tsdf = 1.0; float w = 0.0; // Camera origin c2w_transform_indexer.RigidTransform(0, 0, 0, &x_o, &y_o, &z_o); // Direction c2w_transform_indexer.Unproject(static_cast<float>(x), static_cast<float>(y), 1.0f, &x_c, &y_c, &z_c); c2w_transform_indexer.RigidTransform(x_c, y_c, z_c, &x_g, &y_g, &z_g); float x_d = (x_g - x_o); float y_d = (y_g - y_o); float z_d = (z_g - z_o); BlockCache cache{0, 0, 0, -1}; bool surface_found = false; while (t < t_max) { voxel_t* voxel_ptr = GetVoxelAtT(x_o, y_o, z_o, x_d, y_d, z_d, t, cache); if (!voxel_ptr) { t_prev = t; t += block_size; } else { tsdf_prev = tsdf; tsdf = voxel_ptr->GetTSDF(); w = voxel_ptr->GetWeight(); if (tsdf_prev > 0 && w >= weight_threshold && tsdf <= 0) { surface_found = true; break; } t_prev = t; float delta = tsdf * sdf_trunc; t += delta < voxel_size ? voxel_size : delta; } } if (surface_found) { float t_intersect = (t * tsdf_prev - t_prev * tsdf) / (tsdf_prev - tsdf); x_g = x_o + t_intersect * x_d; y_g = y_o + t_intersect * y_d; z_g = z_o + t_intersect * z_d; // Trivial vertex assignment if (enable_depth) { *depth_ptr = t_intersect * depth_scale; } if (enable_vertex) { w2c_transform_indexer.RigidTransform( x_g, y_g, z_g, vertex_ptr + 0, vertex_ptr + 1, vertex_ptr + 2); } // Trilinear interpolation // TODO(wei): simplify the flow by splitting the // functions given what is enabled if (enable_color || enable_normal) { int x_b = static_cast<int>(floor(x_g / block_size)); int y_b = static_cast<int>(floor(y_g / block_size)); int z_b = static_cast<int>(floor(z_g / block_size)); float x_v = (x_g - float(x_b) * block_size) / voxel_size; float y_v = (y_g - float(y_b) * block_size) / voxel_size; float z_v = (z_g - float(z_b) * block_size) / voxel_size; Key key; key(0) = x_b; key(1) = y_b; key(2) = z_b; int block_addr = cache.Check(x_b, y_b, z_b); if (block_addr < 0) { auto iter = hashmap_impl.find(key); if (iter == hashmap_impl.end()) return; block_addr = iter->second; cache.Update(x_b, y_b, z_b, block_addr); } int x_v_floor = static_cast<int>(floor(x_v)); int y_v_floor = static_cast<int>(floor(y_v)); int z_v_floor = static_cast<int>(floor(z_v)); float ratio_x = x_v - float(x_v_floor); float ratio_y = y_v - float(y_v_floor); float ratio_z = z_v - float(z_v_floor); float sum_weight_color = 0.0; float sum_weight_normal = 0.0; for (int k = 0; k < 8; ++k) { int dx_v = (k & 1) > 0 ? 1 : 0; int dy_v = (k & 2) > 0 ? 1 : 0; int dz_v = (k & 4) > 0 ? 1 : 0; float ratio = (dx_v * (ratio_x) + (1 - dx_v) * (1 - ratio_x)) * (dy_v * (ratio_y) + (1 - dy_v) * (1 - ratio_y)) * (dz_v * (ratio_z) + (1 - dz_v) * (1 - ratio_z)); voxel_t* voxel_ptr_k = GetVoxelAtP( x_b, y_b, z_b, x_v_floor + dx_v, y_v_floor + dy_v, z_v_floor + dz_v, block_addr, cache); if (enable_color && voxel_ptr_k && voxel_ptr_k->GetWeight() > 0) { sum_weight_color += ratio; color_ptr[0] += ratio * voxel_ptr_k->GetR(); color_ptr[1] += ratio * voxel_ptr_k->GetG(); color_ptr[2] += ratio * voxel_ptr_k->GetB(); } if (enable_normal) { for (int dim = 0; dim < 3; ++dim) { voxel_t* voxel_ptr_k_plus = GetVoxelAtP( x_b, y_b, z_b, x_v_floor + dx_v + (dim == 0), y_v_floor + dy_v + (dim == 1), z_v_floor + dz_v + (dim == 2), block_addr, cache); voxel_t* voxel_ptr_k_minus = GetVoxelAtP(x_b, y_b, z_b, x_v_floor + dx_v - (dim == 0), y_v_floor + dy_v - (dim == 1), z_v_floor + dz_v - (dim == 2), block_addr, cache); bool valid = false; if (voxel_ptr_k_plus && voxel_ptr_k_plus->GetWeight() > 0) { normal_ptr[dim] += ratio * voxel_ptr_k_plus ->GetTSDF() / (2 * voxel_size); valid = true; } if (voxel_ptr_k_minus && voxel_ptr_k_minus->GetWeight() > 0) { normal_ptr[dim] -= ratio * voxel_ptr_k_minus ->GetTSDF() / (2 * voxel_size); valid = true; } sum_weight_normal += valid ? ratio : 0; } } // if (enable_normal) } // loop over 8 neighbors if (enable_color && sum_weight_color > 0) { sum_weight_color *= 255.0; color_ptr[0] /= sum_weight_color; color_ptr[1] /= sum_weight_color; color_ptr[2] /= sum_weight_color; } if (enable_normal && sum_weight_normal > 0) { normal_ptr[0] /= sum_weight_normal; normal_ptr[1] /= sum_weight_normal; normal_ptr[2] /= sum_weight_normal; float norm = sqrt(normal_ptr[0] * normal_ptr[0] + normal_ptr[1] * normal_ptr[1] + normal_ptr[2] * normal_ptr[2]); w2c_transform_indexer.Rotate( normal_ptr[0] / norm, normal_ptr[1] / norm, normal_ptr[2] / norm, normal_ptr + 0, normal_ptr + 1, normal_ptr + 2); } } // if (color or normal) } // if (tsdf < 0) }); }); #if defined(__CUDACC__) OPEN3D_CUDA_CHECK(cudaDeviceSynchronize()); #endif } } // namespace tsdf } // namespace kernel } // namespace geometry } // namespace t } // namespace open3d

preprocess.c

/* * preprocess.c * * Created on: 2018-3-29 * Author: qiushuang * * This file preprocesses De Bruijn graph: removing one-directed edge, indexing vertices with their location index, * using new index to replace the neighbors of vertices, splitting and gathering vertices to junctions and linear vertices */ #include <omp.h> #include "../include/dbgraph.h" #include "../include/graph.h" #include "../include/comm.h" #include "../include/hash.h" #include "../include/preprocess.h" #include "../include/bitkmer.h" #include "../include/hash.h" #include "../include/malloc.h" #include "../include/share.h" #define CPU_THREADS 128 // for debugging extern thread_function shift_dictionary[]; #ifdef LITTLE_ENDIAN static const ull zerotable[8] = { 0xffffffffffffff00, 0xffffffffffff00ff, 0xffffffffff00ffff, 0xffffffff00ffffff, 0xffffff00ffffffff, 0xffff00ffffffffff, 0xff00ffffffffffff, 0xffffffffffffff}; #else static const ull zerotable[8] = { 0xffffffffffffff, 0xff00ffffffffffff, 0xffff00ffffffffff, 0xffffff00ffffffff, 0xffffffff00ffffff, 0xffffffffff00ffff, 0xffffffffffff00ff, 0xffffffffffffff00}; #endif extern long cpu_threads; extern float elem_factor; extern voff_t max_ss; extern int cutoff; ull send_linear = 0; ull send_junction = 0; ull receive_linear = 0; ull receive_junction = 0; ull reverse_flag = 0; ull stride_true = 0; static uint * size_prime_index; // for hash table lookup static goffset_t * id_offsets; // used to assign global id for each node in subgraphs static goffset_t * jid_offset; // junction vertex id offsets, used to calculate id of each vertex from its index static kmer_t * kmers; // temporary kmers for fast kmer binary search in assigning neighbor ids static vertex_t * vertices; // vertex structure static voff_t * jvalid; // freed after filtering static voff_t * lvalid; // freed after filtering static int * id2index; // partition id to the index of partition list static voff_t * send_offsets; // used to locate the write position of messages for each partition in send buffer static voff_t * receive_offsets; static voff_t * extra_send_offsets; static voff_t * send_offsets_th; static voff_t * tmp_send_offsets_th; static voff_t * index_offsets; extern int lock_flag[NUM_OF_PROCS]; extern float push_offset_time[NUM_OF_PROCS]; extern float push_time[NUM_OF_PROCS]; extern float pull_intra_time[NUM_OF_PROCS]; extern float pull_inter_time[NUM_OF_PROCS]; static void * send; static void * receive; // ********** the following are used for output junctions and linear vertices static kmer_t * jkmers; // for output sorted junction kmers //static kmer_t * lkmers; // for output sorted linear kmers static edge_type * post_edges; // for output sorted post edges of linear vertices static edge_type * pre_edges; // for output sorted pre edges of linear vertices static vid_t * posts; // for output post neighbor of a linear vertex static vid_t * pres; // for output pre neighbors of linear vertices static vid_t * adj_nbs[EDGE_DIC_SIZE]; // for output neigbhors of junctions static ull * spids; // for output shared pids of neighbors of kmers static ull * spidsr; // for output shared pids of neighbors of reverse complements static uint * spidlv; // for output shared pids of post and pre of linear vertices static ull * junct_edges; // for output edges of junctions static voff_t not_found[CPU_THREADS]; voff_t gmax_lsize = 0; voff_t gmax_jsize = 0; #define get_reverse_edge(edge, kmer) { \ edge = (kmer.x >> (KMER_UNIT_BITS - 2)) ^ 0x3; } static void set_globals_filter_cpu (dbmeta_t * dbm) { vertices = dbm->vs; jvalid = dbm->jvld; lvalid = dbm->lvld; jid_offset = dbm->jid_offset; id_offsets = dbm->id_offsets; send = dbm->comm.send; } static void set_kmer_for_host_pull (dbmeta_t * dbm) { kmers = dbm->nds.kmer; } static void set_pull_push_receive (comm_t * cm) { receive = cm->receive; } static void set_globals_preprocessing (dbmeta_t * dbm, int num_of_partitions) { send_offsets = dbm->comm.send_offsets; receive_offsets = dbm->comm.receive_offsets; send = dbm->comm.send; id2index = dbm->comm.id2index; index_offsets = dbm->comm.index_offsets; send_offsets_th = (voff_t*) malloc (sizeof(voff_t) * (num_of_partitions+1) * (cpu_threads+1)); CHECK_PTR_RETURN (send_offsets_th, "malloc local send offsets for multi-threads in push mssg offset error!\n"); memset (send_offsets_th, 0, sizeof(voff_t) * (num_of_partitions+1) * (cpu_threads+1)); tmp_send_offsets_th = (voff_t*) malloc (sizeof(voff_t) * (num_of_partitions+1) * (cpu_threads+1)); CHECK_PTR_RETURN (send_offsets_th, "malloc tmp send offsets for multi-threads in push mssg offset error!\n"); memset (tmp_send_offsets_th, 0, sizeof(voff_t) * (num_of_partitions+1) * (cpu_threads+1)); } void init_preprocessing_data_cpu (dbmeta_t * dbm, int num_of_partitions) { set_globals_preprocessing (dbm, num_of_partitions); } static void set_globals_gather (dbmeta_t * dbm) { int i; for (i=0; i<EDGE_DIC_SIZE; i++) { adj_nbs[i] = dbm->djs.nbs[i]; } posts = dbm->dls.posts; pres = dbm->dls.pres; jkmers = dbm->djs.kmers; // lkmers = dbm->dls.kmers; post_edges = dbm->dls.post_edges; pre_edges = dbm->dls.pre_edges; junct_edges = dbm->djs.edges; spids = dbm->djs.spids; spidsr = dbm->djs.spidsr; spidlv = dbm->dls.spids; } void reset_globals_gather_cpu (dbmeta_t * dbm) { set_globals_gather (dbm); } static void release_globals_cpu (void) { free(send_offsets_th); free(tmp_send_offsets_th); } void finalize_preprocessing_data_cpu (void) { release_globals_cpu(); } static void init_kmers (uint size, voff_t index_offset) { entry_t * buf = (entry_t *) send; int r; #pragma omp parallel for for (r=0; r<size; r++) { int index = r; if (buf[index].occupied) { lvalid[index+1] = 1; } } } static void gather_vs (uint size, voff_t index_offset, entry_t * send) { entry_t * buf = (entry_t *) send; vertex_t * vs = vertices + index_offset; int r; #pragma omp parallel for for (r=0; r<size; r++) { int index = r; if (buf[index].occupied) { vs[lvalid[index]].kmer = buf[index].kmer; vs[lvalid[index]].edge = buf[index].edge; vs[lvalid[index]].vid = buf[index].occupied;//2 } } } static void gather_vs_sorted (uint size, voff_t index_offset, entry_t * send) { entry_t * buf = send; vertex_t * vs = vertices + index_offset; int r; #pragma omp parallel for for (r=0; r<size; r++) { int index = r; vs[index].kmer = buf[index].kmer; vs[index].edge = buf[index].edge; vs[index].vid = buf[index].occupied;//2 } } static void set_mssg_offset_buffer (dbmeta_t * dbm) { extra_send_offsets = dbm->comm.extra_send_offsets; } void init_binary_data_cpu (int did, master_t * mst, dbmeta_t * dbm, dbtable_t * tbs) { int * num_partitions = mst->num_partitions; int * partition_list = mst->partition_list; int num_of_partitions = num_partitions[did+1]-num_partitions[did]; // number of partitions in this processor int total_num_partitions = mst->total_num_partitions; // total number of partitions in this compute node voff_t * index_offset = mst->index_offset[did]; int world_size = mst->world_size; int world_rank = mst->world_rank; int np_per_node = (total_num_partitions + world_size - 1)/world_size; int start_partition_id = np_per_node*world_rank; set_globals_filter_cpu (dbm); set_mssg_offset_buffer (dbm); int i; voff_t offset = 0; for (i=0; i<num_of_partitions; i++) { int poffset = num_partitions[did]; int pid = partition_list[poffset+i] - start_partition_id; // !!!be careful here, this pid is not the global partition id int pindex = mst->id2index[did][pid + start_partition_id]; if (pindex != i) { printf ("ERROR IN DISTRIBUTING PARTITIONS!!!!!!!!\n"); exit(0); } voff_t size = tbs[pid].size; memset (dbm->lvld, 0, sizeof(vid_t) * (size+1)); memcpy(dbm->comm.send, tbs[pid].buf, sizeof(entry_t) * size); init_kmers (size, offset); // inclusive_prefix_sum (dbm->lvld, size+1); tbb_scan_uint (dbm->lvld, dbm->lvld, size+1); offset = dbm->lvld[size]; gather_vs (size, index_offset[i], (entry_t*)(dbm->comm.send)); if (offset > max_ss) { printf ("error!!!!!!\n"); exit(0); } tbb_vertex_sort (dbm->vs + index_offset[i], offset); index_offset[i+1] = index_offset[i] + offset; free (tbs[pid].buf); } // printf ("index offset on CPU %d: \n", did); // print_offsets(index_offset, num_of_partitions); } void init_binary_data_cpu_sorted (int did, master_t * mst, dbmeta_t * dbm, dbtable_t * tbs) { int * num_partitions = mst->num_partitions; int * partition_list = mst->partition_list; int num_of_partitions = num_partitions[did+1]-num_partitions[did]; // number of partitions in this processor int total_num_partitions = mst->total_num_partitions; // total number of partitions in this compute node voff_t * index_offset = mst->index_offset[did]; int world_size = mst->world_size; int world_rank = mst->world_rank; int np_per_node = (total_num_partitions + world_size - 1)/world_size; int start_partition_id = np_per_node*world_rank; set_globals_filter_cpu (dbm); set_mssg_offset_buffer (dbm); int i; for (i=0; i<num_of_partitions; i++) { int poffset = num_partitions[did]; int pid = partition_list[poffset+i] - start_partition_id; // !!!be careful here, this pid is not the global partition id int pindex = mst->id2index[did][pid + start_partition_id]; if (pindex != i) { printf ("ERROR IN DISTRIBUTING PARTITIONS!!!!!!!!\n"); exit(0); } voff_t size = tbs[pid].size; gather_vs_sorted (size, index_offset[i], tbs[pid].buf); index_offset[i+1] = index_offset[i] + size; free (tbs[pid].buf); } // printf ("index offset on CPU %d: \n", did); // print_offsets(index_offset, num_of_partitions+1); } static int binary_search_vertex (vertex_t * vs, kmer_t * akmer, uint size) { int begin = 0; int end = size - 1; int index = (begin + end) / 2; int ret; while (begin <= end) { ret = compare_2kmers_cpu (&vs[index].kmer, akmer); if (ret == 0) return index; else if (ret < 0) { end = index - 1; } else if (ret > 0) { begin = index + 1; } index = (begin + end) / 2; } // printf ("!!!!!!!!!!!!! Error occurs here: %u, %u\n", akmer->x, akmer->y); return -1; } static int lookup_with_hash_cpu (hashval_t hashval, kmer_t * akmer, kmer_t * kmers, hashsize_t size, int pid) { hashval_t index, hash2; uint i; index = hashtab_mod_cpu (hashval, size_prime_index[pid]); if (index >= size) { printf ("index %u is larger than size %u\n", index, size); return -1; } kmer_t * entry = kmers + index; if (is_equal_kmer_cpu(entry, akmer)) { return index; } hash2 = hashtab_mod_m2_cpu (hashval, size_prime_index[pid]); for (i=0; i<size; i++) { index += hash2; if (index >= size) index -= size; entry = kmers + index; if (is_equal_kmer_cpu(entry, akmer)) { return index; } } return -1; } static int lookup_kmer_assign_source_id_binary (assid_t * mssg, vertex_t * vs, uint size, uint * not_found) { edge_type edge; int stride; edge = (mssg->code >> (8*2)) & 0xff; if (edge > 3) { printf ("Encoded edge error!!!!!!!!!! %u\n", edge); exit (0); } int index = binary_search_vertex (vs, &mssg->dst, size); if (mssg->code & REVERSE_FLAG) { stride = EDGE_DIC_SIZE / 2; } else { stride = 0; } if (index==-1) { return -1; } else { vs[index].nbs[edge + stride] = mssg->srcid; /* int pid = query_partition_id_from_idoffsets(mssg->srcid, 32, id_offsets); if (mssg->srcid >= id_offsets[pid] && mssg->srcid < id_offsets[pid] + jid_offset[pid]) // a junction id receive_junction++; else receive_linear++;*/ } return 0; } static int lookup_kmer_set_edge_zero_binary (shakehands_t * mssg, vertex_t * vs, uint size, uint * not_found) { edge_type edge; int stride; edge = (mssg->code >> (8*2)) & 0xff; if (edge > 3) { printf ("Encoded edge error!!!!!!!!!! %u\n", edge); exit (0); } int index = binary_search_vertex (vs, &mssg->dst, size); if (mssg->code & REVERSE_FLAG) { stride = EDGE_DIC_SIZE / 2; } else { stride = 0; } if (index==-1) { return -1; } else { atomic_and (&vs[index].edge, zerotable[edge+stride]); } return 0; } static void init_hashtab_cpu (uint size, voff_t index_offset) { vertex_t * vs = vertices + index_offset; entry_t * buf = (entry_t *)send; kmer_t * local_kmers = kmers + index_offset; int r; for (r = 0; r < size; r++) { int index = r; if (buf[index].occupied) { if (buf[index].occupied != 2) { printf ("ERROR IN INPUT DATA!!!!!!!!!!!!\n"); exit (0); } vs[index].kmer = buf[index].kmer; vs[index].edge = buf[index].edge; vs[index].vid = buf[index].occupied; local_kmers[index] = buf[index].kmer; } } } void init_hashtab_data_cpu (int did, master_t * mst, dbmeta_t * dbm, dbtable_t * tbs) { int * num_partitions = mst->num_partitions; int * partition_list = mst->partition_list; int num_of_partitions = num_partitions[did+1]-num_partitions[did]; // number of partitions in this processor int total_num_partitions = mst->total_num_partitions; // total number of partitions in this compute node voff_t * index_offset = mst->index_offset[did]; int world_size = mst->world_size; int world_rank = mst->world_rank; int np_per_node = (total_num_partitions + world_size - 1)/world_size; int start_partition_id = np_per_node*world_rank; size_prime_index = (uint *) malloc (sizeof(uint) * num_of_partitions); set_globals_filter_cpu (dbm); set_kmer_for_host_pull (dbm); int i; voff_t offset = 0; for (i=0; i<num_of_partitions; i++) { int poffset = num_partitions[did]; int pid = partition_list[poffset+i] - start_partition_id; int pindex = mst->id2index[did][pid+start_partition_id]; if (pindex != i) { printf ("ERROR IN DISTRIBUTING PARTITIONS!!!!!!!!\n"); // unsorted distribution // exit(0); } voff_t size = tbs[pid].size; // printf ("partition size of hash table %d: %u\n", pid+start_partition_id, size); memcpy(dbm->comm.send, tbs[pid].buf, sizeof(entry_t) * size); // init_hashtab (size, offset); init_hashtab_cpu (size, offset); index_offset[i] = offset; offset += size; uint num_of_elems = tbs[pid].num_elems; size_prime_index[i] = higher_prime_index (num_of_elems * elem_factor); // printf ("num_of_elems = %u, size_prime_index[%d]= %u\n", num_of_elems, i, size_prime_index[i]); free (tbs[pid].buf); } index_offset[i] = offset; // printf ("index offset on CPU %d: \n", did); // print_offsets(index_offset, num_of_partitions); } void finalize_hashtab_data_cpu (void) { free (size_prime_index); } static int lookup_kmer_assign_source_id_cpu2 (assid_t mssg, vertex_t * vs, kmer_t * kmers, uint size, int pindex, uint * not_found) { int edge; int stride; edge = (mssg.code >> (8*2)) && 0xff; if (edge > 3) { printf ("Encoded edge error!!!!!!!!!! %u\n", edge); exit (0); } hashval_t seed = DEFAULT_SEED; hashval_t hash = murmur_hash3_32 ((uint *)&mssg.dst, seed); int index = lookup_with_hash_cpu (hash, &mssg.dst, kmers, size, pindex); if (mssg.code >> (8*3)) { stride = EDGE_DIC_SIZE / 2; } else { stride = 0; } if (index==-1) { (*not_found)++; return -1; } else { vs[index].nbs[edge + stride] = mssg.srcid; } return 0; } static int get_adj_id_from_post (kmer_t * kmer, edge_type edge, int k, int p, int num_of_partitions) { if (edge>=4) printf("Error in getting adj id from post: edge must be a number in [0-3]!\n"); minstr_t minpstr = 0, rminpstr = 0; minstr_t curr = 0; minstr_t pstr = 0, rpstr = 0; unit_kmer_t * ptr; kmer_t node[2]; node[0].x = kmer->x; node[0].y = kmer->y; #ifdef LONG_KMER node[0].z = kmer->z; node[0].w = kmer->w; #endif kmer_32bit_left_shift (&node[0], 2); ptr = (unit_kmer_t *)(&node[0]) + (k * 2) / KMER_UNIT_BITS; *ptr |= ((unit_kmer_t)edge) << (KMER_UNIT_BITS - (k * 2) % KMER_UNIT_BITS); get_reverse_kmer (&node[0], &node[1], k); /* get first minimum p-substring */ get_first_pstr ((unit_kmer_t *)&node[0], &pstr, p); get_first_pstr ((unit_kmer_t *)&node[1], &rpstr, p); minpstr = pstr; rminpstr = rpstr; int j; for (j = 1; j < k - p + 1; j++) { right_shift_pstr ((unit_kmer_t *)&node[0], &pstr, p, j); right_shift_pstr ((unit_kmer_t *)&node[1], &rpstr, p, j); if (pstr < minpstr) minpstr = pstr; if (rpstr < rminpstr) rminpstr = rpstr; } curr = rminpstr < minpstr ? rminpstr : minpstr; msp_id_t mspid = get_partition_id_cpu (curr, p, num_of_partitions); return mspid; } static int get_adj_id_from_pre (kmer_t * kmer, edge_type edge, int k, int p, int num_of_partitions) { if (edge>=4) printf("Error in getting adj id from post: edge must be a number in [0-3]!\n"); minstr_t minpstr = 0, rminpstr = 0; minstr_t curr = 0; minstr_t pstr = 0, rpstr = 0; unit_kmer_t * ptr; kmer_t node[2]; node[0].x = kmer->x; node[0].y = kmer->y; #ifdef LONG_KMER node[0].z = kmer->z; node[0].w = kmer->w; #endif get_reverse_kmer (&node[0], &node[1], k); kmer_32bit_left_shift (&node[1], 2); ptr = (unit_kmer_t *)(&node[1]) + (k*2)/KMER_UNIT_BITS; *ptr |= ((unit_kmer_t)edge) << (KMER_UNIT_BITS - (k*2)%KMER_UNIT_BITS); get_reverse_kmer (&node[1], &node[0], k); /* get first minimum p-substring */ get_first_pstr ((unit_kmer_t *)&node[0], &pstr, p); get_first_pstr ((unit_kmer_t *)&node[1], &rpstr, p); minpstr = pstr; rminpstr = rpstr; int j; for (j = 1; j < k - p + 1; j++) { right_shift_pstr ((unit_kmer_t *)&node[0], &pstr, p, j); right_shift_pstr ((unit_kmer_t *)&node[1], &rpstr, p, j); if (pstr < minpstr) minpstr = pstr; if (rpstr < rminpstr) rminpstr = rpstr; } curr = rminpstr < minpstr ? rminpstr : minpstr; msp_id_t mspid = get_partition_id_cpu (curr, p, num_of_partitions); return mspid; } static void get_adj_mssg_from_post (kmer_t * kmer, edge_type edge, int k, assid_t * mssg, msp_id_t pid) { if (edge>=4) printf("Error in getting adj id from post: edge must be a number in [0-3]!\n"); uint seed = DEFAULT_SEED; unit_kmer_t * ptr; kmer_t node[2]; edge_type edges[2]; edges[0] = edge; // edges[0] from node[0] node[0].x = kmer->x; node[0].y = kmer->y; #ifdef LONG_KMER node[0].z = kmer->z; node[0].w = kmer->w; #endif get_reverse_edge (edges[1], node[0]); // edges[1] from node[1] kmer_32bit_left_shift (&node[0], 2); ptr = (unit_kmer_t *)(&node[0]) + (k * 2) / KMER_UNIT_BITS; *ptr |= ((unit_kmer_t)edge) << (KMER_UNIT_BITS - (k * 2) % KMER_UNIT_BITS); get_reverse_kmer (&node[0], &node[1], k); int flag; hashval_t hash[2]; hash[0] = murmur_hash3_32 ((uint *)&node[0], seed); hash[1] = murmur_hash3_32 ((uint *)&node[1], seed); if (hash[0] == hash[1]) { int ret = compare_2kmers_cpu (&node[0], &node[1]); if (ret >= 0) flag = 0; else flag = 1; } else if (hash[0] < hash[1]) flag = 0; else flag = 1; mssg->dst = node[flag]; mssg->code = 0; if (flag == 0) { mssg->code = (((uint)edges[1]) << (8*2)) | REVERSE_FLAG | pid; reverse_flag++; } else mssg->code = (((uint)edges[1]) << (8*2)) | pid; } static void get_adj_mssg_from_pre (kmer_t * kmer, edge_type edge, int k, assid_t * mssg, msp_id_t pid) { if (edge>=4) printf("Error in getting adj id from post: edge must be a number in [0-3]!\n"); uint seed = DEFAULT_SEED; unit_kmer_t * ptr; kmer_t node[2]; edge_type edges[2]; edges[1] = edge; // edges[1] from kmer - node[1] node[0].x = kmer->x; node[0].y = kmer->y; #ifdef LONG_KMER node[0].z = kmer->z; node[0].w = kmer->w; #endif get_reverse_kmer (&node[0], &node[1], k); get_reverse_edge (edges[0], node[1]); // edges[0] from kmer node[0] kmer_32bit_left_shift (&node[1], 2); ptr = (unit_kmer_t *)(&node[1]) + (k*2)/KMER_UNIT_BITS; *ptr |= ((unit_kmer_t)edge) << (KMER_UNIT_BITS - (k*2)%KMER_UNIT_BITS); get_reverse_kmer (&node[1], &node[0], k); int flag; hashval_t hash[2]; hash[0] = murmur_hash3_32 ((uint *)&node[0], seed); hash[1] = murmur_hash3_32 ((uint *)&node[1], seed); if (hash[0] == hash[1]) { int ret = compare_2kmers_cpu (&node[0], &node[1]); if (ret >= 0) flag = 0; else flag = 1; } else if (hash[0] < hash[1]) flag = 0; else flag = 1; mssg->dst = node[flag]; mssg->code = 0; if (flag==1) { mssg->code = (((uint)edges[0]) << (8*2)) | REVERSE_FLAG | pid; reverse_flag++; } else mssg->code = (((uint)edges[0]) << (8*2)) | pid; } static void push_mssg_offset_shakehands_cpu (voff_t size, int num_of_partitions, voff_t index_offset, int k, int p) { int nump = omp_get_num_procs(); #pragma omp parallel num_threads(cpu_threads) { int nth = omp_get_num_threads(); if (nth != cpu_threads) { printf ("warning: setting cpu threads failed! real number of threads: %d\n", nth); // exit(0); } voff_t size_per_th = (size + nth - 1)/nth; if (size_per_th <= nth) size_per_th = size/nth; voff_t size_th; int thid = omp_get_thread_num(); if (thid == nth-1) { size_th = size - size_per_th * (nth - 1); } else size_th = size_per_th; vertex_t * local_vs = vertices + index_offset + thid * size_per_th; voff_t * local_send_offsets = send_offsets_th + (thid+1) * (num_of_partitions+1); uint r; for(r = 0; r < size_th; r++) { int index = r; int pindex; int i; for (i = 0; i < EDGE_DIC_SIZE / 2; i++) { if ((local_vs[index].edge >> (i*8) & 0xff) >= cutoff) { local_vs[index].nbs[i] = get_adj_id_from_post (&local_vs[index].kmer, (edge_type) i, k, p, num_of_partitions); if (local_vs[index].nbs[i] < 0 || local_vs[index].nbs[i] >= num_of_partitions) { printf ("ERROR IN GETTING MSP ID!!!!!!\n"); } pindex = id2index[local_vs[index].nbs[i]]; local_send_offsets[pindex+1]++; } else local_vs[index].nbs[i] = DEADEND; if ((local_vs[index].edge >> ((EDGE_DIC_SIZE / 2 + i) * 8) & 0xff) >= cutoff) { local_vs[index].nbs[EDGE_DIC_SIZE / 2 + i] = get_adj_id_from_pre (&local_vs[index].kmer, (edge_type) i, k, p, num_of_partitions); if (local_vs[index].nbs[EDGE_DIC_SIZE / 2 + i] < 0 || local_vs[index].nbs[EDGE_DIC_SIZE / 2 + i] >= num_of_partitions) { printf ("ERROR IN GETTING MSP ID!!!!!!\n"); } pindex = id2index[local_vs[index].nbs[EDGE_DIC_SIZE / 2 + i]]; local_send_offsets[pindex+1]++; } else local_vs[index].nbs[EDGE_DIC_SIZE / 2 + i] = DEADEND; // dead end branch } } } } static void push_mssg_shakehands_cpu (voff_t size, int num_of_partitions, voff_t index_offset, int k, int p, int curr_id) { omp_set_num_threads(cpu_threads); #pragma omp parallel { int nth = omp_get_num_threads(); // printf ("PUSH MSSG OFFSET THREADS: %d!!!!!!!!!\n", nth); if (nth != cpu_threads) { printf ("warning: setting cpu threads failed! real number of threads: %d\n", nth); // exit(0); } uint size_per_th = (size + nth - 1)/nth; if (size_per_th <= nth) size_per_th = size/nth; uint size_th; int thid = omp_get_thread_num(); if (thid == nth-1) { size_th = size - size_per_th * (nth - 1); } else size_th = size_per_th; vertex_t * local_vs = vertices + index_offset + thid * size_per_th; voff_t * local_send_offsets = tmp_send_offsets_th + (thid+1) * (num_of_partitions+1); shakehands_t * buf = (shakehands_t *) send; uint r; for(r = 0; r < size_th; r++) { int index = r; int pindex; msp_id_t pid; voff_t local_offset; voff_t off; shakehands_t tmp; int i; for (i=0; i<EDGE_DIC_SIZE/2; i++) { if ((local_vs[index].edge >> (i*8) & 0xff) >= cutoff) { pid = local_vs[index].nbs[i]; if (pid < 0 || pid >= num_of_partitions) printf("ERRORRRRRRRRRRRR\n"); pindex = id2index[pid]; // local_offset = local_send_offsets[pindex+1]++; off = local_send_offsets[pindex+1] + send_offsets_th[thid*(num_of_partitions+1)+(pindex+1)] + send_offsets[pindex]; local_send_offsets[pindex+1]++; get_adj_mssg_from_post (&local_vs[index].kmer, (edge_type)i, k, (assid_t*)(&tmp), curr_id); buf[off] = tmp; } if ((local_vs[index].edge >> ((EDGE_DIC_SIZE / 2 + i) * 8) & 0xff) >= cutoff) { pid = local_vs[index].nbs[EDGE_DIC_SIZE / 2 + i]; if (pid < 0 || pid >= num_of_partitions) printf("ERRORRRRRRRRRRRR\n"); pindex = id2index[pid]; // local_offset = local_send_offsets[pindex+1]++; off = local_send_offsets[pindex+1] + send_offsets_th[thid*(num_of_partitions+1)+(pindex+1)] + send_offsets[pindex]; local_send_offsets[pindex+1]++; get_adj_mssg_from_pre (&local_vs[index].kmer, (edge_type)i, k, (assid_t*)(&tmp), curr_id); buf[off] = tmp; } } } } } static void push_mssg_offset_respond_cpu (voff_t num_mssgs, int pid, voff_t psize, voff_t index_offset, int num_of_partitions, voff_t receive_start, bool intra_inter, int k, int p) { omp_set_num_threads(cpu_threads); #pragma omp parallel { int nth = omp_get_num_threads(); if (nth != cpu_threads) { printf ("warning: setting cpu thread number failed!\n"); // exit(0); } uint size_per_th = (num_mssgs + nth - 1)/nth; if (size_per_th <= nth) size_per_th = num_mssgs/nth; uint size_th; int thid = omp_get_thread_num(); if (thid == nth-1) { size_th = num_mssgs - size_per_th * (nth - 1); } else size_th = size_per_th; shakehands_t * buf; voff_t * local_send_offsets = send_offsets_th + (thid+1) * (num_of_partitions+1); if (intra_inter) { int pindex = id2index[pid]; buf = (shakehands_t *)send + receive_start + send_offsets[pindex] + thid * size_per_th; } else { int pindex = id2index[pid]; buf = (shakehands_t *)send + receive_start + receive_offsets[pindex] + thid * size_per_th; } vertex_t * local_vs = vertices + index_offset; voff_t r; for (r=0; r<size_th; r++) { int index=r; shakehands_t tmp = buf[index]; int thid = omp_get_thread_num (); int ret = binary_search_vertex (local_vs, &buf[index].dst, psize); int match = 0; if (ret != -1) { edge_type edge = (tmp.code >> (8*2)) & 0xff; int stride; if (tmp.code >> (8*3)) { stride = EDGE_DIC_SIZE / 2; } else { stride = 0; } if ((local_vs[ret].edge >> ((stride + edge) * 8) & 0xff) < cutoff) { match = -1; } } if (ret == -1 || match == -1) { msp_id_t pid = tmp.code & ID_BITS; int pindex = id2index[pid]; local_send_offsets[pindex+1]++; } } } } static void push_mssg_respond_cpu (uint num_mssgs, int pid, voff_t psize, voff_t index_offset, int num_of_partitions, voff_t receive_start, bool intra_inter, int k, int p) { omp_set_num_threads(cpu_threads); #pragma omp parallel { int nth = omp_get_num_threads(); if (nth != cpu_threads) { printf ("warning: setting cpu thread number failed!\n"); // exit(0); } uint size_per_th = (num_mssgs + nth - 1)/nth; if (size_per_th <= nth) size_per_th = num_mssgs/nth; uint size_th; int thid = omp_get_thread_num(); if (thid == nth-1) { size_th = num_mssgs - size_per_th * (nth - 1); } else size_th = size_per_th; shakehands_t * buf; shakehands_t * vs = (shakehands_t *)receive; voff_t * local_offsets = extra_send_offsets; voff_t * local_send_offsets = tmp_send_offsets_th + (thid+1) * (num_of_partitions+1); if (intra_inter) { int pindex = id2index[pid]; buf = (shakehands_t *)send + receive_start + send_offsets[pindex] + thid * size_per_th; } else { int pindex = id2index[pid]; buf = (shakehands_t *)send + receive_start + receive_offsets[pindex] + thid * size_per_th; } vertex_t * local_vs = vertices + index_offset; voff_t r; for (r=0; r<size_th; r++) { int index=r; shakehands_t tmp = buf[index]; edge_type edge = (tmp.code >> (8*2)) & 0xff; int stride; if (tmp.code >> (8*3)) { stride = EDGE_DIC_SIZE / 2; } else { stride = 0; } int thid = omp_get_thread_num (); int mspid; int ret = binary_search_vertex (local_vs, &buf[index].dst, psize); int match = 0; if (ret != -1) { if ((local_vs[ret].edge >> ((stride + edge) * 8) & 0xff) < cutoff) { match = -1; } } if (ret == -1 || match == -1) { mspid = tmp.code & ID_BITS; if (stride == 0) get_adj_mssg_from_post (&tmp.dst, edge, k, (assid_t*)(&tmp), mspid); else get_adj_mssg_from_pre (&tmp.dst, edge, k, (assid_t*)(&tmp), mspid); int pindex = id2index[mspid]; voff_t local_send_offset = local_send_offsets[pindex+1]++; off_t off = local_send_offset + send_offsets_th[thid*(num_of_partitions+1)+(pindex+1)] + local_offsets[pindex]; vs[off] = tmp; } } } } static void pull_mssg_respond_cpu (uint num_mssgs, int pid, voff_t psize, voff_t index_offset, void * local_receive, bool intra_inter) { int pindex = id2index[pid]; shakehands_t * buf; if (intra_inter) // true if intra partitions { buf = (shakehands_t *)local_receive + extra_send_offsets[pindex]; } else { buf = (shakehands_t *)local_receive + receive_offsets[pindex]; } vertex_t * local_vs = vertices + index_offset; int r; #pragma omp parallel for num_threads(cpu_threads) for (r=0; r<num_mssgs; r++) { int index = r; int thid = omp_get_thread_num (); if (lookup_kmer_set_edge_zero_binary (&buf[index], local_vs, psize, &not_found[thid]) == -1) { printf ("RESPOND ERROR WITH SOURCE KMER: %u, %u, pindex=%d, pid=%d\n", buf[index].dst.x, buf[index].dst.y, pindex, pid); } } } static void push_mssg_offset_assign_id_cpu (voff_t size, int num_of_partitions, voff_t index_offset, int k, int p) { omp_set_num_threads(cpu_threads); #pragma omp parallel { int nth = omp_get_num_threads(); if (nth != cpu_threads) { printf ("warning: setting cpu threads failed! real number of threads: %d\n", nth); } voff_t size_per_th = (size + nth - 1)/nth; if (size_per_th <= nth) size_per_th = size/nth; voff_t size_th; int thid = omp_get_thread_num(); if (thid == nth-1) { size_th = size - size_per_th * (nth - 1); } else size_th = size_per_th; vertex_t * local_vs = vertices + index_offset + thid * size_per_th; voff_t * local_send_offsets = send_offsets_th + (thid+1) * (num_of_partitions+1); uint r; for(r = 0; r < size_th; r++) { int index = r; int pindex; int i; for (i = 0; i < EDGE_DIC_SIZE / 2; i++) { if ((local_vs[index].edge >> (i*8) & 0xff) >= cutoff) { // local_vs[index].nbs[i] = get_adj_id_from_post (&local_vs[index].kmer, (edge_type) i, k, p, num_of_partitions); if (local_vs[index].nbs[i] > num_of_partitions) { printf ("ERROR IN GETTING MSP ID!!!!!!\n"); } pindex = id2index[local_vs[index].nbs[i]]; local_send_offsets[pindex+1]++; } // else // local_vs[index].nbs[i] = DEADEND; if ((local_vs[index].edge >> ((EDGE_DIC_SIZE / 2 + i) * 8) & 0xff) >= cutoff) { // local_vs[index].nbs[EDGE_DIC_SIZE / 2 + i] = get_adj_id_from_pre (&local_vs[index].kmer, (edge_type) i, k, p, num_of_partitions); if (local_vs[index].nbs[EDGE_DIC_SIZE / 2 + i] > num_of_partitions) { printf ("ERROR IN GETTING MSP ID!!!!!!\n"); } pindex = id2index[local_vs[index].nbs[EDGE_DIC_SIZE / 2 + i]]; local_send_offsets[pindex+1]++; } // else // local_vs[index].nbs[EDGE_DIC_SIZE / 2 + i] = DEADEND; // dead end branch } } } } static void push_mssg_assign_id_cpu (uint size, int num_of_partitions, voff_t index_offset, int k, int p, int curr_id) { omp_set_num_threads(cpu_threads); #pragma omp parallel { int nth = omp_get_num_threads(); if (nth != cpu_threads) { printf ("warning: setting cpu threads failed! real number of threads: %d\n", nth); } uint size_per_th = (size + nth - 1)/nth; if (size_per_th <= nth) size_per_th = size/nth; uint size_th; int thid = omp_get_thread_num(); if (thid == nth-1) { size_th = size - size_per_th * (nth - 1); } else size_th = size_per_th; vertex_t * local_vs = vertices + index_offset + thid * size_per_th; voff_t * local_send_offsets = tmp_send_offsets_th + (thid+1) * (num_of_partitions+1); assid_t * buf = (assid_t *) send; uint r; for(r = 0; r < size_th; r++) { int index = r; int pindex; msp_id_t pid; voff_t local_offset; voff_t off; assid_t tmp; kmer_t reverse; int i; for (i=0; i<EDGE_DIC_SIZE/2; i++) { if ((local_vs[index].edge >> (i*8) & 0xff) >= cutoff) { pid = local_vs[index].nbs[i]; if (pid < 0 || pid > num_of_partitions) printf("ERRORRRRRRRRRRRR\n"); pindex = id2index[pid]; // local_offset = local_send_offsets[pindex+1]++; off = local_send_offsets[pindex+1] + send_offsets_th[thid*(num_of_partitions+1)+(pindex+1)] + send_offsets[pindex]; local_send_offsets[pindex+1]++; get_adj_mssg_from_post (&local_vs[index].kmer, (edge_type)i, k, &tmp, pid); tmp.srcid = local_vs[index].vid - 1; // **************************** BE CAREFUL HERE !!!!!!!!!!! *********************** if (tmp.srcid >= 0 && tmp.srcid < jid_offset[curr_id]) // junction send_junction++; else send_linear++; buf[off] = tmp; } if ((local_vs[index].edge >> ((EDGE_DIC_SIZE / 2 + i) * 8) & 0xff) >= cutoff) { pid = local_vs[index].nbs[EDGE_DIC_SIZE / 2 + i]; if (pid < 0 || pid > num_of_partitions) printf("ERRORRRRRRRRRRRR\n"); pindex = id2index[pid]; // local_offset = local_send_offsets[pindex+1]++; off = local_send_offsets[pindex+1] + send_offsets_th[thid*(num_of_partitions+1)+(pindex+1)] + send_offsets[pindex]; local_send_offsets[pindex+1]++; get_adj_mssg_from_pre (&local_vs[index].kmer, (edge_type)i, k, &tmp, pid); tmp.srcid = local_vs[index].vid - 1; // **************************** BE CAREFUL HERE !!!!!!!!!!! *********************** if (tmp.srcid >= 0 && tmp.srcid < jid_offset[curr_id]) // junction send_junction++; else send_linear++; buf[off] = tmp; } } } } } static void pull_mssg_assign_id_cpu (uint num_mssgs, int pid, uint psize, voff_t index_offset, int num_of_partitions, voff_t receive_start, bool intra_inter) { assid_t * buf; int pindex = id2index[pid]; if (intra_inter) buf = (assid_t *)send + receive_start + send_offsets[pindex]; else buf = (assid_t *)send + receive_start + receive_offsets[pindex]; vertex_t * local_vs = vertices + index_offset; // kmer_t * local_kmer = kmers + index_offset; int r; #pragma omp parallel for num_threads(cpu_threads) for (r=0; r<num_mssgs; r++) { int index = r; assid_t tmp = buf[index]; msp_id_t id = tmp.code & ID_BITS; // CHECK // if (id != pid) // printf ("ERROR IN ID ENCODING! id = %d, pid = %d\n", id, pid); int thid = omp_get_thread_num (); // lookup_kmer_assign_source_id_cpu (tmp, local_vs, psize, pindex, &not_found[thid]); // assign the neigbhor id for kmer tmp.dst // if (lookup_kmer_assign_source_id_cpu2 (tmp, local_vs, local_kmer, psize, pindex, &not_found[thid]) == -1) if (lookup_kmer_assign_source_id_binary (&buf[index], local_vs, psize, &not_found[thid]) == -1) { printf ("CPU KMER NOT FOUND: %u, %u, pindex=%d, pid=%d\n", tmp.dst.x, tmp.dst.y, pindex, pid); // exit(0); } } } void * neighbor_push_intra_pull_cpu (void * arg) { evaltime_t start, end; pre_arg * carg = (pre_arg *) arg; comm_t * cm = &carg->dbm->comm; master_t * mst = carg->mst; int did = carg->did; int k = carg->k; int p = carg->p; // int total_num_partitions = mst->num_partitions[num_of_cpus+num_of_devices]; int total_num_partitions = mst->total_num_partitions; int num_of_partitions = mst->num_partitions[did + 1] - mst->num_partitions[did]; int poffset = mst->num_partitions[did]; voff_t * index_offset = mst->index_offset[did]; if (mst->world_rank == 0) printf ("WORLD RANK %d: Neighboring push intra pull cpu:\n", mst->world_rank); memset(cm->send_offsets, 0, sizeof(voff_t) * (total_num_partitions + 1)); memset (send_offsets_th, 0, sizeof(voff_t) * (total_num_partitions+1) * (cpu_threads+1)); #ifdef MEASURE_TIME_ gettimeofday (&start, NULL); #endif int i; for (i=0; i<num_of_partitions; i++) { int pid = mst->partition_list[poffset+i]; voff_t size = index_offset[i+1] - index_offset[i]; push_mssg_offset_assign_id_cpu (size, total_num_partitions, index_offset[i], k, p); // a better version than above } #ifdef MEASURE_TIME_ gettimeofday (&end, NULL); push_offset_time[did] += (float)((end.tv_sec * 1000000 + end.tv_usec) - (start.tv_sec * 1000000 + start.tv_usec)) / 1000; print_exec_time (start, end, "***************** PUSH MSSG OFFSET FOR CPU *ASSIGNING ID* INTRA PROCESSOR TIME: "); #endif get_global_offsets (cm->send_offsets, send_offsets_th, total_num_partitions, (cpu_threads+1)); inclusive_prefix_sum (cm->send_offsets, total_num_partitions + 1); memset (tmp_send_offsets_th, 0, sizeof(voff_t) * (total_num_partitions+1) * (cpu_threads+1)); #ifdef MEASURE_TIME_ gettimeofday (&start, NULL); #endif for (i=0; i<num_of_partitions; i++) { int pid = mst->partition_list[poffset+i]; voff_t size = index_offset[i+1] - index_offset[i]; push_mssg_assign_id_cpu (size, total_num_partitions, index_offset[i], k, p, i); // a better version than above } #ifdef MEASURE_TIME_ gettimeofday (&end, NULL); push_time[did] += (float)((end.tv_sec * 1000000 + end.tv_usec) - (start.tv_sec * 1000000 + start.tv_usec)) / 1000; print_exec_time (start, end, "***************** PUSH MSSG FOR CPU *ASSIGNING ID* INTRA PROCESSOR TIME: "); #endif memcpy(mst->roff[did], cm->send_offsets, sizeof(voff_t)*(total_num_partitions + 1)); voff_t inter_start = mst->roff[did][num_of_partitions]; voff_t inter_end = mst->roff[did][total_num_partitions]; mst->receive[did] = (assid_t *)cm->send+inter_start; #ifndef SYNC_ALL2ALL_ if (atomic_set_value (&lock_flag[did], 1, 0) == false) printf("!!!!!!!!!!!!!!!!!! CAREFUL, SETTING VALUE DOES NOT WORK FINE!\n"); #endif memset (not_found, 0, sizeof(uint) * cpu_threads); #ifdef MEASURE_TIME_ gettimeofday (&start, NULL); #endif for (i=0; i<num_of_partitions; i++) { int pid = mst->partition_list[poffset + i]; voff_t num_mssgs = cm->send_offsets[i+1] - cm->send_offsets[i]; voff_t size = index_offset[i+1] - index_offset[i]; pull_mssg_assign_id_cpu (num_mssgs, pid, size, index_offset[i], total_num_partitions, 0, 1); // a better version } #ifdef MEASURE_TIME_ gettimeofday (&end, NULL); pull_intra_time[did] += (float)((end.tv_sec * 1000000 + end.tv_usec) - (start.tv_sec * 1000000 + start.tv_usec)) / 1000; print_exec_time (start, end, "***************** PULL MSSG FOR CPU *ASSIGNING ID* INTRA PROCESSOR TIME: "); #endif return ((void*) 0); } void * neighbor_inter_pull_cpu (void * arg) { evaltime_t start, end; pre_arg * carg = (pre_arg *) arg; comm_t * cm = &carg->dbm->comm; master_t * mst = carg->mst; int num_of_cpus = mst->num_of_cpus; int num_of_devices = mst->num_of_devices; int did = carg->did; int total_num_partitions = mst->total_num_partitions; int num_of_partitions = mst->num_partitions[did + 1] - mst->num_partitions[did]; voff_t * index_offset = mst->index_offset[did]; if (mst->world_rank == 0) printf ("WORLD RANK %d: Neighboring inter pull cpu:\n", mst->world_rank); voff_t receive_start = mst->roff[did][num_of_partitions]; memcpy(cm->receive_offsets, mst->soff[did], sizeof(voff_t) * (num_of_partitions + 1)); voff_t inter_size = mst->soff[did][num_of_partitions]; if(inter_size == 0) return ((void*) 0); memcpy((assid_t*)cm->send + receive_start, mst->send[did], sizeof(assid_t) * inter_size); int poffset = mst->num_partitions[did]; int i; #ifdef MEASURE_TIME_ gettimeofday (&start, NULL); #endif for (i=0; i<num_of_partitions; i++) { int pid = mst->partition_list[poffset + i]; voff_t num_mssgs = cm->receive_offsets[i+1] - cm->receive_offsets[i]; voff_t size = index_offset[i+1] - index_offset[i]; pull_mssg_assign_id_cpu (num_mssgs, pid, size, index_offset[i], total_num_partitions, receive_start, 0); } #ifdef MEASURE_TIME_ gettimeofday (&end, NULL); pull_inter_time[did] += (float)((end.tv_sec * 1000000 + end.tv_usec) - (start.tv_sec * 1000000 + start.tv_usec)) / 1000; print_exec_time (start, end, "***************** PULL MSSG FOR CPU *NEIGHBORING* INTER PROCESSORS TIME: "); #endif return ((void *) 0); } void * shakehands_push_respond_intra_push_cpu (void * arg) { evaltime_t start, end; pre_arg * carg = (pre_arg *) arg; comm_t * cm = &carg->dbm->comm; master_t * mst = carg->mst; int did = carg->did; int k = carg->k; int p = carg->p; int total_num_partitions = mst->total_num_partitions; int num_of_partitions = mst->num_partitions[did + 1] - mst->num_partitions[did]; int poffset = mst->num_partitions[did]; voff_t * index_offset = mst->index_offset[did]; if (mst->world_rank == 0) printf ("WORLD RANK %d: shakehands push respond intra push cpu:\n", mst->world_rank); memset(cm->send_offsets, 0, sizeof(voff_t) * (total_num_partitions + 1)); memset (send_offsets_th, 0, sizeof(voff_t) * (total_num_partitions+1) * (cpu_threads+1)); #ifdef MEASURE_TIME_ gettimeofday (&start, NULL); #endif int i; for (i=0; i<num_of_partitions; i++) { int pid = mst->partition_list[poffset+i]; voff_t size = index_offset[i+1] - index_offset[i]; push_mssg_offset_shakehands_cpu (size, total_num_partitions, index_offset[i], k, p); // a better version than above } #ifdef MEASURE_TIME_ gettimeofday (&end, NULL); push_offset_time[did] += (float)((end.tv_sec * 1000000 + end.tv_usec) - (start.tv_sec * 1000000 + start.tv_usec)) / 1000; print_exec_time (start, end, "***************** PUSH MSSG OFFSET FOR CPU *SHAKEHANDS* INTRA PROCESSOR TIME: "); #endif get_global_offsets (cm->send_offsets, send_offsets_th, total_num_partitions, (cpu_threads+1)); inclusive_prefix_sum (cm->send_offsets, total_num_partitions + 1); memset (tmp_send_offsets_th, 0, sizeof(voff_t) * (total_num_partitions+1) * (cpu_threads+1)); #ifdef MEASURE_TIME_ gettimeofday (&start, NULL); #endif for (i=0; i<num_of_partitions; i++) { int pid = mst->partition_list[poffset+i]; voff_t size = index_offset[i+1] - index_offset[i]; push_mssg_shakehands_cpu (size, total_num_partitions, index_offset[i], k, p, pid); // a better version than above } #ifdef MEASURE_TIME_ gettimeofday (&end, NULL); push_time[did] += (float)((end.tv_sec * 1000000 + end.tv_usec) - (start.tv_sec * 1000000 + start.tv_usec)) / 1000; print_exec_time (start, end, "***************** PUSH MSSG FOR CPU *SHAKEHANDS* INTRA PROCESSOR TIME: "); #endif memcpy(mst->roff[did], cm->send_offsets, sizeof(voff_t)*(total_num_partitions + 1)); voff_t inter_start = mst->roff[did][num_of_partitions]; voff_t inter_end = mst->roff[did][total_num_partitions]; mst->receive[did] = (shakehands_t *)cm->send+inter_start; #ifndef SYNC_ALL2ALL_ if (atomic_set_value (&lock_flag[did], 1, 0) == false) printf("!!!!!!!!!!!!!!!!!! CAREFUL, SETTING VALUE DOES NOT WORK FINE!\n"); #endif memset (cm->extra_send_offsets, 0, sizeof(voff_t) * (total_num_partitions+1)); memset (send_offsets_th, 0, sizeof(voff_t) * (total_num_partitions+1) * (cpu_threads+1)); memset (not_found, 0, sizeof(uint) * cpu_threads); #ifdef MEASURE_TIME_ gettimeofday (&start, NULL); #endif for (i=0; i<num_of_partitions; i++) { int pid = mst->partition_list[poffset + i]; voff_t num_mssgs = cm->send_offsets[i+1] - cm->send_offsets[i]; voff_t size = index_offset[i+1] - index_offset[i]; push_mssg_offset_respond_cpu (num_mssgs, pid, size, index_offset[i], total_num_partitions, 0, 1, k, p); // a better version } #ifdef MEASURE_TIME_ gettimeofday (&end, NULL); pull_intra_time[did] += (float)((end.tv_sec * 1000000 + end.tv_usec) - (start.tv_sec * 1000000 + start.tv_usec)) / 1000; print_exec_time (start, end, "***************** PUSH *RESPOND* OFFSET CPU INTRA PROCESSOR TIME: "); #endif return ((void*) 0); } void * shakehands_pull_respond_inter_push_intra_pull_cpu (void * arg) { evaltime_t start, end; pre_arg * carg = (pre_arg *) arg; comm_t * cm = &carg->dbm->comm; master_t * mst = carg->mst; int num_of_cpus = mst->num_of_cpus; int num_of_devices = mst->num_of_devices; int did = carg->did; int k = carg->k; int p = carg->p; int total_num_partitions = mst->total_num_partitions; int num_of_partitions = mst->num_partitions[did + 1] - mst->num_partitions[did]; int poffset = mst->num_partitions[did]; voff_t * index_offset = mst->index_offset[did]; if (mst->world_rank == 0) printf ("WORLD RANK %d: Shakehands pull respond update inter push intra pull cpu:\n", mst->world_rank); voff_t receive_start = cm->send_offsets[num_of_partitions]; memcpy(cm->receive_offsets, mst->soff[did], sizeof(voff_t) * (num_of_partitions + 1)); voff_t inter_size = cm->receive_offsets[num_of_partitions]; memcpy((shakehands_t*)(cm->send) + receive_start, mst->send[did], sizeof(shakehands_t) * inter_size); #ifdef MEASURE_TIME_ gettimeofday (&start, NULL); #endif int i; for (i=0; i<num_of_partitions; i++) { int pid = mst->partition_list[poffset + i]; voff_t num_mssgs = cm->receive_offsets[i+1] - cm->receive_offsets[i]; voff_t size = index_offset[i+1] - index_offset[i]; push_mssg_offset_respond_cpu (num_mssgs, pid, size, index_offset[i], total_num_partitions, receive_start, 0, k, p); } #ifdef MEASURE_TIME_ gettimeofday (&end, NULL); pull_inter_time[did] += (float)((end.tv_sec * 1000000 + end.tv_usec) - (start.tv_sec * 1000000 + start.tv_usec)) / 1000; print_exec_time (start, end, "*********** PUSH *RESPOND* OFFSET CPU INTER PROCESSORS TIME: "); #endif get_global_offsets (cm->extra_send_offsets, send_offsets_th, total_num_partitions, (cpu_threads+1)); inclusive_prefix_sum (cm->extra_send_offsets, total_num_partitions + 1); // *************** malloc (send and) receive buffer for pull and push mode, this is for junctions??????? voff_t rcv_size = cm->extra_send_offsets[num_of_partitions]; if (rcv_size == 0) { printf ("WORLD RANK %d: CPU::: CCCCCCCCCcccareful:::::::::: receive size from intra junction update push is 0!!!!!!!!\n", mst->world_rank); rcv_size = 1000; } malloc_pull_push_receive_cpu (cm, sizeof(shakehands_t), did, rcv_size, 2*(total_num_partitions+num_of_partitions-1)/num_of_partitions); set_pull_push_receive (cm); memset (tmp_send_offsets_th, 0, sizeof(voff_t) * (total_num_partitions+1) * (cpu_threads+1)); #ifdef MEASURE_TIME_ gettimeofday (&start, NULL); #endif for (i=0; i<num_of_partitions; i++) { int pid = mst->partition_list[poffset+i]; voff_t num_mssgs = cm->send_offsets[i+1] - cm->send_offsets[i]; voff_t size = index_offset[i+1] - index_offset[i]; push_mssg_respond_cpu (num_mssgs, pid, size, index_offset[i], total_num_partitions, 0, 1, k, p); } #ifdef MEASURE_TIME_ gettimeofday (&end, NULL); push_time[did] += (float)((end.tv_sec * 1000000 + end.tv_usec) - (start.tv_sec * 1000000 + start.tv_usec)) / 1000; print_exec_time (start, end, "************** PUSH *RESPOND* MSSG CPU INTRA PROCESSOR TIME: "); #endif #ifdef MEASURE_TIME_ gettimeofday (&start, NULL); #endif for (i=0; i<num_of_partitions; i++) { int pid = mst->partition_list[poffset+i]; voff_t num_mssgs = cm->receive_offsets[i+1] - cm->receive_offsets[i]; voff_t size = index_offset[i+1] - index_offset[i]; push_mssg_respond_cpu (num_mssgs, pid, size, index_offset[i], total_num_partitions, receive_start, 0, k, p); } #ifdef MEASURE_TIME_ gettimeofday (&end, NULL); push_time[did] += (float)((end.tv_sec * 1000000 + end.tv_usec) - (start.tv_sec * 1000000 + start.tv_usec)) / 1000; print_exec_time (start, end, "************** PUSH *RESPOND* MSSG CPU INTER PROCESSORS TIME: "); #endif memcpy(mst->roff[did], cm->extra_send_offsets, sizeof(voff_t)*(total_num_partitions + 1)); voff_t inter_start = cm->extra_send_offsets[num_of_partitions]; voff_t inter_end = cm->extra_send_offsets[total_num_partitions]; printf ("@@@@@@@@@@@@@@@@@@@@@ WORLD RANK %d:: total number of shakehands pushed in device %d: %lu\n", mst->world_rank, did, inter_end); printf ("############### WORLD RANK %d:: number of intra mssgs pulled for inter shakehands of device %d: %lu\n", mst->world_rank, did, inter_start); printf ("############### WORLD RANK %d:: number of slots malloced for receive buffer of device %d: %u\n", mst->world_rank, did, cm->temp_size/sizeof(shakehands_t)); mst->receive[did] = (shakehands_t*)(cm->receive) + inter_start; #ifndef SYNC_ALL2ALL_ if (atomic_set_value (&lock_flag[did], 1, 0) == false) printf("!!!!!!!!!!!!!!!!!! CAREFUL, SETTING VALUE DOES NOT WORK FINE!\n"); #endif #ifdef MEASURE_TIME_ gettimeofday (&start, NULL); #endif for (i=0; i<num_of_partitions; i++) { int pid = mst->partition_list[poffset + i]; voff_t num_mssgs = cm->extra_send_offsets[i+1] - cm->extra_send_offsets[i]; voff_t size = index_offset[i+1] - index_offset[i]; pull_mssg_respond_cpu (num_mssgs, pid, size, index_offset[i], cm->receive, 1); } #ifdef MEASURE_TIME_ gettimeofday (&end, NULL); pull_intra_time[did] += (float)((end.tv_sec * 1000000 + end.tv_usec) - (start.tv_sec * 1000000 + start.tv_usec)) / 1000; print_exec_time (start, end, "WORLD RANK %d ***************** PULL *RESPOND* MSSG CPU INTRA PROCESSOR TIME: ", mst->world_rank); #endif return ((void *) 0); } void * respond_inter_pull_cpu (void * arg) { evaltime_t start, end; pre_arg * carg = (pre_arg *) arg; comm_t * cm = &carg->dbm->comm; master_t * mst = carg->mst; int num_of_cpus = mst->num_of_cpus; int num_of_devices = mst->num_of_devices; int did = carg->did; int total_num_partitions = mst->total_num_partitions; int num_of_partitions = mst->num_partitions[did + 1] - mst->num_partitions[did]; voff_t * index_offset = mst->index_offset[did]; if (mst->world_rank == 0) printf ("WORLD RANK %d: respond inter pull cpu:\n", mst->world_rank); voff_t receive_start = mst->roff[did][num_of_partitions]; //cm->extra_send_offsets[num_of_partitions]; memcpy(cm->receive_offsets, mst->soff[did], sizeof(voff_t) * (num_of_partitions + 1)); voff_t inter_size = mst->soff[did][num_of_partitions]; if(inter_size == 0) return ((void*) 0); if (cm->temp_size <= (inter_size+receive_start)*sizeof(shakehands_t)) { printf("WORLD RANK %d: CPU: Error:::::::: malloced receive buffer size smaller than actual receive buffer size!\n", mst->world_rank); exit(0); } memcpy((shakehands_t*)(cm->receive) + receive_start, mst->send[did], sizeof(shakehands_t) * inter_size); printf ("############### number of inter mssgs pulled for inter shakehands of device %d: %lu\n", did, inter_size); int poffset = mst->num_partitions[did]; int i; #ifdef MEASURE_TIME_ gettimeofday (&start, NULL); #endif for (i=0; i<num_of_partitions; i++) { int pid = mst->partition_list[poffset + i]; voff_t num_mssgs = cm->receive_offsets[i+1] - cm->receive_offsets[i]; voff_t size = index_offset[i+1] - index_offset[i]; pull_mssg_respond_cpu (num_mssgs, pid, size, index_offset[i], cm->receive + sizeof(shakehands_t) * receive_start, 0); } #ifdef MEASURE_TIME_ gettimeofday (&end, NULL); pull_inter_time[did] += (float)((end.tv_sec * 1000000 + end.tv_usec) - (start.tv_sec * 1000000 + start.tv_usec)) / 1000; print_exec_time (start, end, "***************** PULL *RESPOND* MSSG FOR CPU INTER PROCESSORS TIME: "); #endif // *************** free (send and) receive buffer for pull and push mode free_pull_push_receive_cpu(cm); return ((void *) 0); } static void label_vertex_with_flags_cpu (uint size, voff_t index_offset) { vertex_t * local_vs = vertices + index_offset; voff_t * local_jvalid = jvalid + index_offset; voff_t * local_lvalid = lvalid + index_offset; uint r; #pragma omp parallel for num_threads(cpu_threads) for (r = 0; r < size; r++) { int ind = 0; int outd = 0; uint index = r; if (local_vs[index].vid == 0) continue; int i; for (i = 0; i < EDGE_DIC_SIZE / 2; i++) { if ((local_vs[index].edge >> ((EDGE_DIC_SIZE / 2 + i) * 8) & 0xff) >= cutoff) { ind++; } if ((local_vs[index].edge >> (i*8) & 0xff) >= cutoff) { outd++; } } if (ind==0 && outd==0) // filter isolated vertices { local_vs[index].vid=0; continue; } if (ind > 1 || outd > 1) { local_jvalid[index] = 1; // to pick out junction nodes } if (ind <= 1 && outd <= 1) { if (outd <= 1) { for (i = 0; i < EDGE_DIC_SIZE / 2; i++) { if ((local_vs[index].edge >> (i*8) & 0xff) >= cutoff) { break; } } if (i == EDGE_DIC_SIZE / 2) { local_jvalid[index] = 1; // set a vertex with only one edge or no edge to be a junction } } if (ind <= 1) { for (i = EDGE_DIC_SIZE / 2; i < EDGE_DIC_SIZE; i++) { if ((local_vs[index].edge >> (i*8) & 0xff) >= cutoff) { break; } } if (i == EDGE_DIC_SIZE) { local_jvalid[index] = 1; // set a vertex with only one edge or no edge to be a junction } } if (local_jvalid[index] != 1) local_lvalid[index] = 1; // a linear vertex } } } static void assid_vertex_with_flags_cpu (uint size, int pid, voff_t index_offset) { uint r; vertex_t * local_vs = vertices + index_offset; voff_t * local_jvalid = jvalid + index_offset; voff_t * local_lvalid = lvalid + index_offset; #pragma omp parallel for num_threads(cpu_threads) for (r = 0; r < size; r++) { uint index = r; bool jflag, lflag; if (index==0) { if (local_jvalid[index]) jflag = true; else jflag = false; if (local_lvalid[index]) lflag = true; else lflag = false; } else { if (local_jvalid[index] - local_jvalid[index-1]) jflag = true; else jflag = false; if (local_lvalid[index] - local_lvalid[index-1]) lflag = true; else lflag = false; } if (jflag==false && lflag==false) // empty slot { local_vs[index].vid = 0; continue; } // **************************** BE CAREFUL HERE !!!!!!!!!!! *********************** if (jflag==true) // a junction local_vs[index].vid = local_jvalid[index]; else if (lflag) // a linear vertex local_vs[index].vid = jid_offset[pid] + local_lvalid[index]; } } void * identify_vertices_cpu (void * arg) { evaltime_t start, end; pre_arg * garg = (pre_arg *) arg; master_t * mst = garg->mst; dbmeta_t * dbm = garg->dbm; int did = garg->did; if (mst->world_rank == 0) printf ("WORLD RANK %d: identifying vertices cpu %d:\n", mst->world_rank, did); int num_of_partitions = mst->num_partitions[did + 1] - mst->num_partitions[did]; voff_t * index_offset = mst->index_offset[did]; memset (dbm->lvld, 0, sizeof(vid_t) * (max_ss + 1)); int i; #ifdef MEASURE_TIME_ gettimeofday (&start, NULL); #endif for (i=0; i<num_of_partitions; i++) { int poffset = mst->num_partitions[did]; int pid = mst->partition_list[poffset+i]; voff_t size = index_offset[i+1] - index_offset[i]; label_vertex_with_flags_cpu (size, index_offset[i]); // inclusive_prefix_sum ((int *)(dbm->jvld + index_offset[i]), size); tbb_scan_uint (dbm->jvld + index_offset[i], dbm->jvld + index_offset[i], size); // inclusive_prefix_sum ((int *)(dbm->lvld + index_offset[i]), size); tbb_scan_uint (dbm->lvld + index_offset[i], dbm->lvld + index_offset[i], size); mst->jid_offset[pid] = (dbm->jvld + index_offset[i])[size-1]; mst->id_offsets[pid+1] = (dbm->jvld + index_offset[i])[size-1] + (dbm->lvld + index_offset[i])[size-1]; // pid+1, for prefix-sum later } #ifdef MEASURE_TIME_ gettimeofday (&end, NULL); print_exec_time (start, end, "&&&&&&&&&&&&&&&&&&&& IDENTIFYING IDS OF VERTICES TIME: "); #endif return ((void *)0); } void * assign_vertex_ids_cpu (void * arg) { evaltime_t start, end; pre_arg * garg = (pre_arg *) arg; master_t * mst = garg->mst; int did = garg->did; if (mst->world_rank == 0) printf ("WORLD RANK %d: Assigning vertices cpu %d:\n", mst->world_rank, did); int num_of_partitions = mst->num_partitions[did + 1] - mst->num_partitions[did]; voff_t * index_offset = mst->index_offset[did]; int i; #ifdef MEASURE_TIME_ gettimeofday (&start, NULL); #endif for (i=0; i<num_of_partitions; i++) { int poffset = mst->num_partitions[did]; int pid = mst->partition_list[poffset+i]; voff_t size = index_offset[i+1] - index_offset[i]; // assid_vertex_with_flags (size, pid, index_offset[i]); assid_vertex_with_flags_cpu (size, pid, index_offset[i]); } #ifdef MEASURE_TIME_ gettimeofday (&end, NULL); print_exec_time (start, end, "&&&&&&&&&&&&&&&&&&&& ASSIGNING IDS OF VERTICES TIME: "); #endif return ((void *)0); } static void gather_vertex_cpu (uint size, int pid, voff_t index_offset, int total_num_partitions) { vertex_t * local_vs = vertices + index_offset; uint count=0; uint dead=0; uint r; #pragma omp parallel for num_threads(cpu_threads) firstprivate(pid, size, local_vs) for (r = 0; r < size; r++) { int i; uint index = r; if (local_vs[index].vid == 0) continue; voff_t off = local_vs[index].vid - id_offsets[pid] - 1; if (local_vs[index].vid < id_offsets[pid] + 1) { printf ("Gather vertex cpu: error in vertex id and id_offsets: local_vs[%u].vid=%lu, id_offsets[%d]=%lu!\n", \ index, local_vs[index].vid, pid, id_offsets[pid]); exit(0); } if (local_vs[index].vid - id_offsets[pid] <= jid_offset[pid]) // a junction here { for (i=0; i<EDGE_DIC_SIZE; i++) { adj_nbs[i][off] = local_vs[index].nbs[i]; if (local_vs[index].nbs[i] != DEADEND) { int ppid = query_partition_id_from_idoffsets (local_vs[index].nbs[i], total_num_partitions, id_offsets); if (local_vs[index].nbs[i] - id_offsets[ppid] <= jid_offset[ppid]) count++; } else dead++; } jkmers[off] = local_vs[index].kmer; junct_edges[off] = local_vs[index].edge; } else // a linear vertex { for (i = 0; i < EDGE_DIC_SIZE / 2; i++) { if ((local_vs[index].edge >> (i*8) & 0xff) >= cutoff) { posts[off - jid_offset[pid]] = local_vs[index].nbs[i]; post_edges[off - jid_offset[pid]] = i; if (local_vs[index].nbs[i] != DEADEND) { int ppid = query_partition_id_from_idoffsets (local_vs[index].nbs[i], total_num_partitions, id_offsets); if (local_vs[index].nbs[i] - id_offsets[ppid] <= jid_offset[ppid]) count++; } else { dead++; printf ("error in gathering neighbors of linear vertices here!\n"); exit(0); } } } for (i = EDGE_DIC_SIZE / 2; i < EDGE_DIC_SIZE; i++) { if ((local_vs[index].edge >> (i*8) & 0xff) >= cutoff) { pres[off - jid_offset[pid]] = local_vs[index].nbs[i]; pre_edges[off - jid_offset[pid]] = i - EDGE_DIC_SIZE/2; if (local_vs[index].nbs[i] != DEADEND) { int ppid = query_partition_id_from_idoffsets (local_vs[index].nbs[i], total_num_partitions, id_offsets); if (local_vs[index].nbs[i] - id_offsets[ppid] <= jid_offset[ppid]) count++; } else { dead++; printf ("error in gathering neighbors of linear vertices here!\n"); exit(0); } break; } } // lkmers[off - jid_offset[pid]] = local_vs[index].kmer; } } // printf ("partition %d: number of junctions in neighbors: %u, deadend = %u, size = %u\n", pid, count, dead, size); } static void gather_vertex_partitioned (uint size, int pid, voff_t index_offset, int total_num_partitions, int k, int p, voff_t max_jsize, voff_t max_lsize) { vertex_t * local_vs = vertices + index_offset; uint count=0; uint dead=0; uint r; memset (spids, 0, sizeof(ull) * max_jsize); memset (spidsr, 0, sizeof(ull) * max_jsize); memset (spidlv, 0, sizeof(uint) * max_lsize); #pragma omp parallel for num_threads(cpu_threads) firstprivate(pid, size, local_vs) for (r = 0; r < size; r++) { int i; uint index = r; if (local_vs[index].vid == 0) continue; voff_t off = local_vs[index].vid - 1; if (local_vs[index].vid <= jid_offset[pid]) // a junction here: do not use is_junction for its <= { for (i=0; i<EDGE_DIC_SIZE / 2; i++) { if ((local_vs[index].edge >> (i*8) & 0xff) >= cutoff) { spids[off] |= (ull)(get_adj_id_from_post (&local_vs[index].kmer, (edge_type) i, k, p, total_num_partitions)) << (i*SPID_BITS); } adj_nbs[i][off] = local_vs[index].nbs[i]; } for (i=EDGE_DIC_SIZE / 2; i<EDGE_DIC_SIZE; i++) { if ((local_vs[index].edge >> (i*8) & 0xff) >= cutoff) { spidsr[off] |= (ull)(get_adj_id_from_pre (&local_vs[index].kmer, (edge_type) (i-EDGE_DIC_SIZE/2), k, p, total_num_partitions)) << ((i-EDGE_DIC_SIZE/2)*SPID_BITS); } adj_nbs[i][off] = local_vs[index].nbs[i]; } jkmers[off] = local_vs[index].kmer; junct_edges[off] = local_vs[index].edge; } else // a linear vertex { for (i = 0; i < EDGE_DIC_SIZE / 2; i++) { if ((local_vs[index].edge >> (i*8) & 0xff) >= cutoff) { spidlv[off - jid_offset[pid]] |= (get_adj_id_from_post (&local_vs[index].kmer, (edge_type) i, k, p, total_num_partitions)); posts[off - jid_offset[pid]] = local_vs[index].nbs[i]; post_edges[off - jid_offset[pid]] = i; break; } } for (i = EDGE_DIC_SIZE / 2; i < EDGE_DIC_SIZE; i++) { if ((local_vs[index].edge >> (i*8) & 0xff) >= cutoff) { spidlv[off - jid_offset[pid]] |= get_adj_id_from_pre (&local_vs[index].kmer, (edge_type) (i-EDGE_DIC_SIZE/2), k, p, total_num_partitions) << SPID_BITS; pres[off - jid_offset[pid]] = local_vs[index].nbs[i]; pre_edges[off - jid_offset[pid]] = i - EDGE_DIC_SIZE/2; break; } } } } // printf ("partition %d: number of junctions in neighbors: %u, deadend = %u, size = %u\n", pid, count, dead, size); } void * gather_vertices_cpu (void * arg) { evaltime_t start, end; pre_arg * garg = (pre_arg *) arg; master_t * mst = garg->mst; dbmeta_t * dbm = garg->dbm; d_jvs_t * js = garg->js; d_lvs_t * ls = garg->ls; int k = garg->k; int p = garg->p; subgraph_t * subgraph = garg->subgraph; int did = garg->did; if (mst->world_rank == 0) printf ("WORLD RANK %d: Assigning vertices cpu %d:\n", mst->world_rank, did); int total_num_partitions = mst->total_num_partitions; int num_of_partitions = mst->num_partitions[did + 1] - mst->num_partitions[did]; voff_t * index_offset = mst->index_offset[did]; int i; #ifdef MEASURE_TIME_ gettimeofday (&start, NULL); #endif for (i=0; i<num_of_partitions; i++) { int poffset = mst->num_partitions[did]; int pid = mst->partition_list[poffset+i]; voff_t size = index_offset[i+1] - index_offset[i]; // gather_vertex_cpu (size, pid, index_offset[i], total_num_partitions); gather_vertex_partitioned (size, pid, index_offset[i], total_num_partitions, k, p, gmax_jsize, gmax_lsize); uint jsize = mst->jid_offset[pid]; uint lsize = mst->id_offsets[pid+1] - mst->id_offsets[pid] - jsize; // write_junctions_cpu (dbm, mst, jsize, lsize, pid, total_num_partitions, did); // write_linear_vertices_cpu (dbm, mst, jsize, lsize, pid, total_num_partitions, did); output_vertices_cpu (dbm, mst, jsize, lsize, pid, total_num_partitions, did, js, ls, subgraph); write_kmers_edges_cpu (dbm, mst, jsize, lsize, pid, total_num_partitions, did); } #ifdef MEASURE_TIME_ gettimeofday (&end, NULL); print_exec_time (start, end, "CPU: &&&&&&&&&&&&&&&&&&&& ASSIGNING IDS OF VERTICES TIME: "); #endif if (mst->world_rank == 0 && mst->num_of_devices == 0) { printf ("CPU: NUMBER OF VERTICES PROCESSED: %u\n", index_offset[num_of_partitions]); printf ("CPU: number of messages sent by junction: %lu\n" "number of messages sent by linear vertices: %lu\n" "number of messages received from junction: %lu\n" "number of messages received from linear vertices: %lu\n",\ send_junction, send_linear, receive_junction, receive_linear); } // write_ids_cpu (dbm, mst, num_of_partitions, did); // print_offsets(mst->id_offsets, total_num_partitions+1); return ((void *)0); }

ark_heat1D_omp.c

/*--------------------------------------------------------------- * Programmer(s): Shelby Lockhart @ LLNL *--------------------------------------------------------------- * Based on the serial code ark_heat1D.c developed by * Daniel R. Reynolds @ SMU and parallelized with OpenMP *--------------------------------------------------------------- * SUNDIALS Copyright Start * Copyright (c) 2002-2022, Lawrence Livermore National Security * and Southern Methodist University. * All rights reserved. * * See the top-level LICENSE and NOTICE files for details. * * SPDX-License-Identifier: BSD-3-Clause * SUNDIALS Copyright End *--------------------------------------------------------------- * Example problem: * * The following test simulates a simple 1D heat equation, * u_t = k*u_xx + f * for t in [0, 10], x in [0, 1], with initial conditions * u(0,x) = 0 * Dirichlet boundary conditions, i.e. * u_t(t,0) = u_t(t,1) = 0, * and a point-source heating term, * f = 1 for x=0.5. * * The spatial derivatives are computed using second-order * centered differences, with the data distributed over N points * on a uniform spatial grid. * * This program solves the problem with either an ERK or DIRK * method. For the DIRK method, we use a Newton iteration with * the SUNPCG linear solver, and a user-supplied Jacobian-vector * product routine. * * 100 outputs are printed at equal intervals, and run statistics * are printed at the end. *---------------------------------------------------------------*/ /* Header files */ #include <stdio.h> #include <stdlib.h> #include <math.h> #include <arkode/arkode_arkstep.h> /* prototypes for ARKStep fcts., consts */ #include <nvector/nvector_openmp.h> /* OpenMP N_Vector types, fcts., macros */ #include <sunlinsol/sunlinsol_pcg.h> /* access to PCG SUNLinearSolver */ #include <sundials/sundials_types.h> /* defs. of realtype, sunindextype, etc */ #ifdef _OPENMP #include <omp.h> /* OpenMP function defs. */ #endif #if defined(SUNDIALS_EXTENDED_PRECISION) #define GSYM "Lg" #define ESYM "Le" #define FSYM "Lf" #else #define GSYM "g" #define ESYM "e" #define FSYM "f" #endif /* user data structure */ typedef struct { sunindextype N; /* number of intervals */ int nthreads; /* number of OpenMP threads */ realtype dx; /* mesh spacing */ realtype k; /* diffusion coefficient */ } *UserData; /* User-supplied Functions Called by the Solver */ static int f(realtype t, N_Vector y, N_Vector ydot, void *user_data); static int Jac(N_Vector v, N_Vector Jv, realtype t, N_Vector y, N_Vector fy, void *user_data, N_Vector tmp); /* Private function to check function return values */ static int check_flag(void *flagvalue, const char *funcname, int opt); /* Main Program */ int main(int argc, char *argv[]) { /* general problem parameters */ realtype T0 = RCONST(0.0); /* initial time */ realtype Tf = RCONST(1.0); /* final time */ int Nt = 10; /* total number of output times */ realtype rtol = 1.e-6; /* relative tolerance */ realtype atol = 1.e-10; /* absolute tolerance */ UserData udata = NULL; realtype *data; sunindextype N = 201; /* spatial mesh size */ realtype k = 0.5; /* heat conductivity */ sunindextype i; /* general problem variables */ int flag; /* reusable error-checking flag */ N_Vector y = NULL; /* empty vector for storing solution */ SUNLinearSolver LS = NULL; /* empty linear solver object */ void *arkode_mem = NULL; /* empty ARKStep memory structure */ FILE *FID, *UFID; realtype t, dTout, tout; int iout, num_threads; long int nst, nst_a, nfe, nfi, nsetups, nli, nJv, nlcf, nni, ncfn, netf; /* Create the SUNDIALS context object for this simulation */ SUNContext ctx; flag = SUNContext_Create(NULL, &ctx); if (check_flag(&flag, "SUNContext_Create", 1)) return 1; /* set the number of threads to use */ num_threads = 1; /* default value */ #ifdef _OPENMP num_threads = omp_get_max_threads(); /* overwrite with OMP_NUM_THREADS environment variable */ #endif if (argc > 1) /* overwrite with command line value, if supplied */ num_threads = (int) strtol(argv[1], NULL, 0); /* allocate and fill udata structure */ udata = (UserData) malloc(sizeof(*udata)); udata->N = N; udata->k = k; udata->dx = RCONST(1.0)/(N-1); /* mesh spacing */ udata->nthreads = num_threads; /* Initial problem output */ printf("\n1D Heat PDE test problem:\n"); printf(" N = %li\n", (long int) udata->N); printf(" diffusion coefficient: k = %"GSYM"\n", udata->k); /* Initialize data structures */ y = N_VNew_OpenMP(N, num_threads, ctx); /* Create OpenMP vector for solution */ if (check_flag((void *) y, "N_VNew_OpenMP", 0)) return 1; N_VConst(0.0, y); /* Set initial conditions */ arkode_mem = ARKStepCreate(NULL, f, T0, y, ctx); /* Create the solver memory */ if (check_flag((void *) arkode_mem, "ARKStepCreate", 0)) return 1; /* Set routines */ flag = ARKStepSetUserData(arkode_mem, (void *) udata); /* Pass udata to user functions */ if (check_flag(&flag, "ARKStepSetUserData", 1)) return 1; flag = ARKStepSetMaxNumSteps(arkode_mem, 10000); /* Increase max num steps */ if (check_flag(&flag, "ARKStepSetMaxNumSteps", 1)) return 1; flag = ARKStepSetPredictorMethod(arkode_mem, 1); /* Specify maximum-order predictor */ if (check_flag(&flag, "ARKStepSetPredictorMethod", 1)) return 1; flag = ARKStepSStolerances(arkode_mem, rtol, atol); /* Specify tolerances */ if (check_flag(&flag, "ARKStepSStolerances", 1)) return 1; /* Initialize PCG solver -- no preconditioning, with up to N iterations */ LS = SUNLinSol_PCG(y, 0, (int) N, ctx); if (check_flag((void *)LS, "SUNLinSol_PCG", 0)) return 1; /* Linear solver interface -- set user-supplied J*v routine (no 'jtsetup' required) */ flag = ARKStepSetLinearSolver(arkode_mem, LS, NULL); /* Attach linear solver to ARKStep */ if (check_flag(&flag, "ARKStepSetLinearSolver", 1)) return 1; flag = ARKStepSetJacTimes(arkode_mem, NULL, Jac); /* Set the Jacobian routine */ if (check_flag(&flag, "ARKStepSetJacTimes", 1)) return 1; /* Specify linearly implicit RHS, with non-time-dependent Jacobian */ flag = ARKStepSetLinear(arkode_mem, 0); if (check_flag(&flag, "ARKStepSetLinear", 1)) return 1; /* output mesh to disk */ FID=fopen("heat_mesh.txt","w"); for (i=0; i<N; i++) fprintf(FID," %.16"ESYM"\n", udata->dx*i); fclose(FID); /* Open output stream for results, access data array */ UFID=fopen("heat1D.txt","w"); data = N_VGetArrayPointer(y); /* output initial condition to disk */ for (i=0; i<N; i++) fprintf(UFID," %.16"ESYM"", data[i]); fprintf(UFID,"\n"); /* Main time-stepping loop: calls ARKStep to perform the integration, then prints results. Stops when the final time has been reached */ t = T0; dTout = (Tf-T0)/Nt; tout = T0+dTout; printf(" t ||u||_rms\n"); printf(" -------------------------\n"); printf(" %10.6"FSYM" %10.6f\n", t, sqrt(N_VDotProd(y,y)/N)); for (iout=0; iout<Nt; iout++) { flag = ARKStepEvolve(arkode_mem, tout, y, &t, ARK_NORMAL); /* call integrator */ if (check_flag(&flag, "ARKStepEvolve", 1)) break; printf(" %10.6"FSYM" %10.6f\n", t, sqrt(N_VDotProd(y,y)/N)); /* print solution stats */ if (flag >= 0) { /* successful solve: update output time */ tout += dTout; tout = (tout > Tf) ? Tf : tout; } else { /* unsuccessful solve: break */ fprintf(stderr,"Solver failure, stopping integration\n"); break; } /* output results to disk */ for (i=0; i<N; i++) fprintf(UFID," %.16"ESYM"", data[i]); fprintf(UFID,"\n"); } printf(" -------------------------\n"); fclose(UFID); /* Print some final statistics */ flag = ARKStepGetNumSteps(arkode_mem, &nst); check_flag(&flag, "ARKStepGetNumSteps", 1); flag = ARKStepGetNumStepAttempts(arkode_mem, &nst_a); check_flag(&flag, "ARKStepGetNumStepAttempts", 1); flag = ARKStepGetNumRhsEvals(arkode_mem, &nfe, &nfi); check_flag(&flag, "ARKStepGetNumRhsEvals", 1); flag = ARKStepGetNumLinSolvSetups(arkode_mem, &nsetups); check_flag(&flag, "ARKStepGetNumLinSolvSetups", 1); flag = ARKStepGetNumErrTestFails(arkode_mem, &netf); check_flag(&flag, "ARKStepGetNumErrTestFails", 1); flag = ARKStepGetNumNonlinSolvIters(arkode_mem, &nni); check_flag(&flag, "ARKStepGetNumNonlinSolvIters", 1); flag = ARKStepGetNumNonlinSolvConvFails(arkode_mem, &ncfn); check_flag(&flag, "ARKStepGetNumNonlinSolvConvFails", 1); flag = ARKStepGetNumLinIters(arkode_mem, &nli); check_flag(&flag, "ARKStepGetNumLinIters", 1); flag = ARKStepGetNumJtimesEvals(arkode_mem, &nJv); check_flag(&flag, "ARKStepGetNumJtimesEvals", 1); flag = ARKStepGetNumLinConvFails(arkode_mem, &nlcf); check_flag(&flag, "ARKStepGetNumLinConvFails", 1); printf("\nFinal Solver Statistics:\n"); printf(" Internal solver steps = %li (attempted = %li)\n", nst, nst_a); printf(" Total RHS evals: Fe = %li, Fi = %li\n", nfe, nfi); printf(" Total linear solver setups = %li\n", nsetups); printf(" Total linear iterations = %li\n", nli); printf(" Total number of Jacobian-vector products = %li\n", nJv); printf(" Total number of linear solver convergence failures = %li\n", nlcf); printf(" Total number of Newton iterations = %li\n", nni); printf(" Total number of nonlinear solver convergence failures = %li\n", ncfn); printf(" Total number of error test failures = %li\n", netf); /* Clean up and return with successful completion */ N_VDestroy(y); /* Free vectors */ free(udata); /* Free user data */ ARKStepFree(&arkode_mem); /* Free integrator memory */ SUNLinSolFree(LS); /* Free linear solver */ SUNContext_Free(&ctx); /* Free context */ return 0; } /*-------------------------------- * Functions called by the solver *--------------------------------*/ /* f routine to compute the ODE RHS function f(t,y). */ static int f(realtype t, N_Vector y, N_Vector ydot, void *user_data) { UserData udata = (UserData) user_data; /* access problem data */ sunindextype N = udata->N; /* set variable shortcuts */ realtype k = udata->k; realtype dx = udata->dx; realtype *Y=NULL, *Ydot=NULL; realtype c1, c2; sunindextype i = 0; sunindextype isource; Y = N_VGetArrayPointer(y); /* access data arrays */ if (check_flag((void *) Y, "N_VGetArrayPointer", 0)) return 1; Ydot = N_VGetArrayPointer(ydot); if (check_flag((void *) Ydot, "N_VGetArrayPointer", 0)) return 1; N_VConst(0.0, ydot); /* Initialize ydot to zero */ /* iterate over domain, computing all equations */ c1 = k/dx/dx; c2 = -RCONST(2.0)*k/dx/dx; isource = N/2; Ydot[0] = 0.0; /* left boundary condition */ #pragma omp parallel for default(shared) private(i) schedule(static) num_threads(udata->nthreads) for (i=1; i<N-1; i++) Ydot[i] = c1*Y[i-1] + c2*Y[i] + c1*Y[i+1]; Ydot[N-1] = 0.0; /* right boundary condition */ Ydot[isource] += 0.01/dx; /* source term */ return 0; /* Return with success */ } /* Jacobian routine to compute J(t,y) = df/dy. */ static int Jac(N_Vector v, N_Vector Jv, realtype t, N_Vector y, N_Vector fy, void *user_data, N_Vector tmp) { UserData udata = (UserData) user_data; /* variable shortcuts */ sunindextype N = udata->N; realtype k = udata->k; realtype dx = udata->dx; realtype *V=NULL, *JV=NULL; realtype c1, c2; sunindextype i = 0; V = N_VGetArrayPointer(v); /* access data arrays */ if (check_flag((void *) V, "N_VGetArrayPointer", 0)) return 1; JV = N_VGetArrayPointer(Jv); if (check_flag((void *) JV, "N_VGetArrayPointer", 0)) return 1; N_VConst(0.0, Jv); /* initialize Jv product to zero */ /* iterate over domain, computing all Jacobian-vector products */ c1 = k/dx/dx; c2 = -RCONST(2.0)*k/dx/dx; JV[0] = 0.0; #pragma omp parallel for default(shared) private(i) schedule(static) num_threads(udata->nthreads) for (i=1; i<N-1; i++) JV[i] = c1*V[i-1] + c2*V[i] + c1*V[i+1]; JV[N-1] = 0.0; return 0; /* Return with success */ } /*------------------------------- * Private helper functions *-------------------------------*/ /* Check function return value... opt == 0 means SUNDIALS function allocates memory so check if returned NULL pointer opt == 1 means SUNDIALS function returns a flag so check if flag >= 0 opt == 2 means function allocates memory so check if returned NULL pointer */ static int check_flag(void *flagvalue, const char *funcname, int opt) { int *errflag; /* Check if SUNDIALS function returned NULL pointer - no memory allocated */ if (opt == 0 && flagvalue == NULL) { fprintf(stderr, "\nSUNDIALS_ERROR: %s() failed - returned NULL pointer\n\n", funcname); return 1; } /* Check if flag < 0 */ else if (opt == 1) { errflag = (int *) flagvalue; if (*errflag < 0) { fprintf(stderr, "\nSUNDIALS_ERROR: %s() failed with flag = %d\n\n", funcname, *errflag); return 1; }} /* Check if function returned NULL pointer - no memory allocated */ else if (opt == 2 && flagvalue == NULL) { fprintf(stderr, "\nMEMORY_ERROR: %s() failed - returned NULL pointer\n\n", funcname); return 1; } return 0; } /*---- end of file ----*/

otfft_eightstep.h

// Copyright (c) 2015, OK おじさん(岡久卓也) // Copyright (c) 2015, OK Ojisan(Takuya OKAHISA) // Copyright (c) 2017 to the present, DEWETRON GmbH // OTFFT Implementation Version 9.5 // based on Stockham FFT algorithm // from OK Ojisan(Takuya OKAHISA), source: http://www.moon.sannet.ne.jp/okahisa/stockham/stockham.html #pragma once #include "otfft_types.h" namespace OTFFT_NAMESPACE { namespace OTFFT_Eightstep { ///////////////////////////////////////////////////// using namespace OTFFT; using namespace OTFFT_MISC; using OTFFT_Sixstep::weight_t; using OTFFT_Sixstep::const_index_vector; static const int OMP_THRESHOLD1 = 1<<13; static const int OMP_THRESHOLD2 = 1<<16; /////////////////////////////////////////////////////////////////////////////// template <int log_N, int mode> struct fwdfftr { static const int N = 1 << log_N; static const int N0 = 0; static const int N1 = N/8; static const int N2 = N1*2; static const int N3 = N1*3; static const int N4 = N1*4; static const int N5 = N1*5; static const int N6 = N1*6; static const int N7 = N1*7; static inline void transpose_kernel( const int p, complex_vector x, complex_vector y) noexcept { const ymm aA = getpz2(x+p+N0); const ymm bB = getpz2(x+p+N1); const ymm cC = getpz2(x+p+N2); const ymm dD = getpz2(x+p+N3); const ymm eE = getpz2(x+p+N4); const ymm fF = getpz2(x+p+N5); const ymm gG = getpz2(x+p+N6); const ymm hH = getpz2(x+p+N7); const ymm ab = catlo(aA, bB); const ymm AB = cathi(aA, bB); const ymm cd = catlo(cC, dD); const ymm CD = cathi(cC, dD); const ymm ef = catlo(eE, fF); const ymm EF = cathi(eE, fF); const ymm gh = catlo(gG, hH); const ymm GH = cathi(gG, hH); setpz2(y+8*p+ 0, ab); setpz2(y+8*p+ 2, cd); setpz2(y+8*p+ 4, ef); setpz2(y+8*p+ 6, gh); setpz2(y+8*p+ 8, AB); setpz2(y+8*p+10, CD); setpz2(y+8*p+12, EF); setpz2(y+8*p+14, GH); } static inline void fft_and_mult_twiddle_factor_kernel( const int p, complex_vector x, complex_vector y, weight_t W) noexcept { const ymm w1p = getpz2(W+p); const ymm w2p = mulpz2(w1p, w1p); const ymm w3p = mulpz2(w1p, w2p); const ymm w4p = mulpz2(w2p, w2p); const ymm w5p = mulpz2(w2p, w3p); const ymm w6p = mulpz2(w3p, w3p); const ymm w7p = mulpz2(w3p, w4p); const ymm x0 = scalepz2<N,mode>(getpz2(x+p+N0)); const ymm x1 = scalepz2<N,mode>(getpz2(x+p+N1)); const ymm x2 = scalepz2<N,mode>(getpz2(x+p+N2)); const ymm x3 = scalepz2<N,mode>(getpz2(x+p+N3)); const ymm x4 = scalepz2<N,mode>(getpz2(x+p+N4)); const ymm x5 = scalepz2<N,mode>(getpz2(x+p+N5)); const ymm x6 = scalepz2<N,mode>(getpz2(x+p+N6)); const ymm x7 = scalepz2<N,mode>(getpz2(x+p+N7)); const ymm a04 = addpz2(x0, x4); const ymm s04 = subpz2(x0, x4); const ymm a26 = addpz2(x2, x6); const ymm js26 = jxpz2(subpz2(x2, x6)); const ymm a15 = addpz2(x1, x5); const ymm s15 = subpz2(x1, x5); const ymm a37 = addpz2(x3, x7); const ymm js37 = jxpz2(subpz2(x3, x7)); const ymm a04_p1_a26 = addpz2(a04, a26); const ymm s04_mj_s26 = subpz2(s04, js26); const ymm a04_m1_a26 = subpz2(a04, a26); const ymm s04_pj_s26 = addpz2(s04, js26); const ymm a15_p1_a37 = addpz2(a15, a37); const ymm w8_s15_mj_s37 = w8xpz2(subpz2(s15, js37)); const ymm j_a15_m1_a37 = jxpz2(subpz2(a15, a37)); const ymm v8_s15_pj_s37 = v8xpz2(addpz2(s15, js37)); setpz2(y+p+N0, addpz2(a04_p1_a26, a15_p1_a37)); setpz2(y+p+N1, mulpz2(w1p, addpz2(s04_mj_s26, w8_s15_mj_s37))); setpz2(y+p+N2, mulpz2(w2p, subpz2(a04_m1_a26, j_a15_m1_a37))); setpz2(y+p+N3, mulpz2(w3p, subpz2(s04_pj_s26, v8_s15_pj_s37))); setpz2(y+p+N4, mulpz2(w4p, subpz2(a04_p1_a26, a15_p1_a37))); setpz2(y+p+N5, mulpz2(w5p, subpz2(s04_mj_s26, w8_s15_mj_s37))); setpz2(y+p+N6, mulpz2(w6p, addpz2(a04_m1_a26, j_a15_m1_a37))); setpz2(y+p+N7, mulpz2(w7p, addpz2(s04_pj_s26, v8_s15_pj_s37))); } void operator()(const_index_vector ip, complex_vector x, complex_vector y, weight_t W, weight_t Ws) const noexcept { if (N < OMP_THRESHOLD1) { for (int p = 0; p < N1; p += 2) { fft_and_mult_twiddle_factor_kernel(p, x, y, W); } OTFFT_Sixstep::fwdffts8<log_N-3,scale_1,1>()(ip, y+N0, x+N0, W, Ws); OTFFT_Sixstep::fwdffts8<log_N-3,scale_1,1>()(ip, y+N1, x+N1, W, Ws); OTFFT_Sixstep::fwdffts8<log_N-3,scale_1,1>()(ip, y+N2, x+N2, W, Ws); OTFFT_Sixstep::fwdffts8<log_N-3,scale_1,1>()(ip, y+N3, x+N3, W, Ws); OTFFT_Sixstep::fwdffts8<log_N-3,scale_1,1>()(ip, y+N4, x+N4, W, Ws); OTFFT_Sixstep::fwdffts8<log_N-3,scale_1,1>()(ip, y+N5, x+N5, W, Ws); OTFFT_Sixstep::fwdffts8<log_N-3,scale_1,1>()(ip, y+N6, x+N6, W, Ws); OTFFT_Sixstep::fwdffts8<log_N-3,scale_1,1>()(ip, y+N7, x+N7, W, Ws); for (int p = 0; p < N1; p += 2) { transpose_kernel(p, y, x); } } else if (N < OMP_THRESHOLD2) #pragma omp parallel firstprivate(x,y,W,Ws) { #pragma omp for schedule(guided) for (int p = 0; p < N1; p += 2) { fft_and_mult_twiddle_factor_kernel(p, x, y, W); } #pragma omp for schedule(static) for (int i = 0; i < 8; i++) { OTFFT_Sixstep::fwdffts8<log_N-3,scale_1,1>()(ip, y+i*N1, x+i*N1, W, Ws); } #pragma omp for schedule(static) for (int p = 0; p < N1; p += 2) { transpose_kernel(p, y, x); } } else { #pragma omp parallel for schedule(guided) firstprivate(x,y,W) for (int p = 0; p < N1; p += 2) { fft_and_mult_twiddle_factor_kernel(p, x, y, W); } OTFFT_Sixstep::fwdffts8<log_N-3,scale_1>()(ip, y+N0, x+N0, W, Ws); OTFFT_Sixstep::fwdffts8<log_N-3,scale_1>()(ip, y+N1, x+N1, W, Ws); OTFFT_Sixstep::fwdffts8<log_N-3,scale_1>()(ip, y+N2, x+N2, W, Ws); OTFFT_Sixstep::fwdffts8<log_N-3,scale_1>()(ip, y+N3, x+N3, W, Ws); OTFFT_Sixstep::fwdffts8<log_N-3,scale_1>()(ip, y+N4, x+N4, W, Ws); OTFFT_Sixstep::fwdffts8<log_N-3,scale_1>()(ip, y+N5, x+N5, W, Ws); OTFFT_Sixstep::fwdffts8<log_N-3,scale_1>()(ip, y+N6, x+N6, W, Ws); OTFFT_Sixstep::fwdffts8<log_N-3,scale_1>()(ip, y+N7, x+N7, W, Ws); #pragma omp parallel for schedule(static) firstprivate(x,y) for (int p = 0; p < N1; p += 2) { transpose_kernel(p, y, x); } } } }; /////////////////////////////////////////////////////////////////////////////// template <int log_N, int mode> struct invfftr { static const int N = 1 << log_N; static const int N0 = 0; static const int N1 = N/8; static const int N2 = N1*2; static const int N3 = N1*3; static const int N4 = N1*4; static const int N5 = N1*5; static const int N6 = N1*6; static const int N7 = N1*7; static inline void transpose_kernel( const int p, complex_vector x, complex_vector y) noexcept { fwdfftr<log_N,mode>::transpose_kernel(p, x, y); } static inline void fft_and_mult_twiddle_factor_kernel( const int p, complex_vector x, complex_vector y, weight_t W) noexcept { const ymm w1p = cnjpz2(getpz2(W+p)); const ymm w2p = mulpz2(w1p, w1p); const ymm w3p = mulpz2(w1p, w2p); const ymm w4p = mulpz2(w2p, w2p); const ymm w5p = mulpz2(w2p, w3p); const ymm w6p = mulpz2(w3p, w3p); const ymm w7p = mulpz2(w3p, w4p); const ymm x0 = scalepz2<N,mode>(getpz2(x+p+N0)); const ymm x1 = scalepz2<N,mode>(getpz2(x+p+N1)); const ymm x2 = scalepz2<N,mode>(getpz2(x+p+N2)); const ymm x3 = scalepz2<N,mode>(getpz2(x+p+N3)); const ymm x4 = scalepz2<N,mode>(getpz2(x+p+N4)); const ymm x5 = scalepz2<N,mode>(getpz2(x+p+N5)); const ymm x6 = scalepz2<N,mode>(getpz2(x+p+N6)); const ymm x7 = scalepz2<N,mode>(getpz2(x+p+N7)); const ymm a04 = addpz2(x0, x4); const ymm s04 = subpz2(x0, x4); const ymm a26 = addpz2(x2, x6); const ymm js26 = jxpz2(subpz2(x2, x6)); const ymm a15 = addpz2(x1, x5); const ymm s15 = subpz2(x1, x5); const ymm a37 = addpz2(x3, x7); const ymm js37 = jxpz2(subpz2(x3, x7)); const ymm a04_p1_a26 = addpz2(a04, a26); const ymm s04_pj_s26 = addpz2(s04, js26); const ymm a04_m1_a26 = subpz2(a04, a26); const ymm s04_mj_s26 = subpz2(s04, js26); const ymm a15_p1_a37 = addpz2(a15, a37); const ymm v8_s15_pj_s37 = v8xpz2(addpz2(s15, js37)); const ymm j_a15_m1_a37 = jxpz2(subpz2(a15, a37)); const ymm w8_s15_mj_s37 = w8xpz2(subpz2(s15, js37)); setpz2(y+p+N0, addpz2(a04_p1_a26, a15_p1_a37)); setpz2(y+p+N1, mulpz2(w1p, addpz2(s04_pj_s26, v8_s15_pj_s37))); setpz2(y+p+N2, mulpz2(w2p, addpz2(a04_m1_a26, j_a15_m1_a37))); setpz2(y+p+N3, mulpz2(w3p, subpz2(s04_mj_s26, w8_s15_mj_s37))); setpz2(y+p+N4, mulpz2(w4p, subpz2(a04_p1_a26, a15_p1_a37))); setpz2(y+p+N5, mulpz2(w5p, subpz2(s04_pj_s26, v8_s15_pj_s37))); setpz2(y+p+N6, mulpz2(w6p, subpz2(a04_m1_a26, j_a15_m1_a37))); setpz2(y+p+N7, mulpz2(w7p, addpz2(s04_mj_s26, w8_s15_mj_s37))); } void operator()(const_index_vector ip, complex_vector x, complex_vector y, weight_t W, weight_t Ws) const noexcept { if (N < OMP_THRESHOLD1) { for (int p = 0; p < N1; p += 2) { fft_and_mult_twiddle_factor_kernel(p, x, y, W); } OTFFT_Sixstep::invffts8<log_N-3,scale_1,1>()(ip, y+N0, x+N0, W, Ws); OTFFT_Sixstep::invffts8<log_N-3,scale_1,1>()(ip, y+N1, x+N1, W, Ws); OTFFT_Sixstep::invffts8<log_N-3,scale_1,1>()(ip, y+N2, x+N2, W, Ws); OTFFT_Sixstep::invffts8<log_N-3,scale_1,1>()(ip, y+N3, x+N3, W, Ws); OTFFT_Sixstep::invffts8<log_N-3,scale_1,1>()(ip, y+N4, x+N4, W, Ws); OTFFT_Sixstep::invffts8<log_N-3,scale_1,1>()(ip, y+N5, x+N5, W, Ws); OTFFT_Sixstep::invffts8<log_N-3,scale_1,1>()(ip, y+N6, x+N6, W, Ws); OTFFT_Sixstep::invffts8<log_N-3,scale_1,1>()(ip, y+N7, x+N7, W, Ws); for (int p = 0; p < N1; p += 2) { transpose_kernel(p, y, x); } } else if (N < OMP_THRESHOLD2) #pragma omp parallel firstprivate(x,y,W,Ws) { #pragma omp for schedule(guided) for (int p = 0; p < N1; p += 2) { fft_and_mult_twiddle_factor_kernel(p, x, y, W); } #pragma omp for schedule(static) for (int i = 0; i < 8; i++) { OTFFT_Sixstep::invffts8<log_N-3,scale_1,1>()(ip, y+i*N1, x+i*N1, W, Ws); } #pragma omp for schedule(static) for (int p = 0; p < N1; p += 2) { transpose_kernel(p, y, x); } } else { #pragma omp parallel for schedule(guided) firstprivate(x,y,W) for (int p = 0; p < N1; p += 2) { fft_and_mult_twiddle_factor_kernel(p, x, y, W); } OTFFT_Sixstep::invffts8<log_N-3,scale_1>()(ip, y+N0, x+N0, W, Ws); OTFFT_Sixstep::invffts8<log_N-3,scale_1>()(ip, y+N1, x+N1, W, Ws); OTFFT_Sixstep::invffts8<log_N-3,scale_1>()(ip, y+N2, x+N2, W, Ws); OTFFT_Sixstep::invffts8<log_N-3,scale_1>()(ip, y+N3, x+N3, W, Ws); OTFFT_Sixstep::invffts8<log_N-3,scale_1>()(ip, y+N4, x+N4, W, Ws); OTFFT_Sixstep::invffts8<log_N-3,scale_1>()(ip, y+N5, x+N5, W, Ws); OTFFT_Sixstep::invffts8<log_N-3,scale_1>()(ip, y+N6, x+N6, W, Ws); OTFFT_Sixstep::invffts8<log_N-3,scale_1>()(ip, y+N7, x+N7, W, Ws); #pragma omp parallel for schedule(static) firstprivate(x,y) for (int p = 0; p < N1; p += 2) { transpose_kernel(p, y, x); } } } }; } ///////////////////////////////////////////////////////////////////////////// }

laplace.c

#include <stdlib.h> #include <stdio.h> #include <math.h> #include <sys/time.h> #define WIDTH 1000 #define HEIGHT 1000 #define TEMP_TOLERANCE 0.01 double Temperature[HEIGHT+2][WIDTH+2]; double Temperature_previous[HEIGHT+2][WIDTH+2]; void initialize(); void track_progress(int iter); int main(int argc, char *argv[]) { int i, j; int iteration = 1; double worst_dt = 100; struct timeval start_time, stop_time, elapsed_time; gettimeofday(&start_time, NULL); initialize(); while (worst_dt > TEMP_TOLERANCE) { #pragma omp parallel for private(i, j) for (i = 1; i <= HEIGHT; i++) { for (j = 1; j <= WIDTH; j++) { Temperature[i][j] = 0.25 * (Temperature_previous[i+1][j] + Temperature_previous[i-1][j] + Temperature_previous[i][j+1] + Temperature_previous[i][j-1]); } } worst_dt = 0.0; #pragma omp parallel for reduction(max:worst_dt) private(i,j) for (i = 1; i <= HEIGHT; i++) { for (j = 1; j <= WIDTH; j++) { worst_dt = fmax(fabs(Temperature[i][j] - Temperature_previous[i][j]), worst_dt); Temperature_previous[i][j] = Temperature[i][j]; } } if ((iteration % 100) == 0) { track_progress(iteration); } iteration++; } gettimeofday(&stop_time, NULL); timersub(&stop_time, &start_time, &elapsed_time); printf("\nMax error at iteration %d was %f\n", iteration-1, worst_dt); printf("Total time was %f seconds.\n", elapsed_time.tv_sec+elapsed_time.tv_usec/1000000.0); } void initialize() { int i, j; for (i = 0; i < HEIGHT+1; i++) { for (j = 0; j < WIDTH+1; j++) { Temperature_previous[i][j] = 0.0; } } for (i = 0; i < HEIGHT+1; i++) { Temperature_previous[i][0] = 0.0; Temperature_previous[i][WIDTH+1] = (100.0/HEIGHT) * i; } for (j = 0; j < WIDTH+1; j++) { Temperature_previous[0][j] = 0; Temperature_previous[HEIGHT+1][j] = (100.0/WIDTH)*j; } } void track_progress(int iteration) { int i; printf("---------- Iteration number: %d ----------\n", iteration); for (i = HEIGHT-5; i <= HEIGHT; i++) { printf("[%d,%d]: %5.2f ", i, i, Temperature[i][i]); } printf("\n"); }

spgsolver.h

/* Algorithm for Steiner Problem in Graphs Copyright (c) Microsoft Corporation All rights reserved. MIT License Permission is hereby granted, free of charge, to any person obtaining a copy of this software and associated documentation files (the "Software"), to deal in the Software without restriction, including without limitation the rights to use, copy, modify, merge, publish, distribute, sublicense, and/or sell copies of the Software, and to permit persons to whom the Software is furnished to do so, subject to the following conditions: The above copyright notice and this permission notice shall be included in all copies or substantial portions of the Software. THE SOFTWARE IS PROVIDED *AS IS*, WITHOUT WARRANTY OF ANY KIND, EXPRESS OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE. */ #pragma once #include <cstdint> #include <cstdio> #include <cstdlib> #include <iostream> #include <iomanip> #include <fstream> #include <vector> #include <algorithm> #include "binheap.h" #include "graph.h" #include "solution.h" #include "rfw_timer.h" #include "uf.h" #include "uset.h" #include "voronoi.h" #include "rfw_random.h" #include "rfw_stack.h" #include "drawer.h" #include "dual.h" #include "stedgelinear.h" #include "pairheap.h" #include "buckets.h" #include <cstring> #include <cmath> #include "elite.h" #include "spgconfig.h" #include <omp.h> #include "constructive.h" #include "execution_log.h" #include "LSVertexInsertion.h" #include "LSVertexElimination.h" #include "LSBasics.h" #include "LSKeyPath.h" #include "BranchBound.h" #include "perturbation.h" #include "preprocess.h" using namespace std; class SPGSolver { private: static void fatal (const string &msg) { fprintf (stderr, "ERROR: %s.\n", msg.c_str()); fflush(stderr); exit(-1); } static void warning (const string &msg) { fprintf (stderr, "%s", msg.c_str()); fflush(stderr); } /* static void ShowUsage() { fprintf (stderr, "Usage: steiner <filename> <upper bound> [-prep 1] [-seed <s>]\n"); }*/ static void ExtractFilename (char *filename, char *name) { strcpy (name, filename); //fprintf (stderr, "<%s> ", name); //exit(-1); char *lastsep = NULL; char *lastdot = NULL; char *end = &name[strlen(name)]; char *p = name; for (p=name; p<=end; p++) { if (*p=='/' || *p=='\\') lastsep = p; if (*p=='.') lastdot = p; } if (lastsep == NULL) { lastsep = name; } else { lastsep ++; } if (lastdot == NULL) { lastdot = end; } // avoid weird cases if (lastdot <= lastsep) { lastdot = end; lastsep = name; } *lastdot = 0; int i = 0; while (1) { name[i] = *lastsep; if (name[i] == 0) break; i++; lastsep ++; } //fprintf (file, "graph %s\n", lastsep); //fprintf (file, "graph %s\n", name); //delete [] name; } static void OutputGraphStats (FILE *file, Graph &g, char *filename) { fprintf (file, "file %s\n", filename); fprintf (file, "nvertices %d\n", g.VertexCount()); fprintf (file, "nedges %d\n", g.EdgeCount()); fprintf (file, "nterminals %d\n", g.TerminalCount()); } public: static EdgeCost ReadBound(FILE *logfile, char *graphname) { EdgeCost answer = -1; FILE *file = fopen ("bounds.txt", "r"); if (!file) { fprintf (stderr, "Could not find bounds file.\n"); fflush (stderr); return answer; } fprintf (stderr, "Reading bounds file... "); fflush (stderr); double solution; const int BUFSIZE = 65534; //1048574; char buffer [BUFSIZE+2]; char bufseries [BUFSIZE+2]; char bufclass [BUFSIZE+2]; char bufinstance [BUFSIZE+2]; sprintf (bufseries, "undefined"); sprintf (bufclass, "undefined"); while (fgets(buffer, BUFSIZE, file)!=0) { //fprintf (stderr, "<%s> ", buffer); if (sscanf (buffer, "#series %s", bufseries) > 0) { continue; } if (sscanf (buffer, "#class %s", bufclass) > 0) { continue; } if (sscanf (buffer, "%s %lg", bufinstance, &solution)>0) { if (strcmp (bufinstance, graphname) == 0) { answer = (EdgeCost)solution; fprintf (logfile, "instance %s\n", graphname); fprintf (logfile, "series %s\n", bufseries); fprintf (logfile, "class %s\n", bufclass); fprintf (logfile, "bestknown %.20f\n", (double)solution); } } } fclose(file); //fprintf (stderr, "done (solution is %.0f).\n", (double)answer); //fflush (stderr); return answer; } typedef enum { MS_PLAIN, MS_COMBINATION, MS_BINARY, MS_MULTILEVEL, MS_TIMEBOUNDEDCOMBINATION, MS_TIMEBOUNDEDMULTILEVEL, MS_TIMEBOUNDEDADAPTIVE, MS_NUMBER } MSType; static void ShowUsage () { fprintf (stderr, "Usage: steiner <stp_file> [-bb] [-ub] [-prep] [-msit] [-seed] [-mstype]\n"); fprintf (stderr, "Valid types: plain(%d) combination(%d) binary(%d) multilevel(%d)\n", MS_PLAIN, MS_COMBINATION, MS_BINARY, MS_MULTILEVEL); exit (-1); } static void RunMultistart(Graph &g, int mstype, int msit, EdgeCost &gbestfound, EdgeCost &bestknown, SteinerConfig &config, char *name, GlobalInfo *ginfo, ExecutionLog *executionLogPtr, SteinerSolution *outSolution) { double mstime = 0; EdgeCost mscost = g.GetFixedCost(); int elite = -1; EdgeCost bestfound = gbestfound; if (g.EdgeCount()>0 && g.TerminalCount()>1) { fprintf(stderr, "MULTISTARTING WITH %d\n", mstype); mscost = INFINITE_COST; // If the multistart type is the time bounded combination multistart type, do not do the // incremental number of iterations. if (mstype == MS_TIMEBOUNDEDCOMBINATION || mstype == MS_TIMEBOUNDEDMULTILEVEL || mstype == MS_TIMEBOUNDEDADAPTIVE) { SteinerSolution solution(&g); RFWTimer mstimer(true); TimeBoundedMultistart(solution, mstype, msit, config.OUTPUT_INCUMBENT ? name : NULL, -1, &config, ginfo, executionLogPtr); mstime = mstimer.getTime(); if (outSolution != nullptr) { outSolution->CopyFrom(&solution); mscost = solution.GetCost(); } } else { int doneit = 0; for (int maxit = (config.TIME_LIMIT <= 0 ? (msit <= 0 ? 2 : msit) : 2); (msit <= 0 || doneit < msit) && (config.TIME_LIMIT <= 0 || executionLogPtr->timerPtr->getTime() < config.TIME_LIMIT); maxit *= 2) { SteinerSolution solution(&g); int curit = maxit; if (msit > 0 && doneit + maxit > msit) curit = msit - doneit; fprintf(stderr, "RUNNING %d ITERATIONS (%d ALREADY DONE IN %.2f SEC).\n", curit, doneit, executionLogPtr->timerPtr->getTime()); RFWTimer mstimer(true); switch (mstype) { case MS_PLAIN: PlainMultistart(solution, curit, -1, &config); break; case MS_COMBINATION: CombinationMultistart(solution, curit, elite, config.OUTPUT_INCUMBENT ? name : NULL, -1, &config, ginfo, executionLogPtr); break; case MS_BINARY: BinaryMultistart(solution, curit, name, &config); break; case MS_MULTILEVEL: MultilevelMultistart(solution, curit, curit, elite, config.OUTPUT_INCUMBENT ? name : NULL, -1, &config); break; }; doneit += curit; mstime += mstimer.getTime(); if (solution.GetCost() < mscost) { fprintf(stderr, "FOUND BETTER SOLUTION. IMPROVING COST FROM %.0f TO %.0f.\n", mscost, solution.GetCost()); mscost = solution.GetCost(); if (outSolution != nullptr && (outSolution->GetCost() > solution.GetCost() || outSolution->EdgeCount() == 0)) { outSolution->CopyFrom(&solution); } } //if (outSolution != nullptr && (outSolution->GetCost() > solution.GetCost() || outSolution->EdgeCount() == 0)) { // outSolution->CopyFrom(&solution); // fprintf(stderr, "FOUND BETTER SOLUTION. IMPROVING COST FROM %.0f TO %.0f.\n", mscost, solution.GetCost()); // mscost = solution.GetCost(); //} } } } if (mscost < bestfound) bestfound = mscost; fprintf (stderr, "Solution is %.12f.\n", (double)mscost); /* double ratio = (double)mscost / (double)bestknown; double error = ratio - 1; fprintf (stdout, "ratio %.12f\n", ratio); fprintf (stdout, "error %.12f\n", error); fprintf (stdout, "pcterror %.12f\n", 100.0 * error); */ Basics::ReportResults(stdout, "ms", mstime, mscost, bestknown); fprintf (stdout, "msiterations %d\n", msit); fprintf(stdout, "mstype %d\n", mstype); //fprintf (stdout, "mssolution %.0f\n", mscost); //fprintf (stdout, "mstimeseconds %.12f\n", mstime); gbestfound = bestfound; } static void Solve (int argc, char **argv) { const uint64_t version = 201706010852; cout << "version " << version << endl << "precision " << fixed << setprecision(20) << EDGE_COST_PRECISION << endl; if (argc < 2) ShowUsage(); Graph g; g.ReadSTP(argv[1]); char *filename = argv[1]; char *name = new char[strlen(filename)+1]; ExtractFilename(filename, name); OutputGraphStats (stdout, g, argv[1]); fprintf (stdout, "graph %s\n", name); EdgeCost bestknown = ReadBound(stdout, name); EdgeCost bestfound = INFINITE_COST; //ReadBound("bounds.txt", ); EdgeCost solcost = 0; bool MSTPRUNE = false; bool PREPROCESS = false; bool SAFE_PREPROCESS = false; bool DUALASCENT = false; bool BRANCHBOUND = false; bool LOCALSEARCH = false; bool MULTISTART = false; bool BINARYMULTISTART = true; int mstype = MS_COMBINATION; int msit = 0; int seed = 17; EdgeCost primal = INFINITE_COST; //fprintf (stderr, "ARGC is %d\n", argc); SteinerConfig config; for (int i=2; i<argc; i+=2) { if (i == argc-1) ShowUsage(); if (strcmp(argv[i], "-ub")==0) { primal = atoi(argv[i+1]); fprintf (stderr, "Setting upper bound to %.0f.\n", primal); continue; } if (strcmp(argv[i], "-bb")==0) { if (atoi(argv[i+1])==0) { BRANCHBOUND = false; } else { BRANCHBOUND = true; } continue; } if (strcmp(argv[i], "-prep")==0) { if (atoi(argv[i+1])!=0) { fprintf (stderr, "Will do preprocessing.\n"); PREPROCESS = true; if (atoi(argv[i + 1]) > 1) SAFE_PREPROCESS = true; } continue; } if (strcmp(argv[i], "-ls")==0) { if (atoi(argv[i+1])!=0) { fprintf (stderr, "Will do localsearch.\n"); LOCALSEARCH = true; } continue; } if (strcmp(argv[i], "-bms")==0) { if (atoi(argv[i+1])!=0) { fprintf (stderr, "Will do binary.\n"); BINARYMULTISTART = true; } continue; } if (strcmp(argv[i], "-msit")==0) { msit = (atoi(argv[i+1])); fprintf (stderr, "Will run %d multistart iterations.\n", msit); continue; } if (strcmp(argv[i], "-mstype")==0) { mstype = (atoi(argv[i+1])); fprintf (stderr, "Will run multistart type %d.\n", mstype); assert(mstype != 14); // This is corrupt (BB with TimeBoundedMultistart) continue; } if (strcmp(argv[i], "-seed")==0) { seed = atoi(argv[i+1]); fprintf (stderr, "Set seed to %d.\n", seed); continue; } //maybe config knows what to do with this parameter config.ReadParameter (argv[i], argv[i+1]); } fflush (stderr); if (config.EARLY_STOP_BOUND < 0) {config.EARLY_STOP_BOUND = bestknown;} bestfound = primal; config.Output(stdout); fprintf (stdout, "seed %d\n", seed); // if there is a best known solution, output it whenever we find it if (config.OUTPUT_THRESHOLD<0 && bestknown>=0) { config.OUTPUT_THRESHOLD = bestknown; } RFWTimer timer(true); // solution cost log. ExecutionLog executionLog(&g, &timer, config.TIME_LIMIT); MULTISTART = (msit != 0); RFWRandom::randomize(seed); bool APPLY_PERTURBATION = false; if (APPLY_PERTURBATION) { fprintf (stderr, "Applying perturbation... "); int m = g.EdgeCount(); vector<EdgeCost> pertcost (m+1,-1); RFWLocalRandom random(seed+17); PerturbationTools::ApplyPerturbation(g, pertcost, random, 1, 1.0001); g.ApplyCosts(pertcost); for (int i=1; i<std::min(10, m); i++) { fprintf (stderr, "%.5f ", (double)g.GetCost(i)); } fprintf (stderr, "done.\n"); } if (PREPROCESS) { fprintf (stderr, "Should be preprocessing.\n"); RFWTimer preptime(true); Preprocessing::RunPreprocessing(g, !SAFE_PREPROCESS); fprintf (stdout, "preptime %.6f\n", preptime.getTime()); fprintf (stdout, "prepfixed %.6f\n", g.GetFixedCost()); //PrepBottleneck(g); //exit(-1); } bool GUARDED_MULTISTART = false; if (mstype > MS_NUMBER) { GUARDED_MULTISTART = true; mstype = mstype % 10; fprintf (stderr, "Will run guarded mode %d.\n", mstype); } double second_time = 0; double first_time; SteinerSolution bestSolution(&g); if (MULTISTART && GUARDED_MULTISTART) { fprintf (stderr, "There are %d threads, %d processes.\n", omp_get_max_threads(), omp_get_num_procs()); GlobalInfo ginfo; ginfo.fixed = g.GetFixedCost(); config.DEPTH_LIMIT = 128; fprintf (stderr, "Setting depth limit to %d.\n", config.DEPTH_LIMIT); omp_set_num_threads(2); RFWTimer ftimer(true); #pragma omp parallel { Graph thread_g = g; EdgeCost thread_bestfound = bestfound; fprintf (stderr, "<%d> ", omp_get_thread_num()); if (omp_get_thread_num() == 0) { RunMultistart(thread_g, mstype, msit, thread_bestfound, bestknown, config, name, &ginfo, &executionLog, nullptr); fprintf (stderr, "DONE RUNNING MULTISTART AND FOUND %.3f\n", thread_bestfound); ginfo.MakeSolved(); } else if (omp_get_thread_num() == 1) { RFWTimer stimer(true); fprintf (stderr, "Should be running something smarter here.\n"); int bbseed = seed; if (bbseed > 0) bbseed = -bbseed; BranchBound::RunBranchAndBound(thread_g, bbseed, thread_bestfound, thread_bestfound, bestknown, config, &ginfo, &executionLog); second_time += stimer.getTime(); fprintf (stderr, "DONE RUNNING BRANCHING-AND-BOUND!\n"); if (!ginfo.bbpruned) ginfo.MakeSolved(); else fprintf (stderr, "Did not find the optimal solution, though.\n"); } #pragma omp critical { if (thread_bestfound < bestfound) { bestfound = thread_bestfound; fprintf (stderr, "THREAD %d UPDATED TO %.3f\n", omp_get_thread_num(), bestfound); } } } #pragma omp barrier { fprintf (stderr, "Done with this.\n"); } first_time = ftimer.getTime(); fprintf (stdout, "bbpruned %d\n", ginfo.bbpruned); MULTISTART = false; BRANCHBOUND = false; } if (MULTISTART) { RunMultistart(g, mstype, msit, bestfound, bestknown, config, name, NULL, &executionLog, &bestSolution); } if (LOCALSEARCH) { int maxit = 10; for (int m=0; m<5; m++) { double besttime = 99999999; fprintf (stderr, "Running %d... ", m); fflush(stderr); if (m==3) { fprintf (stderr, "WARNING! SKIPPING METHOD 3.\n"); continue; } //if (m != 2) continue; for (int i=0; i<maxit; i++) { RFWTimer timer(true); SteinerSolution solution(&g); switch (m) { case 0: MSTPrim (g, solution); break; case 1: MSTKruskal (g, solution); break; case 2: ConstructiveAlgorithms::SPH (g, solution, NULL, 1); break; case 3: FullBoruvka (g, solution); break; case 4: TestLocalSearch (g, solution); break; } if (m>=2 && MSTPRUNE) { MSTPrune(g,solution); } solcost = solution.GetCost(); double t = timer.getTime(); if (t < besttime) besttime = t; } fprintf (stderr, "Method %d found solution of cost %d in %.3f milliseconds (best of %d runs).\n", m, solcost, besttime * 1000.0, maxit); fflush(stderr); } } if (BRANCHBOUND) { BranchBound::RunBranchAndBound(g, seed, primal, bestfound, bestknown, config, NULL, &executionLog); } double walltime = timer.getTime(); fprintf (stdout, "totalwalltimeseconds %.12f\n", walltime); //fprintf (stdout, "totaltimeseconds %.12f\n", walltime + second_time); //fprintf (stdout, "bestsolution %.0f\n", bestfound); Basics::ReportResults(stdout, "total", walltime + first_time, bestfound, bestknown); Basics::ReportResults(stdout, "totalcpu", walltime + second_time, bestfound, bestknown); // Dump official output logs. if (!config.LOG_FILENAME.empty()) { ofstream logFile(config.LOG_FILENAME.c_str()); if (logFile.is_open()) { logFile << "SECTION Comment" << endl << "Name \"" << name << "\"" << endl << "Problem \"SPG\"" << endl << "Program \"puw\"" << endl << "Version \"" << version << "\"" << endl << "End" << endl << endl << "SECTION Solutions" << endl; for (size_t i = 0; i < executionLog.solCost.size(); ++i) { logFile << "Solution " << fixed << executionLog.solCost[i].second << " " << fixed << executionLog.solCost[i].first << endl; } logFile << "End" << endl << endl << "SECTION Run" << endl << "Threads 1" << endl << "Time " << fixed << walltime << endl << "Dual 0" << endl; if (executionLog.solCost.empty()) logFile << "Primal inf" << endl; else logFile << "Primal " << fixed << executionLog.bestSolution.GetCost() << endl; logFile << "End" << endl << endl; if (!executionLog.solCost.empty()) { logFile << "SECTION Finalsolution" << endl; size_t numVertices = 0; for (int v = 1; v <= g.VertexCount(); ++v) { if (executionLog.bestSolution.GetDegree(v) > 0 || g.IsTerminal(v)) ++numVertices; } logFile << "Vertices " << numVertices << endl; for (int v = 1; v <= g.VertexCount(); ++v) { if (executionLog.bestSolution.GetDegree(v) > 0 || g.IsTerminal(v)) logFile << "V " << v << endl; } logFile << "Edges " << executionLog.bestSolution.EdgeCount() << endl; for (size_t e = 1; e <= g.EdgeCount(); ++e) { if (executionLog.bestSolution.Contains(e)) logFile << "E " << g.GetFirstEndpoint(e) << " " << g.GetSecondEndpoint(e) << endl; } logFile << "End" << endl; } logFile.close(); } } delete [] name; } static void CombineSolutions(SteinerSolution &target, SteinerSolution &sa, SteinerSolution &sb, RFWLocalRandom &random, SteinerConfig *config) { Graph &g = *sa.g; int n = g.VertexCount(); int m = g.EdgeCount(); const bool verbose = false; /* UniverseSet baselist = new UniverseSet(n); VoronoiData voronoi = new VoronoiData(n); UnionFind uf = new UnionFind(n); SteinerSolution solution = new SteinerSolution(g); BinaryHeap<ArcCost> heap = new BinaryHeap<ArcCost>(n); ArcCost [] pertcost = new ArcCost [m+1]; SteinerSolution target = new SteinerSolution(g); Console.Error.Write("{0} x {1}:", sa.GetCost(), sb.GetCost()); */ vector<EdgeCost> pertcost(m+1,-1); //was: 1000, (100,500), 1 for (int e = 1; e <= m; e++) { int tcount = 0; if (sa.Contains(e)) tcount++; if (sb.Contains(e)) tcount++; int mult = 1; if (tcount == 0) mult = 1000; //random.GetInteger(200,300); //edge in neither solution: very expensive else if (tcount == 1) mult = random.GetInteger(100, 500); //split edge: intermediate cost else { mult = 1; } //random.GetInteger(100,200); } //edge in both: keep it pertcost[e] = g.GetCost(e) * mult; // g.GetCost(a); } int root = Basics::PickRandomTerminal(g, random); ConstructiveAlgorithms::SPH (g, target, &pertcost[0], root); MSTPrune(g,target); RunLocalSearch(g, target, random, -1, config); if (verbose) fprintf (stderr, "%d x %d -> %d\n", sa.GetCost(), sb.GetCost(), target.GetCost()); /* baselist.Reset(); for (int v = 1; v <= n; v++) {if (g.IsTerminal(v)) baselist.Insert(v);} ComputeVoronoi(voronoi, baselist, heap, pertcost); uf.Reset(); target.Reset(); Boruvka(target, voronoi, uf, pertcost); ArcCost borcost = target.GetCost(); FullLocalSearch(target); ArcCost newcost = target.GetCost(); Console.Error.WriteLine(" {0}", newcost); return target; }*/ } static void BinaryMultistart (SteinerSolution &solution, int maxit, char *outprefix, SteinerConfig *config) { int nlevels = 32; vector<SteinerSolution*> levelsol (nlevels, NULL); //solution[i]: solution obtained by combining 2^i solutions Graph &g = *solution.g; int n = g.VertexCount(); int m = g.EdgeCount(); RFWTimer timer(true); RFWLocalRandom random (RFWRandom::getInteger(1,999999999)); EdgeCost bestcost = 999999999; const bool verbose =false; bool USE_PERTURBATION = true; bool ADAPTIVE_PERTURBATION = false; fprintf (stderr, "Running multistart for %d iterations and %d levels (perturbation=%d).\n", maxit, nlevels, USE_PERTURBATION); fflush(stderr); vector<EdgeCost> pertcost (m+1,-1); //bool USE_PERTURBATION = true; //bool ADAPTIVE_PERTURBATION = false; SteinerSolution cursol(&g); SteinerSolution bestsol(&g); SteinerSolution combsol(&g); //EdgeCost bestcost = 999999999; for (int i=0 ; i<maxit; i++) { int root = random.GetInteger(1,n); //PickRandomTerminal(g, random); if (USE_PERTURBATION) { PerturbationTools::InitPerturbation(g, pertcost, random, config); } ConstructiveAlgorithms::SPH (g, cursol, USE_PERTURBATION ? &pertcost[0] : NULL, root); MSTPrune(g,cursol); RunLocalSearch(g, cursol, random, -1, config); if (cursol.GetCost() < bestcost) { bestcost = cursol.GetCost(); bestsol.CopyFrom(&cursol); } int j; for (j=0; j<nlevels; j++) { fprintf (stderr, "%10d : %2d : %.0f : ", (int)i, j, bestcost); if (levelsol[j] == NULL) { fprintf (stderr, "+%.0f\n", cursol.GetCost()); levelsol[j] = new SteinerSolution(&cursol); break; } // so there is a solution at level j //SteinerSolution *refsol = elite.GetReference(random.GetInteger(1, elite.Count())); int maxtries = 5; int t; for (t=0; t<maxtries; t++) { CombineSolutions(combsol, cursol, *levelsol[j], random, config); //fprintf (stderr, "%.0f x %.0f -> %.0f\n", cursol.GetCost(), levelsol[j]->GetCost(), combsol.GetCost()); if (combsol.GetCost() < cursol.GetCost() && combsol.GetCost() < levelsol[j]->GetCost()) { break; //cursol.CopyFrom(&combsol); } } fprintf (stderr, "<%d>", t); if (combsol.GetCost() > cursol.GetCost()) { combsol.CopyFrom(&cursol); fprintf (stderr, "a"); //fprintf (stderr, "!"); } if (combsol.GetCost() > levelsol[j]->GetCost()) { combsol.CopyFrom(levelsol[j]); fprintf (stderr, "b"); } cursol.CopyFrom(&combsol); delete levelsol[j]; levelsol[j] = NULL; //if (cursol.GetCost() < cursol. if (cursol.GetCost() < bestcost) { bestcost = cursol.GetCost(); bestsol.CopyFrom(&cursol); } } if (i%10==0) fflush(stderr); if (j==nlevels) { fprintf (stderr, "Ran out of levels!\n"); break; } } for (int i=0; i<nlevels; i++) { if (levelsol[i]) delete levelsol[i]; } solution.CopyFrom(&bestsol); } static void EliteMultistart (SteinerSolution &solution, int maxit, int capacity, char *outprefix, SteinerConfig *config) { Graph &g = *solution.g; SteinerSolution bestsol(&g); SteinerSolution combsol(&g); EdgeCost bestcost = INFINITE_COST; RFWLocalRandom random (RFWRandom::getInteger(1,999999999)); SolutionPool elite(maxit); for (int i=0; i<999999; i++) { CombinationMultistart(solution, maxit, capacity, NULL, 0); EdgeCost curcost = solution.GetCost(); fprintf (stderr, "Should be adding solution %.0f to capacity %d.\n", (double)curcost, capacity); fflush(stderr); int pos1 = elite.Add(&solution); //int pos1 = -1; CascadedCombination(solution, combsol, elite, -1, random, config); curcost = solution.GetCost(); int pos2 = elite.Add(&solution); fprintf (stderr, "[%d,%d:%.0f] ", pos1, pos2, (double)solution.GetCost()); if (curcost < bestcost) { bestsol.CopyFrom(&solution); bestcost = curcost; } fprintf (stderr, "Iteration %d: %.0f\n", i, (double)bestsol.GetCost()); elite.Output(stderr, 8); } solution.CopyFrom(&bestsol); } //-------------------------- // Repeatedly combine initial solution with others from the elite set, then add the result to elite set itself. // Combinations continue until the algorithm fails to improve 'maxfail' times. static void CascadedCombination(SteinerSolution &solution, SteinerSolution &combsol, SolutionPool &elite, int maxfail, RFWLocalRandom &random, SteinerConfig *config) { if (maxfail < 0) maxfail = config->MAX_COMB_FAIL; int failures_to_go = maxfail; const bool verbose = false; if (verbose) fprintf (stderr, "%d->", solution.GetCost()); while (failures_to_go > 0) { SteinerSolution *refsol = elite.GetReference(random.GetInteger(1, elite.Count())); CombineSolutions(combsol, solution, *refsol, random, config); if (!combsol.IsBetter(&solution)) { failures_to_go --; } else { solution.CopyFrom(&combsol); } } if (verbose) fprintf (stderr, "%d\n", solution.GetCost()); elite.Add(&solution); } static void AddSmallPerturbation (Graph &g) { fatal ("deprecated function"); int m = g.EdgeCount(); vector<EdgeCost> pertcost(m+1); for (int e=1; e<=m; e++) { EdgeCost c = 10000 * g.GetCost(e) + RFWRandom::getInteger(0,10); pertcost[e] = c; } g.ApplyCosts(pertcost); } struct DistancePair { int source; EdgeCost distance; }; class ClosenessData { private: int k; int maxid; void GetBounds (int v, int &first, int &last) { first = v*maxid; last = (v+1)*maxid; } public: vector<DistancePair> data; ClosenessData(int _k, int _maxid) { k = _k; maxid = _maxid; data.resize(k*maxid+1); } }; static void FindKClosest (Graph &g, int k, vector<int> sources, ClosenessData &cdata) { int n = g.VertexCount(); for (int v=1; v<=n; v++) { //cdata[ } } static void KeyVertexInsertion (SteinerSolution &solution, RFWLocalRandom &random) { //return; Graph &g = *solution.g; int n = g.VertexCount(); SteinerSolution tempsol(&g); RFWStack<int,true> tempterm(n+1); //fprintf (stderr, "Should be finding improvements!\n"); fprintf (stderr, "k"); const bool MOVE_SIDEWAYS = true; vector<int> perm(n+1); for (int v=1; v<=n; v++) {perm[v] = v;} for (int i=1; i<n; i++) { int j = random.GetInteger(i,n); std::swap(perm[i], perm[j]); } int improvements = 1; while (improvements > 0) { improvements = 0; //for (int v=1; v<=n; v++) { for (int p=1; p<=n; p++) { int v = perm[p]; //RFWRandom::getInteger(1,n); //warning! Should have a real permutation. //fprintf (stderr, "%d ", v); if (g.IsTerminal(v)) continue; //if (!solution.Contains(v)) continue; //MUCH WEAKER VERSION OF THE SEARCH /* if (solution.GetDegree(v) <= 2) { //fprintf (stderr, "."); continue; //WARNING: THIS IS FOR TESTING ONLY }*/ //fprintf (stderr, "v%d ", v); tempterm.reset(); //fflush (stderr); // push all current terminals for (int w=1; w<=n; w++) { if (g.IsTerminal(w)) continue; if (solution.GetDegree(w) <= 2) continue; //fprintf (stderr, "t%d:%d ", w, solution.GetDegree(w)); tempterm.push(w); } //fprintf (stderr, "Created %d new terminals.\n", tempterm.getNElements()); // push v itself (if not already pushed) //if (solution.GetDegree(v) <= 2) tempterm.push(v); int oldt = g.TerminalCount(); //fprintf (stderr, "oldt=%d ", g.TerminalCount()); for (int i=1; i<=tempterm.getNElements(); i++) { int w = tempterm.peek(i); //fprintf (stderr, "x"); if (g.IsTerminal(w)) fatal ("something wrong!\n"); g.MakeTerminal(w); if (g.TerminalCount() == oldt) fatal ("insertion did nothing"); } //fprintf (stderr, "newt=%d ", g.TerminalCount()); tempsol.Reset(); //fprintf (stderr, "%.0f+%.0f = ", solution.GetCost(), tempsol.GetCost()); ConstructiveAlgorithms::SPH(g, tempsol, NULL, v); //fprintf (stderr, "%.0f>>%.0f ", oldcost, newcost); for (int i=1; i<=tempterm.getNElements(); i++) { int w = tempterm.peek(i); g.UnmakeTerminal(w); } MSTPrune(g, tempsol); EdgeCost oldcost = solution.GetCost(); EdgeCost newcost = tempsol.GetCost(); //if (newcost - oldcost > 0) fprintf (stderr, "%.0f ", newcost - oldcost); //fflush(stderr); double improvement = oldcost - newcost; // remember the new solution if there is an improvement or a tie (if MOVE_SIDEWAYS is true) if (improvement > EDGE_COST_PRECISION || (MOVE_SIDEWAYS && (improvement > -EDGE_COST_PRECISION))) { solution.CopyFrom(&tempsol); if (improvement > EDGE_COST_PRECISION) { fprintf (stderr, "."); improvements ++; fprintf (stderr, "i%.0f ", newcost); fflush(stderr); return; } } } } } static void DecayLocalSearch (SteinerSolution &solution, vector<EdgeCost> &original, RFWLocalRandom &random, int decaysteps, double exponent, SteinerConfig *config, ExecutionLog *executionLogPtr = nullptr) { Graph &g = *solution.g; int m = g.EdgeCount(); vector<EdgeCost> current(m+1); const bool verbose = true; double precision = EDGE_COST_PRECISION; // run a few iterations of the local search while decaying the perturbation (towards unperturbed solution) int decaytogo = decaysteps; for (;;) { EdgeCost prevcost = solution.GetCost(); // run one round of local seach MSTPrune(g,solution); RunLocalSearch(g, solution, random, 1, config, executionLogPtr); EdgeCost newcost = solution.GetCost(); if (decaytogo == 0) break; if (prevcost - newcost <= precision) { fprintf (stderr, "<%d> ", decaysteps - decaytogo); break; } decaytogo --; g.RetrieveCosts(current); for (int e=1; e<=m; e++) { //current[e] = original[e] + (current[e] - original[e]) * exponent; //NOT REALLY AN EXPONENT current[e] = original[e] + (current[e] - original[e]) * exponent; //NOT REALLY AN EXPONENT } g.ApplyCosts(current); solution.UpdateCost(); } g.ApplyCosts(original); //restore original edge costs solution.UpdateCost(); //recost the existing solution EdgeCost before = solution.GetCost(); // this is the original cost //fprintf (stderr, "d%.0f->", solution.GetCost()); //SPH (g, solution, NULL, root); //fprintf (stderr, "[%d->", solution.GetCost()); // run local search on current solution using original costs MSTPrune(g,solution); RunLocalSearch(g, solution, random, -1, config); EdgeCost after = solution.GetCost(); if (verbose) { fprintf (stderr, " %.0f", after); //fprintf (stderr, " %3.0f", before - after); } //fprintf (stderr, "%d]", solution.GetCost()); } /** * Generate randomized solution from scratch by perturbing edge weights, runing a constructive algorithm, then applying local search. * The local search is applied to the perturbed graph initially, but the perturbation may be gradually dampened (removed). * */ static void GenerateRandomizedSolution(SteinerSolution &solution, int root, vector<EdgeCost> &pertcost, RFWLocalRandom &random, SteinerConfig *config, ExecutionLog *executionLogPtr = nullptr) { Graph &g = *solution.g; int m = g.EdgeCount(); const bool VERBOSE_STEP = false; vector<EdgeCost> original (m+1); //remember original costs g.RetrieveCosts(original); // find local optimum with perturbed costs g.ApplyCosts(pertcost); ConstructiveAlgorithms::SPH (g, solution, NULL, root); if (executionLogPtr != nullptr) { fprintf(stderr, "ADDING SPH SOLUTION WITH COST %f.\n", solution.GetCost()); executionLogPtr->AddSolution(solution); } if (VERBOSE_STEP) { fprintf (stderr, "Done after SPH (%d).\n", solution.GetCost()); fflush(stderr); } int LS_PERT_ROUNDS= std::max(999,g.VertexCount()); double LS_PERT_EXPONENT = 1.0; //no decay if (config) { LS_PERT_ROUNDS = config->LS_PERT_ROUNDS; LS_PERT_EXPONENT = config->LS_PERT_EXPONENT; } if (LS_PERT_EXPONENT <= 0) fatal ("invalid perturbation exponent"); bool DECAY_LOCAL_SEARCH = (LS_PERT_EXPONENT <= 0.999999); if (DECAY_LOCAL_SEARCH) { DecayLocalSearch(solution, original, random, LS_PERT_ROUNDS, LS_PERT_EXPONENT, config, executionLogPtr); } else { MSTPrune(g,solution); if (VERBOSE_STEP) { fprintf (stderr, "Done after MSTPrune (%d).\n", solution.GetCost()); fflush(stderr); } RunLocalSearch(g, solution, random, LS_PERT_ROUNDS, config, executionLogPtr); //, 2); if (VERBOSE_STEP) { fprintf (stderr, "Done after LocalSearch (%d).\n", solution.GetCost()); fflush(stderr); } // find real local optimum g.ApplyCosts(original); solution.UpdateCost(); //SPH (g, solution, NULL, root); //fprintf (stderr, "[%d->", solution.GetCost()); MSTPrune(g,solution); RunLocalSearch(g, solution, random, -1, config); //fprintf (stderr, "%d]", solution.GetCost()); } } static int ComputeCapacity(int maxit, SteinerConfig *config) { double denominator = 1.0; if (config) denominator = config->ELITE_DENOMINATOR; int capacity = (int)ceil(sqrt((double)maxit / denominator)); return capacity; } static void PlainMultistart (SteinerSolution &solution, int maxit, int capacity, SteinerConfig *config) { if (capacity<0) capacity = ComputeCapacity(maxit, config); SolutionPool elite (capacity); RFWLocalRandom random (RFWRandom::getInteger(1,999999999)); FlexibleMultistart (solution, maxit, elite, NULL, maxit, config); //CombinationMultistart (solution, maxit, capacity, NULL, maxit, config); SolutionPool children (capacity); SolutionPool *a, *b; a = &elite; b = &children; fprintf (stderr, "There are %d elite solutions.\n", elite.GetCount()); int maxfail = 100; int failures = maxfail; EdgeCost curbest = elite.FindBestCost(); //fprintf (stderr, "Initial best is %.0f\n", curbest); //exit(-1); while (1) { fprintf (stderr, "HERE!\n"); fflush(stderr); RecombineGeneration(*a, *b, random, config); //if (b->FindBestCost() >= a->FindBestCost()) break; //fprintf (stderr, "Doing stuff now.\n"); //fflush (stderr); //EdgeCost newbest = curbest +1; EdgeCost newbest = b->FindBestCost(); if (newbest >= curbest) { failures --; if (failures == 0) break; } else { failures = maxfail; curbest = newbest; } fprintf (stderr, "New best solution is %.0f\n", curbest); //break; //fprintf (stderr, "Swapping (%d,%d)...\n", a->GetCount(), b->GetCount()); //fflush(stderr); std::swap(a,b); //fprintf (stderr, "Resetting...\n"); //fflush(stderr); b->HardReset(); } fprintf (stderr, "Ended with solution with cost %.0f\n", curbest); } static void CombinationMultistart(SteinerSolution &solution, int maxit, int capacity, char *outprefix, int COMBINATION_THRESHOLD = -1, SteinerConfig *config = NULL, GlobalInfo *ginfo = NULL, ExecutionLog *executionLogPtr = nullptr) { if (capacity<0) capacity = ComputeCapacity(maxit, config); SolutionPool elite (capacity); if (!config->AGGRESSIVE_COMBINATION) COMBINATION_THRESHOLD = capacity; fprintf (stderr, "<<<<< %p >>>>>>\n", ginfo); FlexibleMultistart (solution, maxit, elite, outprefix, COMBINATION_THRESHOLD, config, ginfo, executionLogPtr); } static void TimeBoundedMultistart(SteinerSolution &solution, int mstype, int maxitupper, char *outprefix, int COMBINATION_THRESHOLD = -1, SteinerConfig *config = NULL, GlobalInfo *ginfo = NULL, ExecutionLog *executionLogPtr = nullptr) { SolutionPool tentativeElite(2); RFWTimer tentativeTimer(true); FlexibleMultistart(solution, 1, tentativeElite, outprefix, COMBINATION_THRESHOLD, config, ginfo, executionLogPtr, false, false); double tentativeTime = tentativeTimer.getTime(); int maxit = maxitupper; const double blowupFactor = 2.5; // this fell from the sky after careful consideration if (tentativeTime > 0 && config->TIME_LIMIT > 0) maxit = static_cast<int>(ceil(config->TIME_LIMIT / tentativeTime / blowupFactor)); if (maxit > maxitupper) maxit = maxitupper; fprintf(stderr, "TENTATIVE TIME: %.3f SEC; WILL COMPUTE %d ITERATIONS (UPPER BOUND = %d).\n", tentativeTime, maxit, maxitupper); int capacity = ComputeCapacity(maxit, config); SolutionPool elite(capacity); if (!config->AGGRESSIVE_COMBINATION) COMBINATION_THRESHOLD = capacity; // Determine which multistart to call depending on mstype. int localtype = mstype; if (mstype == MS_TIMEBOUNDEDADAPTIVE) { localtype = maxit > 2048 ? MS_TIMEBOUNDEDMULTILEVEL : MS_TIMEBOUNDEDCOMBINATION; } if (localtype == MS_TIMEBOUNDEDCOMBINATION) { FlexibleMultistart(solution, maxitupper, elite, outprefix, COMBINATION_THRESHOLD, config, ginfo, executionLogPtr); } else if (localtype == MS_TIMEBOUNDEDMULTILEVEL) { MultilevelMultistart(solution, maxit, maxitupper, capacity, outprefix, COMBINATION_THRESHOLD, config, ginfo, executionLogPtr); } else { fatal("Not supported."); } if (tentativeElite.FindBestCost() < solution.GetCost()) { solution.CopyFrom(tentativeElite.GetReference(tentativeElite.FindBestPosition())); fprintf(stderr, "USING SOLUTION FROM FIRST TENTATIVE ITERATION.\n"); } fprintf(stdout, "actualmstype %d\n", localtype); } template<class T> static void Permute(vector<T> &array, RFWLocalRandom &random) { int s = (int)array.size(); for (int i=0; i<s-1; i++) { int j = random.GetInteger(i,s-1); std::swap(array[i], array[j]); } } static void MultilevelMultistart(SteinerSolution &solution, int maxit, int maxitupper, int capacity, char *outprefix, int COMBINATION_THRESHOLD = -1, SteinerConfig *config = NULL, GlobalInfo *ginfo = NULL, ExecutionLog *executionLogPtr = nullptr) { fprintf (stderr, "SHOULD BE RUNNING MMS FROM SOLUTION %.0f\n", solution.GetCost()); fflush(stderr); if (capacity<0) capacity = ComputeCapacity(maxit, config); const int SUBCOUNT = 4; SolutionPool *subelite[SUBCOUNT]; if (!config->AGGRESSIVE_COMBINATION) COMBINATION_THRESHOLD = capacity; int localit = maxit / (2*SUBCOUNT); int subcapacity = ComputeCapacity(localit, config); int restit = maxit - SUBCOUNT*localit; int restcap = ComputeCapacity(restit, config); SolutionPool elite(restcap); // Only do phase one of the algorithm if there are enough iterations. if (localit > 0) { for (int i = 0; i < SUBCOUNT; i++) { subelite[i] = new SolutionPool(subcapacity); } // Runs subcount independent multistarts using half the total number of iterations. for (int i = 0; i < SUBCOUNT; i++) { fprintf(stderr, "SUBPROBLEM %d\n", i); FlexibleMultistart(solution, localit, *subelite[i], outprefix, COMBINATION_THRESHOLD, config, ginfo, executionLogPtr); fprintf(stderr, "\n\n"); } vector<SteinerSolution*> solpointers; for (int i = 0; i < SUBCOUNT; i++) { subelite[i]->Output(stderr, 8); fprintf(stderr, "\n"); int count = subelite[i]->GetCount(); for (int j = 1; j <= count; j++) solpointers.push_back(subelite[i]->GetReference(j)); } RFWLocalRandom random(RFWRandom::getInteger(1, 1000000)); Permute(solpointers, random); //std::sort(solpointers.begin(), solpointers.end(), [&](SteinerSolution *x, SteinerSolution *y) {return x->GetCost() >= y->GetCost();}); //sort (&perm[0], &perm[perm.size()], [&](int x, int y) {return totalbound[x]/count[x] > totalbound[y]/count[y];}); for (int i = 0; i < (int)solpointers.size(); i++) { SteinerSolution *sol = solpointers[i]; if (sol->GetCost() < solution.GetCost()) { solution.CopyFrom(sol); } elite.Add(sol); } for (int i = 0; i<SUBCOUNT; i++) { delete subelite[i]; } /* for (int i=0; i<SUBCOUNT; i++) { subelite[i]->Output(stderr, 8); fprintf (stderr, "\n"); int count = subelite[i]->GetCount(); for (int j=1; j<=count; j++) { SteinerSolution *sol = subelite[i]->GetReference(j); if (sol->GetCost() < solution.GetCost()) {solution.CopyFrom(sol);} elite.Add(sol); } }*/ elite.Output(stderr, 8); } fprintf (stderr, "SUPERPROBLEM (from solution %.0f):\n", solution.GetCost()); FlexibleMultistart(solution, maxitupper - SUBCOUNT*localit, elite, outprefix, COMBINATION_THRESHOLD, config, ginfo, executionLogPtr); } static void RecombineGeneration (SolutionPool &parents, SolutionPool &children, RFWLocalRandom &random, SteinerConfig *config) { int pcount = parents.GetCount(); if (pcount == 0) return; fprintf (stderr, "Should be combining.\n"); Graph &g = *(parents.GetReference(1)->g); SteinerSolution newsol(&g); SteinerSolution bestsol(&g); bestsol.CopyFrom(parents.GetReference(parents.FindBestPosition())); //fprintf (stderr, "WARNING: THIS IS VERY WRONG.\n"); for (int i=1; i<pcount; i++) { SteinerSolution *a = parents.GetReference(i); fprintf (stderr, " %.0f", a->GetCost()); for (int j=i+1; j<=pcount; j++) { SteinerSolution *b = parents.GetReference(j); CombineSolutions(newsol, *a, *b, random, config); //fprintf (stderr, "%.0f x %.0f: %.0f\t", a->GetCost(), b->GetCost(), newsol.GetCost()); if (newsol.GetCost() < bestsol.GetCost()) { bestsol.CopyFrom(&newsol); } children.Add(&newsol); } } // make sure the best solution (even if from a previous iteration) is preserved children.Add(&bestsol); fprintf (stderr, "Best solution is %.0f\n", bestsol.GetCost()); } static void FlexibleMultistart(SteinerSolution &solution, int maxit, SolutionPool &elite, char *outprefix, int COMBINATION_THRESHOLD = -1, SteinerConfig *config = NULL, GlobalInfo *ginfo = NULL, ExecutionLog *executionLogPtr = nullptr, bool USE_PERTURBATION = true, bool outputStats = true) { Graph &g = *solution.g; //AddSmallPerturbation(g); int itbits = 6; //int maxit = 1 << itbits; //int capacity = 1 << (itbits / 2); /* if (capacity < 0) { double denominator = 1.0; if (config) denominator = config->ELITE_DENOMINATOR; capacity = (int)ceil(sqrt((double)maxit / denominator)); }*/ int n = g.VertexCount(); SteinerSolution bestsol(&g); //best solution found so far SteinerSolution combsol(&g); //combined solution bestsol.CopyFrom(&solution); //SolutionPool elite (capacity); int capacity = elite.GetCapacity(); //Graph &g = *solution.g; int m = g.EdgeCount(); RFWTimer timer(true); RFWLocalRandom random (RFWRandom::getInteger(1,999999999)); EdgeCost bestcost = INFINITE_COST; if (elite.GetCount() > 0) { int p = elite.FindBestPosition(); bestsol.CopyFrom(elite.GetReference(p)); bestcost = bestsol.GetCost(); } const bool verbose = false; //bool = perturbation; bool ADAPTIVE_PERTURBATION = false; bool RESILIENT_PERTURBATION = USE_PERTURBATION; if (config) { int confpert = config->RESILIENT_PERTURBATION; if (confpert == 0) {RESILIENT_PERTURBATION = false;} else if (confpert == 1) {RESILIENT_PERTURBATION = true;} } fprintf (stderr, "Using resilient perturbation? %d\n", RESILIENT_PERTURBATION); //int COMBINATION_THRESHOLD = -1; //capacity; fprintf (stderr, "Running multistart for %d iterations and %d elite solutions (perturbation=%d).\n", maxit, capacity, USE_PERTURBATION); //fflush (stderr); vector<EdgeCost> pertcost (m+1,-1); const bool VERBOSE_STEP = false; int i; for (i=0; i<maxit; i++) { //if (ginfo) fprintf (stderr, "THERE IS A GINFO.\n"); if (ginfo && ginfo->IsSolved()) { fprintf (stderr, "Stopping at iteration %d.\n", i); break; } if (config->TIME_LIMIT > 0 && executionLogPtr->timerPtr->getTime() >= config->TIME_LIMIT) { fprintf(stderr, "Stopping at iteration %d because of time limit of %2.f sec (%.2f sec passed).\n", i, config->TIME_LIMIT, executionLogPtr->timerPtr->getTime()); break; } int root = random.GetInteger(1,n); //PickRandomTerminal(g, random); if (USE_PERTURBATION) { ADAPTIVE_PERTURBATION = false; //((i % 2) == 1); //random.GetInteger(0,1)==0; //ADAPTIVE_PERTURBATION = true; if (ADAPTIVE_PERTURBATION) { PerturbationTools::AdaptivePerturbation(g, pertcost, elite, random); } else { //fprintf (stderr, "Here!\n"); PerturbationTools::InitPerturbation(g, pertcost, random, config); //fflush (stderr); } } if (RESILIENT_PERTURBATION) { // both constructive and the local search use perturbation GenerateRandomizedSolution (solution, root, pertcost, random, config); } else { // non-resilient perturbation: ConstructiveAlgorithms::SPH (g, solution, USE_PERTURBATION ? &pertcost[0] : NULL, root); if (executionLogPtr != nullptr) executionLogPtr->AddSolution(solution); MSTPrune(g,solution); RunLocalSearch(g, solution, random, -1, config, executionLogPtr); } if (executionLogPtr != nullptr) { executionLogPtr->AddSolution(solution); } //fprintf (stderr, "Adding original solution...\n"); elite.Add(&solution); //add initial solution to the pool //global.UpdateSolution(solution.GetCost()); //make sure we remember it's the best if (i >= COMBINATION_THRESHOLD) { CascadedCombination(solution, combsol, elite, -1, random, config); } else { fprintf (stderr, "! "); } EdgeCost solcost = solution.GetCost(); //fprintf (stderr, "Found solution costing %d.\n", solcost); if (solcost < bestcost) { if (executionLogPtr != nullptr) { executionLogPtr->AddSolution(solution); } bestcost = solcost; bestsol.CopyFrom(&solution); //fprintf (stderr, "HERE (%.2f %p %p %.2f).\n", bestcost, outprefix, config, config->OUTPUT_THRESHOLD); if (outprefix) { if (config && bestcost < config->OUTPUT_THRESHOLD) { fprintf (stderr, "\n<outputting solution with value %0f>\n", bestcost); config->OUTPUT_THRESHOLD = bestcost; bestsol.Output(outprefix); } } if (ginfo) ginfo->UpdateBestFound(bestcost); } bool localverbose = ((i % 10) == 0); if (localverbose) { fprintf (stderr, "%6d : %6d : %10.0f : %10.5f\n", i, root, (double)solcost, (double)bestcost); fflush(stderr); } if (config && bestcost <= config->EARLY_STOP_BOUND) { fprintf (stderr, "Early stop!\n"); break; } //elite.Output(stderr); //if (i % 10 == 0) fflush (stderr); } if (outputStats) { //fprintf (stdout, "msiterations %d\n", maxit); fprintf(stdout, "actualiterations %d\n", i); fprintf(stdout, "earlystop %d\n", maxit != i); fprintf(stdout, "mselite %d\n", capacity); //fprintf (stdout, "totaltimeseconds %.8f\n", timer.getTime()); //fprintf (stdout, "mssolution %.0f\n", (double)bestcost); } fflush (stderr); solution.CopyFrom(&bestsol); } static void Multistart (SteinerSolution &solution, SteinerConfig *config) { int maxit = 9999; Graph &g = *solution.g; int m = g.EdgeCount(); RFWTimer timer(true); RFWLocalRandom random (RFWRandom::getInteger(1,999999999)); EdgeCost bestcost = INFINITE_COST; bool USE_PERTURBATION = true; fprintf (stderr, "Running multistart for %d iterations with perturbation=%d.\n", maxit, USE_PERTURBATION); vector<EdgeCost> pertcost (m+1,-1); for (int i=0; i<maxit; i++) { int root = Basics::PickRandomTerminal(g, random); if (USE_PERTURBATION) PerturbationTools::InitPerturbation(g, pertcost, random, NULL); ConstructiveAlgorithms::SPH (g, solution, USE_PERTURBATION ? &pertcost[0] : NULL, root); MSTPrune(g,solution); RunLocalSearch(g, solution, random, -1, config); EdgeCost solcost = solution.GetCost(); if (solcost < bestcost) { bestcost = solcost; } if (i % 10 == 0) { fprintf (stderr, "%6d : %6d : %6d : %6d\n", i, root, solcost, bestcost); fflush(stderr); } //if (i % 10 == 0) fflush (stderr); } fflush (stderr); fprintf (stderr, "totaltimeseconds %.8f\n", timer.getTime()); fprintf (stderr, "solution %d\n", bestcost); /* if (LOCALSEARCH) { int maxit = 10; for (int m=0; m<5; m++) { double besttime = 99999999; fprintf (stderr, "Running %d... ", m); fflush(stderr); if (m==3) { fprintf (stderr, "WARNING! SKIPPING METHOD 3.\n"); continue; } //if (m != 2) continue; for (int i=0; i<maxit; i++) { RFWTimer timer(true); SteinerSolution solution(&g); switch (m) { case 0: MSTPrim (g, solution); break; case 1: MSTKruskal (g, solution); break; case 2: SPH (g, solution, NULL, 1); break; case 3: FullBoruvka (g, solution); break; case 4: TestLocalSearch (g, solution); break; } if (m>=2 && MSTPRUNE) { MSTPrune(g,solution); } solcost = solution.GetCost(); double t = timer.getTime(); if (t < besttime) besttime = t; } fprintf (stderr, "Method %d found solution of cost %d in %.3f milliseconds (best of %d runs).\n", m, solcost, besttime * 1000.0, maxit); fflush(stderr); } }*/ } static void RunLocalSearch (Graph &g, SteinerSolution &solution, RFWLocalRandom &random, int maxrounds, SteinerConfig *config, ExecutionLog *executionLogPtr = nullptr) { bool RUN_Q = false; bool RUN_V = false; bool RUN_U = false; bool RUN_K = false; bool RESTRICT_K = false; // bool verbose = false; static bool first = true; char *lstype = config->LSTYPE; bool wait = false; for (int i=0; ;i++) { char c = lstype[i]; if (c==0) break; if (c=='w') { wait = true; continue; } switch (c) { case 'k': RUN_K = true; RESTRICT_K = wait; break; case 'v': RUN_V = true; break; case 'u': RUN_U = true; break; case 'q': RUN_Q = true; break; default: fprintf (stderr, "WARNING: invalid local search parameter (%c).\n", c); } wait = false; } //fprintf (stderr, "<%d%d>", RUN_K, RESTRICT_K); //return; //int maxrounds = 999; if (maxrounds < 0) maxrounds = 999; //999; //large number if (first) { fprintf (stderr, "Running with maxrounds %d.\n", maxrounds); } //SPH (g, solution, NULL, PickRandomTerminal(g,random)); //if (verbose) fprintf (stderr, "SPH found solution %d.\n", solution.GetCost()); int n = g.VertexCount(); EdgeCost oldcost = solution.GetCost(); RFWTimer timer(true); int rounds = 0; int i=0; for (i=0; i<maxrounds; i++) { rounds ++; if (RUN_V) { LSVertexInsertion::VertexInsertion(g, solution, n, random); MSTPrune(g, solution); if (verbose) fprintf (stderr, " v%d ", solution.GetCost()); } //fprintf (stderr, "Starting key vertex elimination!\n"); //fflush (stderr); if (RUN_Q) { LSKeyPath::KeyVertexElimination(g, solution, random); //fprintf (stderr, "Ending key vertex elimination!\n"); if (verbose) fprintf (stderr, " q%d ", solution.GetCost()); } if (RUN_U) { LSVertexElimination::VertexElimination(g, solution, random); if (verbose) fprintf (stderr, " u%d ", solution.GetCost()); } if (RUN_K) { if (!RESTRICT_K || solution.GetCost() == oldcost) { KeyVertexInsertion(solution, random); } } EdgeCost newcost = solution.GetCost(); if (newcost > oldcost + EDGE_COST_PRECISION) fatal ("invalid result"); if (newcost > oldcost - EDGE_COST_PRECISION) break; //stop if result did not improve if (executionLogPtr != nullptr) executionLogPtr->AddSolution(solution); oldcost = newcost; } const bool VERBOSE_ROUNDS = false; if (VERBOSE_ROUNDS) fprintf (stderr, "%d ", i); //fprintf (stderr, "%d ", rounds); if (verbose) fprintf (stderr, "\n\nDone with local search: %d (%.2f ms, %.2f ms average)\n", solution.GetCost(), 1000 * timer.getTime(), 1000 * timer.getTime() / (double)rounds); //exit(-1); first = false; } static void TestLocalSearch (Graph &g, SteinerSolution &solution) { RFWLocalRandom random(RFWRandom::getInteger(1,999999999)); bool RUN_Q = true; bool RUN_V = true; bool RUN_U = false; bool verbose = false; ConstructiveAlgorithms::SPH (g, solution, NULL, Basics::PickRandomTerminal(g,random)); if (verbose) fprintf (stderr, "SPH found solution %d.\n", solution.GetCost()); int n = g.VertexCount(); EdgeCost oldcost = solution.GetCost(); RFWTimer timer(true); int rounds = 0; for (int i=0; i<10; i++) { rounds ++; if (RUN_V) { LSVertexInsertion::VertexInsertion(g, solution, n, random); MSTPrune(g, solution); if (verbose) fprintf (stderr, " v%d ", solution.GetCost()); } //fprintf (stderr, "Starting key vertex elimination!\n"); //fflush (stderr); if (RUN_Q) { LSKeyPath::KeyVertexElimination(g, solution, random); //fprintf (stderr, "Ending key vertex elimination!\n"); if (verbose) fprintf (stderr, " q%d ", solution.GetCost()); } if (RUN_U) { LSVertexElimination::VertexElimination(g, solution, random); if (verbose) fprintf (stderr, " u%d ", solution.GetCost()); } EdgeCost newcost = solution.GetCost(); if (newcost > oldcost) fatal ("invalid result"); if (newcost == oldcost) break; oldcost = newcost; } if (verbose) fprintf (stderr, "\n\nDone with local search: %d (%.2f ms, %.2f ms average)\n", solution.GetCost(), 1000 * timer.getTime(), 1000 * timer.getTime() / (double)rounds); //exit(-1); } // Comput minimum spanning tree of the graph g using Prim's algorithm (ignores terminals) // 'solution' will contain the MST edges static void MSTPrim (Graph &g, SteinerSolution &solution) { bool verbose = false; int n = g.VertexCount(); BinaryHeap<EdgeCost> heap(n); // = new BinaryHeap<ArcCost>(n); vector<int> parc (n+1); //not need to initialize unsigned int r = Basics::PickRandomTerminal(g); parc[r] = 0; int nscanned = 0; solution.Reset(); //int inscount = 0; heap.Insert(r, 0); while (!heap.IsEmpty()) { unsigned int v; EdgeCost acost; heap.RemoveFirst(v,acost); //v, out acost); if (v!=r) solution.Insert(parc[v]); //add parent edge to the solution //scan outgoing arcs nscanned ++; SPGArc *a, *end; for (g.GetBounds(v,a,end); a<end; a++) { int w = a->head; //neighbor if (solution.GetDegree(w) > 0) continue; //ignore if already in solution if (heap.Insert(w, a->cost)) { parc[w] = a->label; //inscount ++; } } } //fprintf (stderr, "%.3f ", (double)inscount / (double)n); //if (nscanned != n) fprintf (stderr, "Warning: graph is not connected"); } //-------------------------------------------------------------- // Kruskal's algorithm to compute the MST of the full graph. // (Could be made faster for some instances with partial sort.) //-------------------------------------------------------------- static void MSTKruskal (Graph &g, SteinerSolution &solution) { // create list of all edges sorted in increasing order of weight const bool verbose = false; int i, m = g.EdgeCount(); vector<int> elist(m+1); for (i=0; i<m; i++) {elist[i] = i+1;} sort(&elist[0], &elist[m], [&](int x, int y) {return g.GetCost(x)<g.GetCost(y);}); // create empty solution and union find with singletons solution.Reset(); int n = g.VertexCount(); UnionFind uf(n); int togo = n-1; //number of unions left // process all edges in order for (i=0; i<m; i++) { int e = elist[i]; int v, w; g.GetEndpoints(e,v,w); if (uf.Union(v,w)) { //if successfully joined... solution.Insert(e); //...we have a new edge in the tree if (--togo==0) break; } } if (verbose) fprintf (stderr, "%.3f ", (double)i/(double)m); } /// Compute the MST of the distance network of the subgraph induced /// by the vertices in bases. /// <param name="solution">Final solution (output)</param> /// <param name="bases">Set of bases (key vertices)</param> /* static void DNH(Graph &g, SteinerSolution &solution, UniverseSet &baselist) { int n = g.VertexCount(); int m = g.EdgeCount(); VoronoiData voronoi = new VoronoiData(n); UnionFind uf = new UnionFind(n); BinaryHeap<ArcCost> heap = new BinaryHeap<ArcCost>(n); ArcCost [] pertcost = null; ComputeVoronoi(voronoi, baselist, heap, pertcost); solution.Reset(); Boruvka(solution, voronoi, uf, pertcost); //Console.Error.WriteLine("DNH"); } */ /// Boruvka-based implementation of DNH (given a Voronoi diagram and the associated union-find data structure). /// Traverses a list of edge IDs in each pass, eliminating those that are no longer boundary. /// Seems to be worse than the version that actually traverses graphs. static void Boruvka(Graph &g, SteinerSolution &solution, VoronoiData &voronoi, UnionFind &uf, EdgeCost *pertcost) { int v, n = g.VertexCount(); int m = g.EdgeCount(); EdgeCost solvalue = 0; const bool verbose = false; //count boundary regions in the current diagram int nregions = 0; for (v=1; v<=n; v++) { // it's not clear find is needed, unless some merges happened before if (uf.Find(voronoi.GetBase(v))==v) nregions ++; } //Boruvka's algorithm int *minarc = new int[n+1]; //minimum outgoing edge from the region based in v EdgeCost *minvalue = new EdgeCost[n+1]; //value associated with the neighbor int *elist = new int [m]; //list of all potential boundary edges for (int i=0; i<m; i++) elist[i] = (i+1); int ecount = m; //number of edges in edge list int rounds = 0; bool changes = true; while (changes && nregions > 1) { rounds ++; //if (rounds > 3) break; changes = false; //initially, we don't know what are the arcs out of each component for (v=1; v<=n; v++) { minarc[v] = -1; minvalue[v] = 0; } int nextpos = 0; //fprintf (stderr, "%d ", ecount); for (int i=0; i<ecount; i++) { int e = elist[i]; //get edge in the current position int v, w; g.GetEndpoints(e,v,w); int bv = voronoi.GetBase(v); int bw = voronoi.GetBase(w); if (bv == bw) continue; //same base bv = uf.Find(bv); bw = uf.Find(bw); if (bv == bw) continue; //same component //found a boundary edge: move it forward in the list if (i!=nextpos) elist[nextpos++] = e; // get length of actual edge EdgeCost cost = (pertcost!=NULL) ? pertcost[e] : g.GetCost(e); cost += voronoi.GetDistance(v) + voronoi.GetDistance(w); //update bv and bw if better if (minarc[bv]==-1 || (cost<minvalue[bv])) {minarc[bv]=e; minvalue[bv]=cost;} if (minarc[bw]==-1 || (cost<minvalue[bw])) {minarc[bw]=e; minvalue[bw]=cost;} } ecount = nextpos; //fewer edges for next round //join each region to its best neighbor int bvisited = 0; int b; for (b=1; b<=n; b++) { if (minarc[b] >= 0) { //best neighbor defined... bvisited ++; int w = 0; g.GetEndpoints(minarc[b], v, w); int bv = voronoi.GetBase(v); int bw = voronoi.GetBase(w); if (uf.Union(bv,bw)) { // if they were not already joined... changes = true; nregions--; solution.Insert(minarc[b]); while (v != bv) { int f = voronoi.GetParentArc(v); if (!solution.Insert(f)) break; v = g.GetOther(f, v); } while (w != bw) { int f = voronoi.GetParentArc(w); if (!solution.Insert(f)) break; w = g.GetOther(f, w); } } } } } if (verbose) fprintf(stderr, "\n"); delete [] minvalue; delete [] minarc; delete [] elist; } static void DNHPrim (Graph &g, SteinerSolution &solution, VoronoiData &voronoi, UnionFind &uf) { int n = g.VertexCount(); int m = g.EdgeCount(); vector <int> new2old (m+1,-1); Graph dg; dg.SetVertices(n); dg.SetEdges(m); //maximum tentative number of edges // build appropriate subgraph of the distance network int ecount = 0; for (int v=1; v<=n; v++) { int bv = uf.Find(voronoi.GetBase(v)); EdgeCost vdist = -1; SPGArc *a, *end; for (g.GetBounds(v,a,end); a<end; a++) { int w = a->head; if (v>=w) continue; int bw = uf.Find(voronoi.GetBase(w)); if (bv == bw) continue; dg.MakeTerminal(bv); dg.MakeTerminal(bw); if (vdist<0) vdist = voronoi.GetDistance(v); EdgeCost cost = a->cost + vdist + voronoi.GetDistance(w); dg.AddEdge(bv,bw,cost); new2old[++ecount] = a->label; } } dg.Commit(); //create actual graph // find a solution in the new graph SteinerSolution ds(&dg); MSTPrim(dg,ds); // transform into solution in the new graph solution.Reset(); int newm = dg.EdgeCount(); for (int e=1; e<=newm; e++) { if (!ds.Contains(e)) continue; int orige = new2old[e]; //original boundary edge if (orige<1 || orige>m) {fatal ("Edge out of range.\n");} int v,w; g.GetEndpoints(orige,v,w); solution.Insert(orige); for (;;) { int f = voronoi.GetParentArc(v); if (f<1 || !solution.Insert(f)) break; v = g.GetOther(f,v); } for (;;) { int f = voronoi.GetParentArc(w); if (f<1 || !solution.Insert(f)) break; w = g.GetOther(f,w); } } } /// Run DNH (Boruvka implementation) to create a solution from scratch. /// If 'r' is null, uses the original edge weights; otherwise, perturbs /// edge weights before running the algorithm. /// <param name="solution">The output solution (will be deleted).</param> /// <param name="r">Random number generator.</param> static void FullBoruvka(Graph &g, SteinerSolution &solution) { //, OptRandom r) { int n = g.VertexCount(); int m = g.EdgeCount(); UniverseSet baselist(n); // = new UniverseSet(n); VoronoiData voronoi(n); // = new VoronoiData(n); UnionFind uf(n); // = new UnionFind(n); BinaryHeap<EdgeCost> heap(n); // = new BinaryHeap<ArcCost>(n); /* ArcCost [] pertcost = null; if (r != null) { pertcost = new ArcCost[m + 1]; InitPerturbation(pertcost, r); } */ baselist.Reset(); for (int v = 1; v <= n; v++) { if (g.IsTerminal(v)) baselist.Insert(v); } //fprintf (stderr, "Should be computing Voronoi.\n"); Basics::ComputeVoronoi(g, voronoi, baselist, heap, NULL); //pertcost); solution.Reset(); // return; //fprintf (stderr, "Missing boruvka!\n"); //Boruvka(g, solution, voronoi, uf, NULL); Preprocessing::BoruvkaGraph(g, solution, voronoi, uf, NULL); //DNHPrim(g,solution,voronoi,uf); //Console.Error.WriteLine("t3:{0} ", timer.GetTime()); } /// Modifies a solution by computing the MST of the subgraph induced by its vertices /// and removing all vertices of degree one. Changes the solution. /// <param name="svertices">Vertices in the solution (doesn't change).</param> /// <param name="solution">Edges in the solution (may change).</param> static bool MSTPrune(Graph &g, SteinerSolution &solution) { //return 0; EdgeCost original = solution.GetCost(); int n = g.VertexCount(); UniverseSet svertices(n); Basics::MarkSolutionNodes(g, solution, svertices); MST(g,solution,svertices); Basics::Prune(g,solution); //fprintf (stderr, "Solution costs %d, gain is %d.\n", solution.GetCost(), original - solution.GetCost()); //Prune(g,solution); //fprintf (stderr, "g%d ", original - solution.GetCost()); return (solution.GetCost() < original) ? 1 : 0; } static int VeryOldPickTerminal(Graph &g, RFWLocalRandom &random) { int t = 0; int count = 0; int n = g.VertexCount(); for (int v=1; v<=n; v++) { if (g.IsTerminal(v)) { if (t==0 || g.GetDegree(v) < g.GetDegree(t)) { t = v; } } } return t; } /// <summary> /// Compute the MST of the subgraph induced by svertices /// (assumed to contain all terminals---DO I NEED THIS?) /// </summary> /// <param name="svertices">list of vertices to be spanned</param> /// <param name="solution">solution in which the MST will be stored</param> /// <returns>Number of vertices scanned.</returns> static int MST (Graph &g, SteinerSolution &solution, UniverseSet &svertices) { bool verbose = false; int n = g.VertexCount(); BinaryHeap<EdgeCost> heap(n); vector<int> parc (n+1); int r = Basics::PickRandomTerminal(g); if (!svertices.Contains(r)) fatal ("Terminal does not appear to belong to the solution."); parc[r] = 0; int nscanned = 0; //run Prim's algorithm solution.Reset(); heap.Insert(r, 0); while (!heap.IsEmpty()) { unsigned int v; EdgeCost acost; heap.RemoveFirst(v,acost); if (v!=r) solution.Insert(parc[v]); //add edge (p(v),v) to solution //scan vertices nscanned ++; SPGArc *a, *end; for (g.GetBounds(v,a,end); a<end; a++) { int w = a->head; if (!svertices.Contains(w)) continue; //we only care about svertex if (solution.GetDegree(w) > 0) continue; //vertex already in the new tree if (heap.Insert(w, a->cost)) parc[w] = a->label; } } //if (solution.Count() < g.TerminalCount() - 1) {fatal ("solution does not have enough vertices");} return nscanned; } };

declare_simd_ast_print.c

// RUN: %clang_cc1 -verify -fopenmp -ast-print %s | FileCheck %s // RUN: %clang_cc1 -fopenmp -emit-pch -o %t %s // RUN: %clang_cc1 -fopenmp -include-pch %t -fsyntax-only -verify %s -ast-print | FileCheck %s // RUN: %clang_cc1 -verify -fopenmp-simd -ast-print %s | FileCheck %s // RUN: %clang_cc1 -fopenmp-simd -emit-pch -o %t %s // RUN: %clang_cc1 -fopenmp-simd -include-pch %t -fsyntax-only -verify %s -ast-print | FileCheck %s // expected-no-diagnostics #ifndef HEADER #define HEADER #pragma omp declare simd aligned(b : 64) #pragma omp declare simd simdlen(32) aligned(d, b) #pragma omp declare simd inbranch, uniform(d) linear(val(s1, s2) : 32) #pragma omp declare simd notinbranch simdlen(2), uniform(s1, s2) linear(d: s1) void add_1(float *d, int s1, float *s2, double b[]) __attribute__((cold)); // CHECK: #pragma omp declare simd notinbranch simdlen(2) uniform(s1, s2) linear(val(d): s1){{$}} // CHECK-NEXT: #pragma omp declare simd inbranch uniform(d) linear(val(s1): 32) linear(val(s2): 32){{$}} // CHECK-NEXT: #pragma omp declare simd simdlen(32) aligned(d) aligned(b){{$}} // CHECK-NEXT: #pragma omp declare simd aligned(b: 64){{$}} // CHECK-NEXT: void add_1(float *d, int s1, float *s2, double b[]) __attribute__((cold)) #endif

DRB049-fprintf-orig-no.c

/* Copyright (c) 2017, Lawrence Livermore National Security, LLC. Produced at the Lawrence Livermore National Laboratory Written by Chunhua Liao, Pei-Hung Lin, Joshua Asplund, Markus Schordan, and Ian Karlin (email: liao6@llnl.gov, lin32@llnl.gov, asplund1@llnl.gov, schordan1@llnl.gov, karlin1@llnl.gov) LLNL-CODE-732144 All rights reserved. This file is part of DataRaceBench. For details, see https://github.com/LLNL/dataracebench. Please also see the LICENSE file for our additional BSD notice. Redistribution and use in source and binary forms, with or without modification, are permitted provided that the following conditions are met: * Redistributions of source code must retain the above copyright notice, this list of conditions and the disclaimer below. * Redistributions in binary form must reproduce the above copyright notice, this list of conditions and the disclaimer (as noted below) in the documentation and/or other materials provided with the distribution. * Neither the name of the LLNS/LLNL nor the names of its contributors may be used to endorse or promote products derived from this software without specific prior written permission. THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL LAWRENCE LIVERMORE NATIONAL SECURITY, LLC, THE U.S. DEPARTMENT OF ENERGY OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. */ #include <stdio.h> #include <stdlib.h> /* Example use of fprintf */ #include <stdio.h> int main(int argc, char* argv[]) { int i; int ret; FILE* pfile; int len=1000; int A[1000]; #pragma omp parallel for simd for (i=0; i<len; i++) A[i]=i; pfile = fopen("mytempfile.txt","a+"); if (pfile ==NULL) { fprintf(stderr,"Error in fopen()\n"); } #pragma omp parallel for simd ordered for (i=0; i<len; ++i) { #pragma omp ordered simd fprintf(pfile, "%d\n", A[i] ); } fclose(pfile); ret = remove("mytempfile.txt"); if (ret != 0) { fprintf(stderr, "Error: unable to delete mytempfile.txt\n"); } return 0; }

laplace.h

#ifndef LAPLACE_H #define LAPLACE_H void laplace(const Storage3D& in, Storage3D& out) { for (int64_t i = 0; i < domain_size; ++i) { for (int64_t j = 0; j < domain_size; ++j) { for (int64_t k = 0; k < domain_height; ++k) { out(i, j, k) = -4.0 * in(i, j, k) + ((in(i - 1, j, k) + in(i + 1, j, k)) + (in(i, j + 1, k) + in(i, j - 1, k))); } } } } void laplace_fullfusion(const Storage3D& in, Storage3D& out) { for (int64_t i = 0; i < domain_size; ++i) { for (int64_t j = 0; j < domain_size; ++j) { for (int64_t k = 0; k < domain_height; ++k) { out(i, j, k) = -4.0 * in(i, j, k) + ((in(i - 1, j, k) + in(i + 1, j, k)) + (in(i, j + 1, k) + in(i, j - 1, k))); } } } } void laplace_partialfusion(const Storage3D& in, Storage3D& out) { for (int64_t i = 0; i < domain_size; ++i) { for (int64_t j = 0; j < domain_size; ++j) { for (int64_t k = 0; k < domain_height; ++k) { out(i, j, k) = -4.0 * in(i, j, k) + ((in(i - 1, j, k) + in(i + 1, j, k)) + (in(i, j + 1, k) + in(i, j - 1, k))); } } } } void laplace_openmp(const Storage3D& in, Storage3D& out) { #pragma omp parallel for for (int64_t i = 0; i < domain_size; ++i) { for (int64_t j = 0; j < domain_size; ++j) { for (int64_t k = 0; k < domain_height; ++k) { out(i, j, k) = -4.0 * in(i, j, k) + ((in(i - 1, j, k) + in(i + 1, j, k)) + (in(i, j + 1, k) + in(i, j - 1, k))); } } } } #endif // LAPLACE_H

openmp.c

#include <stdio.h> #include <omp.h> int main(int argc, char **argv) { #pragma omp parallel for for (int i = 0; i < argc; i++) { printf("Thread %d/%d: %s\n", omp_get_thread_num(), omp_get_num_threads(), argv[i]); } }

LAGraph_pagerank3b.c

//------------------------------------------------------------------------------ // LAGraph_pagerank3b: pagerank using a real semiring //------------------------------------------------------------------------------ /* LAGraph: graph algorithms based on GraphBLAS Copyright 2019 LAGraph Contributors. (see Contributors.txt for a full list of Contributors; see ContributionInstructions.txt for information on how you can Contribute to this project). All Rights Reserved. NO WARRANTY. THIS MATERIAL IS FURNISHED ON AN "AS-IS" BASIS. THE LAGRAPH CONTRIBUTORS MAKE NO WARRANTIES OF ANY KIND, EITHER EXPRESSED OR IMPLIED, AS TO ANY MATTER INCLUDING, BUT NOT LIMITED TO, WARRANTY OF FITNESS FOR PURPOSE OR MERCHANTABILITY, EXCLUSIVITY, OR RESULTS OBTAINED FROM USE OF THE MATERIAL. THE CONTRIBUTORS DO NOT MAKE ANY WARRANTY OF ANY KIND WITH RESPECT TO FREEDOM FROM PATENT, TRADEMARK, OR COPYRIGHT INFRINGEMENT. Released under a BSD license, please see the LICENSE file distributed with this Software or contact permission@sei.cmu.edu for full terms. Created, in part, with funding and support from the United States Government. (see Acknowledgments.txt file). This program includes and/or can make use of certain third party source code, object code, documentation and other files ("Third Party Software"). See LICENSE file for more details. */ // LAGraph_pagerank3b: Alternative PageRank implementation using a real // semiring. // // This algorithm follows the specification given in the GAP Benchmark Suite: // https://arxiv.org/abs/1508.03619 // For fastest results, the input matrix should be GrB_FP32, stored in // GxB_BY_COL format. #include "LAGraph.h" #define LAGRAPH_FREE_ALL { \ GrB_free(&transpose_desc); \ GrB_free(&invmask_desc); \ GrB_free(&A); \ GrB_free(&G); \ GrB_free(&grb_d_out); \ GrB_free(&importance_vec); \ GrB_free(&grb_pr); \ }; // uncomment this to see the intermidiate resluts; lots of prints!! //#undef NDEBUG // uncomment this to see the timing info #define PRINT_TIMING_INFO GrB_Info LAGraph_pagerank3b // PageRank definition ( GrB_Vector *result, // output: array of LAGraph_PageRank structs GrB_Matrix A_input, // binary input graph, not modified float damping_factor, // damping factor unsigned long itermax, // maximum number of iterations int* iters // output: number of iterations taken ) { GrB_Info info; GrB_Index n; GrB_Descriptor invmask_desc = NULL ; GrB_Descriptor transpose_desc = NULL ; GrB_Vector grb_d_out = NULL ; GrB_Matrix A = NULL ; #ifdef PRINT_TIMING_INFO // start the timer double tic [2] ; LAGraph_tic (tic) ; #endif GrB_Vector importance_vec = NULL ; GrB_Vector grb_pr = NULL; GrB_Matrix G = NULL ; // a dense row of zeros zeroes(1,n) GrB_Index ncols ; //number of columnns LAGRAPH_OK(GrB_Matrix_ncols(&ncols , A_input)); LAGRAPH_OK(GrB_Matrix_nrows(&n, A_input)); GrB_Index nvals; LAGRAPH_OK(GrB_Matrix_nvals(&nvals, A_input)); if (ncols != n) { return (GrB_DIMENSION_MISMATCH) ; } LAGRAPH_OK(GrB_Matrix_new (&G, GrB_FP32, n, n)); LAGRAPH_OK(GrB_Matrix_new (&A, GrB_FP32, n, n)); LAGRAPH_OK(GxB_set (A, GxB_FORMAT, GxB_BY_COL)); // G is zeros in last row for (GrB_Index c = 0; c < n; c++){ LAGRAPH_OK(GrB_Matrix_setElement (G, 0.0, n-1, c)); } #ifndef NDEBUG int print_size = 5; //number of entries get printed print_size = (print_size > n)? n : print_size; // GxB_print (G, 3) ; #endif // A = A_input + G; LAGRAPH_OK(GrB_eWiseAdd (A, NULL, NULL, GrB_PLUS_FP32, A_input, G, NULL)); GrB_free (&G) ; #ifndef NDEBUG // GxB_print (A, 3) ; #endif // Create complement descriptor LAGRAPH_OK(GrB_Descriptor_new(&invmask_desc)); LAGRAPH_OK(GrB_Descriptor_set(invmask_desc, GrB_MASK, GrB_SCMP)); // Create transpose descriptor LAGRAPH_OK(GrB_Descriptor_new(&transpose_desc)); LAGRAPH_OK(GrB_Descriptor_set(transpose_desc, GrB_INP0, GrB_TRAN)); LAGRAPH_OK(GrB_Descriptor_set(transpose_desc, GrB_OUTP, GrB_REPLACE)); // Matrix A row sum // Stores the outbound degrees of all vertices LAGRAPH_OK(GrB_Vector_new(&grb_d_out, GrB_FP32, n)); LAGRAPH_OK(GrB_reduce( grb_d_out, NULL, NULL, GxB_PLUS_FP32_MONOID, A, NULL )); #ifndef NDEBUG GxB_print (grb_d_out, 1) ; // GxB_print (A, 3) ; #endif // Iteration // Initialize PR vector LAGRAPH_OK(GrB_Vector_new(&grb_pr, GrB_FP32, n)); LAGRAPH_OK(GrB_Vector_new(&importance_vec, GrB_FP32, n)); // Teleport value const float teleport = (1 - damping_factor) / n; float tol = 1e-4; float rdiff = 1 ; // first iteration is always done GrB_Type type = GrB_FP32 ; GrB_Index *dI = NULL ; float *d_sp= NULL ; GrB_Index d_nvals; GrB_Index d_n; // d_sp <----- grb_d_out || export LAGRAPH_OK (GxB_Vector_export (&grb_d_out, &type, &d_n, &d_nvals, &dI, (void **) (&d_sp), NULL)) ; // dens d_out float *d_out = (float *) LAGraph_calloc (n, sizeof(float)); int nthreads = LAGraph_get_nthreads ( ) ; nthreads = LAGRAPH_MIN (n , nthreads) ; nthreads = LAGRAPH_MAX (nthreads, 1) ; #pragma omp parallel for num_threads(nthreads) schedule(static) for (int64_t i = 0 ; i < d_nvals; i++){ GrB_Index ind = (GrB_Index) dI[i]; d_out [ind] = d_sp [i]; } free (d_sp); free (dI); #ifndef NDEBUG for (int i = 0 ; i < print_size; i++){ printf("d_out [%d]=%ld\n", i, d_out [i]); } #endif // initializing pr float *pr = (float *) malloc (n*sizeof(float)); #pragma omp parallel for num_threads(nthreads) schedule(static) for (int i = 0; i < n ; i++){ pr [i] = 1.0/n; } #ifndef NDEBUG for (int i = 0 ; i < print_size ; i++){ printf("pr[%d]=%f\n", i, pr [i]); } #endif float *oldpr = (float *) malloc (n*sizeof(float)); //initailze the dense indices GrB_Index *I = LAGraph_malloc(n, sizeof(GrB_Index)); #pragma omp parallel for num_threads(nthreads) schedule(static) for (GrB_Index j = 0; j < n; j++){ I[j] = j; } #ifdef PRINT_TIMING_INFO // stop the timer double t1 = LAGraph_toc (tic); printf ("\ninitialization time: %12.6e (sec)\n",t1); LAGraph_tic (tic); #endif for ((*iters) = 0 ; (*iters) < itermax && rdiff > tol ; (*iters)++) { // oldpr = pr; deep copy //GrB_Vector_dup(&oldpr, pr); #pragma omp parallel for num_threads(nthreads) schedule(static) for (int i = 0; i < n ; i++){ oldpr [i] = pr [i]; } // Importance calculation #pragma omp parallel for num_threads(nthreads) schedule(static) for (int i = 0 ; i < n; i++){ if (d_out [i] != 0){ pr [i] = damping_factor * pr [i] / d_out [i]; } else{ pr [i] = 0; } } #ifndef NDEBUG for (int i = 0 ; i < print_size; i++){ printf (" pr [%d] = %f\n", i, pr [i]); } #endif // importance_vec <----- pr LAGRAPH_OK (GxB_Vector_import (&importance_vec, GrB_FP32, n, n, &I, (void **) (&pr), NULL)) ; #ifndef NDEBUG printf ("after importance_vec import\n"); GxB_print (importance_vec, 2) ; #endif // Calculate total PR of all inbound vertices // importance_vec = A' * importance_vec LAGRAPH_OK(GrB_mxv( importance_vec, NULL, NULL, GxB_PLUS_TIMES_FP32, A, importance_vec, transpose_desc )); #ifndef NDEBUG printf ("==============2\n"); printf ("after mxv\n"); GxB_print (importance_vec, 1) ; #endif GrB_Index nvals_exp; // pr <----- importance_vec GrB_Type ivtype; LAGRAPH_OK (GxB_Vector_export (&importance_vec, &ivtype, &n, &nvals_exp, &I, (void **) (&pr), NULL)) ; // assert (nvals_exp == n ); // PageRank summarization // Add teleport, importance_vec, and dangling_vec components together // pr = (1-df)/n + pr #pragma omp parallel for num_threads(nthreads) schedule(static) for (int i = 0 ; i < n; i++){ pr [i] += teleport; } #ifndef NDEBUG for (int i = 0 ; i < print_size; i++){ printf (" pr [%d] = %f\n", i, pr [i]); } #endif //---------------------------------------------------------------------- // rdiff = sum ((oldpr-pr).^2) //---------------------------------------------------------------------- rdiff = 0; // norm (oldpr pr, 1) #pragma omp parallel for num_threads(nthreads) reduction(+:rdiff) for (int i = 0 ; i < n; i++){ float d = (oldpr [i] - pr [i]); d = (d > 0 ? d : -d); //abs(d) rdiff += d; } #ifndef NDEBUG printf("---------------------------iters %d rdiff=%f\n",*iters, rdiff); #endif } #ifdef PRINT_TIMING_INFO // stop the timer double t2 = LAGraph_toc (tic); printf ("compuatatin time: %12.6e (sec) ratio (comp/init): %f\n\n", t2, t2/t1); #endif GrB_Index *prI = LAGraph_malloc(n, sizeof(GrB_Index)); // grb_pr<----- pr || import back LAGRAPH_OK (GxB_Vector_import (&grb_pr, GrB_FP32, n, n, &I, (void **) (&pr), NULL)) ; (*result) = grb_pr; free(I); free (oldpr); return (GrB_SUCCESS); }

serial_tree_learner.h

/*! * Copyright (c) 2016 Microsoft Corporation. All rights reserved. * Licensed under the MIT License. See LICENSE file in the project root for license information. */ #ifndef LIGHTGBM_TREELEARNER_SERIAL_TREE_LEARNER_H_ #define LIGHTGBM_TREELEARNER_SERIAL_TREE_LEARNER_H_ #include <LightGBM/dataset.h> #include <LightGBM/tree.h> #include <LightGBM/tree_learner.h> #include <LightGBM/utils/array_args.h> #include <LightGBM/utils/json11.h> #include <LightGBM/utils/random.h> #include <string> #include <cmath> #include <cstdio> #include <memory> #include <random> #include <vector> #include "col_sampler.hpp" #include "data_partition.hpp" #include "feature_histogram.hpp" #include "leaf_splits.hpp" #include "monotone_constraints.hpp" #include "split_info.hpp" #ifdef USE_GPU // Use 4KBytes aligned allocator for ordered gradients and ordered hessians when GPU is enabled. // This is necessary to pin the two arrays in memory and make transferring faster. #include <boost/align/aligned_allocator.hpp> #endif namespace LightGBM { using json11::Json; /*! \brief forward declaration */ class CostEfficientGradientBoosting; /*! * \brief Used for learning a tree by single machine */ class SerialTreeLearner: public TreeLearner { public: friend CostEfficientGradientBoosting; explicit SerialTreeLearner(const Config* config); ~SerialTreeLearner(); void Init(const Dataset* train_data, bool is_constant_hessian) override; void ResetTrainingData(const Dataset* train_data, bool is_constant_hessian) override { ResetTrainingDataInner(train_data, is_constant_hessian, true); } void ResetIsConstantHessian(bool is_constant_hessian) override { share_state_->is_constant_hessian = is_constant_hessian; } virtual void ResetTrainingDataInner(const Dataset* train_data, bool is_constant_hessian, bool reset_multi_val_bin); void ResetConfig(const Config* config) override; inline void SetForcedSplit(const Json* forced_split_json) override { if (forced_split_json != nullptr && !forced_split_json->is_null()) { forced_split_json_ = forced_split_json; } else { forced_split_json_ = nullptr; } } Tree* Train(const score_t* gradients, const score_t *hessians) override; Tree* FitByExistingTree(const Tree* old_tree, const score_t* gradients, const score_t* hessians) const override; Tree* FitByExistingTree(const Tree* old_tree, const std::vector<int>& leaf_pred, const score_t* gradients, const score_t* hessians) override; void SetBaggingData(const Dataset* subset, const data_size_t* used_indices, data_size_t num_data) override { if (subset == nullptr) { data_partition_->SetUsedDataIndices(used_indices, num_data); share_state_->is_use_subrow = false; } else { ResetTrainingDataInner(subset, share_state_->is_constant_hessian, false); share_state_->is_use_subrow = true; share_state_->is_subrow_copied = false; share_state_->bagging_use_indices = used_indices; share_state_->bagging_indices_cnt = num_data; } } void AddPredictionToScore(const Tree* tree, double* out_score) const override { if (tree->num_leaves() <= 1) { return; } CHECK_LE(tree->num_leaves(), data_partition_->num_leaves()); #pragma omp parallel for schedule(static, 1) for (int i = 0; i < tree->num_leaves(); ++i) { double output = static_cast<double>(tree->LeafOutput(i)); data_size_t cnt_leaf_data = 0; auto tmp_idx = data_partition_->GetIndexOnLeaf(i, &cnt_leaf_data); for (data_size_t j = 0; j < cnt_leaf_data; ++j) { out_score[tmp_idx[j]] += output; } } } void RenewTreeOutput(Tree* tree, const ObjectiveFunction* obj, std::function<double(const label_t*, int)> residual_getter, data_size_t total_num_data, const data_size_t* bag_indices, data_size_t bag_cnt) const override; protected: void ComputeBestSplitForFeature(FeatureHistogram* histogram_array_, int feature_index, int real_fidx, bool is_feature_used, int num_data, const LeafSplits* leaf_splits, SplitInfo* best_split); void GetShareStates(const Dataset* dataset, bool is_constant_hessian, bool is_first_time); void RecomputeBestSplitForLeaf(int leaf, SplitInfo* split); /*! * \brief Some initial works before training */ virtual void BeforeTrain(); /*! * \brief Some initial works before FindBestSplit */ virtual bool BeforeFindBestSplit(const Tree* tree, int left_leaf, int right_leaf); virtual void FindBestSplits(const Tree* tree); virtual void ConstructHistograms(const std::vector<int8_t>& is_feature_used, bool use_subtract); virtual void FindBestSplitsFromHistograms(const std::vector<int8_t>& is_feature_used, bool use_subtract, const Tree*); /*! * \brief Partition tree and data according best split. * \param tree Current tree, will be splitted on this function. * \param best_leaf The index of leaf that will be splitted. * \param left_leaf The index of left leaf after splitted. * \param right_leaf The index of right leaf after splitted. */ inline virtual void Split(Tree* tree, int best_leaf, int* left_leaf, int* right_leaf) { SplitInner(tree, best_leaf, left_leaf, right_leaf, true); } void SplitInner(Tree* tree, int best_leaf, int* left_leaf, int* right_leaf, bool update_cnt); /* Force splits with forced_split_json dict and then return num splits forced.*/ int32_t ForceSplits(Tree* tree, int* left_leaf, int* right_leaf, int* cur_depth); /*! * \brief Get the number of data in a leaf * \param leaf_idx The index of leaf * \return The number of data in the leaf_idx leaf */ inline virtual data_size_t GetGlobalDataCountInLeaf(int leaf_idx) const; /*! \brief number of data */ data_size_t num_data_; /*! \brief number of features */ int num_features_; /*! \brief training data */ const Dataset* train_data_; /*! \brief gradients of current iteration */ const score_t* gradients_; /*! \brief hessians of current iteration */ const score_t* hessians_; /*! \brief training data partition on leaves */ std::unique_ptr<DataPartition> data_partition_; /*! \brief pointer to histograms array of parent of current leaves */ FeatureHistogram* parent_leaf_histogram_array_; /*! \brief pointer to histograms array of smaller leaf */ FeatureHistogram* smaller_leaf_histogram_array_; /*! \brief pointer to histograms array of larger leaf */ FeatureHistogram* larger_leaf_histogram_array_; /*! \brief store best split points for all leaves */ std::vector<SplitInfo> best_split_per_leaf_; /*! \brief store best split per feature for all leaves */ std::vector<SplitInfo> splits_per_leaf_; /*! \brief stores minimum and maximum constraints for each leaf */ std::unique_ptr<LeafConstraintsBase> constraints_; /*! \brief stores best thresholds for all feature for smaller leaf */ std::unique_ptr<LeafSplits> smaller_leaf_splits_; /*! \brief stores best thresholds for all feature for larger leaf */ std::unique_ptr<LeafSplits> larger_leaf_splits_; #ifdef USE_GPU /*! \brief gradients of current iteration, ordered for cache optimized, aligned to 4K page */ std::vector<score_t, boost::alignment::aligned_allocator<score_t, 4096>> ordered_gradients_; /*! \brief hessians of current iteration, ordered for cache optimized, aligned to 4K page */ std::vector<score_t, boost::alignment::aligned_allocator<score_t, 4096>> ordered_hessians_; #else /*! \brief gradients of current iteration, ordered for cache optimized */ std::vector<score_t, Common::AlignmentAllocator<score_t, kAlignedSize>> ordered_gradients_; /*! \brief hessians of current iteration, ordered for cache optimized */ std::vector<score_t, Common::AlignmentAllocator<score_t, kAlignedSize>> ordered_hessians_; #endif /*! \brief used to cache historical histogram to speed up*/ HistogramPool histogram_pool_; /*! \brief config of tree learner*/ const Config* config_; ColSampler col_sampler_; const Json* forced_split_json_; std::unique_ptr<TrainingShareStates> share_state_; std::unique_ptr<CostEfficientGradientBoosting> cegb_; }; inline data_size_t SerialTreeLearner::GetGlobalDataCountInLeaf(int leaf_idx) const { if (leaf_idx >= 0) { return data_partition_->leaf_count(leaf_idx); } else { return 0; } } } // namespace LightGBM #endif // LightGBM_TREELEARNER_SERIAL_TREE_LEARNER_H_

PeptideIndexing.h

// -------------------------------------------------------------------------- // OpenMS -- Open-Source Mass Spectrometry // -------------------------------------------------------------------------- // Copyright The OpenMS Team -- Eberhard Karls University Tuebingen, // ETH Zurich, and Freie Universitaet Berlin 2002-2017. // // This software is released under a three-clause BSD license: // * Redistributions of source code must retain the above copyright // notice, this list of conditions and the following disclaimer. // * Redistributions in binary form must reproduce the above copyright // notice, this list of conditions and the following disclaimer in the // documentation and/or other materials provided with the distribution. // * Neither the name of any author or any participating institution // may be used to endorse or promote products derived from this software // without specific prior written permission. // For a full list of authors, refer to the file AUTHORS. // -------------------------------------------------------------------------- // THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" // AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE // IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE // ARE DISCLAIMED. IN NO EVENT SHALL ANY OF THE AUTHORS OR THE CONTRIBUTING // INSTITUTIONS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, // EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, // PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; // OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, // WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR // OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF // ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. // // -------------------------------------------------------------------------- // $Maintainer: Chris Bielow $ // $Authors: Andreas Bertsch, Chris Bielow $ // -------------------------------------------------------------------------- #ifndef OPENMS_ANALYSIS_ID_PEPTIDEINDEXING_H #define OPENMS_ANALYSIS_ID_PEPTIDEINDEXING_H #include <OpenMS/ANALYSIS/ID/AhoCorasickAmbiguous.h> #include <OpenMS/CHEMISTRY/ProteaseDigestion.h> #include <OpenMS/CHEMISTRY/ProteaseDB.h> #include <OpenMS/CONCEPT/LogStream.h> #include <OpenMS/CONCEPT/ProgressLogger.h> #include <OpenMS/DATASTRUCTURES/DefaultParamHandler.h> #include <OpenMS/DATASTRUCTURES/FASTAContainer.h> #include <OpenMS/DATASTRUCTURES/ListUtils.h> #include <OpenMS/DATASTRUCTURES/SeqanIncludeWrapper.h> #include <OpenMS/FORMAT/FASTAFile.h> #include <OpenMS/KERNEL/StandardTypes.h> #include <OpenMS/METADATA/PeptideEvidence.h> #include <OpenMS/METADATA/PeptideIdentification.h> #include <OpenMS/METADATA/ProteinIdentification.h> #include <OpenMS/SYSTEM/StopWatch.h> #include <OpenMS/SYSTEM/SysInfo.h> #include <atomic> #include <algorithm> #include <fstream> namespace OpenMS { /** @brief Refreshes the protein references for all peptide hits in a vector of PeptideIdentifications and adds target/decoy information. All peptide and protein hits are annotated with target/decoy information, using the meta value "target_decoy". For proteins the possible values are "target" and "decoy", depending on whether the protein accession contains the decoy pattern (parameter @p decoy_string) as a suffix or prefix, respectively (see parameter @p prefix). For peptides, the possible values are "target", "decoy" and "target+decoy", depending on whether the peptide sequence is found only in target proteins, only in decoy proteins, or in both. The target/decoy information is crucial for the @ref TOPP_FalseDiscoveryRate tool. (For FDR calculations, "target+decoy" peptide hits count as target hits.) @note Make sure that your protein names in the database contain a correctly formatted decoy string. This can be ensured by using @ref UTILS_DecoyDatabase. If the decoy identifier is not recognized successfully all proteins will be assumed to stem from the target-part of the query.<br> E.g., "sw|P33354_DECOY|YEHR_ECOLI Uncharacterized lipop..." is <b>invalid</b>, since the tool has no knowledge of how SwissProt entries are build up. A correct identifier could be "DECOY_sw|P33354|YEHR_ECOLI Uncharacterized li ..." or "sw|P33354|YEHR_ECOLI_DECOY Uncharacterized li", depending on whether you are using prefix or suffix annotation.<br> This tool will also report some helpful target/decoy statistics when it is done. By default this tool will fail if an unmatched peptide occurs, i.e. if the database does not contain the corresponding protein. You can force it to return successfully in this case by using the flag @p allow_unmatched. Search engines (such as Mascot) will replace ambiguous amino acids ('B', 'J', 'Z' and 'X') in the protein database with unambiguous amino acids in the reported peptides, e.g. exchange 'X' with 'H'. This will cause such peptides to not be found by exactly matching their sequences to the protein database. However, we can recover these cases by using tolerant search for ambiguous amino acids in the protein sequence. This is done by default with up to four amino acids per peptide hit. If you only want exact matches, set @p aaa_max to zero (but expect that unmatched peptides might occur)! Leucine/Isoleucine: Further complications can arise due to the presence of the isobaric amino acids isoleucine ('I') and leucine ('L') in protein sequences. Since the two have the exact same chemical composition and mass, they generally cannot be distinguished by mass spectrometry. If a peptide containing 'I' was reported as a match for a spectrum, a peptide containing 'L' instead would be an equally good match (and vice versa). To account for this inherent ambiguity, setting the flag @p IL_equivalent causes 'I' and 'L' to be considered as indistinguishable.@n For example, if the sequence "PEPTIDE" (matching "Protein1") was identified as a search hit, but the database additionally contained "PEPTLDE" (matching "Protein2"), running PeptideIndexer with the @p IL_equivalent option would report both "Protein1" and "Protein2" as accessions for "PEPTIDE". (This is independent of ambiguous matching via @p aaa_max.) Additionally, setting this flag will convert all 'J's in any protein sequence to 'I'. This way, no tolerant search is required for 'J' (but is still possible for all the other ambiguous amino acids). If @p write_protein_sequences is requested and @p IL_equivalent is set as well, both the I/L-version and unmodified protein sequences need to be stored internally. This requires some extra memory, roughly equivalent to the size of the FASTA database file itself. Enzyme specificity: Once a peptide sequence is found in a protein sequence, this does <b>not</b> imply that the hit is valid! This is where enzyme specificity comes into play. By default, we demand that the peptide is fully tryptic (i.e. the enzyme parameter is set to "trypsin" and specificity is "full"). So unless the peptide coincides with C- and/or N-terminus of the protein, the peptide's cleavage pattern should fulfill the trypsin cleavage rule [KR][^P]. We make two exceptions to the specificity constraints: 1) for peptides starting at the second or third position of a protein are still considered N-terminally specific, since the residues can be cleaved off in vivo; X!Tandem reports these peptides. For example, the two peptides ABAR and LABAR would both match a protein starting with MLABAR. 2) adventitious cleavage at Asp|Pro (Aspartate/D | Proline/P) is allowed for all enzymes (as supported by X!Tandem), i.e. counts as a proper cleavage site (see http://www.thegpm.org/tandem/release.html). You can relax the requirements further by choosing <tt>semi-tryptic</tt> (only one of two "internal" termini must match requirements) or <tt>none</tt> (essentially allowing all hits, no matter their context). These settings should not be used (due to high risk of reporting false positives), unless the search engine was instructed to search peptides in the same way. Threading: This tool support multiple threads (@p threads option) to speed up computation, at the cost of little extra memory. */ class OPENMS_DLLAPI PeptideIndexing : public DefaultParamHandler, public ProgressLogger { public: /// Exit codes enum ExitCodes { EXECUTION_OK, DATABASE_EMPTY, PEPTIDE_IDS_EMPTY, DATABASE_CONTAINS_MULTIPLES, ILLEGAL_PARAMETERS, UNEXPECTED_RESULT }; /// Default constructor PeptideIndexing(); /// Default destructor ~PeptideIndexing() override; /// forward for old interface and pyOpenMS; use run<T>() for more control inline ExitCodes run(std::vector<FASTAFile::FASTAEntry>& proteins, std::vector<ProteinIdentification>& prot_ids, std::vector<PeptideIdentification>& pep_ids) { FASTAContainer<TFI_Vector> protein_container(proteins); return run<TFI_Vector>(protein_container, prot_ids, pep_ids); } /** @brief Re-index peptide identifications honoring enzyme cutting rules, ambiguous amino acids and target/decoy hits. Template parameter 'T' can be either TFI_File or TFI_Vector. If the data is already available, use TFI_Vector and pass the vector. If the data is still in a FASTA file and its not needed afterwards for additional processing, use TFI_File and pass the filename. PeptideIndexer refreshes target/decoy information and mapping of peptides to proteins. The target/decoy information is crucial for the @ref TOPP_FalseDiscoveryRate tool. (For FDR calculations, "target+decoy" peptide hits count as target hits.) PeptideIndexer allows for ambiguous amino acids (B|J|Z|X) in the protein database, but not in the peptide sequences. For the latter only I/L can be treated as equivalent (see 'IL_equivalent' flag), but 'J' is not allowed. Enzyme cutting rules and partial specificity can be specified. Resulting protein hits appear in the order of the FASTA file, except for orphaned proteins, which will appear first with an empty target_decoy metavalue. Duplicate protein accessions & sequences will not raise a warning, but create multiple hits (PeptideIndexer scans over the FASTA file once for efficiency reasons, and thus might not see all accessions & sequences at once). All peptide and protein hits are annotated with target/decoy information, using the meta value "target_decoy". For proteins the possible values are "target" and "decoy", depending on whether the protein accession contains the decoy pattern (parameter @p decoy_string) as a suffix or prefix, respectively (see parameter @p prefix). Peptide hits are annotated with metavalue 'protein_references', and if matched to at least one protein also with metavalue 'target_decoy'. The possible values for 'target_decoy' are "target", "decoy" and "target+decoy", depending on whether the peptide sequence is found only in target proteins, only in decoy proteins, or in both. The metavalue is not present, if the peptide is unmatched. Runtime: PeptideIndexer is usually very fast (loading and storing the data takes the most time) and search speed can be further improved (linearly), but using more threads. Avoid allowing too many (>=4) ambiguous amino acids if your database contains long stretches of 'X' (exponential search space). @param proteins A list of proteins -- either read piecewise from a FASTA file or as existing vector of FASTAEntries. @param prot_ids Resulting protein identifications associated to pep_ids (will be re-written completely) @param pep_ids Peptide identifications which should be search within @p proteins and then linked to @p prot_ids @return Exit status codes. */ template<typename T> ExitCodes run(FASTAContainer<T>& proteins, std::vector<ProteinIdentification>& prot_ids, std::vector<PeptideIdentification>& pep_ids) { //------------------------------------------------------------- // parsing parameters //------------------------------------------------------------- ProteaseDigestion enzyme; enzyme.setEnzyme(enzyme_name_); enzyme.setSpecificity(enzyme.getSpecificityByName(enzyme_specificity_)); const size_t PROTEIN_CACHE_SIZE = 4e5; // 400k should be enough for most DB's and is not too hard on memory either (~200 MB FASTA) //------------------------------------------------------------- // calculations //------------------------------------------------------------- // cache the first proteins proteins.cacheChunk(PROTEIN_CACHE_SIZE); if (proteins.empty()) // we do not allow an empty database { LOG_ERROR << "Error: An empty database was provided. Mapping makes no sense. Aborting..." << std::endl; return DATABASE_EMPTY; } if (pep_ids.empty()) // Aho-Corasick requires non-empty input; but we allow this case, since the TOPP tool should not crash when encountering a bad raw file (with no PSMs) { LOG_WARN << "Warning: An empty set of peptide identifications was provided. Output will be empty as well." << std::endl; if (!keep_unreferenced_proteins_) { // delete only protein hits, not whole ID runs incl. meta data: for (std::vector<ProteinIdentification>::iterator it = prot_ids.begin(); it != prot_ids.end(); ++it) { it->getHits().clear(); } } return PEPTIDE_IDS_EMPTY; } FoundProteinFunctor func(enzyme); // store the matches Map<String, Size> acc_to_prot; // map: accessions --> FASTA protein index std::vector<bool> protein_is_decoy; // protein index -> is decoy? std::vector<std::string> protein_accessions; // protein index -> accession bool invalid_protein_sequence = false; // check for proteins with modifications, i.e. '[' or '(', and throw an exception { // new scope - forget data after search /* BUILD Peptide DB */ bool has_illegal_AAs(false); AhoCorasickAmbiguous::PeptideDB pep_DB; for (std::vector<PeptideIdentification>::const_iterator it1 = pep_ids.begin(); it1 != pep_ids.end(); ++it1) { //String run_id = it1->getIdentifier(); const std::vector<PeptideHit>& hits = it1->getHits(); for (std::vector<PeptideHit>::const_iterator it2 = hits.begin(); it2 != hits.end(); ++it2) { // // Warning: // do not skip over peptides here, since the results are iterated in the same way // String seq = it2->getSequence().toUnmodifiedString().remove('*'); // make a copy, i.e. do NOT change the peptide sequence! if (seqan::isAmbiguous(seqan::AAString(seq.c_str()))) { // do not quit here, to show the user all sequences .. only quit after loop LOG_ERROR << "Peptide sequence '" << it2->getSequence() << "' contains one or more ambiguous amino acids (B|J|Z|X).\n"; has_illegal_AAs = true; } if (IL_equivalent_) // convert L to I; { seq.substitute('L', 'I'); } appendValue(pep_DB, seq.c_str()); } } if (has_illegal_AAs) { LOG_ERROR << "One or more peptides contained illegal amino acids. This is not allowed!" << "\nPlease either remove the peptide or replace it with one of the unambiguous ones (while allowing for ambiguous AA's to match the protein)." << std::endl;; } LOG_INFO << "Mapping " << length(pep_DB) << " peptides to " << (proteins.size() == PROTEIN_CACHE_SIZE ? "? (unknown number of)" : String(proteins.size())) << " proteins." << std::endl; if (length(pep_DB) == 0) { // Aho-Corasick will crash if given empty needles as input LOG_WARN << "Warning: Peptide identifications have no hits inside! Output will be empty as well." << std::endl; return PEPTIDE_IDS_EMPTY; } /* Aho Corasick (fast) */ LOG_INFO << "Searching with up to " << aaa_max_ << " ambiguous amino acid(s) and " << mm_max_ << " mismatch(es)!" << std::endl; SysInfo::MemUsage mu; LOG_INFO << "Building trie ..."; StopWatch s; s.start(); AhoCorasickAmbiguous::FuzzyACPattern pattern; AhoCorasickAmbiguous::initPattern(pep_DB, aaa_max_, mm_max_, pattern); s.stop(); LOG_INFO << " done (" << int(s.getClockTime()) << "s)" << std::endl; s.reset(); uint16_t count_j_proteins(0); bool has_active_data = true; // becomes false if end of FASTA file is reached const std::string jumpX(aaa_max_ + mm_max_ + 1, 'X'); // jump over stretches of 'X' which cost a lot of time; +1 because AXXA is a valid hit for aaa_max == 2 (cannot split it) this->startProgress(0, proteins.size(), "Aho-Corasick"); std::atomic<int> progress_prots(0); #ifdef _OPENMP #pragma omp parallel #endif { FoundProteinFunctor func_threads(enzyme); Map<String, Size> acc_to_prot_thread; // map: accessions --> FASTA protein index AhoCorasickAmbiguous fuzzyAC; String prot; while (true) { #pragma omp barrier // all threads need to be here, since we are about to swap protein data #pragma omp single { DEBUG_ONLY std::cerr << " activating cache ...\n"; has_active_data = proteins.activateCache(); // swap in last cache protein_accessions.resize(proteins.getChunkOffset() + proteins.chunkSize()); } // implicit barrier here if (!has_active_data) break; // leave while-loop SignedSize prot_count = (SignedSize)proteins.chunkSize(); #pragma omp master { DEBUG_ONLY std::cerr << "Filling Protein Cache ..."; proteins.cacheChunk(PROTEIN_CACHE_SIZE); protein_is_decoy.resize(proteins.getChunkOffset() + prot_count); for (SignedSize i = 0; i < prot_count; ++i) { // do this in master only, to avoid false sharing const String& seq = proteins.chunkAt(i).identifier; protein_is_decoy[i + proteins.getChunkOffset()] = (prefix_ ? seq.hasPrefix(decoy_string_) : seq.hasSuffix(decoy_string_)); } DEBUG_ONLY std::cerr << " done" << std::endl; } DEBUG_ONLY std::cerr << " starting for loop \n"; // search all peptides in each protein #pragma omp for schedule(dynamic, 100) nowait for (SignedSize i = 0; i < prot_count; ++i) { ++progress_prots; // atomic if (omp_get_thread_num() == 0) { this->setProgress(progress_prots); } prot = proteins.chunkAt(i).sequence; prot.remove('*'); // check for invalid sequences with modifications if (prot.has('[') || prot.has('(')) { invalid_protein_sequence = true; // not omp-critical because its write-only // we cannot throw an exception here, since we'd need to catch it within the parallel region } // convert L/J to I; also replace 'J' in proteins if (IL_equivalent_) { prot.substitute('L', 'I'); prot.substitute('J', 'I'); } else { // warn if 'J' is found (it eats into aaa_max) if (prot.has('J')) { #pragma omp atomic ++count_j_proteins; } } Size prot_idx = i + proteins.getChunkOffset(); // test if protein was a hit Size hits_total = func_threads.filter_passed + func_threads.filter_rejected; // check if there are stretches of 'X' if (prot.has('X')) { // create chunks of the protein (splitting it at stretches of 'X..X') and feed them to AC one by one size_t offset = -1, start = 0; while ((offset = prot.find(jumpX, offset + 1)) != std::string::npos) { //std::cout << "found X..X at " << offset << " in protein " << proteins[i].identifier << "\n"; addHits_(fuzzyAC, pattern, pep_DB, prot.substr(start, offset + jumpX.size() - start), prot, prot_idx, (int)start, func_threads); // skip ahead while we encounter more X... while (offset + jumpX.size() < prot.size() && prot[offset + jumpX.size()] == 'X') ++offset; start = offset; //std::cout << " new start: " << start << "\n"; } // last chunk if (start < prot.size()) { addHits_(fuzzyAC, pattern, pep_DB, prot.substr(start), prot, prot_idx, (int)start, func_threads); } } else { addHits_(fuzzyAC, pattern, pep_DB, prot, prot, prot_idx, 0, func_threads); } // was protein found? if (hits_total < func_threads.filter_passed + func_threads.filter_rejected) { protein_accessions[prot_idx] = proteins.chunkAt(i).identifier; acc_to_prot_thread[protein_accessions[prot_idx]] = prot_idx; } } // end parallel FOR // join results again DEBUG_ONLY std::cerr << " critical now \n"; #ifdef _OPENMP #pragma omp critical(PeptideIndexer_joinAC) #endif { s.start(); // hits func.merge(func_threads); // accession -> index acc_to_prot.insert(acc_to_prot_thread.begin(), acc_to_prot_thread.end()); acc_to_prot_thread.clear(); s.stop(); } // OMP end critical } // end readChunk } // OMP end parallel this->endProgress(); std::cout << "Merge took: " << s.toString() << "\n"; mu.after(); std::cout << mu.delta("Aho-Corasick") << "\n\n"; LOG_INFO << "\nAho-Corasick done:\n found " << func.filter_passed << " hits for " << func.pep_to_prot.size() << " of " << length(pep_DB) << " peptides.\n"; // write some stats LOG_INFO << "Peptide hits passing enzyme filter: " << func.filter_passed << "\n" << " ... rejected by enzyme filter: " << func.filter_rejected << std::endl; if (count_j_proteins) { LOG_WARN << "PeptideIndexer found " << count_j_proteins << " protein sequences in your database containing the amino acid 'J'." << "To match 'J' in a protein, an ambiguous amino acid placeholder for I/L will be used.\n" << "This costs runtime and eats into the 'aaa_max' limit, leaving less opportunity for B/Z/X matches.\n" << "If you want 'J' to be treated as unambiguous, enable '-IL_equivalent'!" << std::endl; } } // end local scope // // do mapping // // index existing proteins Map<String, Size> runid_to_runidx; // identifier to index for (Size run_idx = 0; run_idx < prot_ids.size(); ++run_idx) { runid_to_runidx[prot_ids[run_idx].getIdentifier()] = run_idx; } // for peptides --> proteins Size stats_matched_unique(0); Size stats_matched_multi(0); Size stats_unmatched(0); // no match to DB Size stats_count_m_t(0); // match to Target DB Size stats_count_m_d(0); // match to Decoy DB Size stats_count_m_td(0); // match to T+D DB Map<Size, std::set<Size> > runidx_to_protidx; // in which protID do appear which proteins (according to mapped peptides) Size pep_idx(0); for (std::vector<PeptideIdentification>::iterator it1 = pep_ids.begin(); it1 != pep_ids.end(); ++it1) { // which ProteinIdentification does the peptide belong to? Size run_idx = runid_to_runidx[it1->getIdentifier()]; std::vector<PeptideHit>& hits = it1->getHits(); for (std::vector<PeptideHit>::iterator it2 = hits.begin(); it2 != hits.end(); ++it2) { // clear protein accessions it2->setPeptideEvidences(std::vector<PeptideEvidence>()); // // is this a decoy hit? // bool matches_target(false); bool matches_decoy(false); std::set<Size> prot_indices; /// protein hits of this peptide // add new protein references for (std::set<PeptideProteinMatchInformation>::const_iterator it_i = func.pep_to_prot[pep_idx].begin(); it_i != func.pep_to_prot[pep_idx].end(); ++it_i) { prot_indices.insert(it_i->protein_index); const String& accession = protein_accessions[it_i->protein_index]; PeptideEvidence pe(accession, it_i->position, it_i->position + (int)it2->getSequence().size() - 1, it_i->AABefore, it_i->AAAfter); it2->addPeptideEvidence(pe); runidx_to_protidx[run_idx].insert(it_i->protein_index); // fill protein hits if (protein_is_decoy[it_i->protein_index]) { matches_decoy = true; } else { matches_target = true; } } if (matches_decoy && matches_target) { it2->setMetaValue("target_decoy", "target+decoy"); ++stats_count_m_td; } else if (matches_target) { it2->setMetaValue("target_decoy", "target"); ++stats_count_m_t; } else if (matches_decoy) { it2->setMetaValue("target_decoy", "decoy"); ++stats_count_m_d; } // else: could match to no protein (i.e. both are false) //else ... // not required (handled below; see stats_unmatched); if (prot_indices.size() == 1) { it2->setMetaValue("protein_references", "unique"); ++stats_matched_unique; } else if (prot_indices.size() > 1) { it2->setMetaValue("protein_references", "non-unique"); ++stats_matched_multi; } else { it2->setMetaValue("protein_references", "unmatched"); ++stats_unmatched; if (stats_unmatched < 15) LOG_INFO << "Unmatched peptide: " << it2->getSequence() << "\n"; else if (stats_unmatched == 15) LOG_INFO << "Unmatched peptide: ...\n"; } ++pep_idx; // next hit } } Size total_peptides = stats_count_m_t + stats_count_m_d + stats_count_m_td + stats_unmatched; LOG_INFO << "-----------------------------------\n"; LOG_INFO << "Peptide statistics\n"; LOG_INFO << "\n"; LOG_INFO << " unmatched : " << stats_unmatched << " (" << stats_unmatched * 100 / total_peptides << " %)\n"; LOG_INFO << " target/decoy:\n"; LOG_INFO << " match to target DB only: " << stats_count_m_t << " (" << stats_count_m_t * 100 / total_peptides << " %)\n"; LOG_INFO << " match to decoy DB only : " << stats_count_m_d << " (" << stats_count_m_d * 100 / total_peptides << " %)\n"; LOG_INFO << " match to both : " << stats_count_m_td << " (" << stats_count_m_td * 100 / total_peptides << " %)\n"; LOG_INFO << "\n"; LOG_INFO << " mapping to proteins:\n"; LOG_INFO << " no match (to 0 protein) : " << stats_unmatched << "\n"; LOG_INFO << " unique match (to 1 protein) : " << stats_matched_unique << "\n"; LOG_INFO << " non-unique match (to >1 protein): " << stats_matched_multi << std::endl; /// for proteins --> peptides Size stats_matched_proteins(0), stats_matched_new_proteins(0), stats_orphaned_proteins(0), stats_proteins_target(0), stats_proteins_decoy(0); // all peptides contain the correct protein hit references, now update the protein hits for (Size run_idx = 0; run_idx < prot_ids.size(); ++run_idx) { std::set<Size> masterset = runidx_to_protidx[run_idx]; // all protein matches from above std::vector<ProteinHit>& phits = prot_ids[run_idx].getHits(); { // go through existing protein hits and count orphaned proteins (with no peptide hits) std::vector<ProteinHit> orphaned_hits; for (std::vector<ProteinHit>::iterator p_hit = phits.begin(); p_hit != phits.end(); ++p_hit) { const String& acc = p_hit->getAccession(); if (!acc_to_prot.has(acc)) // acc_to_prot only contains found proteins from current run { // old hit is orphaned ++stats_orphaned_proteins; if (keep_unreferenced_proteins_) { p_hit->setMetaValue("target_decoy", ""); orphaned_hits.push_back(*p_hit); } } } // only keep orphaned hits (if any) phits = orphaned_hits; } // add new protein hits FASTAFile::FASTAEntry fe; phits.reserve(phits.size() + masterset.size()); for (std::set<Size>::const_iterator it = masterset.begin(); it != masterset.end(); ++it) { ProteinHit hit; hit.setAccession(protein_accessions[*it]); if (write_protein_sequence_ || write_protein_description_) { proteins.readAt(fe, *it); if (write_protein_sequence_) { hit.setSequence(fe.sequence); } // no else, since sequence is empty by default if (write_protein_description_) { hit.setDescription(fe.description); } // no else, since description is empty by default } if (protein_is_decoy[*it]) { hit.setMetaValue("target_decoy", "decoy"); ++stats_proteins_decoy; } else { hit.setMetaValue("target_decoy", "target"); ++stats_proteins_target; } phits.push_back(hit); ++stats_matched_new_proteins; } stats_matched_proteins += phits.size(); } LOG_INFO << "-----------------------------------\n"; LOG_INFO << "Protein statistics\n"; LOG_INFO << "\n"; LOG_INFO << " total proteins searched: " << proteins.size() << "\n"; LOG_INFO << " matched proteins : " << stats_matched_proteins << " (" << stats_matched_new_proteins << " new)\n"; if (stats_matched_proteins) { // prevent Division-by-0 Exception LOG_INFO << " matched target proteins: " << stats_proteins_target << " (" << stats_proteins_target * 100 / stats_matched_proteins << " %)\n"; LOG_INFO << " matched decoy proteins : " << stats_proteins_decoy << " (" << stats_proteins_decoy * 100 / stats_matched_proteins << " %)\n"; } LOG_INFO << " orphaned proteins : " << stats_orphaned_proteins << (keep_unreferenced_proteins_ ? " (all kept)" : " (all removed)\n"); LOG_INFO << "-----------------------------------" << std::endl; /// exit if no peptides were matched to decoy bool has_error = false; if (invalid_protein_sequence) { LOG_ERROR << "Error: One or more protein sequences contained the characters '[' or '(', which are illegal in protein sequences." << "\nPeptide hits might be masked by these characters (which usually indicate presence of modifications).\n"; has_error = true; } if ((stats_count_m_d + stats_count_m_td) == 0) { String msg("No peptides were matched to the decoy portion of the database! Did you provide the correct concatenated database? Are your 'decoy_string' (=" + String(decoy_string_) + ") and 'decoy_string_position' (=" + String(param_.getValue("decoy_string_position")) + ") settings correct?"); if (missing_decoy_action_ == "error") { LOG_ERROR << "Error: " << msg << "\nSet 'missing_decoy_action' to 'warn' if you are sure this is ok!\nAborting ..." << std::endl; has_error = true; } else if (missing_decoy_action_ == "warn") { LOG_WARN << "Warn: " << msg << "\nSet 'missing_decoy_action' to 'error' if you want to elevate this to an error!" << std::endl; } else // silent { } } if ((!allow_unmatched_) && (stats_unmatched > 0)) { LOG_ERROR << "PeptideIndexer found unmatched peptides, which could not be associated to a protein.\n" << "Potential solutions:\n" << " - check your FASTA database for completeness\n" << " - set 'enzyme:specificity' to match the identification parameters of the search engine\n" << " - some engines (e.g. X! Tandem) employ loose cutting rules generating non-tryptic peptides;\n" << " if you trust them, disable enzyme specificity\n" << " - increase 'aaa_max' to allow more ambiguous amino acids\n" << " - as a last resort: use the 'allow_unmatched' option to accept unmatched peptides\n" << " (note that unmatched peptides cannot be used for FDR calculation or quantification)\n"; has_error = true; } if (has_error) { LOG_ERROR << "Result files will be written, but PeptideIndexer will exit with an error code." << std::endl; return UNEXPECTED_RESULT; } return EXECUTION_OK; } protected: struct PeptideProteinMatchInformation { /// index of the protein the peptide is contained in OpenMS::Size protein_index; /// the position of the peptide in the protein OpenMS::Int position; /// the amino acid after the peptide in the protein char AABefore; /// the amino acid before the peptide in the protein char AAAfter; bool operator<(const PeptideProteinMatchInformation& other) const { if (protein_index != other.protein_index) { return protein_index < other.protein_index; } else if (position != other.position) { return position < other.position; } else if (AABefore != other.AABefore) { return AABefore < other.AABefore; } else if (AAAfter != other.AAAfter) { return AAAfter < other.AAAfter; } return false; } bool operator==(const PeptideProteinMatchInformation& other) const { return protein_index == other.protein_index && position == other.position && AABefore == other.AABefore && AAAfter == other.AAAfter; } }; struct FoundProteinFunctor { public: typedef std::map<OpenMS::Size, std::set<PeptideProteinMatchInformation> > MapType; /// peptide index --> protein indices MapType pep_to_prot; /// number of accepted hits (passing addHit() constraints) OpenMS::Size filter_passed; /// number of rejected hits (not passing addHit()) OpenMS::Size filter_rejected; private: ProteaseDigestion enzyme_; public: explicit FoundProteinFunctor(const ProteaseDigestion& enzyme) : pep_to_prot(), filter_passed(0), filter_rejected(0), enzyme_(enzyme) { } void merge(FoundProteinFunctor& other) { if (pep_to_prot.empty()) { // first merge is easy pep_to_prot.swap(other.pep_to_prot); } else { for (FoundProteinFunctor::MapType::const_iterator it = other.pep_to_prot.begin(); it != other.pep_to_prot.end(); ++it) { // augment set this->pep_to_prot[it->first].insert(other.pep_to_prot[it->first].begin(), other.pep_to_prot[it->first].end()); } other.pep_to_prot.clear(); } // cheap members this->filter_passed += other.filter_passed; other.filter_passed = 0; this->filter_rejected += other.filter_rejected; other.filter_rejected = 0; } void addHit(const OpenMS::Size idx_pep, const OpenMS::Size idx_prot, const OpenMS::Size len_pep, const OpenMS::String& seq_prot, OpenMS::Int position) { if (enzyme_.isValidProduct(seq_prot, position, len_pep, true, true)) { PeptideProteinMatchInformation match; match.protein_index = idx_prot; match.position = position; match.AABefore = (position == 0) ? PeptideEvidence::N_TERMINAL_AA : seq_prot[position - 1]; match.AAAfter = (position + len_pep >= seq_prot.size()) ? PeptideEvidence::C_TERMINAL_AA : seq_prot[position + len_pep]; pep_to_prot[idx_pep].insert(match); ++filter_passed; } else { //std::cerr << "REJECTED Peptide " << seq_pep << " with hit to protein " // << seq_prot << " at position " << position << std::endl; ++filter_rejected; } } }; inline void addHits_(AhoCorasickAmbiguous& fuzzyAC, const AhoCorasickAmbiguous::FuzzyACPattern& pattern, const AhoCorasickAmbiguous::PeptideDB& pep_DB, const String& prot, const String& full_prot, SignedSize idx_prot, Int offset, FoundProteinFunctor& func_threads) const { fuzzyAC.setProtein(prot); while (fuzzyAC.findNext(pattern)) { const seqan::Peptide& tmp_pep = pep_DB[fuzzyAC.getHitDBIndex()]; func_threads.addHit(fuzzyAC.getHitDBIndex(), idx_prot, length(tmp_pep), full_prot, fuzzyAC.getHitProteinPosition() + offset); } } void updateMembers_() override; String decoy_string_; bool prefix_; String missing_decoy_action_; String enzyme_name_; String enzyme_specificity_; bool write_protein_sequence_; bool write_protein_description_; bool keep_unreferenced_proteins_; bool allow_unmatched_; bool IL_equivalent_; Int aaa_max_; Int mm_max_; }; } #endif // OPENMS_ANALYSIS_ID_PEPTIDEINDEXING_H

par_nongalerkin.c

/*BHEADER********************************************************************** * Copyright (c) 2008, Lawrence Livermore National Security, LLC. * Produced at the Lawrence Livermore National Laboratory. * This file is part of HYPRE. See file COPYRIGHT for details. * * HYPRE is free software; you can redistribute it and/or modify it under the * terms of the GNU Lesser General Public License (as published by the Free * Software Foundation) version 2.1 dated February 1999. * * $Revision: 2.14 $ ***********************************************************************EHEADER*/ #include "_hypre_parcsr_ls.h" #include "../HYPRE.h" /* This file contains the routines for constructing non-Galerkin coarse grid * operators, based on the original Galerkin coarse grid */ /* Take all of the indices from indices[start, start+1, start+2, ..., end] * and take the corresponding entries in array and place them in-order in output. * Assumptions: * output is of length end-start+1 * indices never contains an index that goes out of bounds in array * */ HYPRE_Int hypre_GrabSubArray(HYPRE_Int * indices, HYPRE_Int start, HYPRE_Int end, HYPRE_BigInt * array, HYPRE_Int * output) { HYPRE_Int i, length; length = end - start + 1; for(i = 0; i < length; i++) { output[i] = array[ indices[start + i] ]; } return 0; } /* Quick Sort based on magnitude on w (HYPRE_Real), move v */ void hypre_qsort2_abs( HYPRE_Int *v, HYPRE_Real *w, HYPRE_Int left, HYPRE_Int right ) { HYPRE_Int i, last; if (left >= right) return; hypre_swap2( v, w, left, (left+right)/2); last = left; for (i = left+1; i <= right; i++) if (fabs(w[i]) < fabs(w[left])) { hypre_swap2(v, w, ++last, i); } hypre_swap2(v, w, left, last); hypre_qsort2_abs(v, w, left, last-1); hypre_qsort2_abs(v, w, last+1, right); } /* Compute the intersection of x and y, placing * the intersection in z. Additionally, the array * x_data is associated with x, i.e., the entries * that we grab from x, we also grab from x_data. * If x[k] is placed in z[m], then x_data[k] goes to * output_x_data[m]. * * Assumptions: * z is of length min(x_length, y_length) * x and y are sorted * x_length and y_length are similar in size, otherwise, * looping over the smaller array and doing binary search * in the longer array is faster. * */ HYPRE_Int hypre_IntersectTwoArrays(HYPRE_Int *x, HYPRE_Real *x_data, HYPRE_Int x_length, HYPRE_Int *y, HYPRE_Int y_length, HYPRE_Int *z, HYPRE_Real *output_x_data, HYPRE_Int *intersect_length) { HYPRE_Int x_index = 0; HYPRE_Int y_index = 0; *intersect_length = 0; /* Compute Intersection, looping over each array */ while ( (x_index < x_length) && (y_index < y_length) ) { if (x[x_index] > y[y_index]) { y_index = y_index + 1; } else if (x[x_index] < y[y_index]) { x_index = x_index + 1; } else { z[*intersect_length] = x[x_index]; output_x_data[*intersect_length] = x_data[x_index]; x_index = x_index + 1; y_index = y_index + 1; *intersect_length = *intersect_length + 1; } } return 1; } /* Copy CSR matrix A to CSR matrix B. The column indices are * assumed to be sorted, and the sparsity pattern of B is a subset * of the sparsity pattern of A. * * Assumptions: * Column indices of A and B are sorted * Sparsity pattern of B is a subset of A's * A and B are the same size and have same data layout **/ HYPRE_Int hypre_SortedCopyParCSRData(hypre_ParCSRMatrix *A, hypre_ParCSRMatrix *B) { /* Grab off A and B's data structures */ hypre_CSRMatrix *A_diag = hypre_ParCSRMatrixDiag(A); HYPRE_Int *A_diag_i = hypre_CSRMatrixI(A_diag); HYPRE_Int *A_diag_j = hypre_CSRMatrixJ(A_diag); HYPRE_Real *A_diag_data = hypre_CSRMatrixData(A_diag); hypre_CSRMatrix *A_offd = hypre_ParCSRMatrixOffd(A); HYPRE_Int *A_offd_i = hypre_CSRMatrixI(A_offd); HYPRE_Int *A_offd_j = hypre_CSRMatrixJ(A_offd); HYPRE_Real *A_offd_data = hypre_CSRMatrixData(A_offd); hypre_CSRMatrix *B_diag = hypre_ParCSRMatrixDiag(B); HYPRE_Int *B_diag_i = hypre_CSRMatrixI(B_diag); HYPRE_Int *B_diag_j = hypre_CSRMatrixJ(B_diag); HYPRE_Real *B_diag_data = hypre_CSRMatrixData(B_diag); hypre_CSRMatrix *B_offd = hypre_ParCSRMatrixOffd(B); HYPRE_Int *B_offd_i = hypre_CSRMatrixI(B_offd); HYPRE_Int *B_offd_j = hypre_CSRMatrixJ(B_offd); HYPRE_Real *B_offd_data = hypre_CSRMatrixData(B_offd); HYPRE_Int num_variables = hypre_CSRMatrixNumRows(A_diag); HYPRE_Int *temp_int_array = NULL; HYPRE_Int temp_int_array_length=0; HYPRE_Int i, length, offset_A, offset_B; for(i = 0; i < num_variables; i++) { /* Deal with the first row entries, which may be diagonal elements */ if( A_diag_j[A_diag_i[i]] == i) { offset_A = 1; } else { offset_A = 0; } if( B_diag_j[B_diag_i[i]] == i) { offset_B = 1; } else { offset_B = 0; } if( (offset_B == 1) && (offset_A == 1) ) { B_diag_data[B_diag_i[i]] = A_diag_data[A_diag_i[i]]; } /* This finds the intersection of the column indices, and * also copies the matching data in A to the data array in B **/ if( (A_diag_i[i+1] - A_diag_i[i] - offset_A) > temp_int_array_length ) { hypre_TFree(temp_int_array, HYPRE_MEMORY_HOST); temp_int_array_length = (A_diag_i[i+1] - A_diag_i[i] - offset_A); temp_int_array = hypre_CTAlloc(HYPRE_Int, temp_int_array_length, HYPRE_MEMORY_HOST); } hypre_IntersectTwoArrays(&(A_diag_j[A_diag_i[i] + offset_A]), &(A_diag_data[A_diag_i[i] + offset_A]), A_diag_i[i+1] - A_diag_i[i] - offset_A, &(B_diag_j[B_diag_i[i] + offset_B]), B_diag_i[i+1] - B_diag_i[i] - offset_B, temp_int_array, &(B_diag_data[B_diag_i[i] + offset_B]), &length); if( (A_offd_i[i+1] - A_offd_i[i]) > temp_int_array_length ) { hypre_TFree(temp_int_array, HYPRE_MEMORY_HOST); temp_int_array_length = (A_offd_i[i+1] - A_offd_i[i]); temp_int_array = hypre_CTAlloc(HYPRE_Int, temp_int_array_length, HYPRE_MEMORY_HOST); } hypre_IntersectTwoArrays(&(A_offd_j[A_offd_i[i]]), &(A_offd_data[A_offd_i[i]]), A_offd_i[i+1] - A_offd_i[i], &(B_offd_j[B_offd_i[i]]), B_offd_i[i+1] - B_offd_i[i], temp_int_array, &(B_offd_data[B_offd_i[i]]), &length); } if(temp_int_array) { hypre_TFree(temp_int_array, HYPRE_MEMORY_HOST); } return 1; } /* * Equivalent to hypre_BoomerAMGCreateS, except, the data array of S * is not Null and contains the data entries from A. */ HYPRE_Int hypre_BoomerAMG_MyCreateS(hypre_ParCSRMatrix *A, HYPRE_Real strength_threshold, HYPRE_Real max_row_sum, HYPRE_Int num_functions, HYPRE_Int *dof_func, hypre_ParCSRMatrix **S_ptr) { MPI_Comm comm = hypre_ParCSRMatrixComm(A); hypre_ParCSRCommPkg *comm_pkg = hypre_ParCSRMatrixCommPkg(A); hypre_ParCSRCommHandle *comm_handle; hypre_CSRMatrix *A_diag = hypre_ParCSRMatrixDiag(A); HYPRE_Int *A_diag_i = hypre_CSRMatrixI(A_diag); HYPRE_Real *A_diag_data = hypre_CSRMatrixData(A_diag); hypre_CSRMatrix *A_offd = hypre_ParCSRMatrixOffd(A); HYPRE_Int *A_offd_i = hypre_CSRMatrixI(A_offd); HYPRE_Real *A_offd_data = NULL; HYPRE_Int *A_diag_j = hypre_CSRMatrixJ(A_diag); HYPRE_Int *A_offd_j = hypre_CSRMatrixJ(A_offd); HYPRE_BigInt *row_starts = hypre_ParCSRMatrixRowStarts(A); HYPRE_Int num_variables = hypre_CSRMatrixNumRows(A_diag); HYPRE_BigInt global_num_vars = hypre_ParCSRMatrixGlobalNumRows(A); HYPRE_Int num_nonzeros_diag; HYPRE_Int num_nonzeros_offd = 0; HYPRE_Int num_cols_offd = 0; hypre_ParCSRMatrix *S; hypre_CSRMatrix *S_diag; HYPRE_Int *S_diag_i; HYPRE_Int *S_diag_j; HYPRE_Real *S_diag_data; hypre_CSRMatrix *S_offd; HYPRE_Int *S_offd_i = NULL; HYPRE_Int *S_offd_j = NULL; HYPRE_Real *S_offd_data; HYPRE_Real diag, row_scale, row_sum; HYPRE_Int i, jA, jS; HYPRE_Int ierr = 0; HYPRE_Int *dof_func_offd; HYPRE_Int num_sends; HYPRE_Int *int_buf_data; HYPRE_Int index, start, j; /*-------------------------------------------------------------- * Compute a ParCSR strength matrix, S. * * For now, the "strength" of dependence/influence is defined in * the following way: i depends on j if * aij > hypre_max (k != i) aik, aii < 0 * or * aij < hypre_min (k != i) aik, aii >= 0 * Then S_ij = aij, else S_ij = 0. * * NOTE: the entries are negative initially, corresponding * to "unaccounted-for" dependence. *----------------------------------------------------------------*/ num_nonzeros_diag = A_diag_i[num_variables]; num_cols_offd = hypre_CSRMatrixNumCols(A_offd); A_offd_i = hypre_CSRMatrixI(A_offd); num_nonzeros_offd = A_offd_i[num_variables]; /* Initialize S */ S = hypre_ParCSRMatrixCreate(comm, global_num_vars, global_num_vars, row_starts, row_starts, num_cols_offd, num_nonzeros_diag, num_nonzeros_offd); /* row_starts is owned by A, col_starts = row_starts */ hypre_ParCSRMatrixSetRowStartsOwner(S,0); S_diag = hypre_ParCSRMatrixDiag(S); hypre_CSRMatrixI(S_diag) = hypre_CTAlloc(HYPRE_Int, num_variables+1, HYPRE_MEMORY_HOST); hypre_CSRMatrixJ(S_diag) = hypre_CTAlloc(HYPRE_Int, num_nonzeros_diag, HYPRE_MEMORY_HOST); hypre_CSRMatrixData(S_diag) = hypre_CTAlloc(HYPRE_Real, num_nonzeros_diag, HYPRE_MEMORY_HOST); S_offd = hypre_ParCSRMatrixOffd(S); hypre_CSRMatrixI(S_offd) = hypre_CTAlloc(HYPRE_Int, num_variables+1, HYPRE_MEMORY_HOST); S_diag_i = hypre_CSRMatrixI(S_diag); S_diag_j = hypre_CSRMatrixJ(S_diag); S_diag_data = hypre_CSRMatrixData(S_diag); S_offd_i = hypre_CSRMatrixI(S_offd); dof_func_offd = NULL; if (num_cols_offd) { A_offd_data = hypre_CSRMatrixData(A_offd); hypre_CSRMatrixJ(S_offd) = hypre_CTAlloc(HYPRE_Int, num_nonzeros_offd, HYPRE_MEMORY_HOST); hypre_CSRMatrixData(S_offd) = hypre_CTAlloc(HYPRE_Real, num_nonzeros_offd, HYPRE_MEMORY_HOST); S_offd_j = hypre_CSRMatrixJ(S_offd); S_offd_data = hypre_CSRMatrixData(S_offd); hypre_ParCSRMatrixColMapOffd(S) = hypre_CTAlloc(HYPRE_BigInt, num_cols_offd, HYPRE_MEMORY_HOST); if (num_functions > 1) dof_func_offd = hypre_CTAlloc(HYPRE_Int, num_cols_offd, HYPRE_MEMORY_HOST); } /*------------------------------------------------------------------- * Get the dof_func data for the off-processor columns *-------------------------------------------------------------------*/ if (!comm_pkg) { hypre_MatvecCommPkgCreate(A); comm_pkg = hypre_ParCSRMatrixCommPkg(A); } num_sends = hypre_ParCSRCommPkgNumSends(comm_pkg); if (num_functions > 1) { int_buf_data = hypre_CTAlloc(HYPRE_Int, hypre_ParCSRCommPkgSendMapStart(comm_pkg, num_sends), HYPRE_MEMORY_HOST); index = 0; for (i = 0; i < num_sends; i++) { start = hypre_ParCSRCommPkgSendMapStart(comm_pkg, i); for (j=start; j < hypre_ParCSRCommPkgSendMapStart(comm_pkg, i+1); j++) int_buf_data[index++] = dof_func[hypre_ParCSRCommPkgSendMapElmt(comm_pkg,j)]; } comm_handle = hypre_ParCSRCommHandleCreate( 11, comm_pkg, int_buf_data, dof_func_offd); hypre_ParCSRCommHandleDestroy(comm_handle); hypre_TFree(int_buf_data, HYPRE_MEMORY_HOST); } /* give S same nonzero structure as A */ hypre_ParCSRMatrixCopy(A,S,1); #ifdef HYPRE_USING_OPENMP #pragma omp parallel for private(i,diag,row_scale,row_sum,jA) HYPRE_SMP_SCHEDULE #endif for (i = 0; i < num_variables; i++) { diag = A_diag_data[A_diag_i[i]]; /* compute scaling factor and row sum */ row_scale = 0.0; row_sum = diag; if (num_functions > 1) { if (diag < 0) { for (jA = A_diag_i[i]+1; jA < A_diag_i[i+1]; jA++) { if (dof_func[i] == dof_func[A_diag_j[jA]]) { row_scale = hypre_max(row_scale, A_diag_data[jA]); row_sum += A_diag_data[jA]; } } for (jA = A_offd_i[i]; jA < A_offd_i[i+1]; jA++) { if (dof_func[i] == dof_func_offd[A_offd_j[jA]]) { row_scale = hypre_max(row_scale, A_offd_data[jA]); row_sum += A_offd_data[jA]; } } } else { for (jA = A_diag_i[i]+1; jA < A_diag_i[i+1]; jA++) { if (dof_func[i] == dof_func[A_diag_j[jA]]) { row_scale = hypre_min(row_scale, A_diag_data[jA]); row_sum += A_diag_data[jA]; } } for (jA = A_offd_i[i]; jA < A_offd_i[i+1]; jA++) { if (dof_func[i] == dof_func_offd[A_offd_j[jA]]) { row_scale = hypre_min(row_scale, A_offd_data[jA]); row_sum += A_offd_data[jA]; } } } } else { if (diag < 0) { for (jA = A_diag_i[i]+1; jA < A_diag_i[i+1]; jA++) { row_scale = hypre_max(row_scale, A_diag_data[jA]); row_sum += A_diag_data[jA]; } for (jA = A_offd_i[i]; jA < A_offd_i[i+1]; jA++) { row_scale = hypre_max(row_scale, A_offd_data[jA]); row_sum += A_offd_data[jA]; } } else { for (jA = A_diag_i[i]+1; jA < A_diag_i[i+1]; jA++) { row_scale = hypre_min(row_scale, A_diag_data[jA]); row_sum += A_diag_data[jA]; } for (jA = A_offd_i[i]; jA < A_offd_i[i+1]; jA++) { row_scale = hypre_min(row_scale, A_offd_data[jA]); row_sum += A_offd_data[jA]; } } } /* compute row entries of S */ S_diag_j[A_diag_i[i]] = -1; if ((fabs(row_sum) > fabs(diag)*max_row_sum) && (max_row_sum < 1.0)) { /* make all dependencies weak */ for (jA = A_diag_i[i]+1; jA < A_diag_i[i+1]; jA++) { S_diag_j[jA] = -1; } for (jA = A_offd_i[i]; jA < A_offd_i[i+1]; jA++) { S_offd_j[jA] = -1; } } else { if (num_functions > 1) { if (diag < 0) { for (jA = A_diag_i[i]+1; jA < A_diag_i[i+1]; jA++) { if (A_diag_data[jA] <= strength_threshold * row_scale || dof_func[i] != dof_func[A_diag_j[jA]]) { S_diag_j[jA] = -1; } } for (jA = A_offd_i[i]; jA < A_offd_i[i+1]; jA++) { if (A_offd_data[jA] <= strength_threshold * row_scale || dof_func[i] != dof_func_offd[A_offd_j[jA]]) { S_offd_j[jA] = -1; } } } else { for (jA = A_diag_i[i]+1; jA < A_diag_i[i+1]; jA++) { if (A_diag_data[jA] >= strength_threshold * row_scale || dof_func[i] != dof_func[A_diag_j[jA]]) { S_diag_j[jA] = -1; } } for (jA = A_offd_i[i]; jA < A_offd_i[i+1]; jA++) { if (A_offd_data[jA] >= strength_threshold * row_scale || dof_func[i] != dof_func_offd[A_offd_j[jA]]) { S_offd_j[jA] = -1; } } } } else { if (diag < 0) { for (jA = A_diag_i[i]+1; jA < A_diag_i[i+1]; jA++) { if (A_diag_data[jA] <= strength_threshold * row_scale) { S_diag_j[jA] = -1; } } for (jA = A_offd_i[i]; jA < A_offd_i[i+1]; jA++) { if (A_offd_data[jA] <= strength_threshold * row_scale) { S_offd_j[jA] = -1; } } } else { for (jA = A_diag_i[i]+1; jA < A_diag_i[i+1]; jA++) { if (A_diag_data[jA] >= strength_threshold * row_scale) { S_diag_j[jA] = -1; } } for (jA = A_offd_i[i]; jA < A_offd_i[i+1]; jA++) { if (A_offd_data[jA] >= strength_threshold * row_scale) { S_offd_j[jA] = -1; } } } } } } /*-------------------------------------------------------------- * "Compress" the strength matrix. * * NOTE: S has *NO DIAGONAL ELEMENT* on any row. Caveat Emptor! * * NOTE: This "compression" section of code may not be removed, the * non-Galerkin routine depends on it. *----------------------------------------------------------------*/ /* RDF: not sure if able to thread this loop */ jS = 0; for (i = 0; i < num_variables; i++) { S_diag_i[i] = jS; for (jA = A_diag_i[i]; jA < A_diag_i[i+1]; jA++) { if (S_diag_j[jA] > -1) { S_diag_j[jS] = S_diag_j[jA]; S_diag_data[jS] = S_diag_data[jA]; jS++; } } } S_diag_i[num_variables] = jS; hypre_CSRMatrixNumNonzeros(S_diag) = jS; /* RDF: not sure if able to thread this loop */ jS = 0; for (i = 0; i < num_variables; i++) { S_offd_i[i] = jS; for (jA = A_offd_i[i]; jA < A_offd_i[i+1]; jA++) { if (S_offd_j[jA] > -1) { S_offd_j[jS] = S_offd_j[jA]; S_offd_data[jS] = S_offd_data[jA]; jS++; } } } S_offd_i[num_variables] = jS; hypre_CSRMatrixNumNonzeros(S_offd) = jS; hypre_ParCSRMatrixCommPkg(S) = NULL; *S_ptr = S; hypre_TFree(dof_func_offd, HYPRE_MEMORY_HOST); return (ierr); } /** * Initialize the IJBuffer counters **/ HYPRE_Int hypre_NonGalerkinIJBufferInit( HYPRE_Int *ijbuf_cnt, /* See NonGalerkinIJBufferWrite for parameter descriptions */ HYPRE_Int *ijbuf_rowcounter, HYPRE_Int *ijbuf_numcols ) { HYPRE_Int ierr = 0; (*ijbuf_cnt) = 0; (*ijbuf_rowcounter) = 1; /*Always points to the next row*/ ijbuf_numcols[0] = 0; return ierr; } /** * Initialize the IJBuffer counters **/ HYPRE_Int hypre_NonGalerkinIJBigBufferInit( HYPRE_Int *ijbuf_cnt, /* See NonGalerkinIJBufferWrite for parameter descriptions */ HYPRE_Int *ijbuf_rowcounter, HYPRE_BigInt *ijbuf_numcols ) { HYPRE_Int ierr = 0; (*ijbuf_cnt) = 0; (*ijbuf_rowcounter) = 1; /*Always points to the next row*/ ijbuf_numcols[0] = 0; return ierr; } /** * Update the buffer counters **/ HYPRE_Int hypre_NonGalerkinIJBufferNewRow(HYPRE_BigInt *ijbuf_rownums, /* See NonGalerkinIJBufferWrite for parameter descriptions */ HYPRE_Int *ijbuf_numcols, HYPRE_Int *ijbuf_rowcounter, HYPRE_BigInt new_row) { HYPRE_Int ierr = 0; /* First check to see if the previous row was empty, and if so, overwrite that row */ if( ijbuf_numcols[(*ijbuf_rowcounter)-1] == 0 ) { ijbuf_rownums[(*ijbuf_rowcounter)-1] = new_row; } else { /* Move to the next row */ ijbuf_rownums[(*ijbuf_rowcounter)] = new_row; ijbuf_numcols[(*ijbuf_rowcounter)] = 0; (*ijbuf_rowcounter)++; } return ierr; } /** * Compress the current row in an IJ Buffer by removing duplicate entries **/ HYPRE_Int hypre_NonGalerkinIJBufferCompressRow( HYPRE_Int *ijbuf_cnt, /* See NonGalerkinIJBufferWrite for parameter descriptions */ HYPRE_Int ijbuf_rowcounter, HYPRE_Real *ijbuf_data, HYPRE_BigInt *ijbuf_cols, HYPRE_BigInt *ijbuf_rownums, HYPRE_Int *ijbuf_numcols) { HYPRE_Int ierr = 0; HYPRE_Int nentries, i, nduplicate; /* Compress the current row by removing any repeat entries, * making sure to decrement ijbuf_cnt by nduplicate */ nentries = ijbuf_numcols[ ijbuf_rowcounter-1 ]; nduplicate = 0; hypre_BigQsort1(ijbuf_cols, ijbuf_data, (*ijbuf_cnt)-nentries, (*ijbuf_cnt)-1 ); for(i =(*ijbuf_cnt)-nentries+1; i <= (*ijbuf_cnt)-1; i++) { if( ijbuf_cols[i] == ijbuf_cols[i-1] ) { /* Shift duplicate entry down */ nduplicate++; ijbuf_data[i - nduplicate] += ijbuf_data[i]; } else if(nduplicate > 0) { ijbuf_data[i - nduplicate] = ijbuf_data[i]; ijbuf_cols[i - nduplicate] = ijbuf_cols[i]; } } (*ijbuf_cnt) -= nduplicate; ijbuf_numcols[ ijbuf_rowcounter-1 ] -= nduplicate; return ierr; } /** * Compress the entire buffer, removing duplicate rows **/ HYPRE_Int hypre_NonGalerkinIJBufferCompress( HYPRE_Int ijbuf_size, HYPRE_Int *ijbuf_cnt, /* See NonGalerkinIJBufferWrite for parameter descriptions */ HYPRE_Int *ijbuf_rowcounter, HYPRE_Real **ijbuf_data, HYPRE_BigInt **ijbuf_cols, HYPRE_BigInt **ijbuf_rownums, HYPRE_Int **ijbuf_numcols) { HYPRE_Int ierr = 0; HYPRE_Int *indys = hypre_CTAlloc(HYPRE_Int, (*ijbuf_rowcounter) , HYPRE_MEMORY_HOST); HYPRE_Int i, j, duplicate, cnt_new, rowcounter_new, prev_row; HYPRE_Int row_loc; HYPRE_BigInt row_start, row_stop, row; HYPRE_Real *data_new; HYPRE_BigInt *cols_new; HYPRE_BigInt *rownums_new; HYPRE_Int *numcols_new; /* Do a sort on rownums, but store the original order in indys. * Then see if there are any duplicate rows */ for(i = 0; i < (*ijbuf_rowcounter); i++) { indys[i] = i; } hypre_BigQsortbi((*ijbuf_rownums), indys, 0, (*ijbuf_rowcounter)-1); duplicate = 0; for(i = 1; i < (*ijbuf_rowcounter); i++) { if(indys[i] != (indys[i-1]+1)) { duplicate = 1; break; } } /* Compress duplicate rows */ if(duplicate) { /* Accumulate numcols, so that it functions like a CSR row-pointer */ for(i = 1; i < (*ijbuf_rowcounter); i++) { (*ijbuf_numcols)[i] += (*ijbuf_numcols)[i-1]; } /* Initialize new buffer */ prev_row = -1; rowcounter_new = 0; cnt_new = 0; data_new = hypre_CTAlloc(HYPRE_Real, ijbuf_size, HYPRE_MEMORY_HOST); cols_new = hypre_CTAlloc(HYPRE_BigInt, ijbuf_size, HYPRE_MEMORY_HOST); rownums_new = hypre_CTAlloc(HYPRE_BigInt, ijbuf_size, HYPRE_MEMORY_HOST); numcols_new = hypre_CTAlloc(HYPRE_Int, ijbuf_size, HYPRE_MEMORY_HOST); numcols_new[0] = 0; /* Cycle through each row */ for(i = 0; i < (*ijbuf_rowcounter); i++) { /* Find which row this is in local and global numberings, and where * this row's data starts and stops in the buffer*/ row_loc = indys[i]; row = (*ijbuf_rownums)[i]; if(row_loc > 0) { row_start = (*ijbuf_numcols)[row_loc-1]; row_stop = (*ijbuf_numcols)[row_loc]; } else { row_start = 0; row_stop = (*ijbuf_numcols)[row_loc]; } /* Is this a new row? If so, compress previous row, and add a new * one. Noting that prev_row = -1 is a special value */ if(row != prev_row) { if(prev_row != -1) { /* Compress previous row */ hypre_NonGalerkinIJBufferCompressRow(&cnt_new, rowcounter_new, data_new, cols_new, rownums_new, numcols_new); } prev_row = row; numcols_new[rowcounter_new] = 0; rownums_new[rowcounter_new] = row; rowcounter_new++; } /* Copy row into new buffer */ for(j = row_start; j < row_stop; j++) { data_new[cnt_new] = (*ijbuf_data)[j]; cols_new[cnt_new] = (*ijbuf_cols)[j]; numcols_new[rowcounter_new-1]++; cnt_new++; } } /* Compress the final row */ if(i > 1) { hypre_NonGalerkinIJBufferCompressRow(&cnt_new, rowcounter_new, data_new, cols_new, rownums_new, numcols_new); } *ijbuf_cnt = cnt_new; *ijbuf_rowcounter = rowcounter_new; /* Point to the new buffer */ hypre_TFree(*ijbuf_data, HYPRE_MEMORY_HOST); hypre_TFree(*ijbuf_cols, HYPRE_MEMORY_HOST); hypre_TFree(*ijbuf_rownums, HYPRE_MEMORY_HOST); hypre_TFree(*ijbuf_numcols, HYPRE_MEMORY_HOST); (*ijbuf_data) = data_new; (*ijbuf_cols) = cols_new; (*ijbuf_rownums) = rownums_new; (*ijbuf_numcols) = numcols_new; } hypre_TFree(indys, HYPRE_MEMORY_HOST); return ierr; } /** * Do a buffered write to an IJ matrix. * That is, write to the buffer, until the buffer is full. Then when the * buffer is full, write to the IJ matrix and reset the buffer counters * In effect, this buffers this operation * A[row_to_write, col_to_write] += val_to_write **/ HYPRE_Int hypre_NonGalerkinIJBufferWrite( HYPRE_IJMatrix B, /* Unassembled matrix to add an entry to */ HYPRE_Int *ijbuf_cnt, /* current buffer size */ HYPRE_Int ijbuf_size, /* max buffer size */ HYPRE_Int *ijbuf_rowcounter, /* num of rows in rownums, (i.e., size of rownums) */ /* This counter will increase as you call this function for multiple rows */ HYPRE_Real **ijbuf_data, /* Array of values, of size ijbuf_size */ HYPRE_BigInt **ijbuf_cols, /* Array of col indices, of size ijbuf_size */ HYPRE_BigInt **ijbuf_rownums, /* Holds row-indices that with numcols makes for a CSR-like data structure*/ HYPRE_Int **ijbuf_numcols, /* rownums[i] is the row num, and numcols holds the number of entries being added */ /* for that row. Note numcols is not cumulative like an actual CSR data structure*/ HYPRE_BigInt row_to_write, /* Entry to add to the buffer */ HYPRE_BigInt col_to_write, /* Ditto */ HYPRE_Real val_to_write ) /* Ditto */ { HYPRE_Int ierr = 0; if( (*ijbuf_cnt) == 0 ) { /* brand new buffer: increment buffer structures for the new row */ hypre_NonGalerkinIJBufferNewRow((*ijbuf_rownums), (*ijbuf_numcols), ijbuf_rowcounter, row_to_write); } else if((*ijbuf_rownums)[ (*ijbuf_rowcounter)-1 ] != row_to_write) { /* If this is a new row, compress the previous row */ hypre_NonGalerkinIJBufferCompressRow(ijbuf_cnt, (*ijbuf_rowcounter), (*ijbuf_data), (*ijbuf_cols), (*ijbuf_rownums), (*ijbuf_numcols)); /* increment buffer structures for the new row */ hypre_NonGalerkinIJBufferNewRow( (*ijbuf_rownums), (*ijbuf_numcols), ijbuf_rowcounter, row_to_write); } /* Add new entry to buffer */ (*ijbuf_cols)[(*ijbuf_cnt)] = col_to_write; (*ijbuf_data)[(*ijbuf_cnt)] = val_to_write; (*ijbuf_numcols)[ (*ijbuf_rowcounter)-1 ]++; (*ijbuf_cnt)++; /* Buffer is full, write to the matrix object */ if ( (*ijbuf_cnt) == (ijbuf_size-1) ) { /* If the last row is empty, decrement rowcounter */ if( (*ijbuf_numcols)[ (*ijbuf_rowcounter)-1 ] == 0) { (*ijbuf_rowcounter)--; } /* Compress and Add Entries */ hypre_NonGalerkinIJBufferCompressRow(ijbuf_cnt, (*ijbuf_rowcounter), (*ijbuf_data), (*ijbuf_cols), (*ijbuf_rownums), (*ijbuf_numcols)); hypre_NonGalerkinIJBufferCompress(ijbuf_size, ijbuf_cnt, ijbuf_rowcounter, ijbuf_data, ijbuf_cols, ijbuf_rownums, ijbuf_numcols); ierr += HYPRE_IJMatrixAddToValues(B, *ijbuf_rowcounter, (*ijbuf_numcols), (*ijbuf_rownums), (*ijbuf_cols), (*ijbuf_data)); /* Reinitialize the buffer */ hypre_NonGalerkinIJBufferInit( ijbuf_cnt, ijbuf_rowcounter, (*ijbuf_numcols)); hypre_NonGalerkinIJBufferNewRow((*ijbuf_rownums), (*ijbuf_numcols), ijbuf_rowcounter, row_to_write); } return ierr; } /** * Empty the IJ Buffer with a final AddToValues. **/ HYPRE_Int hypre_NonGalerkinIJBufferEmpty(HYPRE_IJMatrix B, /* See NonGalerkinIJBufferWrite for parameter descriptions */ HYPRE_Int ijbuf_size, HYPRE_Int *ijbuf_cnt, HYPRE_Int ijbuf_rowcounter, HYPRE_Real **ijbuf_data, HYPRE_BigInt **ijbuf_cols, HYPRE_BigInt **ijbuf_rownums, HYPRE_Int **ijbuf_numcols) { HYPRE_Int ierr = 0; if( (*ijbuf_cnt) > 0) { /* Compress the last row and then write */ hypre_NonGalerkinIJBufferCompressRow(ijbuf_cnt, ijbuf_rowcounter, (*ijbuf_data), (*ijbuf_cols), (*ijbuf_rownums), (*ijbuf_numcols)); hypre_NonGalerkinIJBufferCompress(ijbuf_size, ijbuf_cnt, &ijbuf_rowcounter, ijbuf_data, ijbuf_cols, ijbuf_rownums, ijbuf_numcols); ierr += HYPRE_IJMatrixAddToValues(B, ijbuf_rowcounter, (*ijbuf_numcols), (*ijbuf_rownums), (*ijbuf_cols), (*ijbuf_data)); } (*ijbuf_cnt = 0); return ierr; } /* * Construct sparsity pattern based on R_I A P, plus entries required by drop tolerance */ hypre_ParCSRMatrix * hypre_NonGalerkinSparsityPattern(hypre_ParCSRMatrix *R_IAP, hypre_ParCSRMatrix *RAP, HYPRE_Int * CF_marker, HYPRE_Real droptol, HYPRE_Int sym_collapse, HYPRE_Int collapse_beta ) { /* MPI Communicator */ MPI_Comm comm = hypre_ParCSRMatrixComm(RAP); /* Declare R_IAP */ hypre_CSRMatrix *R_IAP_diag = hypre_ParCSRMatrixDiag(R_IAP); HYPRE_Int *R_IAP_diag_i = hypre_CSRMatrixI(R_IAP_diag); HYPRE_Int *R_IAP_diag_j = hypre_CSRMatrixJ(R_IAP_diag); hypre_CSRMatrix *R_IAP_offd = hypre_ParCSRMatrixOffd(R_IAP); HYPRE_Int *R_IAP_offd_i = hypre_CSRMatrixI(R_IAP_offd); HYPRE_Int *R_IAP_offd_j = hypre_CSRMatrixJ(R_IAP_offd); HYPRE_BigInt *col_map_offd_R_IAP = hypre_ParCSRMatrixColMapOffd(R_IAP); /* Declare RAP */ hypre_CSRMatrix *RAP_diag = hypre_ParCSRMatrixDiag(RAP); HYPRE_Int *RAP_diag_i = hypre_CSRMatrixI(RAP_diag); HYPRE_Real *RAP_diag_data = hypre_CSRMatrixData(RAP_diag); HYPRE_Int *RAP_diag_j = hypre_CSRMatrixJ(RAP_diag); HYPRE_BigInt first_col_diag_RAP = hypre_ParCSRMatrixFirstColDiag(RAP); HYPRE_Int num_cols_diag_RAP = hypre_CSRMatrixNumCols(RAP_diag); HYPRE_BigInt last_col_diag_RAP = first_col_diag_RAP + (HYPRE_BigInt)num_cols_diag_RAP - 1; hypre_CSRMatrix *RAP_offd = hypre_ParCSRMatrixOffd(RAP); HYPRE_Int *RAP_offd_i = hypre_CSRMatrixI(RAP_offd); HYPRE_Real *RAP_offd_data = NULL; HYPRE_Int *RAP_offd_j = hypre_CSRMatrixJ(RAP_offd); HYPRE_BigInt *col_map_offd_RAP = hypre_ParCSRMatrixColMapOffd(RAP); HYPRE_Int num_cols_RAP_offd = hypre_CSRMatrixNumCols(RAP_offd); HYPRE_Int num_variables = hypre_CSRMatrixNumRows(RAP_diag); /* Declare A */ HYPRE_Int num_fine_variables = hypre_CSRMatrixNumRows(R_IAP_diag); /* Declare IJ matrices */ HYPRE_IJMatrix Pattern; hypre_ParCSRMatrix *Pattern_CSR = NULL; /* Buffered IJAddToValues */ HYPRE_Int ijbuf_cnt, ijbuf_size, ijbuf_rowcounter; HYPRE_Real *ijbuf_data; HYPRE_BigInt *ijbuf_cols, *ijbuf_rownums; HYPRE_Int *ijbuf_numcols; /* Buffered IJAddToValues for Symmetric Entries */ HYPRE_Int ijbuf_sym_cnt, ijbuf_sym_rowcounter; HYPRE_Real *ijbuf_sym_data; HYPRE_BigInt *ijbuf_sym_cols, *ijbuf_sym_rownums; HYPRE_Int *ijbuf_sym_numcols; /* Other Declarations */ HYPRE_Int ierr = 0; HYPRE_Real max_entry = 0.0; HYPRE_Real max_entry_offd = 0.0; HYPRE_Int * rownz = NULL; HYPRE_Int i, j, Cpt; HYPRE_BigInt row_start, row_end, global_row, global_col; /* Other Setup */ if (num_cols_RAP_offd) { RAP_offd_data = hypre_CSRMatrixData(RAP_offd); } /* * Initialize the IJ matrix, leveraging our rough knowledge of the * nonzero structure of Pattern based on RAP * * ilower, iupper, jlower, jupper */ ierr += HYPRE_IJMatrixCreate(comm, first_col_diag_RAP, last_col_diag_RAP, first_col_diag_RAP, last_col_diag_RAP, &Pattern); ierr += HYPRE_IJMatrixSetObjectType(Pattern, HYPRE_PARCSR); rownz = hypre_CTAlloc(HYPRE_Int, num_variables, HYPRE_MEMORY_HOST); for(i = 0; i < num_variables; i++) { rownz[i] = 1.2*(RAP_diag_i[i+1] - RAP_diag_i[i]) + 1.2*(RAP_offd_i[i+1] - RAP_offd_i[i]); } HYPRE_IJMatrixSetRowSizes(Pattern, rownz); ierr += HYPRE_IJMatrixInitialize(Pattern); hypre_TFree(rownz, HYPRE_MEMORY_HOST); /* *For efficiency, we do a buffered IJAddToValues. * Here, we initialize the buffer and then initialize the buffer counters */ ijbuf_size = 1000; ijbuf_data = hypre_CTAlloc(HYPRE_Real, ijbuf_size, HYPRE_MEMORY_HOST); ijbuf_cols = hypre_CTAlloc(HYPRE_BigInt, ijbuf_size, HYPRE_MEMORY_HOST); ijbuf_rownums = hypre_CTAlloc(HYPRE_BigInt, ijbuf_size, HYPRE_MEMORY_HOST); ijbuf_numcols = hypre_CTAlloc(HYPRE_Int, ijbuf_size, HYPRE_MEMORY_HOST); hypre_NonGalerkinIJBigBufferInit( &ijbuf_cnt, &ijbuf_rowcounter, ijbuf_cols ); if(sym_collapse) { ijbuf_sym_data = hypre_CTAlloc(HYPRE_Real, ijbuf_size, HYPRE_MEMORY_HOST); ijbuf_sym_cols = hypre_CTAlloc(HYPRE_BigInt, ijbuf_size, HYPRE_MEMORY_HOST); ijbuf_sym_rownums= hypre_CTAlloc(HYPRE_BigInt, ijbuf_size, HYPRE_MEMORY_HOST); ijbuf_sym_numcols= hypre_CTAlloc(HYPRE_Int, ijbuf_size, HYPRE_MEMORY_HOST); hypre_NonGalerkinIJBigBufferInit( &ijbuf_sym_cnt, &ijbuf_sym_rowcounter, ijbuf_sym_cols ); } /* * Place entries in R_IAP into Pattern */ Cpt = -1; /* Cpt contains the fine grid index of the i-th Cpt */ for(i = 0; i < num_variables; i++) { global_row = i+first_col_diag_RAP; /* Find the next Coarse Point in CF_marker */ for(j = Cpt+1; j < num_fine_variables; j++) { if(CF_marker[j] == 1) /* Found Next C-point */ { Cpt = j; break; } } /* Diag Portion */ row_start = R_IAP_diag_i[Cpt]; row_end = R_IAP_diag_i[Cpt+1]; for(j = row_start; j < row_end; j++) { global_col = R_IAP_diag_j[j] + first_col_diag_RAP; /* This call adds a 1 x 1 to i j data */ hypre_NonGalerkinIJBufferWrite( Pattern, &ijbuf_cnt, ijbuf_size, &ijbuf_rowcounter, &ijbuf_data, &ijbuf_cols, &ijbuf_rownums, &ijbuf_numcols, global_row, global_col, 1.0); if (sym_collapse) { hypre_NonGalerkinIJBufferWrite( Pattern, &ijbuf_sym_cnt, ijbuf_size, &ijbuf_sym_rowcounter, &ijbuf_sym_data, &ijbuf_sym_cols, &ijbuf_sym_rownums, &ijbuf_sym_numcols, global_col, global_row, 1.0); } } /* Offdiag Portion */ row_start = R_IAP_offd_i[Cpt]; row_end = R_IAP_offd_i[Cpt+1]; for(j = row_start; j < row_end; j++) { global_col = col_map_offd_R_IAP[ R_IAP_offd_j[j] ]; /* This call adds a 1 x 1 to i j data */ hypre_NonGalerkinIJBufferWrite( Pattern, &ijbuf_cnt, ijbuf_size, &ijbuf_rowcounter, &ijbuf_data, &ijbuf_cols, &ijbuf_rownums, &ijbuf_numcols, global_row, global_col, 1.0); if (sym_collapse) { hypre_NonGalerkinIJBufferWrite( Pattern, &ijbuf_sym_cnt, ijbuf_size, &ijbuf_sym_rowcounter, &ijbuf_sym_data, &ijbuf_sym_cols, &ijbuf_sym_rownums, &ijbuf_sym_numcols, global_col, global_row, 1.0); } } } /* * Use drop-tolerance to compute new entries for sparsity pattern */ /*#ifdef HYPRE_USING_OPENMP #pragma omp parallel for private(i,j,max_entry,max_entry_offd,global_col,global_row) HYPRE_SMP_SCHEDULE #endif*/ for(i = 0; i < num_variables; i++) { global_row = i+first_col_diag_RAP; /* Compute the drop tolerance for this row, which is just * abs(max of row i)*droptol */ max_entry = -1.0; for(j = RAP_diag_i[i]; j < RAP_diag_i[i+1]; j++) { if( (RAP_diag_j[j] != i) && (max_entry < fabs(RAP_diag_data[j]) ) ) { max_entry = fabs(RAP_diag_data[j]); } } for(j = RAP_offd_i[i]; j < RAP_offd_i[i+1]; j++) { { if( max_entry < fabs(RAP_offd_data[j]) ) { max_entry = fabs(RAP_offd_data[j]); } } } max_entry *= droptol; max_entry_offd = max_entry*collapse_beta; /* Loop over diag portion, adding all entries that are "strong" */ for(j = RAP_diag_i[i]; j < RAP_diag_i[i+1]; j++) { if( fabs(RAP_diag_data[j]) > max_entry ) { global_col = RAP_diag_j[j] + first_col_diag_RAP; /*#ifdef HYPRE_USING_OPENMP #pragma omp critical (IJAdd) #endif {*/ /* For efficiency, we do a buffered IJAddToValues * A[global_row, global_col] += 1.0 */ hypre_NonGalerkinIJBufferWrite( Pattern, &ijbuf_cnt, ijbuf_size, &ijbuf_rowcounter, &ijbuf_data, &ijbuf_cols, &ijbuf_rownums, &ijbuf_numcols, global_row, global_col, 1.0 ); if(sym_collapse) { hypre_NonGalerkinIJBufferWrite( Pattern, &ijbuf_sym_cnt, ijbuf_size, &ijbuf_sym_rowcounter, &ijbuf_sym_data, &ijbuf_sym_cols, &ijbuf_sym_rownums, &ijbuf_sym_numcols, global_col, global_row, 1.0 ); } /*}*/ } } /* Loop over offd portion, adding all entries that are "strong" */ for(j = RAP_offd_i[i]; j < RAP_offd_i[i+1]; j++) { if( fabs(RAP_offd_data[j]) > max_entry_offd ) { global_col = col_map_offd_RAP[ RAP_offd_j[j] ]; /*#ifdef HYPRE_USING_OPENMP #pragma omp critical (IJAdd) #endif {*/ /* For efficiency, we do a buffered IJAddToValues * A[global_row, global_col] += 1.0 */ hypre_NonGalerkinIJBufferWrite( Pattern, &ijbuf_cnt, ijbuf_size, &ijbuf_rowcounter, &ijbuf_data, &ijbuf_cols, &ijbuf_rownums, &ijbuf_numcols, global_row, global_col, 1.0 ); if(sym_collapse) { hypre_NonGalerkinIJBufferWrite( Pattern, &ijbuf_sym_cnt, ijbuf_size, &ijbuf_sym_rowcounter, &ijbuf_sym_data, &ijbuf_sym_cols, &ijbuf_sym_rownums, &ijbuf_sym_numcols, global_col, global_row, 1.0 ); } /*}*/ } } } /* For efficiency, we do a buffered IJAddToValues. * This empties the buffer of any remaining values */ hypre_NonGalerkinIJBufferEmpty(Pattern, ijbuf_size, &ijbuf_cnt, ijbuf_rowcounter, &ijbuf_data, &ijbuf_cols, &ijbuf_rownums, &ijbuf_numcols); if(sym_collapse) hypre_NonGalerkinIJBufferEmpty(Pattern, ijbuf_size, &ijbuf_sym_cnt, ijbuf_sym_rowcounter, &ijbuf_sym_data, &ijbuf_sym_cols, &ijbuf_sym_rownums, &ijbuf_sym_numcols); /* Finalize Construction of Pattern */ ierr += HYPRE_IJMatrixAssemble(Pattern); ierr += HYPRE_IJMatrixGetObject( Pattern, (void**) &Pattern_CSR ); /* Deallocate */ ierr += HYPRE_IJMatrixSetObjectType(Pattern, -1); ierr += HYPRE_IJMatrixDestroy(Pattern); hypre_TFree(ijbuf_data, HYPRE_MEMORY_HOST); hypre_TFree(ijbuf_cols, HYPRE_MEMORY_HOST); hypre_TFree(ijbuf_rownums, HYPRE_MEMORY_HOST); hypre_TFree(ijbuf_numcols, HYPRE_MEMORY_HOST); if(sym_collapse) { hypre_TFree(ijbuf_sym_data, HYPRE_MEMORY_HOST); hypre_TFree(ijbuf_sym_cols, HYPRE_MEMORY_HOST); hypre_TFree(ijbuf_sym_rownums, HYPRE_MEMORY_HOST); hypre_TFree(ijbuf_sym_numcols, HYPRE_MEMORY_HOST); } return Pattern_CSR; } HYPRE_Int hypre_BoomerAMGBuildNonGalerkinCoarseOperator( hypre_ParCSRMatrix **RAP_ptr, hypre_ParCSRMatrix *AP, HYPRE_Real strong_threshold, HYPRE_Real max_row_sum, HYPRE_Int num_functions, HYPRE_Int * dof_func_value, HYPRE_Real S_commpkg_switch, HYPRE_Int * CF_marker, HYPRE_Real droptol, HYPRE_Int sym_collapse, HYPRE_Real lump_percent, HYPRE_Int collapse_beta ) { /* Initializations */ MPI_Comm comm = hypre_ParCSRMatrixComm(*RAP_ptr); hypre_ParCSRMatrix *S = NULL; hypre_ParCSRMatrix *RAP = *RAP_ptr; HYPRE_Int *col_offd_S_to_A = NULL; HYPRE_Int i, j, k, row_start, row_end, value, num_cols_offd_Sext, num_procs; HYPRE_Int S_ext_diag_size, S_ext_offd_size, last_col_diag_RAP, cnt_offd, cnt_diag, cnt; HYPRE_Int col_indx_Pattern, current_Pattern_j, col_indx_RAP; /* HYPRE_Real start_time = hypre_MPI_Wtime(); */ /* HYPRE_Real end_time; */ HYPRE_BigInt *temp = NULL; HYPRE_Int ierr = 0; char filename[256]; /* Lumping related variables */ HYPRE_IJMatrix ijmatrix; HYPRE_Int * Pattern_offd_indices = NULL; HYPRE_Int * S_offd_indices = NULL; HYPRE_Int * offd_intersection = NULL; HYPRE_Real * offd_intersection_data = NULL; HYPRE_Int * diag_intersection = NULL; HYPRE_Real * diag_intersection_data = NULL; HYPRE_Int Pattern_offd_indices_len = 0; HYPRE_Int Pattern_offd_indices_allocated_len= 0; HYPRE_Int S_offd_indices_len = 0; HYPRE_Int S_offd_indices_allocated_len = 0; HYPRE_Int offd_intersection_len = 0; HYPRE_Int offd_intersection_allocated_len = 0; HYPRE_Int diag_intersection_len = 0; HYPRE_Int diag_intersection_allocated_len = 0; HYPRE_Real intersection_len = 0; HYPRE_Int * Pattern_indices_ptr = NULL; HYPRE_Int Pattern_diag_indices_len = 0; HYPRE_Int global_row = 0; HYPRE_Int has_row_ended = 0; HYPRE_Real lump_value = 0.; HYPRE_Real diagonal_lump_value = 0.; HYPRE_Real neg_lump_value = 0.; HYPRE_Real sum_strong_neigh = 0.; HYPRE_Int * rownz = NULL; /* offd and diag portions of RAP */ hypre_CSRMatrix *RAP_diag = hypre_ParCSRMatrixDiag(RAP); HYPRE_Int *RAP_diag_i = hypre_CSRMatrixI(RAP_diag); HYPRE_Real *RAP_diag_data = hypre_CSRMatrixData(RAP_diag); HYPRE_Int *RAP_diag_j = hypre_CSRMatrixJ(RAP_diag); HYPRE_BigInt first_col_diag_RAP = hypre_ParCSRMatrixFirstColDiag(RAP); HYPRE_Int num_cols_diag_RAP = hypre_CSRMatrixNumCols(RAP_diag); hypre_CSRMatrix *RAP_offd = hypre_ParCSRMatrixOffd(RAP); HYPRE_Int *RAP_offd_i = hypre_CSRMatrixI(RAP_offd); HYPRE_Real *RAP_offd_data = NULL; HYPRE_Int *RAP_offd_j = hypre_CSRMatrixJ(RAP_offd); HYPRE_BigInt *col_map_offd_RAP = hypre_ParCSRMatrixColMapOffd(RAP); HYPRE_Int num_cols_RAP_offd = hypre_CSRMatrixNumCols(RAP_offd); HYPRE_Int num_variables = hypre_CSRMatrixNumRows(RAP_diag); HYPRE_BigInt global_num_vars = hypre_ParCSRMatrixGlobalNumRows(RAP); /* offd and diag portions of S */ hypre_CSRMatrix *S_diag = NULL; HYPRE_Int *S_diag_i = NULL; HYPRE_Real *S_diag_data = NULL; HYPRE_Int *S_diag_j = NULL; hypre_CSRMatrix *S_offd = NULL; HYPRE_Int *S_offd_i = NULL; HYPRE_Real *S_offd_data = NULL; HYPRE_Int *S_offd_j = NULL; HYPRE_BigInt *col_map_offd_S = NULL; HYPRE_Int num_cols_offd_S; /* HYPRE_Int num_nonzeros_S_diag; */ /* off processor portions of S */ hypre_CSRMatrix *S_ext = NULL; HYPRE_Int *S_ext_i = NULL; HYPRE_Real *S_ext_data = NULL; HYPRE_BigInt *S_ext_j = NULL; HYPRE_Int *S_ext_diag_i = NULL; HYPRE_Real *S_ext_diag_data = NULL; HYPRE_Int *S_ext_diag_j = NULL; HYPRE_Int *S_ext_offd_i = NULL; HYPRE_Real *S_ext_offd_data = NULL; HYPRE_Int *S_ext_offd_j = NULL; HYPRE_BigInt *col_map_offd_Sext = NULL; /* HYPRE_Int num_nonzeros_S_ext_diag; HYPRE_Int num_nonzeros_S_ext_offd; HYPRE_Int num_rows_Sext = 0; */ HYPRE_Int row_indx_Sext = 0; /* offd and diag portions of Pattern */ hypre_ParCSRMatrix *Pattern = NULL; hypre_CSRMatrix *Pattern_diag = NULL; HYPRE_Int *Pattern_diag_i = NULL; HYPRE_Real *Pattern_diag_data = NULL; HYPRE_Int *Pattern_diag_j = NULL; hypre_CSRMatrix *Pattern_offd = NULL; HYPRE_Int *Pattern_offd_i = NULL; HYPRE_Real *Pattern_offd_data = NULL; HYPRE_Int *Pattern_offd_j = NULL; HYPRE_BigInt *col_map_offd_Pattern = NULL; HYPRE_Int num_cols_Pattern_offd; HYPRE_Int my_id; /* Buffered IJAddToValues */ HYPRE_Int ijbuf_cnt, ijbuf_size, ijbuf_rowcounter; HYPRE_Real *ijbuf_data; HYPRE_BigInt *ijbuf_cols, *ijbuf_rownums; HYPRE_Int *ijbuf_numcols; /* Buffered IJAddToValues for Symmetric Entries */ HYPRE_Int ijbuf_sym_cnt, ijbuf_sym_rowcounter; HYPRE_Real *ijbuf_sym_data; HYPRE_BigInt *ijbuf_sym_cols, *ijbuf_sym_rownums; HYPRE_Int *ijbuf_sym_numcols; /* Further Initializations */ if (num_cols_RAP_offd) { RAP_offd_data = hypre_CSRMatrixData(RAP_offd); } hypre_MPI_Comm_size(comm, &num_procs); hypre_MPI_Comm_rank(comm, &my_id); /* Compute Sparsity Pattern */ Pattern = hypre_NonGalerkinSparsityPattern(AP, RAP, CF_marker, droptol, sym_collapse, collapse_beta); Pattern_diag = hypre_ParCSRMatrixDiag(Pattern); Pattern_diag_i = hypre_CSRMatrixI(Pattern_diag); Pattern_diag_data = hypre_CSRMatrixData(Pattern_diag); Pattern_diag_j = hypre_CSRMatrixJ(Pattern_diag); Pattern_offd = hypre_ParCSRMatrixOffd(Pattern); Pattern_offd_i = hypre_CSRMatrixI(Pattern_offd); Pattern_offd_j = hypre_CSRMatrixJ(Pattern_offd); col_map_offd_Pattern = hypre_ParCSRMatrixColMapOffd(Pattern); num_cols_Pattern_offd = hypre_CSRMatrixNumCols(Pattern_offd); if (num_cols_Pattern_offd) { Pattern_offd_data = hypre_CSRMatrixData(Pattern_offd); } /** * Fill in the entries of Pattern with entries from RAP **/ /* First, sort column indices in RAP and Pattern */ for(i = 0; i < num_variables; i++) { /* The diag matrices store the diagonal as first element in each row. * We maintain that for the case of Pattern and RAP, because the * strength of connection routine relies on it and we need to ignore * diagonal entries in Pattern later during set intersections. * */ /* Sort diag portion of RAP */ row_start = RAP_diag_i[i]; if( RAP_diag_j[row_start] == i) { row_start = row_start + 1; } row_end = RAP_diag_i[i+1]; hypre_qsort1(RAP_diag_j, RAP_diag_data, row_start, row_end-1 ); /* Sort diag portion of Pattern */ row_start = Pattern_diag_i[i]; if( Pattern_diag_j[row_start] == i) { row_start = row_start + 1; } row_end = Pattern_diag_i[i+1]; hypre_qsort1(Pattern_diag_j, Pattern_diag_data, row_start, row_end-1 ); /* Sort offd portion of RAP */ row_start = RAP_offd_i[i]; row_end = RAP_offd_i[i+1]; hypre_qsort1(RAP_offd_j, RAP_offd_data, row_start, row_end-1 ); /* Sort offd portion of Pattern */ /* Be careful to map coarse dof i with CF_marker into Pattern */ row_start = Pattern_offd_i[i]; row_end = Pattern_offd_i[i+1]; hypre_qsort1(Pattern_offd_j, Pattern_offd_data, row_start, row_end-1 ); } /* Create Strength matrix based on RAP or Pattern. If Pattern is used, * then the SortedCopyParCSRData(...) function call must also be commented * back in */ /* hypre_SortedCopyParCSRData(RAP, Pattern); */ if(0) { /* hypre_BoomerAMG_MyCreateS(Pattern, strong_threshold, max_row_sum, */ hypre_BoomerAMG_MyCreateS(RAP, strong_threshold, max_row_sum, num_functions, dof_func_value, &S); } else { /* Passing in "1, NULL" because dof_array is not needed * because we assume that the number of functions is 1 */ /* hypre_BoomerAMG_MyCreateS(Pattern, strong_threshold, max_row_sum,*/ hypre_BoomerAMG_MyCreateS(RAP, strong_threshold, max_row_sum, 1, NULL, &S); } /*if (0)*/ /*(strong_threshold > S_commpkg_switch)*/ /*{ hypre_BoomerAMG_MyCreateSCommPkg(RAP, S, &col_offd_S_to_A); }*/ /* Grab diag and offd parts of S */ S_diag = hypre_ParCSRMatrixDiag(S); S_diag_i = hypre_CSRMatrixI(S_diag); S_diag_j = hypre_CSRMatrixJ(S_diag); S_diag_data = hypre_CSRMatrixData(S_diag); S_offd = hypre_ParCSRMatrixOffd(S); S_offd_i = hypre_CSRMatrixI(S_offd); S_offd_j = hypre_CSRMatrixJ(S_offd); S_offd_data = hypre_CSRMatrixData(S_offd); col_map_offd_S = hypre_ParCSRMatrixColMapOffd(S); num_cols_offd_S = hypre_CSRMatrixNumCols(S_offd); /* num_nonzeros_S_diag = S_diag_i[num_variables]; */ /* Grab part of S that is distance one away from the local rows * This is needed later for the stencil collapsing. This section * of the code mimics par_rap.c when it extracts Ps_ext. * When moving from par_rap.c, the variable name changes were: * A --> RAP * P --> S * Ps_ext --> S_ext * P_ext_diag --> S_ext_diag * P_ext_offd --> S_ext_offd * * The data layout of S_ext as returned by ExtractBExt gives you only global * column indices, and must be converted to the local numbering. This code * section constructs S_ext_diag and S_ext_offd, which are the distance 1 * couplings in S based on the sparsity structure in RAP. * --> S_ext_diag corresponds to the same column slice that RAP_diag * corresponds to. Thus, the column indexing is the same as in * RAP_diag such that S_ext_diag_j[k] just needs to be offset by * the RAP_diag first global dof offset. * --> S_ext_offd column indexing is a little more complicated, and * requires the computation below of col_map_S_ext_offd, which * maps the local 0,1,2,... column indexing in S_ext_offd to global * dof numbers. Note, that the num_cols_RAP_offd is NOT equal to * num_cols_offd_S_ext * --> The row indexing of S_ext_diag|offd is as follows. Use * col_map_offd_RAP, where the first index corresponds to the * first global row index in S_ext_diag|offd. Remember that ExtractBExt * grabs the information from S required for locally computing * (RAP*S)[proc_k row slice, :] */ if (num_procs > 1) { S_ext = hypre_ParCSRMatrixExtractBExt(S,RAP,1); S_ext_data = hypre_CSRMatrixData(S_ext); S_ext_i = hypre_CSRMatrixI(S_ext); S_ext_j = hypre_CSRMatrixBigJ(S_ext); } /* This uses the num_cols_RAP_offd to set S_ext_diag|offd_i, because S_ext * is the off-processor information needed to compute RAP*S. That is, * num_cols_RAP_offd represents the number of rows needed from S_ext for * the multiplication */ S_ext_diag_i = hypre_CTAlloc(HYPRE_Int, num_cols_RAP_offd+1, HYPRE_MEMORY_HOST); S_ext_offd_i = hypre_CTAlloc(HYPRE_Int, num_cols_RAP_offd+1, HYPRE_MEMORY_HOST); S_ext_diag_size = 0; S_ext_offd_size = 0; /* num_rows_Sext = num_cols_RAP_offd; */ last_col_diag_RAP = first_col_diag_RAP + num_cols_diag_RAP - 1; /* construct the S_ext_diag and _offd row-pointer arrays by counting elements * This looks to create offd and diag blocks related to the local rows belonging * to this processor...we may not need to split up S_ext this way...or we could. * It would make for faster binary searching and set intersecting later...this will * be the bottle neck so LETS SPLIT THIS UP Between offd and diag*/ for (i=0; i < num_cols_RAP_offd; i++) { for (j=S_ext_i[i]; j < S_ext_i[i+1]; j++) if (S_ext_j[j] < first_col_diag_RAP || S_ext_j[j] > last_col_diag_RAP) S_ext_offd_size++; else S_ext_diag_size++; S_ext_diag_i[i+1] = S_ext_diag_size; S_ext_offd_i[i+1] = S_ext_offd_size; } if (S_ext_diag_size) { S_ext_diag_j = hypre_CTAlloc(HYPRE_Int, S_ext_diag_size, HYPRE_MEMORY_HOST); S_ext_diag_data = hypre_CTAlloc(HYPRE_Real, S_ext_diag_size, HYPRE_MEMORY_HOST); } if (S_ext_offd_size) { S_ext_offd_j = hypre_CTAlloc(HYPRE_Int, S_ext_offd_size, HYPRE_MEMORY_HOST); S_ext_offd_data = hypre_CTAlloc(HYPRE_Real, S_ext_offd_size, HYPRE_MEMORY_HOST); } /* This copies over the column indices into the offd and diag parts. * The diag portion has it's local column indices shifted to start at 0. * The offd portion requires more work to construct the col_map_offd array * and a local column ordering. */ cnt_offd = 0; cnt_diag = 0; cnt = 0; for (i=0; i < num_cols_RAP_offd; i++) { for (j=S_ext_i[i]; j < S_ext_i[i+1]; j++) if (S_ext_j[j] < first_col_diag_RAP || S_ext_j[j] > last_col_diag_RAP) { S_ext_offd_data[cnt_offd] = S_ext_data[j]; //S_ext_offd_j[cnt_offd++] = S_ext_j[j]; S_ext_j[cnt_offd++] = S_ext_j[j]; } else { S_ext_diag_data[cnt_diag] = S_ext_data[j]; S_ext_diag_j[cnt_diag++] = (HYPRE_Int)(S_ext_j[j] - first_col_diag_RAP); } } /* This creates col_map_offd_Sext */ if (S_ext_offd_size || num_cols_offd_S) { temp = hypre_CTAlloc(HYPRE_BigInt, S_ext_offd_size+num_cols_offd_S, HYPRE_MEMORY_HOST); for (i=0; i < S_ext_offd_size; i++) temp[i] = S_ext_j[i]; cnt = S_ext_offd_size; for (i=0; i < num_cols_offd_S; i++) temp[cnt++] = col_map_offd_S[i]; } if (cnt) { /* after this, the first so many entries of temp will hold the * unique column indices in S_ext_offd_j unioned with the indices * in col_map_offd_S */ hypre_BigQsort0(temp, 0, cnt-1); num_cols_offd_Sext = 1; value = temp[0]; for (i=1; i < cnt; i++) { if (temp[i] > value) { value = temp[i]; temp[num_cols_offd_Sext++] = value; } } } else { num_cols_offd_Sext = 0; } /* num_nonzeros_S_ext_diag = cnt_diag; num_nonzeros_S_ext_offd = S_ext_offd_size; */ if (num_cols_offd_Sext) col_map_offd_Sext = hypre_CTAlloc(HYPRE_BigInt, num_cols_offd_Sext, HYPRE_MEMORY_HOST); for (i=0; i < num_cols_offd_Sext; i++) col_map_offd_Sext[i] = temp[i]; if (S_ext_offd_size || num_cols_offd_S) hypre_TFree(temp, HYPRE_MEMORY_HOST); /* look for S_ext_offd_j[i] in col_map_offd_Sext, and set S_ext_offd_j[i] * to the index of that column value in col_map_offd_Sext */ for (i=0 ; i < S_ext_offd_size; i++) S_ext_offd_j[i] = hypre_BigBinarySearch(col_map_offd_Sext, S_ext_j[i], num_cols_offd_Sext); if (num_procs > 1) { hypre_CSRMatrixDestroy(S_ext); S_ext = NULL; } /* Need to sort column indices in S and S_ext */ for(i = 0; i < num_variables; i++) { /* Re-Sort diag portion of Pattern, placing the diagonal entry in a * sorted position */ row_start = Pattern_diag_i[i]; row_end = Pattern_diag_i[i+1]; hypre_qsort1(Pattern_diag_j, Pattern_diag_data, row_start, row_end-1 ); /* Sort diag portion of S, noting that no diagonal entry */ /* S has not "data" array...it's just NULL */ row_start = S_diag_i[i]; row_end = S_diag_i[i+1]; hypre_qsort1(S_diag_j, S_diag_data, row_start, row_end-1 ); /* Sort offd portion of S */ /* S has no "data" array...it's just NULL */ row_start = S_offd_i[i]; row_end = S_offd_i[i+1]; hypre_qsort1(S_offd_j, S_offd_data, row_start, row_end-1 ); } /* Sort S_ext * num_cols_RAP_offd equals num_rows for S_ext*/ for(i = 0; i < num_cols_RAP_offd; i++) { /* Sort diag portion of S_ext */ row_start = S_ext_diag_i[i]; row_end = S_ext_diag_i[i+1]; hypre_qsort1(S_ext_diag_j, S_ext_diag_data, row_start, row_end-1 ); /* Sort offd portion of S_ext */ row_start = S_ext_offd_i[i]; row_end = S_ext_offd_i[i+1]; hypre_qsort1(S_ext_offd_j, S_ext_offd_data, row_start, row_end-1 ); } /* * Now, for the fun stuff -- Computing the Non-Galerkin Operator */ /* Initialize the ijmatrix, leveraging our knowledge of the nonzero * structure in Pattern */ ierr += HYPRE_IJMatrixCreate(comm, first_col_diag_RAP, last_col_diag_RAP, first_col_diag_RAP, last_col_diag_RAP, &ijmatrix); ierr += HYPRE_IJMatrixSetObjectType(ijmatrix, HYPRE_PARCSR); rownz = hypre_CTAlloc(HYPRE_Int, num_variables, HYPRE_MEMORY_HOST); for(i = 0; i < num_variables; i++) { rownz[i] = 1.2*(Pattern_diag_i[i+1] - Pattern_diag_i[i]) + 1.2*(Pattern_offd_i[i+1] - Pattern_offd_i[i]); } HYPRE_IJMatrixSetRowSizes(ijmatrix, rownz); ierr += HYPRE_IJMatrixInitialize(ijmatrix); hypre_TFree(rownz, HYPRE_MEMORY_HOST); /* *For efficiency, we do a buffered IJAddToValues. * Here, we initialize the buffer and then initialize the buffer counters */ ijbuf_size = 1000; ijbuf_data = hypre_CTAlloc(HYPRE_Real, ijbuf_size, HYPRE_MEMORY_HOST); ijbuf_cols = hypre_CTAlloc(HYPRE_BigInt, ijbuf_size, HYPRE_MEMORY_HOST); ijbuf_rownums = hypre_CTAlloc(HYPRE_BigInt, ijbuf_size, HYPRE_MEMORY_HOST); ijbuf_numcols = hypre_CTAlloc(HYPRE_Int, ijbuf_size, HYPRE_MEMORY_HOST); hypre_NonGalerkinIJBigBufferInit( &ijbuf_cnt, &ijbuf_rowcounter, ijbuf_cols ); if(sym_collapse) { ijbuf_sym_data = hypre_CTAlloc(HYPRE_Real, ijbuf_size, HYPRE_MEMORY_HOST); ijbuf_sym_cols = hypre_CTAlloc(HYPRE_BigInt, ijbuf_size, HYPRE_MEMORY_HOST); ijbuf_sym_rownums= hypre_CTAlloc(HYPRE_BigInt, ijbuf_size, HYPRE_MEMORY_HOST); ijbuf_sym_numcols= hypre_CTAlloc(HYPRE_Int, ijbuf_size, HYPRE_MEMORY_HOST); hypre_NonGalerkinIJBigBufferInit( &ijbuf_sym_cnt, &ijbuf_sym_rowcounter, ijbuf_sym_cols ); } /* * Eliminate Entries In RAP_diag * */ for(i = 0; i < num_variables; i++) { global_row = i+first_col_diag_RAP; row_start = RAP_diag_i[i]; row_end = RAP_diag_i[i+1]; has_row_ended = 0; /* Only do work if row has nonzeros */ if( row_start < row_end) { /* Grab pointer to current entry in Pattern_diag */ current_Pattern_j = Pattern_diag_i[i]; col_indx_Pattern = Pattern_diag_j[current_Pattern_j]; /* Grab this row's indices out of Pattern offd and diag. This will * be for computing index set intersections for lumping */ /* Ensure adequate length */ Pattern_offd_indices_len = Pattern_offd_i[i+1] - Pattern_offd_i[i]; if(Pattern_offd_indices_allocated_len < Pattern_offd_indices_len) { hypre_TFree(Pattern_offd_indices, HYPRE_MEMORY_HOST); Pattern_offd_indices = hypre_CTAlloc(HYPRE_Int, Pattern_offd_indices_len, HYPRE_MEMORY_HOST); Pattern_offd_indices_allocated_len = Pattern_offd_indices_len; } /* Grab sub array from col_map, corresponding to the slice of Pattern_offd_j */ hypre_GrabSubArray(Pattern_offd_j, Pattern_offd_i[i], Pattern_offd_i[i+1]-1, col_map_offd_Pattern, Pattern_offd_indices); /* No need to grab info out of Pattern_diag_j[...], here we just start from * Pattern_diag_i[i] and end at index Pattern_diag_i[i+1] - 1. We do need to * ignore the diagonal entry in Pattern, because we don't lump entries there */ if( Pattern_diag_j[Pattern_diag_i[i]] == i ) { Pattern_indices_ptr = &( Pattern_diag_j[Pattern_diag_i[i]+1]); Pattern_diag_indices_len = Pattern_diag_i[i+1] - Pattern_diag_i[i] - 1; } else { Pattern_indices_ptr = &( Pattern_diag_j[Pattern_diag_i[i]]); Pattern_diag_indices_len = Pattern_diag_i[i+1] - Pattern_diag_i[i]; } } for(j = row_start; j < row_end; j++) { col_indx_RAP = RAP_diag_j[j]; /* Ignore zero entries in RAP */ if( RAP_diag_data[j] != 0.0) { /* Don't change the diagonal, just write it */ if(col_indx_RAP == i) { /*#ifdef HY PRE_USING_OPENMP #pragma omp critical (IJAdd) #endif {*/ /* For efficiency, we do a buffered IJAddToValues. * A[global_row, global_row] += RAP_diag_data[j] */ hypre_NonGalerkinIJBufferWrite( ijmatrix, &ijbuf_cnt, ijbuf_size, &ijbuf_rowcounter, &ijbuf_data, &ijbuf_cols, &ijbuf_rownums, &ijbuf_numcols, global_row, global_row, RAP_diag_data[j] ); /*}*/ } /* The entry in RAP does not appear in Pattern, so LUMP it */ else if( (col_indx_RAP < col_indx_Pattern) || has_row_ended) { /* Lump entry (i, col_indx_RAP) in RAP */ /* Grab the indices for row col_indx_RAP of S_offd and diag. This will * be for computing lumping locations */ S_offd_indices_len = S_offd_i[col_indx_RAP+1] - S_offd_i[col_indx_RAP]; if(S_offd_indices_allocated_len < S_offd_indices_len) { hypre_TFree(S_offd_indices, HYPRE_MEMORY_HOST); S_offd_indices = hypre_CTAlloc(HYPRE_Int, S_offd_indices_len, HYPRE_MEMORY_HOST); S_offd_indices_allocated_len = S_offd_indices_len; } /* Grab sub array from col_map, corresponding to the slice of S_offd_j */ hypre_GrabSubArray(S_offd_j, S_offd_i[col_indx_RAP], S_offd_i[col_indx_RAP+1]-1, col_map_offd_S, S_offd_indices); /* No need to grab info out of S_diag_j[...], here we just start from * S_diag_i[col_indx_RAP] and end at index S_diag_i[col_indx_RAP+1] - 1 */ /* Intersect the diag and offd pieces, remembering that the * diag array will need to have the offset +first_col_diag_RAP */ cnt = hypre_max(S_offd_indices_len, Pattern_offd_indices_len); if(offd_intersection_allocated_len < cnt) { hypre_TFree(offd_intersection, HYPRE_MEMORY_HOST); hypre_TFree(offd_intersection_data, HYPRE_MEMORY_HOST); offd_intersection = hypre_CTAlloc(HYPRE_Int, cnt, HYPRE_MEMORY_HOST); offd_intersection_data = hypre_CTAlloc(HYPRE_Real, cnt, HYPRE_MEMORY_HOST); offd_intersection_allocated_len = cnt; } /* This intersection also tracks S_offd_data and assumes that * S_offd_indices is the first argument here */ hypre_IntersectTwoArrays(S_offd_indices, &(S_offd_data[ S_offd_i[col_indx_RAP] ]), S_offd_indices_len, Pattern_offd_indices, Pattern_offd_indices_len, offd_intersection, offd_intersection_data, &offd_intersection_len); /* Now, intersect the indices for the diag block. Note that S_diag_j does * not have a diagonal entry, so no lumping occurs to the diagonal. */ cnt = hypre_max(Pattern_diag_indices_len, S_diag_i[col_indx_RAP+1] - S_diag_i[col_indx_RAP] ); if(diag_intersection_allocated_len < cnt) { hypre_TFree(diag_intersection, HYPRE_MEMORY_HOST); hypre_TFree(diag_intersection_data, HYPRE_MEMORY_HOST); diag_intersection = hypre_CTAlloc(HYPRE_Int, cnt, HYPRE_MEMORY_HOST); diag_intersection_data = hypre_CTAlloc(HYPRE_Real, cnt, HYPRE_MEMORY_HOST); diag_intersection_allocated_len = cnt; } /* There is no diagonal entry in first position of S */ hypre_IntersectTwoArrays( &(S_diag_j[S_diag_i[col_indx_RAP]]), &(S_diag_data[ S_diag_i[col_indx_RAP] ]), S_diag_i[col_indx_RAP+1] - S_diag_i[col_indx_RAP], Pattern_indices_ptr, Pattern_diag_indices_len, diag_intersection, diag_intersection_data, &diag_intersection_len); /* Loop over these intersections, and lump a constant fraction of * RAP_diag_data[j] to each entry */ intersection_len = diag_intersection_len + offd_intersection_len; if(intersection_len > 0) { /* Sum the strength-of-connection values from row * col_indx_RAP in S, corresponding to the indices we are * collapsing to in row i This will give us our collapsing * weights. */ sum_strong_neigh = 0.0; for(k = 0; k < diag_intersection_len; k++) { sum_strong_neigh += fabs(diag_intersection_data[k]); } for(k = 0; k < offd_intersection_len; k++) { sum_strong_neigh += fabs(offd_intersection_data[k]); } sum_strong_neigh = RAP_diag_data[j]/sum_strong_neigh; /* When lumping with the diag_intersection, must offset column index */ for(k = 0; k < diag_intersection_len; k++) { lump_value = lump_percent * fabs(diag_intersection_data[k])*sum_strong_neigh; diagonal_lump_value = (1.0 - lump_percent) * fabs(diag_intersection_data[k])*sum_strong_neigh; neg_lump_value = -1.0 * lump_value; cnt = diag_intersection[k]+first_col_diag_RAP; /*#ifdef HY PRE_USING_OPENMP #pragma omp critical (IJAdd) #endif {*/ /* For efficiency, we do a buffered IJAddToValues. * A[global_row, cnt] += RAP_diag_data[j] */ hypre_NonGalerkinIJBufferWrite( ijmatrix, &ijbuf_cnt, ijbuf_size, &ijbuf_rowcounter, &ijbuf_data, &ijbuf_cols, &ijbuf_rownums, &ijbuf_numcols, global_row, cnt, lump_value ); if (lump_percent < 1.0) { /* Preserve row sum by updating diagonal */ hypre_NonGalerkinIJBufferWrite( ijmatrix, &ijbuf_cnt, ijbuf_size, &ijbuf_rowcounter, &ijbuf_data, &ijbuf_cols, &ijbuf_rownums, &ijbuf_numcols, global_row, global_row, diagonal_lump_value ); } /* Update mirror entries, if symmetric collapsing */ if(sym_collapse) { /* Update mirror entry */ hypre_NonGalerkinIJBufferWrite( ijmatrix, &ijbuf_sym_cnt, ijbuf_size, &ijbuf_sym_rowcounter, &ijbuf_sym_data, &ijbuf_sym_cols, &ijbuf_sym_rownums, &ijbuf_sym_numcols, cnt, global_row, lump_value ); /* Update mirror entry diagonal */ hypre_NonGalerkinIJBufferWrite( ijmatrix, &ijbuf_sym_cnt, ijbuf_size, &ijbuf_sym_rowcounter, &ijbuf_sym_data, &ijbuf_sym_cols, &ijbuf_sym_rownums, &ijbuf_sym_numcols, cnt, cnt, neg_lump_value ); } /*}*/ } /* The offd_intersection has global column indices, i.e., the * col_map arrays contain global indices */ for(k = 0; k < offd_intersection_len; k++) { lump_value = lump_percent * fabs(offd_intersection_data[k])*sum_strong_neigh; diagonal_lump_value = (1.0 - lump_percent) * fabs(offd_intersection_data[k])*sum_strong_neigh; neg_lump_value = -1.0 * lump_value; hypre_NonGalerkinIJBufferWrite( ijmatrix, &ijbuf_cnt, ijbuf_size, &ijbuf_rowcounter, &ijbuf_data, &ijbuf_cols, &ijbuf_rownums, &ijbuf_numcols, global_row, offd_intersection[k], lump_value ); if (lump_percent < 1.0) { hypre_NonGalerkinIJBufferWrite( ijmatrix, &ijbuf_cnt, ijbuf_size, &ijbuf_rowcounter, &ijbuf_data, &ijbuf_cols, &ijbuf_rownums, &ijbuf_numcols, global_row, global_row, diagonal_lump_value ); } /* Update mirror entries, if symmetric collapsing */ if (sym_collapse) { hypre_NonGalerkinIJBufferWrite( ijmatrix, &ijbuf_sym_cnt, ijbuf_size, &ijbuf_sym_rowcounter, &ijbuf_sym_data, &ijbuf_sym_cols, &ijbuf_sym_rownums, &ijbuf_sym_numcols, offd_intersection[k], global_row, lump_value ); hypre_NonGalerkinIJBufferWrite( ijmatrix, &ijbuf_sym_cnt, ijbuf_size, &ijbuf_sym_rowcounter, &ijbuf_sym_data, &ijbuf_sym_cols, &ijbuf_sym_rownums, &ijbuf_sym_numcols, offd_intersection[k], offd_intersection[k], neg_lump_value ); } } } /* If intersection is empty, do not eliminate entry */ else { /* Don't forget to update mirror entry if collapsing symmetrically */ if (sym_collapse) { lump_value = 0.5*RAP_diag_data[j]; } else { lump_value = RAP_diag_data[j]; } cnt = col_indx_RAP+first_col_diag_RAP; hypre_NonGalerkinIJBufferWrite( ijmatrix, &ijbuf_cnt, ijbuf_size, &ijbuf_rowcounter, &ijbuf_data, &ijbuf_cols, &ijbuf_rownums, &ijbuf_numcols, global_row, cnt, lump_value ); if (sym_collapse) { hypre_NonGalerkinIJBufferWrite( ijmatrix, &ijbuf_sym_cnt, ijbuf_size, &ijbuf_sym_rowcounter, &ijbuf_sym_data, &ijbuf_sym_cols, &ijbuf_sym_rownums, &ijbuf_sym_numcols, cnt, global_row, lump_value ); } } } /* The entry in RAP appears in Pattern, so keep it */ else if(col_indx_RAP == col_indx_Pattern) { cnt = col_indx_RAP+first_col_diag_RAP; hypre_NonGalerkinIJBufferWrite( ijmatrix, &ijbuf_cnt, ijbuf_size, &ijbuf_rowcounter, &ijbuf_data, &ijbuf_cols, &ijbuf_rownums, &ijbuf_numcols, global_row, cnt, RAP_diag_data[j] ); /* Only go to the next entry in Pattern, if this is not the end of a row */ if( current_Pattern_j < Pattern_diag_i[i+1]-1 ) { current_Pattern_j += 1; col_indx_Pattern = Pattern_diag_j[current_Pattern_j]; } else { has_row_ended = 1;} } /* Increment col_indx_Pattern, and repeat this loop iter for current * col_ind_RAP value */ else if(col_indx_RAP > col_indx_Pattern) { for(; current_Pattern_j < Pattern_diag_i[i+1]; current_Pattern_j++) { col_indx_Pattern = Pattern_diag_j[current_Pattern_j]; if(col_indx_RAP <= col_indx_Pattern) { break;} } /* If col_indx_RAP is still greater (i.e., we've reached a row end), then * we need to lump everything else in this row */ if(col_indx_RAP > col_indx_Pattern) { has_row_ended = 1; } /* Decrement j, in order to repeat this loop iteration for the current * col_indx_RAP value */ j--; } } } } /* * Eliminate Entries In RAP_offd * Structure of this for-loop is very similar to the RAP_diag for-loop * But, not so similar that these loops should be combined into a single fuction. * */ if(num_cols_RAP_offd) { for(i = 0; i < num_variables; i++) { global_row = i+first_col_diag_RAP; row_start = RAP_offd_i[i]; row_end = RAP_offd_i[i+1]; has_row_ended = 0; /* Only do work if row has nonzeros */ if( row_start < row_end) { current_Pattern_j = Pattern_offd_i[i]; Pattern_offd_indices_len = Pattern_offd_i[i+1] - Pattern_offd_i[i]; if( (Pattern_offd_j != NULL) && (Pattern_offd_indices_len > 0) ) { col_indx_Pattern = col_map_offd_Pattern[ Pattern_offd_j[current_Pattern_j] ]; } else { /* if Pattern_offd_j is not allocated or this is a zero length row, then all entries need to be lumped. This is an analagous situation to has_row_ended=1. */ col_indx_Pattern = -1; has_row_ended = 1; } /* Grab this row's indices out of Pattern offd and diag. This will * be for computing index set intersections for lumping. The above * loop over RAP_diag ensures adequate length of Pattern_offd_indices */ /* Ensure adequate length */ hypre_GrabSubArray(Pattern_offd_j, Pattern_offd_i[i], Pattern_offd_i[i+1]-1, col_map_offd_Pattern, Pattern_offd_indices); /* No need to grab info out of Pattern_diag_j[...], here we just start from * Pattern_diag_i[i] and end at index Pattern_diag_i[i+1] - 1. We do need to * ignore the diagonal entry in Pattern, because we don't lump entries there */ if( Pattern_diag_j[Pattern_diag_i[i]] == i ) { Pattern_indices_ptr = &( Pattern_diag_j[Pattern_diag_i[i]+1]); Pattern_diag_indices_len = Pattern_diag_i[i+1] - Pattern_diag_i[i] - 1; } else { Pattern_indices_ptr = &( Pattern_diag_j[Pattern_diag_i[i]]); Pattern_diag_indices_len = Pattern_diag_i[i+1] - Pattern_diag_i[i]; } } for(j = row_start; j < row_end; j++) { /* Ignore zero entries in RAP */ if( RAP_offd_data[j] != 0.0) { /* In general for all the offd_j arrays, we have to indirectly * index with the col_map_offd array to get a global index */ col_indx_RAP = col_map_offd_RAP[ RAP_offd_j[j] ]; /* The entry in RAP does not appear in Pattern, so LUMP it */ if( (col_indx_RAP < col_indx_Pattern) || has_row_ended) { /* The row_indx_Sext would be found with: row_indx_Sext = hypre_BinarySearch(col_map_offd_RAP, col_indx_RAP, num_cols_RAP_offd); But, we already know the answer to this with, */ row_indx_Sext = RAP_offd_j[j]; /* Grab the indices for row row_indx_Sext from the offd and diag parts. This will * be for computing lumping locations */ S_offd_indices_len = S_ext_offd_i[row_indx_Sext+1] - S_ext_offd_i[row_indx_Sext]; if(S_offd_indices_allocated_len < S_offd_indices_len) { hypre_TFree(S_offd_indices, HYPRE_MEMORY_HOST); S_offd_indices = hypre_CTAlloc(HYPRE_Int, S_offd_indices_len, HYPRE_MEMORY_HOST); S_offd_indices_allocated_len = S_offd_indices_len; } /* Grab sub array from col_map, corresponding to the slice of S_ext_offd_j */ hypre_GrabSubArray(S_ext_offd_j, S_ext_offd_i[row_indx_Sext], S_ext_offd_i[row_indx_Sext+1]-1, col_map_offd_Sext, S_offd_indices); /* No need to grab info out of S_ext_diag_j[...], here we just start from * S_ext_diag_i[row_indx_Sext] and end at index S_ext_diag_i[row_indx_Sext+1] - 1 */ /* Intersect the diag and offd pieces, remembering that the * diag array will need to have the offset +first_col_diag_RAP */ cnt = hypre_max(S_offd_indices_len, Pattern_offd_indices_len); if(offd_intersection_allocated_len < cnt) { hypre_TFree(offd_intersection, HYPRE_MEMORY_HOST); hypre_TFree(offd_intersection_data, HYPRE_MEMORY_HOST); offd_intersection = hypre_CTAlloc(HYPRE_Int, cnt, HYPRE_MEMORY_HOST); offd_intersection_data = hypre_CTAlloc(HYPRE_Real, cnt, HYPRE_MEMORY_HOST); offd_intersection_allocated_len = cnt; } hypre_IntersectTwoArrays(S_offd_indices, &(S_ext_offd_data[ S_ext_offd_i[row_indx_Sext] ]), S_offd_indices_len, Pattern_offd_indices, Pattern_offd_indices_len, offd_intersection, offd_intersection_data, &offd_intersection_len); /* Now, intersect the indices for the diag block. */ cnt = hypre_max(Pattern_diag_indices_len, S_ext_diag_i[row_indx_Sext+1] - S_ext_diag_i[row_indx_Sext] ); if(diag_intersection_allocated_len < cnt) { hypre_TFree(diag_intersection, HYPRE_MEMORY_HOST); hypre_TFree(diag_intersection_data, HYPRE_MEMORY_HOST); diag_intersection = hypre_CTAlloc(HYPRE_Int, cnt, HYPRE_MEMORY_HOST); diag_intersection_data = hypre_CTAlloc(HYPRE_Real, cnt, HYPRE_MEMORY_HOST); diag_intersection_allocated_len = cnt; } hypre_IntersectTwoArrays( &(S_ext_diag_j[S_ext_diag_i[row_indx_Sext]]), &(S_ext_diag_data[ S_ext_diag_i[row_indx_Sext] ]), S_ext_diag_i[row_indx_Sext+1] - S_ext_diag_i[row_indx_Sext], Pattern_indices_ptr, Pattern_diag_indices_len, diag_intersection, diag_intersection_data, &diag_intersection_len); /* Loop over these intersections, and lump a constant fraction of * RAP_offd_data[j] to each entry */ intersection_len = diag_intersection_len + offd_intersection_len; if(intersection_len > 0) { /* Sum the strength-of-connection values from row * row_indx_Sext in S, corresponding to the indices we are * collapsing to in row i. This will give us our collapsing * weights. */ sum_strong_neigh = 0.0; for(k = 0; k < diag_intersection_len; k++) { sum_strong_neigh += fabs(diag_intersection_data[k]); } for(k = 0; k < offd_intersection_len; k++) { sum_strong_neigh += fabs(offd_intersection_data[k]); } sum_strong_neigh = RAP_offd_data[j]/sum_strong_neigh; /* When lumping with the diag_intersection, must offset column index */ for(k = 0; k < diag_intersection_len; k++) { lump_value = lump_percent * fabs(diag_intersection_data[k])*sum_strong_neigh; diagonal_lump_value = (1.0 - lump_percent) * fabs(diag_intersection_data[k])*sum_strong_neigh; neg_lump_value = -1.0 * lump_value; cnt = diag_intersection[k]+first_col_diag_RAP; hypre_NonGalerkinIJBufferWrite( ijmatrix, &ijbuf_cnt, ijbuf_size, &ijbuf_rowcounter, &ijbuf_data, &ijbuf_cols, &ijbuf_rownums, &ijbuf_numcols, global_row, cnt, lump_value ); if (lump_percent < 1.0) { hypre_NonGalerkinIJBufferWrite( ijmatrix, &ijbuf_cnt, ijbuf_size, &ijbuf_rowcounter, &ijbuf_data, &ijbuf_cols, &ijbuf_rownums, &ijbuf_numcols, global_row, global_row, diagonal_lump_value ); } /* Update mirror entries, if symmetric collapsing */ if (sym_collapse) { hypre_NonGalerkinIJBufferWrite( ijmatrix, &ijbuf_sym_cnt, ijbuf_size, &ijbuf_sym_rowcounter, &ijbuf_sym_data, &ijbuf_sym_cols, &ijbuf_sym_rownums, &ijbuf_sym_numcols, cnt, global_row, lump_value); hypre_NonGalerkinIJBufferWrite( ijmatrix, &ijbuf_sym_cnt, ijbuf_size, &ijbuf_sym_rowcounter, &ijbuf_sym_data, &ijbuf_sym_cols, &ijbuf_sym_rownums, &ijbuf_sym_numcols, cnt, cnt, neg_lump_value ); } } /* The offd_intersection has global column indices, i.e., the * col_map arrays contain global indices */ for(k = 0; k < offd_intersection_len; k++) { lump_value = lump_percent * fabs(offd_intersection_data[k])*sum_strong_neigh; diagonal_lump_value = (1.0 - lump_percent) * fabs(offd_intersection_data[k])*sum_strong_neigh; neg_lump_value = -1.0 * lump_value; hypre_NonGalerkinIJBufferWrite( ijmatrix, &ijbuf_cnt, ijbuf_size, &ijbuf_rowcounter, &ijbuf_data, &ijbuf_cols, &ijbuf_rownums, &ijbuf_numcols, global_row, offd_intersection[k], lump_value ); if (lump_percent < 1.0) { hypre_NonGalerkinIJBufferWrite( ijmatrix, &ijbuf_cnt, ijbuf_size, &ijbuf_rowcounter, &ijbuf_data, &ijbuf_cols, &ijbuf_rownums, &ijbuf_numcols, global_row, global_row, diagonal_lump_value ); } /* Update mirror entries, if symmetric collapsing */ if (sym_collapse) { hypre_NonGalerkinIJBufferWrite( ijmatrix, &ijbuf_sym_cnt, ijbuf_size, &ijbuf_sym_rowcounter, &ijbuf_sym_data, &ijbuf_sym_cols, &ijbuf_sym_rownums, &ijbuf_sym_numcols, offd_intersection[k], global_row, lump_value ); hypre_NonGalerkinIJBufferWrite( ijmatrix, &ijbuf_sym_cnt, ijbuf_size, &ijbuf_sym_rowcounter, &ijbuf_sym_data, &ijbuf_sym_cols, &ijbuf_sym_rownums, &ijbuf_sym_numcols, offd_intersection[k], offd_intersection[k], neg_lump_value ); } } } /* If intersection is empty, do not eliminate entry */ else { /* Don't forget to update mirror entry if collapsing symmetrically */ if (sym_collapse) { lump_value = 0.5*RAP_offd_data[j]; } else { lump_value = RAP_offd_data[j]; } hypre_NonGalerkinIJBufferWrite( ijmatrix, &ijbuf_cnt, ijbuf_size, &ijbuf_rowcounter, &ijbuf_data, &ijbuf_cols, &ijbuf_rownums, &ijbuf_numcols, global_row, col_indx_RAP, lump_value ); if (sym_collapse) { hypre_NonGalerkinIJBufferWrite( ijmatrix, &ijbuf_sym_cnt, ijbuf_size, &ijbuf_sym_rowcounter, &ijbuf_sym_data, &ijbuf_sym_cols, &ijbuf_sym_rownums, &ijbuf_sym_numcols, col_indx_RAP, global_row, lump_value ); } } } /* The entry in RAP appears in Pattern, so keep it */ else if (col_indx_RAP == col_indx_Pattern) { /* For the offd structure, col_indx_RAP is a global dof number */ hypre_NonGalerkinIJBufferWrite( ijmatrix, &ijbuf_cnt, ijbuf_size, &ijbuf_rowcounter, &ijbuf_data, &ijbuf_cols, &ijbuf_rownums, &ijbuf_numcols, global_row, col_indx_RAP, RAP_offd_data[j]); /* Only go to the next entry in Pattern, if this is not the end of a row */ if( current_Pattern_j < Pattern_offd_i[i+1]-1 ) { current_Pattern_j += 1; col_indx_Pattern = col_map_offd_Pattern[ Pattern_offd_j[current_Pattern_j] ]; } else { has_row_ended = 1;} } /* Increment col_indx_Pattern, and repeat this loop iter for current * col_ind_RAP value */ else if(col_indx_RAP > col_indx_Pattern) { for(; current_Pattern_j < Pattern_offd_i[i+1]; current_Pattern_j++) { col_indx_Pattern = col_map_offd_Pattern[ Pattern_offd_j[current_Pattern_j] ]; if(col_indx_RAP <= col_indx_Pattern) { break;} } /* If col_indx_RAP is still greater (i.e., we've reached a row end), then * we need to lump everything else in this row */ if(col_indx_RAP > col_indx_Pattern) { has_row_ended = 1; } /* Decrement j, in order to repeat this loop iteration for the current * col_indx_RAP value */ j--; } } } } } /* For efficiency, we do a buffered IJAddToValues. * This empties the buffer of any remaining values */ hypre_NonGalerkinIJBufferEmpty(ijmatrix, ijbuf_size, &ijbuf_cnt, ijbuf_rowcounter, &ijbuf_data, &ijbuf_cols, &ijbuf_rownums, &ijbuf_numcols); if(sym_collapse) hypre_NonGalerkinIJBufferEmpty(ijmatrix, ijbuf_size, &ijbuf_sym_cnt, ijbuf_sym_rowcounter, &ijbuf_sym_data, &ijbuf_sym_cols, &ijbuf_sym_rownums, &ijbuf_sym_numcols); /* Assemble non-Galerkin Matrix, and overwrite current RAP*/ ierr += HYPRE_IJMatrixAssemble (ijmatrix); ierr += HYPRE_IJMatrixGetObject( ijmatrix, (void**) RAP_ptr); /* Optional diagnostic matrix printing */ if (0) { hypre_sprintf(filename, "Pattern_%d.ij", global_num_vars); hypre_ParCSRMatrixPrintIJ(Pattern, 0, 0, filename); hypre_sprintf(filename, "Strength_%d.ij", global_num_vars); hypre_ParCSRMatrixPrintIJ(S, 0, 0, filename); hypre_sprintf(filename, "RAP_%d.ij", global_num_vars); hypre_ParCSRMatrixPrintIJ(RAP, 0, 0, filename); hypre_sprintf(filename, "RAPc_%d.ij", global_num_vars); hypre_ParCSRMatrixPrintIJ(*RAP_ptr, 0, 0, filename); hypre_sprintf(filename, "AP_%d.ij", global_num_vars); hypre_ParCSRMatrixPrintIJ(AP, 0, 0, filename); } /* Free matrices and variables and arrays */ hypre_TFree(ijbuf_data, HYPRE_MEMORY_HOST); hypre_TFree(ijbuf_cols, HYPRE_MEMORY_HOST); hypre_TFree(ijbuf_rownums, HYPRE_MEMORY_HOST); hypre_TFree(ijbuf_numcols, HYPRE_MEMORY_HOST); if(sym_collapse) { hypre_TFree(ijbuf_sym_data, HYPRE_MEMORY_HOST); hypre_TFree(ijbuf_sym_cols, HYPRE_MEMORY_HOST); hypre_TFree(ijbuf_sym_rownums, HYPRE_MEMORY_HOST); hypre_TFree(ijbuf_sym_numcols, HYPRE_MEMORY_HOST); } hypre_TFree(Pattern_offd_indices, HYPRE_MEMORY_HOST); hypre_TFree(S_ext_diag_i, HYPRE_MEMORY_HOST); hypre_TFree(S_ext_offd_i, HYPRE_MEMORY_HOST); hypre_TFree(S_offd_indices, HYPRE_MEMORY_HOST); hypre_TFree(offd_intersection, HYPRE_MEMORY_HOST); hypre_TFree(offd_intersection_data, HYPRE_MEMORY_HOST); hypre_TFree(diag_intersection, HYPRE_MEMORY_HOST); hypre_TFree(diag_intersection_data, HYPRE_MEMORY_HOST); if (S_ext_diag_size) { hypre_TFree(S_ext_diag_j, HYPRE_MEMORY_HOST); hypre_TFree(S_ext_diag_data, HYPRE_MEMORY_HOST); } if (S_ext_offd_size) { hypre_TFree(S_ext_offd_j, HYPRE_MEMORY_HOST); hypre_TFree(S_ext_offd_data, HYPRE_MEMORY_HOST); } if (num_cols_offd_Sext) { hypre_TFree(col_map_offd_Sext, HYPRE_MEMORY_HOST); } if (0) /*(strong_threshold > S_commpkg_switch)*/ { hypre_TFree(col_offd_S_to_A, HYPRE_MEMORY_HOST); } ierr += hypre_ParCSRMatrixDestroy(Pattern); ierr += hypre_ParCSRMatrixDestroy(RAP); ierr += hypre_ParCSRMatrixDestroy(S); ierr += HYPRE_IJMatrixSetObjectType(ijmatrix, -1); ierr += HYPRE_IJMatrixDestroy(ijmatrix); /*end_time = hypre_MPI_Wtime(); if(my_id == 0) { fprintf(stdout, "NonGalerkin Time: %1.2e\n", end_time-start_time); } */ return ierr; }

random.c

/* Copyright (c) 2013, Intel Corporation Redistribution and use in source and binary forms, with or without modification, are permitted provided that the following conditions are met: * Redistributions of source code must retain the above copyright notice, this list of conditions and the following disclaimer. * Redistributions in binary form must reproduce the above copyright notice, this list of conditions and the following disclaimer in the documentation and/or other materials provided with the distribution. * Neither the name of Intel Corporation nor the names of its contributors may be used to endorse or promote products derived from this software without specific prior written permission. THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. */ /************************************************************* Copyright (c) 2013 The University of Tennessee. All rights reserved. Redistribution and use in source and binary forms, with or without modification, are permitted provided that the following conditions are met: - Redistributions of source code must retain the above copyright notice, this list of conditions and the following disclaimer. - Redistributions in binary form must reproduce the above copyright notice, this list of conditions and the following disclaimer listed in this license in the documentation and/or other materials provided with the distribution. - Neither the name of the copyright holders nor the names of its contributors may be used to endorse or promote products derived from this software without specific prior written permission. This software is provided by the copyright holders and contributors "as is" and any express or implied warranties, including, but not limited to, the implied warranties of merchantability and fitness for a particular purpose are disclaimed. in no event shall the copyright owner or contributors be liable for any direct, indirect, incidental, special, exemplary, or consequential damages (including, but not limited to, procurement of substitute goods or services; loss of use, data, or profits; or business interruption) however caused and on any theory of liability, whether in contract, strict liability, or tort (including negligence or otherwise) arising in any way out of the use of this software, even if advised of the possibility of such damage. *************************************************************/ /******************************************************************* NAME: RandomAccess PURPOSE: This program tests the efficiency of the memory subsystem to update elements of an array with irregular stride. USAGE: The program takes as input the number of threads involved, the 2log of the size of the table that gets updated, the ratio of table size over number of updates, and the vector length of simultaneously updatable table elements. When multiple threads participate, they all share the same table. This can lead to conflicts in memory accesses. Setting the ATOMICFLAG variable in the Makefile will avoid conflicts, but at a large price, because the atomic directive is currently not implemented on IA for the type of update operation used here. Instead, a critical section is used, serializing the main loop. If the CHUNKFLAG variable is set, contiguous, non-overlapping chunks of the array are assigned to individual threads. Each thread computes all pseudo-random indices into the table, but only updates table elements that fall inside its chunk. Hence, this version is safe, and there is no false sharing. It is also non-scalable. <progname> <# threads> <log2 tablesize> <#update ratio> <vector length> FUNCTIONS CALLED: Other than OpenMP or standard C functions, the following functions are used in this program: wtime() bail_out() PRK_starts() poweroftwo() NOTES: This program is derived from HPC Challenge Random Access. The random number generator computes successive powers of 0x2, modulo the primitive polynomial x^63+x^2+x+1. The principal differences between this code and the HPCC version are: - we start the stream of random numbers not with seed 0x1, but the SEQSEED-th element in the stream of powers of 0x2. - the timed code applies the RandomAccess operator twice to the table of computed resuls (starting with the same seed(s) for "ran" in both iterations. The second pass makes sure that any update to any table element that sets high-order bits in the first pass resets those bits to zero. - the verification test now simply constitutes checking whether table element j equals j. - the number of independent streams (vector length) can be changed by the user. We note that the vectorized version of this code (i.e. nstarts unequal to 1), does not feature exactly the same sequence of accesses and intermediate update values in the table as the scalar version. The reason for this is twofold. 1. the elements in the stream of powers of 0x2 that get computed outside the main timed loop as seeds for independent streams in the vectorized version, using the jump-ahead function PRK_starts, are computed inside the timed loop for the scalar version. However, since both versions do the same number of timed random accesses, the vectorized version must progress further in the sequence of powers of 0x2. 2. The independent streams of powers of 0x2 computed in the vectorized version can (and will) cause updates of the same elements of the table in an order that is not consistent with the scalar version. That is, distinct values of "ran" can refer to the same table element "ran&(tablesize-1)," but the operation Table[ran&(tablesize-1)] ^= ran will deposit different values in that table element for different values of ran. At the end of each pass over the data set, the table will contain the same values in the vector and scalar version (ignoring the small differences caused by 1.) because of commutativity of the XOR operator. If the update operator had been non-commutative, the vector and scalar version would have yielded different results. HISTORY: Written by Rob Van der Wijngaart, June 2006. Histogram code (verbose mode) courtesy Roger Golliver Shared table version derived from random.c by Michael Frumkin, October 2006 ************************************************************************************/ #include <par-res-kern_general.h> #include <par-res-kern_omp.h> /* Define constants */ /* PERIOD = (2^63-1)/7 = 7*73*127*337*92737*649657 */ #if LONG_IS_64BITS #define POLY 0x0000000000000007UL #define PERIOD 1317624576693539401L /* sequence number in stream of random numbers to be used as initial value */ #define SEQSEED 834568137686317453L #else #define POLY 0x0000000000000007ULL #define PERIOD 1317624576693539401LL /* sequence number in stream of random numbers to be used as initial value */ #define SEQSEED 834568137686317453LL #endif #if HPCC #undef ATOMIC #undef CHUNKED #undef ERRORPERCENT #define ERRORPERCENT 1 #else #if CHUNKED #undef ATOMIC #endif #endif static u64Int PRK_starts(s64Int); #if UNUSED static int poweroftwo(int); #endif int main(int argc, char **argv) { int my_ID; /* thread ID */ int update_ratio; /* multiplier of tablesize for # updates */ int nstarts; /* vector length */ s64Int i, j, round, oldsize; /* dummies */ s64Int error; /* number of incorrect table elements */ s64Int tablesize; /* aggregate table size (all threads */ s64Int nupdate; /* number of updates per thread */ size_t tablespace; /* bytes per thread required for table */ u64Int *ran; /* vector of random numbers */ s64Int index; /* index into Table */ #if VERBOSE u64Int * RESTRICT Hist; /* histogram of # updates to table elements */ unsigned int *HistHist; /* histogram of update frequencies */ #endif u64Int * RESTRICT Table; /* (pseudo-)randomly accessed array */ double random_time; int nthread_input; /* thread parameters */ int nthread; int log2tablesize; /* log2 of aggregate table size */ int num_error=0; /* flag that signals that requested and obtained numbers of threads are the same */ printf("Parallel Research Kernels version %s\n", PRKVERSION); printf("OpenMP Random Access test\n"); #if LONG_IS_64BITS if (sizeof(long) != 8) { printf("ERROR: Makefile says \"long\" is 8 bytes, but it is %d bytes\n", sizeof(long)); exit(EXIT_FAILURE); } #endif /********************************************************************* ** process and test input parameters *********************************************************************/ if (argc != 5){ printf("Usage: %s <# threads> <log2 tablesize> <#update ratio> ", *argv); printf("<vector length>\n"); exit(EXIT_FAILURE); } nthread_input = atoi(*++argv); /* test whether number of threads is positive */ if (nthread_input <1) { printf("ERROR: Invalid number of threads: %d, must be positive\n", nthread_input); exit(EXIT_FAILURE); } omp_set_num_threads(nthread_input); log2tablesize = atoi(*++argv); if (log2tablesize < 1){ printf("ERROR: Log2 tablesize is %d; must be >= 1\n",log2tablesize); exit(EXIT_FAILURE); } update_ratio = atoi(*++argv); /* test whether update ratio is positive */ if (update_ratio <1) { printf("ERROR: Invalid update ratio: %d, must be positive\n", update_ratio); exit(EXIT_FAILURE); } nstarts = atoi(*++argv); /* if whether vector length is positive */ if (nstarts <1) { printf("ERROR: Invalid vector length: %d, must be positive\n", nstarts); exit(EXIT_FAILURE); } /* do some additional divisibility tests */ if (nstarts%nthread_input) { printf("ERROR: vector length %d must be divisible by # threads %d\n", nstarts, nthread_input); exit(EXIT_FAILURE); } if (update_ratio%nstarts) { printf("ERROR: update ratio %d must be divisible by vector length %d\n", update_ratio, nstarts); exit(EXIT_FAILURE); } /* compute table size carefully to make sure it can be represented */ tablesize = 1; for (i=0; i<log2tablesize; i++) { oldsize = tablesize; tablesize <<=1; if (tablesize/2 != oldsize) { printf("Requested table size too large; reduce log2 tablesize = %d\n", log2tablesize); exit(EXIT_FAILURE); } } /* even though the table size can be represented, computing the space required for the table may lead to overflow */ tablespace = (size_t) tablesize*sizeof(u64Int); if ((tablespace/sizeof(u64Int)) != tablesize || tablespace <=0) { printf("Cannot represent space for table on this system; "); printf("reduce log2 tablesize\n"); exit(EXIT_FAILURE); } #if VERBOSE Hist = (u64Int *) prk_malloc(tablespace); HistHist = (unsigned int *) prk_malloc(tablespace); if (!Hist || ! HistHist) { printf("ERROR: Could not allocate space for histograms\n"); exit(EXIT_FAILURE); } #endif /* compute number of updates carefully to make sure it can be represented */ nupdate = update_ratio * tablesize; if (nupdate/tablesize != update_ratio) { printf("Requested number of updates too large; "); printf("reduce log2 tablesize or update ratio\n"); exit(EXIT_FAILURE); } Table = (u64Int *) prk_malloc(tablespace); if (!Table) { printf("ERROR: Could not allocate space of "FSTR64U" bytes for table\n", (u64Int) tablespace); exit(EXIT_FAILURE); } error = 0; #pragma omp parallel private(i, j, ran, round, index, my_ID) reduction(+:error) { int my_starts; my_ID = omp_get_thread_num(); #pragma omp master { nthread = omp_get_num_threads(); if (nthread != nthread_input) { num_error = 1; printf("ERROR: number of requested threads %d does not equal ", nthread_input); printf("number of spawned threads %d\n", nthread); } else { printf("Number of threads = "FSTR64U"\n", (u64Int) nthread_input); printf("Table size (shared) = "FSTR64U"\n", tablesize); printf("Update ratio = "FSTR64U"\n", (u64Int) update_ratio); printf("Number of updates = "FSTR64U"\n", nupdate); printf("Vector length = "FSTR64U"\n", (u64Int) nstarts); printf("Percent errors allowed = "FSTR64U"\n", (u64Int) ERRORPERCENT); #if RESTRICT_KEYWORD printf("No aliasing = on\n"); #else printf("No aliasing = off\n"); #endif #if defined(ATOMIC) && !defined(CHUNKED) printf("Shared table, atomic updates\n"); #elif defined(CHUNKED) printf("Shared, chunked table\n"); #else printf("Shared table, non-atomic updates\n"); #endif } } bail_out(num_error); #if CHUNKED /* compute upper and lower table bounds for this thread */ u64Int low = my_ID *(tablesize/nthread); u64Int up = (my_ID+1)*(tablesize/nthread); my_starts = nstarts; #else my_starts = nstarts/nthread; #endif ran = (u64Int *) prk_malloc(my_starts*sizeof(u64Int)); if (!ran) { printf("ERROR: Thread %d Could not allocate %d bytes for random numbers\n", my_ID, my_starts*(int)sizeof(u64Int)); num_error = 1; } bail_out(num_error); /* initialize the table */ #pragma omp for for(i=0;i<tablesize;i++) Table[i] = (u64Int) i; #pragma omp barrier #pragma omp master { random_time = wtime(); } /* ran is privatized. Must make sure for non-chunked version that we pick the right section of the originally shared ran array */ #if CHUNKED int offset = 0; #else int offset = my_ID*my_starts; #endif /* do two identical rounds of Random Access to make sure we recover the initial condition */ for (round=0; round <2; round++) { for (j=0; j<my_starts; j++) { ran[j] = PRK_starts(SEQSEED+(nupdate/nstarts)*(j+offset)); } for (j=0; j<my_starts; j++) { /* because we do two rounds, we divide nupdates in two */ for (i=0; i<nupdate/(nstarts*2); i++) { ran[j] = (ran[j] << 1) ^ ((s64Int)ran[j] < 0? POLY: 0); index = ran[j] & (tablesize-1); #if defined(ATOMIC) #pragma omp atomic #elif defined(CHUNKED) if (index >= low && index < up) { #endif Table[index] ^= ran[j]; #if VERBOSE #pragma omp atomic Hist[index] += 1; #endif #if CHUNKED } #endif } } } #pragma omp master { random_time = wtime() - random_time; } } /* end of OpenMP parallel region */ /* verification test */ for(i=0;i<tablesize;i++) { if(Table[i] != (u64Int) i) { #if VERBOSE printf("Error Table["FSTR64U"]="FSTR64U"\n",i,Table[i]); #endif error++; } } if ((error && (ERRORPERCENT==0)) || ((double)error/(double)tablesize > ((double) ERRORPERCENT)*0.01)) { printf("ERROR: number of incorrect table elements = "FSTR64U"\n", error); exit(EXIT_FAILURE); } else { printf("Solution validates, number of errors: %ld\n",(long) error); printf("Rate (GUPs/s): %lf, time (s) = %lf\n", 1.e-9*nupdate/random_time,random_time); } #if VERBOSE for(i=0;i<tablesize;i++) HistHist[Hist[i]]+=1; for(i=0;i<=tablesize;i++) if (HistHist[i] != 0) printf("HistHist[%4.1d]=%9.1d\n",(int)i,HistHist[i]); #endif exit(EXIT_SUCCESS); } /* Utility routine to start random number generator at nth step */ u64Int PRK_starts(s64Int n) { int i, j; u64Int m2[64]; u64Int temp, ran; while (n < 0) n += PERIOD; while (n > PERIOD) n -= PERIOD; if (n == 0) return 0x1; temp = 0x1; for (i=0; i<64; i++) { m2[i] = temp; temp = (temp << 1) ^ ((s64Int) temp < 0 ? POLY : 0); temp = (temp << 1) ^ ((s64Int) temp < 0 ? POLY : 0); } for (i=62; i>=0; i--) if ((n >> i) & 1) break; ran = 0x2; while (i > 0) { temp = 0; for (j=0; j<64; j++) if ((unsigned int)((ran >> j) & 1)) temp ^= m2[j]; ran = temp; i -= 1; if ((n >> i) & 1) ran = (ran << 1) ^ ((s64Int) ran < 0 ? POLY : 0); } return ran; } #if UNUSED /* utility routine that tests whether an integer is a power of two */ int poweroftwo(int n) { int log2n = 0; while ((1<<log2n)<n) log2n++; if (1<<log2n != n) return (-1); else return (log2n); } #endif

NETLMv2_fmt_plug.c

/* * NETLMv2_fmt.c -- LMv2 Challenge/Response * * Written by JoMo-Kun <jmk at foofus.net> in 2008 * and placed in the public domain. * * Performance fixes, OMP and utf-8 support by magnum 2010-2011 * * This algorithm is designed for performing brute-force cracking of the LMv2 * challenge/response sets exchanged during network-based authentication * attempts [1]. The captured challenge/response set from these attempts * should be stored using the following format: * * USERNAME::DOMAIN:SERVER CHALLENGE:LMv2 RESPONSE:CLIENT CHALLENGE * * For example: * Administrator::WORKGROUP:1122334455667788:6759A5A7EFB25452911DE7DE8296A0D8:F503236B200A5B3A * * It should be noted that a LMv2 authentication response is not same as a LM * password hash, which can be extracted using tools such as FgDump [2]. In * fact, a NTLM hash and not a LM hash is used within the LMv2 algorithm. LMv2 * challenge/response authentication typically takes place when the GPO * "Network Security: LAN Manager authentication level" is configured to a setting * that enforces the use of NTLMv2, such as "Send NTLMv2 response only\refuse * LM & NTLM." * * LMv2 responses can be gathered via normal network capture or via tools which * perform layer 2 attacks, such as Ettercap [3] and Cain [4]. The responses can * also be harvested using a modified Samba service [5] in conjunction with * some trickery to convince the user to connect to it. I leave what that * trickery may actually be as an exercise for the reader (HINT: Karma, NMB * broadcasts, IE, Outlook, social engineering, ...). * * [1] http://davenport.sourceforge.net/ntlm.html#theLmv2Response * [2] http://www.foofus.net/~fizzgig/fgdump/ * [3] http://ettercap.sourceforge.net/ * [4] http://www.oxid.it/cain.html * [5] http://www.foofus.net/jmk/smbchallenge.html * */ #if FMT_EXTERNS_H extern struct fmt_main fmt_NETLMv2; #elif FMT_REGISTERS_H john_register_one(&fmt_NETLMv2); #else #include <string.h> #ifdef _OPENMP #include <omp.h> #endif #include "arch.h" #include "misc.h" #include "common.h" #include "formats.h" #include "options.h" #include "unicode.h" #include "stdint.h" #include "md5.h" #include "hmacmd5.h" #include "byteorder.h" #include "memdbg.h" #ifndef uchar #define uchar unsigned char #endif #define FORMAT_LABEL "netlmv2" #define FORMAT_NAME "LMv2 C/R" #define ALGORITHM_NAME "MD4 HMAC-MD5 32/" ARCH_BITS_STR #define BENCHMARK_COMMENT "" #define BENCHMARK_LENGTH 0 #define PLAINTEXT_LENGTH 125 /* lmcons.h - PWLEN (256) ? 127 ? */ #define USERNAME_LENGTH 60 /* lmcons.h - UNLEN (256) / LM20_UNLEN (20) */ #define DOMAIN_LENGTH 45 /* lmcons.h - CNLEN / DNLEN */ #define BINARY_SIZE 16 #define BINARY_ALIGN 4 #define CHALLENGE_LENGTH 32 #define SALT_SIZE 16 + 1 + 2 * (USERNAME_LENGTH + DOMAIN_LENGTH) + 1 #define SALT_ALIGN 4 #define CIPHERTEXT_LENGTH 32 #define TOTAL_LENGTH 12 + USERNAME_LENGTH + DOMAIN_LENGTH + CHALLENGE_LENGTH + CIPHERTEXT_LENGTH // these may be altered in init() if running OMP #define MIN_KEYS_PER_CRYPT 1 #define MAX_KEYS_PER_CRYPT 1 #ifndef OMP_SCALE #define OMP_SCALE 1536 #endif static struct fmt_tests tests[] = { {"", "1337adminPASS", {"FOODOM\\Administrator", "", "", "1122334455667788", "6F64C5C1E35F68DD80388C0F00F34406", "F0F3FF27037AA69F"} }, {"$NETLMv2$ADMINISTRATORFOODOM$1122334455667788$6F64C5C1E35F68DD80388C0F00F34406$F0F3FF27037AA69F", "1337adminPASS"}, {"$NETLMv2$USER1$1122334455667788$B1D163EA5881504F3963DC50FCDC26C1$EB4D9E8138149E20", "foobar"}, // repeat in exactly the same format that is used in john.pot (lower case hex) {"$NETLMv2$USER1$1122334455667788$b1d163ea5881504f3963dc50fcdc26c1$eb4d9e8138149e20", "foobar"}, {"$NETLMv2$ATEST$1122334455667788$83B59F1536D3321DBF1FAEC14ADB1675$A1E7281FE8C10E53", "SomeFancyP4$$w0rdHere"}, {"", "1337adminPASS", {"administrator", "", "FOODOM", "1122334455667788", "6F64C5C1E35F68DD80388C0F00F34406", "F0F3FF27037AA69F"} }, {"", "foobar", {"user1", "", "", "1122334455667788", "B1D163EA5881504F3963DC50FCDC26C1", "EB4D9E8138149E20"} }, {"", "SomeFancyP4$$w0rdHere", {"aTest", "", "", "1122334455667788", "83B59F1536D3321DBF1FAEC14ADB1675", "A1E7281FE8C10E53"} }, {NULL} }; static uchar (*saved_plain)[PLAINTEXT_LENGTH + 1]; static int (*saved_len); static uchar (*output)[BINARY_SIZE]; static HMACMD5Context (*saved_ctx); static int keys_prepared; static unsigned char *challenge; static void init(struct fmt_main *self) { #ifdef _OPENMP int omp_t = omp_get_max_threads(); self->params.min_keys_per_crypt *= omp_t; omp_t *= OMP_SCALE; self->params.max_keys_per_crypt *= omp_t; #endif saved_plain = mem_calloc(self->params.max_keys_per_crypt, sizeof(*saved_plain)); saved_len = mem_calloc(self->params.max_keys_per_crypt, sizeof(*saved_len)); output = mem_calloc(self->params.max_keys_per_crypt, sizeof(*output)); saved_ctx = mem_calloc(self->params.max_keys_per_crypt, sizeof(*saved_ctx)); } static void done(void) { MEM_FREE(saved_ctx); MEM_FREE(output); MEM_FREE(saved_len); MEM_FREE(saved_plain); } static int valid(char *ciphertext, struct fmt_main *self) { char *pos, *pos2; if (ciphertext == NULL) return 0; else if (strncmp(ciphertext, "$NETLMv2$", 9)!=0) return 0; pos = &ciphertext[9]; /* Validate Username and Domain Length */ for (pos2 = pos; *pos2 != '$'; pos2++) if ((unsigned char)*pos2 < 0x20) return 0; if ( !(*pos2 && (pos2 - pos <= USERNAME_LENGTH + DOMAIN_LENGTH)) ) return 0; /* Validate Server Challenge Length */ pos2++; pos = pos2; for (; *pos2 != '$'; pos2++) if (atoi16[ARCH_INDEX(*pos2)] == 0x7F) return 0; if ( !(*pos2 && (pos2 - pos == CHALLENGE_LENGTH / 2)) ) return 0; /* Validate LMv2 Response Length */ pos2++; pos = pos2; for (; *pos2 != '$'; pos2++) if (atoi16[ARCH_INDEX(*pos2)] == 0x7F) return 0; if ( !(*pos2 && (pos2 - pos == CIPHERTEXT_LENGTH)) ) return 0; /* Validate Client Challenge Length */ pos2++; pos = pos2; for (; atoi16[ARCH_INDEX(*pos2)] != 0x7F; pos2++); if (pos2 - pos != CHALLENGE_LENGTH / 2) return 0; if (pos2[0] != '\0') return 0; return 1; } static char *prepare(char *split_fields[10], struct fmt_main *self) { char *srv_challenge = split_fields[3]; char *nethashv2 = split_fields[4]; char *cli_challenge = split_fields[5]; char *login = split_fields[0]; char *uid = split_fields[2]; char *identity = NULL, *tmp; if (!strncmp(split_fields[1], "$NETLMv2$", 9)) return split_fields[1]; if (!split_fields[0]||!split_fields[2]||!split_fields[3]||!split_fields[4]||!split_fields[5]) return split_fields[1]; /* DOMAIN\USER: -or- USER::DOMAIN: */ if ((tmp = strstr(login, "\\")) != NULL) { identity = (char *) mem_alloc(strlen(login)*2 + 1); strcpy(identity, tmp + 1); /* Upper-Case Username - Not Domain */ enc_strupper(identity); strncat(identity, login, tmp - login); } else { identity = (char *) mem_alloc(strlen(login)*2 + strlen(uid) + 1); strcpy(identity, login); enc_strupper(identity); strcat(identity, uid); } tmp = (char *) mem_alloc(9 + strlen(identity) + 1 + strlen(srv_challenge) + 1 + strlen(nethashv2) + 1 + strlen(cli_challenge) + 1); sprintf(tmp, "$NETLMv2$%s$%s$%s$%s", identity, srv_challenge, nethashv2, cli_challenge); MEM_FREE(identity); if (valid(tmp, self)) { char *cp = str_alloc_copy(tmp); MEM_FREE(tmp); return cp; } MEM_FREE(tmp); return split_fields[1]; } static char *split(char *ciphertext, int index, struct fmt_main *self) { static char out[TOTAL_LENGTH + 1]; char *pos = NULL; int identity_length = 0; /* Calculate identity length */ for (pos = ciphertext + 9; *pos != '$'; pos++); identity_length = pos - (ciphertext + 9); memset(out, 0, TOTAL_LENGTH + 1); memcpy(out, ciphertext, strlen(ciphertext)); strlwr(&out[10 + identity_length]); /* Exclude: $NETLMv2$USERDOMAIN$ */ return out; } static void *get_binary(char *ciphertext) { static uchar *binary; char *pos = NULL; int i, identity_length; if (!binary) binary = mem_alloc_tiny(BINARY_SIZE, MEM_ALIGN_WORD); for (pos = ciphertext + 9; *pos != '$'; pos++); identity_length = pos - (ciphertext + 9); ciphertext += 9 + identity_length + 1 + CHALLENGE_LENGTH / 2 + 1; for (i=0; i<BINARY_SIZE; i++) { binary[i] = (atoi16[ARCH_INDEX(ciphertext[i*2])])<<4; binary[i] |= (atoi16[ARCH_INDEX(ciphertext[i*2+1])]); } return binary; } /* Calculate the LMv2 response for the given challenge, using the specified authentication identity (username and domain), password and client nonce. */ static int crypt_all(int *pcount, struct db_salt *salt) { const int count = *pcount; int i = 0; #ifdef _OPENMP #pragma omp parallel for for(i = 0; i < count; i++) #endif { unsigned char ntlm_v2_hash[16]; HMACMD5Context ctx; // can't be moved above the OMP pragma if (!keys_prepared) { int len; unsigned char ntlm[16]; /* Generate 16-byte NTLM hash */ len = E_md4hash(saved_plain[i], saved_len[i], ntlm); // We do key setup of the next HMAC_MD5 here (once per salt) hmac_md5_init_K16(ntlm, &saved_ctx[i]); if (len <= 0) saved_plain[i][-len] = 0; // match truncation } /* HMAC-MD5(Username + Domain, NTLM Hash) */ memcpy(&ctx, &saved_ctx[i], sizeof(ctx)); hmac_md5_update(&challenge[17], (int)challenge[16], &ctx); hmac_md5_final(ntlm_v2_hash, &ctx); /* Generate 16-byte non-client nonce portion of LMv2 Response */ /* HMAC-MD5(Challenge + Nonce, NTLMv2 Hash) + Nonce */ hmac_md5(ntlm_v2_hash, challenge, 16, (unsigned char*)output[i]); } keys_prepared = 1; return count; } static int cmp_all(void *binary, int count) { int index; for(index=0; index<count; index++) if (!memcmp(output[index], binary, BINARY_SIZE)) return 1; return 0; } static int cmp_one(void *binary, int index) { return !memcmp(output[index], binary, BINARY_SIZE); } static int cmp_exact(char *source, int index) { return !memcmp(output[index], get_binary(source), BINARY_SIZE); } /* We're essentially using three salts, but we're going to pack it into a single blob for now. |Client Challenge (8 Bytes)|Server Challenge (8 Bytes)|Unicode(Username (<=20).Domain (<=15)) */ static void *get_salt(char *ciphertext) { static unsigned char *binary_salt; unsigned char identity[USERNAME_LENGTH + DOMAIN_LENGTH + 1]; UTF16 identity_ucs2[USERNAME_LENGTH + DOMAIN_LENGTH + 1]; int i, identity_length; int identity_ucs2_length; char *pos = NULL; if (!binary_salt) binary_salt = mem_alloc_tiny(SALT_SIZE, MEM_ALIGN_WORD); memset(binary_salt, 0, SALT_SIZE); /* Calculate identity length */ for (pos = ciphertext + 9; *pos != '$'; pos++); identity_length = pos - (ciphertext + 9); /* Convert identity (username + domain) string to NT unicode */ strnzcpy((char *)identity, ciphertext + 9, sizeof(identity)); identity_ucs2_length = enc_to_utf16((UTF16 *)identity_ucs2, USERNAME_LENGTH + DOMAIN_LENGTH, (UTF8 *)identity, identity_length) * sizeof(int16_t); if (identity_ucs2_length < 0) // Truncated at Unicode conversion. identity_ucs2_length = strlen16((UTF16 *)identity_ucs2) * sizeof(int16_t); binary_salt[16] = (unsigned char)identity_ucs2_length; memcpy(&binary_salt[17], (char *)identity_ucs2, identity_ucs2_length); /* Set server challenge */ ciphertext += 10 + identity_length; for (i = 0; i < 8; i++) binary_salt[i] = (atoi16[ARCH_INDEX(ciphertext[i*2])] << 4) + atoi16[ARCH_INDEX(ciphertext[i*2+1])]; /* Set client challenge */ ciphertext += 2 + CHALLENGE_LENGTH / 2 + CIPHERTEXT_LENGTH; for (i = 0; i < 8; ++i) binary_salt[i + 8] = (atoi16[ARCH_INDEX(ciphertext[i*2])] << 4) + atoi16[ARCH_INDEX(ciphertext[i*2+1])]; /* Return a concatenation of the server and client challenges and the identity value */ return (void*)binary_salt; } static void set_salt(void *salt) { challenge = salt; } static void set_key(char *key, int index) { saved_len[index] = strlen(key); memcpy((char *)saved_plain[index], key, saved_len[index] + 1); keys_prepared = 0; } static char *get_key(int index) { return (char *)saved_plain[index]; } static int salt_hash(void *salt) { // Hash the client challenge (in case server salt was spoofed) return (*(ARCH_WORD_32 *)salt+8) & (SALT_HASH_SIZE - 1); } static int get_hash_0(int index) { return *(ARCH_WORD_32 *)output[index] & PH_MASK_0; } static int get_hash_1(int index) { return *(ARCH_WORD_32 *)output[index] & PH_MASK_1; } static int get_hash_2(int index) { return *(ARCH_WORD_32 *)output[index] & PH_MASK_2; } static int get_hash_3(int index) { return *(ARCH_WORD_32 *)output[index] & PH_MASK_3; } static int get_hash_4(int index) { return *(ARCH_WORD_32 *)output[index] & PH_MASK_4; } static int get_hash_5(int index) { return *(ARCH_WORD_32 *)output[index] & PH_MASK_5; } static int get_hash_6(int index) { return *(ARCH_WORD_32 *)output[index] & PH_MASK_6; } struct fmt_main fmt_NETLMv2 = { { FORMAT_LABEL, FORMAT_NAME, ALGORITHM_NAME, BENCHMARK_COMMENT, BENCHMARK_LENGTH, 0, PLAINTEXT_LENGTH, BINARY_SIZE, BINARY_ALIGN, SALT_SIZE, SALT_ALIGN, MIN_KEYS_PER_CRYPT, MAX_KEYS_PER_CRYPT, FMT_CASE | FMT_8_BIT | FMT_SPLIT_UNIFIES_CASE | FMT_OMP | FMT_UNICODE | FMT_UTF8, { NULL }, tests }, { init, done, fmt_default_reset, prepare, valid, split, get_binary, get_salt, { NULL }, fmt_default_source, { fmt_default_binary_hash_0, fmt_default_binary_hash_1, fmt_default_binary_hash_2, fmt_default_binary_hash_3, fmt_default_binary_hash_4, fmt_default_binary_hash_5, fmt_default_binary_hash_6 }, salt_hash, NULL, set_salt, set_key, get_key, fmt_default_clear_keys, crypt_all, { get_hash_0, get_hash_1, get_hash_2, get_hash_3, get_hash_4, get_hash_5, get_hash_6 }, cmp_all, cmp_one, cmp_exact } }; #endif /* plugin stanza */

rawMD5flat_fmt_plug.c

/* * Raw-MD5 "flat intrinsics" experimental format * * This software is Copyright (c) 2011-2015 magnum, * and it is hereby released to the general public under the following terms: * Redistribution and use in source and binary forms, with or without * modification, are permitted. * */ #include "arch.h" #if USE_EXPERIMENTAL #if FMT_EXTERNS_H extern struct fmt_main fmt_rawMD5f; #elif FMT_REGISTERS_H john_register_one(&fmt_rawMD5f); #else #include <string.h> #include "md5.h" #include "common.h" #include "formats.h" #if !FAST_FORMATS_OMP #undef _OPENMP #endif #ifdef _OPENMP #ifdef SIMD_COEF_32 #ifndef OMP_SCALE #define OMP_SCALE 1024 #endif #else #ifndef OMP_SCALE #define OMP_SCALE 2048 #endif #endif #include <omp.h> #endif #include "simd-intrinsics.h" #include "memdbg.h" #ifdef SIMD_COEF_32 #define NBKEYS (SIMD_COEF_32 * SIMD_PARA_MD5) #define PLAINTEXT_LENGTH 55 #define MIN_KEYS_PER_CRYPT NBKEYS #define MAX_KEYS_PER_CRYPT NBKEYS #else #define PLAINTEXT_LENGTH 125 #define MIN_KEYS_PER_CRYPT 1 #define MAX_KEYS_PER_CRYPT 1 #endif #define FORMAT_LABEL "Raw-MD5-flat" #define FORMAT_NAME "" #define ALGORITHM_NAME "MD5 " MD5_ALGORITHM_NAME " (experimental)" #define BENCHMARK_COMMENT "" #define BENCHMARK_LENGTH -1 #define CIPHERTEXT_LENGTH 32 #define DIGEST_SIZE 16 #define BINARY_SIZE 16 // source() #define BINARY_ALIGN 4 #define SALT_SIZE 0 #define SALT_ALIGN 1 #define FORMAT_TAG "$dynamic_0$" #define TAG_LENGTH (sizeof(FORMAT_TAG) - 1) static struct fmt_tests tests[] = { {"5a105e8b9d40e1329780d62ea2265d8a", "test1"}, {FORMAT_TAG "5a105e8b9d40e1329780d62ea2265d8a", "test1"}, {"098f6bcd4621d373cade4e832627b4f6", "test"}, {FORMAT_TAG "378e2c4a07968da2eca692320136433d", "thatsworking"}, {FORMAT_TAG "8ad8757baa8564dc136c1e07507f4a98", "test3"}, {"d41d8cd98f00b204e9800998ecf8427e", ""}, #ifdef DEBUG #if PLAINTEXT_LENGTH >= 55 {FORMAT_TAG "c9ccf168914a1bcfc3229f1948e67da0","1234567890123456789012345678901234567890123456789012345"}, #if PLAINTEXT_LENGTH >= 80 {FORMAT_TAG "57edf4a22be3c955ac49da2e2107b67a","12345678901234567890123456789012345678901234567890123456789012345678901234567890"}, #endif // 80 #endif // 55 #endif // DEBUG {NULL} }; #ifdef SIMD_COEF_32 static ARCH_WORD_32 (*crypt_key)[DIGEST_SIZE/4*NBKEYS]; static ARCH_WORD_32 (*saved_key)[64/4]; static int sz; #else static char (*saved_key)[PLAINTEXT_LENGTH + 1]; static ARCH_WORD_32 (*crypt_key)[DIGEST_SIZE/4]; #endif static void init(struct fmt_main *self) { #ifdef _OPENMP int omp_t = omp_get_max_threads(); self->params.min_keys_per_crypt *= omp_t; omp_t *= OMP_SCALE; self->params.max_keys_per_crypt *= omp_t; #endif sz = self->params.max_keys_per_crypt * 64; #ifndef SIMD_COEF_32 saved_key = mem_calloc(self->params.max_keys_per_crypt, sizeof(*saved_key)); crypt_key = mem_calloc(self->params.max_keys_per_crypt, sizeof(*crypt_key)); #else saved_key = mem_calloc_align(self->params.max_keys_per_crypt, sizeof(*saved_key), MEM_ALIGN_SIMD); crypt_key = mem_calloc_align(self->params.max_keys_per_crypt/NBKEYS, sizeof(*crypt_key), MEM_ALIGN_SIMD); #endif } static void done(void) { MEM_FREE(crypt_key); MEM_FREE(saved_key); } static int valid(char *ciphertext, struct fmt_main *self) { char *p, *q; p = ciphertext; if (!strncmp(p, FORMAT_TAG, TAG_LENGTH)) p += TAG_LENGTH; q = p; while (atoi16[ARCH_INDEX(*q)] != 0x7F) { if (*q >= 'A' && *q <= 'F') /* support lowercase only */ return 0; q++; } return !*q && q - p == CIPHERTEXT_LENGTH; } static char *split(char *ciphertext, int index, struct fmt_main *self) { static char out[TAG_LENGTH + CIPHERTEXT_LENGTH + 1]; if (!strncmp(ciphertext, FORMAT_TAG, TAG_LENGTH)) return ciphertext; memcpy(out, FORMAT_TAG, TAG_LENGTH); memcpy(out + TAG_LENGTH, ciphertext, CIPHERTEXT_LENGTH + 1); return out; } static void *get_binary(char *ciphertext) { static unsigned char *out; char *p; int i; if (!out) out = mem_alloc_tiny(DIGEST_SIZE, MEM_ALIGN_WORD); p = ciphertext + TAG_LENGTH; for (i = 0; i < DIGEST_SIZE; i++) { out[i] = (atoi16[ARCH_INDEX(*p)] << 4) | atoi16[ARCH_INDEX(p[1])]; p += 2; } return out; } #ifdef SIMD_COEF_32 #define HASH_OFFSET (index&(SIMD_COEF_32-1))+(((unsigned int)index%NBKEYS)/SIMD_COEF_32)*SIMD_COEF_32*4 static int get_hash_0(int index) { return crypt_key[index/NBKEYS][HASH_OFFSET] & PH_MASK_0; } static int get_hash_1(int index) { return crypt_key[index/NBKEYS][HASH_OFFSET] & PH_MASK_1; } static int get_hash_2(int index) { return crypt_key[index/NBKEYS][HASH_OFFSET] & PH_MASK_2; } static int get_hash_3(int index) { return crypt_key[index/NBKEYS][HASH_OFFSET] & PH_MASK_3; } static int get_hash_4(int index) { return crypt_key[index/NBKEYS][HASH_OFFSET] & PH_MASK_4; } static int get_hash_5(int index) { return crypt_key[index/NBKEYS][HASH_OFFSET] & PH_MASK_5; } static int get_hash_6(int index) { return crypt_key[index/NBKEYS][HASH_OFFSET] & PH_MASK_6; } #else static int get_hash_0(int index) { return crypt_key[index][0] & PH_MASK_0; } static int get_hash_1(int index) { return crypt_key[index][0] & PH_MASK_1; } static int get_hash_2(int index) { return crypt_key[index][0] & PH_MASK_2; } static int get_hash_3(int index) { return crypt_key[index][0] & PH_MASK_3; } static int get_hash_4(int index) { return crypt_key[index][0] & PH_MASK_4; } static int get_hash_5(int index) { return crypt_key[index][0] & PH_MASK_5; } static int get_hash_6(int index) { return crypt_key[index][0] & PH_MASK_6; } #endif static void set_key(char *key, int index) { #ifdef SIMD_COEF_32 int len = strlen(key); strncpy((char*)saved_key[index], key, sizeof(saved_key[0])); ((unsigned char*)saved_key[index])[len] = 0x80; saved_key[index][14] = len << 3; #else strcpy(saved_key[index], key); #endif } static char *get_key(int index) { #ifdef SIMD_COEF_32 int len = saved_key[index][14] >> 3; ((char*)saved_key[index])[len] = 0; #endif return (char*)saved_key[index]; } static int crypt_all(int *pcount, struct db_salt *salt) { const int count = *pcount; int index = 0; #ifdef _OPENMP #ifdef SIMD_COEF_32 const int inc = SIMD_COEF_32; #else const int inc = 1; #endif const int loops = (count + MAX_KEYS_PER_CRYPT - 1) / MAX_KEYS_PER_CRYPT; #pragma omp parallel for for (index = 0; index < loops; index += inc) #endif { #if SIMD_COEF_32 SIMDmd5body(saved_key[index], crypt_key[index/NBKEYS], NULL, SSEi_FLAT_IN); #else MD5_CTX ctx; MD5_Init(&ctx); MD5_Update(&ctx, saved_key[index], strlen(saved_key[index])); MD5_Final((unsigned char *)crypt_key[index], &ctx); #endif } return count; } static int cmp_all(void *binary, int count) { int index; for (index = 0; index < count; index++) #ifdef SIMD_COEF_32 if (((ARCH_WORD_32 *) binary)[0] == ((ARCH_WORD_32*)crypt_key)[(index&(SIMD_COEF_32-1)) + (unsigned int)index/SIMD_COEF_32*4*SIMD_COEF_32]) #else if ( ((ARCH_WORD_32*)binary)[0] == crypt_key[index][0] ) #endif return 1; return 0; } static int cmp_one(void *binary, int index) { #ifdef SIMD_COEF_32 int i; for (i = 0; i < BINARY_SIZE/sizeof(ARCH_WORD_32); i++) if (((ARCH_WORD_32 *) binary)[i] != ((ARCH_WORD_32*)crypt_key)[(index&(SIMD_COEF_32-1)) + (unsigned int)index/SIMD_COEF_32*4*SIMD_COEF_32+i*SIMD_COEF_32]) return 0; return 1; #else return !memcmp(binary, crypt_key[index], BINARY_SIZE); #endif } static int cmp_exact(char *source, int index) { return 1; } static char *source(char *source, void *binary) { static char Buf[CIPHERTEXT_LENGTH + TAG_LENGTH + 1]; unsigned char *cpi; char *cpo; int i; strcpy(Buf, FORMAT_TAG); cpo = &Buf[TAG_LENGTH]; cpi = (unsigned char*)(binary); for (i = 0; i < BINARY_SIZE; ++i) { *cpo++ = itoa16[(*cpi)>>4]; *cpo++ = itoa16[*cpi&0xF]; ++cpi; } *cpo = 0; return Buf; } struct fmt_main fmt_rawMD5f = { { FORMAT_LABEL, FORMAT_NAME, ALGORITHM_NAME, BENCHMARK_COMMENT, BENCHMARK_LENGTH, 0, PLAINTEXT_LENGTH, BINARY_SIZE, BINARY_ALIGN, SALT_SIZE, SALT_ALIGN, MIN_KEYS_PER_CRYPT, MAX_KEYS_PER_CRYPT, #ifdef _OPENMP FMT_OMP | FMT_OMP_BAD | #endif FMT_CASE | FMT_8_BIT, { NULL }, tests }, { init, done, fmt_default_reset, fmt_default_prepare, valid, split, get_binary, fmt_default_salt, { NULL }, source, { fmt_default_binary_hash_0, fmt_default_binary_hash_1, fmt_default_binary_hash_2, fmt_default_binary_hash_3, fmt_default_binary_hash_4, fmt_default_binary_hash_5, fmt_default_binary_hash_6 }, fmt_default_salt_hash, NULL, fmt_default_set_salt, set_key, get_key, fmt_default_clear_keys, crypt_all, { get_hash_0, get_hash_1, get_hash_2, get_hash_3, get_hash_4, get_hash_5, get_hash_6 }, cmp_all, cmp_one, cmp_exact } }; #endif /* plugin stanza */ #endif /* USE_EXPERIMENTAL */

mero-ummap-bandwidth-mpi.c

//mpicc ioc-ummap-bandwidth-mpi.c -I$HOME/test-rdma/usr2/include -lioc-client -lummap-io -L$HOME/test-rdma/usr2/lib -Wl,-rpath,$HOME/test-rdma/usr2/lib -o ioc-ummap-bandwidth-mpi #include <stdlib.h> #include <stdio.h> #include <string.h> #include <stdbool.h> #include <ioc-client.h> #include <time.h> #include <mpi.h> #include <ummap/ummap.h> #include <omp.h> const size_t total_size = 1UL*1024UL*1024UL*1024UL; const size_t ref_repeat = 10; static inline double timespec_diff(struct timespec *a, struct timespec *b) { struct timespec result; result.tv_sec = a->tv_sec - b->tv_sec; result.tv_nsec = a->tv_nsec - b->tv_nsec; if (result.tv_nsec < 0) { --result.tv_sec; result.tv_nsec += 1000000000L; } return (double)result.tv_sec + (double)result.tv_nsec / (double)1e9; } void make_ummap_read(ioc_client_t * client, char * buffer0, size_t size, size_t seg_size, size_t repeat) { //get MPI rank int rank; MPI_Comm_rank(MPI_COMM_WORLD, &rank); size_t threads = omp_get_max_threads(); //calc base size_t base = rank * size; //ummap //ummap_driver_t * driver = ummap_driver_create_ioc(client, 10, 20, rank == 0); ummap_driver_t * driver = ummap_driver_create_uri("clovis://10:20"); ummap_policy_t * policy = ummap_policy_create_fifo(2 * threads * seg_size, true); int flags = 0; if (seg_size <= 131072) flags |= UMMAP_THREAD_UNSAFE; char * buffer = ummap(NULL, size, seg_size, base, PROT_READ|PROT_WRITE, flags, driver, policy, NULL); //access size_t r; size_t offset; size_t sum = 0; for (r = 0 ; r < repeat ; r++) { #pragma omp parallel for for (offset = 0 ; offset < size ; offset +=seg_size) sum+=buffer[offset]; } //unmap umunmap(buffer, false); } void make_ummap_write(ioc_client_t * client, char * buffer0, size_t size, size_t seg_size, size_t repeat) { //get MPI rank int rank; MPI_Comm_rank(MPI_COMM_WORLD, &rank); size_t threads = omp_get_max_threads(); //calc base size_t base = rank * size; //ummap //ummap_driver_t * driver = ummap_driver_create_ioc(client, 10, 20, rank == 0); ummap_driver_t * driver = ummap_driver_create_uri("clovis://10:20"); ummap_policy_t * policy = ummap_policy_create_fifo(2 * threads * seg_size, true); int flags = 0; if (seg_size <= 131072) flags |= UMMAP_THREAD_UNSAFE; char * buffer = ummap(NULL, size, seg_size, base, PROT_READ|PROT_WRITE, UMMAP_NO_FIRST_READ|flags, driver, policy, NULL); //access size_t r; size_t offset; for (r = 0 ; r < repeat ; r++) { ummap_skip_first_read(buffer); #pragma omp parallel for for (offset = 0 ; offset < size ; offset += seg_size) buffer[offset]++; } //unmap umunmap(buffer, false); } void make_write(ioc_client_t * client, char * buffer, size_t size, size_t seg_size, size_t repeat) { //get MPI rank int rank; MPI_Comm_rank(MPI_COMM_WORLD, &rank); //do size_t r; size_t offset; size_t base = rank * size; for (r = 0 ; r < repeat ; r++) for (offset = 0 ; offset < size ; offset += seg_size) ioc_client_obj_write(client, 10, 20, buffer, seg_size, base + offset); } void make_read(ioc_client_t * client, char * buffer, size_t size, size_t seg_size, size_t repeat) { //get MPI rank int rank; MPI_Comm_rank(MPI_COMM_WORLD, &rank); //do size_t r; size_t offset; size_t base = rank * size; for (r = 0 ; r < repeat ; r++) for (offset = 0 ; offset < size ; offset += seg_size) ioc_client_obj_read(client, 10, 20, buffer, seg_size, base + offset); } double calc_bandwidth(ioc_client_t * client, char * buffer, size_t size, size_t seg_size, size_t repeat, void(*op)(ioc_client_t * client, char * buffer, size_t size, size_t seg_size, size_t repeat)) { //wait all MPI_Barrier(MPI_COMM_WORLD); //start struct timespec start, stop; clock_gettime(CLOCK_MONOTONIC, &start); //call to all op(client, buffer, size, seg_size, repeat); //wait all MPI_Barrier(MPI_COMM_WORLD); //stop clock_gettime(CLOCK_MONOTONIC, &stop); //compute time double t = timespec_diff(&stop, &start); //calc bandwidth double bw = (double)repeat * (double)total_size / 1024.0 / 1024.0 / 1024.0 / t; //ok return return bw; } int main(int argc, char ** argv) { //check args if (argc < 2) { fprintf(stderr, "%s {ioc_server_ip}\n", argv[0]); return EXIT_FAILURE; } //init MPI MPI_Init(&argc, &argv); //init ummapio ummap_init(); //get MPI infos int rank; int world; MPI_Comm_rank(MPI_COMM_WORLD, &rank); MPI_Comm_size(MPI_COMM_WORLD, &world); ummap_config_clovis_init_options("mero_ressource_file.rc", rank); //connect to server //ioc_client_t * client = ioc_client_init(argv[1], "8556"); ioc_client_t * client = NULL; //cal size size_t size = total_size / world; //allocate buffer char * buffer = malloc(size); memset(buffer, 0, size); //to ensure object is created, make a first round trip //calc_bandwidth(client, buffer, size, 8*1024*1024, ref_repeat, make_read); //calc_bandwidth(client, buffer, size, 8*1024*1024, ref_repeat, make_write); calc_bandwidth(client, buffer, size, 8*1024*1024, ref_repeat, make_ummap_read); calc_bandwidth(client, buffer, size, 8*1024*1024, ref_repeat, make_ummap_write); //header if (rank == 0) { printf("#total_size=%f GB\n", (double)total_size/1024.0/1024.0/1024.0); printf("#world_size=%d\n", world); printf("#seg_size (bytes) read (GB/s) twrite(GB/s)\n"); } //loop on all size size_t seg_size = 8 * 1024 * 1024; for ( ; seg_size >= 4096 ; seg_size /= 2) { //calc repeat size_t repeat = ref_repeat; //if (seg_size > 256*1024) // repeat *= 2; //measure read //double read_bw = calc_bandwidth(client, buffer, size, seg_size, repeat, make_read); //double write_bw = calc_bandwidth(client, buffer, size, seg_size, repeat, make_write); double read_bw = calc_bandwidth(client, buffer, size, seg_size, repeat, make_ummap_read); double write_bw = calc_bandwidth(client, buffer, size, seg_size, repeat, make_ummap_write); //print if (rank == 0) printf("%zu %f %f\n", seg_size, read_bw, write_bw); } //close connection //ioc_client_fini(client); //fini ummap ummap_finalize(); //fin i mpi MPI_Finalize(); //ok return EXIT_SUCCESS; }

ComputeNonbondedBase2.h

/** *** Copyright (c) 1995, 1996, 1997, 1998, 1999, 2000 by *** The Board of Trustees of the University of Illinois. *** All rights reserved. **/ EXCLUDED( FAST( foo bar ) ) EXCLUDED( MODIFIED( foo bar ) ) EXCLUDED( NORMAL( foo bar ) ) NORMAL( MODIFIED( foo bar ) ) ALCHPAIR( NOT_ALCHPAIR( foo bar ) ) ALCHPAIR( // get alchemical nonbonded scaling parameters (once per pairlist) myLambda = ALCH1(lambdaUp) ALCH2(lambdaDown) ALCH3(lambdaUp) ALCH4(lambdaDown); FEP(myLambda2 = ALCH1(lambda2Up) ALCH2(lambda2Down) ALCH3(lambda2Up) ALCH4(lambda2Down);) myElecLambda = ALCH1(elecLambdaUp) ALCH2(elecLambdaDown) ALCH3(elecLambdaUp) ALCH4(elecLambdaDown); FEP(myElecLambda2 = ALCH1(elecLambda2Up) ALCH2(elecLambda2Down) ALCH3(elecLambda2Up) ALCH4(elecLambda2Down);) myVdwLambda = ALCH1(vdwLambdaUp) ALCH2(vdwLambdaDown) ALCH3(vdwLambdaUp) ALCH4(vdwLambdaDown); FEP(myVdwLambda2 = ALCH1(vdwLambda2Up) ALCH2(vdwLambda2Down) ALCH3(vdwLambda2Up) ALCH4(vdwLambda2Down);) ALCH1(myRepLambda = repLambdaUp) ALCH2(myRepLambda = repLambdaDown); FEP(ALCH1(myRepLambda2 = repLambda2Up) ALCH2(myRepLambda2 = repLambda2Down);) ALCH1(myVdwShift = vdwShiftUp) ALCH2(myVdwShift = vdwShiftDown); FEP(ALCH1(myVdwShift2 = vdwShift2Up) ALCH2(myVdwShift2 = vdwShift2Down);) ) #ifdef A2_QPX #if ( SHORT(1+) 0 ) NORMAL(kq_iv = vec_splats(kq_i); ) MODIFIED(kq_iv = vec_splats((1.0-modf_mod) *kq_i); ) #endif #if ( FULL( 1+ ) 0 ) EXCLUDED( SHORT( full_cnst = (vector4double)(6., 4., 2., 1.); ) NOSHORT( full_cnst = (vector4double)(1., 1., 1., 1.); ) ) MODIFIED( SHORT( full_cnst = (vector4double)(6., 4., 2., 1.); full_cnst = vec_mul (full_cnst, vec_splats(modf_mod)); ) NOSHORT( full_cnst = vec_splats(modf_mod); ) ) #endif #endif #ifdef ARCH_POWERPC __alignx(64, table_four); __alignx(32, p_1); #pragma unroll(1) #pragma ibm independent_loop #endif #ifndef ARCH_POWERPC #pragma ivdep #endif #if ( FULL( EXCLUDED( SHORT( 1+ ) ) ) 0 ) // avoid bug in Intel 15.0 compiler #pragma novector #else #ifdef PRAGMA_SIMD #ifndef TABENERGYFLAG #ifndef GOFORCES #pragma omp simd SHORT(FAST(reduction(+:f_i_x,f_i_y,f_i_z)) ENERGY(FAST(reduction(+:vdwEnergy) SHORT(reduction(+:electEnergy))))) \ FULL(reduction(+:fullf_i_x,fullf_i_y,fullf_i_z) ENERGY(reduction(+:fullElectEnergy))) #endif #endif #pragma loop_count avg=100 #else // PRAGMA_SIMD #pragma loop_count avg=4 #endif // PRAGMA_SIMD #endif for (k=0; k<npairi; ++k) { TABENERGY( const int numtypes = simParams->tableNumTypes; const float table_spacing = simParams->tableSpacing; const int npertype = (int) (namdnearbyint(simParams->tableMaxDist / simParams->tableSpacing) + 1); ) int table_i = (r2iilist[2*k] >> 14) + r2_delta_expc; // table_i >= 0 const int j = pairlisti[k]; //register const CompAtom *p_j = p_1 + j; #define p_j (p_1+j) #ifdef A2_QPX register double *p_j_d = (double *) p_j; #endif // const CompAtomExt *pExt_j = pExt_1 + j; BigReal diffa = r2list[k] - r2_table[table_i]; //const BigReal* const table_four_i = table_four + 16*table_i; #define table_four_i (table_four + 16*table_i) #if ( FAST( 1 + ) TABENERGY( 1 + ) 0 ) // FAST or TABENERGY //const LJTable::TableEntry * lj_pars = // lj_row + 2 * p_j->vdwType MODIFIED(+ 1); const int lj_index = 2 * p_j->vdwType MODIFIED(+ 1); #define lj_pars (lj_row+lj_index) #ifdef A2_QPX double *lj_pars_d = (double *) lj_pars; #endif #endif TABENERGY( register const int tabtype = -1 - ( lj_pars->A < 0 ? lj_pars->A : 0 ); ) #if ( SHORT( FAST( 1+ ) ) 0 ) //Force *f_j = f_1 + j; #define f_j (f_1+j) #endif #if ( FULL( 1+ ) 0 ) //Force *fullf_j = fullf_1 + j; #define fullf_j (fullf_1+j) #endif //Power PC aliasing and alignment constraints #ifdef ARCH_POWERPC #if ( FULL( 1+ ) 0 ) #pragma disjoint (*table_four, *fullf_1) #pragma disjoint (*p_1, *fullf_1) #ifdef A2_QPX #pragma disjoint (*p_j_d, *fullf_1) #endif #pragma disjoint (*r2_table, *fullf_1) #pragma disjoint (*r2list, *fullf_1) #if ( SHORT( FAST( 1+ ) ) 0 ) #pragma disjoint (*f_1 , *fullf_1) #pragma disjoint (*fullf_1, *f_1) #endif //Short + fast #endif //Full #if ( SHORT( FAST( 1+ ) ) 0 ) #pragma disjoint (*table_four, *f_1) #pragma disjoint (*p_1, *f_1) #pragma disjoint (*r2_table, *f_1) #pragma disjoint (*r2list, *f_1) #pragma disjoint (*lj_row, *f_1) #ifdef A2_QPX #pragma disjoint (*p_j_d, *f_1) #endif #endif //Short + Fast __alignx(64, table_four_i); FAST ( __alignx(32, lj_pars); ) __alignx(32, p_j); #endif //ARCH_POWERPC /* BigReal modf = 0.0; int atom2 = p_j->id; register char excl_flag = ( (atom2 >= excl_min && atom2 <= excl_max) ? excl_flags[atom2-excl_min] : 0 ); if ( excl_flag ) { ++exclChecksum; } SELF( if ( j < j_hgroup ) { excl_flag = EXCHCK_FULL; } ) if ( excl_flag ) { if ( excl_flag == EXCHCK_FULL ) { lj_pars = lj_null_pars; modf = 1.0; } else { ++lj_pars; modf = modf_mod; } } */ BigReal kqq = kq_i * p_j->charge; #ifdef A2_QPX float * cg = (float *)&p_j->charge; #if ( FULL( 1+ ) 0 ) #pragma disjoint (*cg, *fullf_1) #endif //Full #if ( SHORT( FAST( 1+ ) ) 0 ) #pragma disjoint (*cg, *f_1) #endif //Short + fast #endif LES( BigReal lambda_pair = lambda_table_i[p_j->partition]; ) #ifndef A2_QPX register const BigReal p_ij_x = p_i_x - p_j->position.x; register const BigReal p_ij_y = p_i_y - p_j->position.y; register const BigReal p_ij_z = p_i_z - p_j->position.z; #else vector4double charge_v = vec_lds(0, cg); vector4double kqqv = vec_mul(kq_iv, charge_v ); vector4double p_ij_v = vec_sub(p_i_v, vec_ld (0, p_j_d)); #define p_ij_x vec_extract(p_i_v, 0) #define p_ij_y vec_extract(p_i_v, 1) #define p_ij_z vec_extract(p_i_v, 2) #endif #if ( FAST(1+) 0 ) const BigReal A = scaling * lj_pars->A; const BigReal B = scaling * lj_pars->B; #ifndef A2_QPX BigReal vdw_d = A * table_four_i[0] - B * table_four_i[4]; BigReal vdw_c = A * table_four_i[1] - B * table_four_i[5]; BigReal vdw_b = A * table_four_i[2] - B * table_four_i[6]; BigReal vdw_a = A * table_four_i[3] - B * table_four_i[7]; #else const vector4double Av = vec_mul(scalingv, vec_lds(0, lj_pars_d)); const vector4double Bv = vec_mul(scalingv, vec_lds(8, lj_pars_d)); vector4double vdw_v = vec_msub( Av, vec_ld(0, (BigReal*)table_four_i), vec_mul(Bv, vec_ld(4*sizeof(BigReal), (BigReal*)table_four_i)) ); #define vdw_d vec_extract(vdw_v, 0) #define vdw_c vec_extract(vdw_v, 1) #define vdw_b vec_extract(vdw_v, 2) #define vdw_a vec_extract(vdw_v, 3) #endif ALCHPAIR ( // Alchemical free energy calculation // Pairlist 1 and 2 are for softcore atoms, while 3 and 4 are single topology atoms. // Pairlists are separated so that lambda-coupled pairs are handled // independently from normal nonbonded (inside ALCHPAIR macro). // The separation-shifted van der Waals potential and a shifted // electrostatics potential for decoupling are calculated explicitly. // Would be faster with lookup tables but because only a small minority // of nonbonded pairs are lambda-coupled the impact is minimal. // Explicit calculation also makes things easier to modify. // These are now inline functions (in ComputeNonbondedFep.C) to // tidy the code const BigReal r2 = r2list[k] - r2_delta; // These are now inline functions (in ComputeNonbondedFep.C) to // tidy the code FEP( ALCH1 ( // Don't merge/recombine the ALCH 1, 2, 3 ,4. Their functions might be modified for future algorithm changes. fep_vdw_forceandenergies(A, B, r2, myVdwShift, myVdwShift2, switchdist2, cutoff2, switchfactor, vdwForceSwitching, myVdwLambda, myVdwLambda2, alchWCAOn, myRepLambda, myRepLambda2, &alch_vdw_energy, &alch_vdw_force, &alch_vdw_energy_2);) ALCH2 ( fep_vdw_forceandenergies(A, B, r2, myVdwShift, myVdwShift2, switchdist2, cutoff2, switchfactor, vdwForceSwitching, myVdwLambda, myVdwLambda2, alchWCAOn, myRepLambda, myRepLambda2, &alch_vdw_energy, &alch_vdw_force, &alch_vdw_energy_2);) ALCH3 ( // In single topology region ALCH3 & 4, all atoms are paired so softcore potential is unnecessary. ENERGY(alch_vdw_energy = -myVdwLambda * (( ( diffa * vdw_d * (1/6.)+ vdw_c * (1/4.)) * diffa + vdw_b *(1/2.)) * diffa + vdw_a);) alch_vdw_energy_2 = -myVdwLambda2 * (( ( diffa * vdw_d * (1/6.)+ vdw_c * (1/4.)) * diffa + vdw_b *(1/2.)) * diffa + vdw_a); alch_vdw_force = myVdwLambda * ((diffa * vdw_d + vdw_c) * diffa + vdw_b);) ALCH4 ( ENERGY(alch_vdw_energy = -myVdwLambda * (( ( diffa * vdw_d * (1/6.)+ vdw_c * (1/4.)) * diffa + vdw_b *(1/2.)) * diffa + vdw_a);) alch_vdw_energy_2 = -myVdwLambda2 * (( ( diffa * vdw_d * (1/6.)+ vdw_c * (1/4.)) * diffa + vdw_b *(1/2.)) * diffa + vdw_a); alch_vdw_force = myVdwLambda * ((diffa * vdw_d + vdw_c) * diffa + vdw_b);) ) TI(ti_vdw_force_energy_dUdl(A, B, r2, myVdwShift, switchdist2, cutoff2, switchfactor, vdwForceSwitching, myVdwLambda, alchVdwShiftCoeff, alchWCAOn, myRepLambda, &alch_vdw_energy, &alch_vdw_force, &alch_vdw_dUdl);) ) //NOT_ALCHPAIR( //TABENERGY( #if (NOT_ALCHPAIR(1+) 0) #if (TABENERGY(1+) 0) if (tabtype >= 0) { register BigReal r1; r1 = sqrt(p_ij_x*p_ij_x + p_ij_y*p_ij_y + p_ij_z*p_ij_z); //CkPrintf("%i %i %f %f %i\n", npertype, tabtype, r1, table_spacing, (int) (namdnearbyint(r1 / table_spacing))); register int eneraddress; eneraddress = 2 * ((npertype * tabtype) + ((int) namdnearbyint(r1 / table_spacing))); //CkPrintf("Using distance bin %i for distance %f\n", eneraddress, r1); #ifndef A2_QPX vdw_d = 0.; vdw_c = 0.; vdw_b = table_ener[eneraddress + 1] / r1; vdw_a = (-1/2.) * diffa * vdw_b; #else vec_insert(0., vdw_v, 0); vec_insert(0., vdw_v, 1); vec_insert(table_ener[eneraddress + 1] / r1, vdw_v, 2); vec_insert((-1/2.) * diffa * vdw_b, vdw_v, 3); #endif ENERGY( register BigReal vdw_val = table_ener[eneraddress]; //CkPrintf("Found vdw energy of %f\n", vdw_val); vdwEnergy += LAM(lambda_pair *) vdw_val; FEP( vdwEnergy_s += d_lambda_pair * vdw_val; ) ) } else { //) #endif ENERGY( register BigReal vdw_val = ( ( diffa * vdw_d * (1/6.)+ vdw_c * (1/4.)) * diffa + vdw_b *(1/2.)) * diffa + vdw_a; vdwEnergy -= LAM(lambda_pair *) vdw_val; FEP(vdwEnergy_s -= vdw_val;) ) //TABENERGY( } ) /* endif (tabtype >= 0) */ #if (TABENERGY (1+) 0) } #endif //) // NOT_ALCHPAIR #endif ALCHPAIR( ENERGY(vdwEnergy += alch_vdw_energy;) FEP(vdwEnergy_s += alch_vdw_energy_2;) TI(ALCH1(vdwEnergy_ti_1 += alch_vdw_dUdl;) ALCH2(vdwEnergy_ti_2 += alch_vdw_dUdl;)) ) // ALCHPAIR #endif // FAST #if ( FAST(1+) 0 ) INT( register BigReal vdw_dir; vdw_dir = ( diffa * vdw_d + vdw_c ) * diffa + vdw_b; //BigReal force_r = LAM(lambda_pair *) vdw_dir; reduction[pairVDWForceIndex_X] += force_sign * vdw_dir * p_ij_x; reduction[pairVDWForceIndex_Y] += force_sign * vdw_dir * p_ij_y; reduction[pairVDWForceIndex_Z] += force_sign * vdw_dir * p_ij_z; ) #if ( SHORT(1+) 0 ) // Short-range electrostatics #ifndef A2_QPX NORMAL( BigReal fast_d = kqq * table_four_i[8]; BigReal fast_c = kqq * table_four_i[9]; BigReal fast_b = kqq * table_four_i[10]; BigReal fast_a = kqq * table_four_i[11]; ) MODIFIED( BigReal modfckqq = (1.0-modf_mod) * kqq; BigReal fast_d = modfckqq * table_four_i[8]; BigReal fast_c = modfckqq * table_four_i[9]; BigReal fast_b = modfckqq * table_four_i[10]; BigReal fast_a = modfckqq * table_four_i[11]; ) #else vector4double fastv = vec_mul(kqqv, vec_ld(8 * sizeof(BigReal), (BigReal*)table_four_i)); #define fast_d vec_extract(fastv, 0) #define fast_c vec_extract(fastv, 1) #define fast_b vec_extract(fastv, 2) #define fast_a vec_extract(fastv, 3) #endif { ENERGY( register BigReal fast_val = ( ( diffa * fast_d * (1/6.)+ fast_c * (1/4.)) * diffa + fast_b *(1/2.)) * diffa + fast_a; NOT_ALCHPAIR ( electEnergy -= LAM(lambda_pair *) fast_val; FEP(electEnergy_s -= fast_val;) ) ) //ENERGY ALCHPAIR( ENERGY(electEnergy -= myElecLambda * fast_val;) FEP(electEnergy_s -= myElecLambda2 * fast_val;) TI( NOENERGY(register BigReal fast_val = ( ( diffa * fast_d * (1/6.)+ fast_c * (1/4.)) * diffa + fast_b *(1/2.)) * diffa + fast_a;) ALCH1(electEnergy_ti_1 -= fast_val;) ALCH2(electEnergy_ti_2 -= fast_val;) ) ) INT( register BigReal fast_dir = ( diffa * fast_d + fast_c ) * diffa + fast_b; // force_r -= -1.0 * LAM(lambda_pair *) fast_dir; reduction[pairElectForceIndex_X] += force_sign * fast_dir * p_ij_x; reduction[pairElectForceIndex_Y] += force_sign * fast_dir * p_ij_y; reduction[pairElectForceIndex_Z] += force_sign * fast_dir * p_ij_z; ) } /***** JE - Go *****/ // Now Go energy should appear in VDW place -- put vdw_b back into place #if ( NORMAL (1+) 0) #if ( GO (1+) 0) // JLai #ifndef CODE_REDUNDANT #define CODE_REDUNDANT 0 #endif #if CODE_REDUNDANT if (ComputeNonbondedUtil::goGroPair) { // Explicit goGroPair calculation; only calculates goGroPair if goGroPair is turned on // // get_gro_force has an internal checklist that sees if atom_i and atom_j are // in the explicit pairlist. This is done because there is no guarantee that a // processor will have atom_i and atom_j so we cannot loop over the explict atom pairs. // We can only loop over all pairs. // // NOTE: It does not look like fast_b is not normalized by the r vector. // // JLai BigReal groLJe = 0.0; BigReal groGausse = 0.0; const CompAtomExt *pExt_z = pExt_1 + j; BigReal groForce = mol->get_gro_force2(p_ij_x, p_ij_y, p_ij_z,pExt_i.id,pExt_z->id,&groLJe,&groGausse); NAMD_die("Failsafe. This line should never be reached\n"); #ifndef A2_QPX fast_b += groForce; #else vec_insert(fast_b + groForce, fastv, 2); #endif ENERGY( NOT_ALCHPAIR ( // JLai groLJEnergy += groLJe; groGaussEnergy += groGausse; ) ) //ENERGY } #endif BigReal goNative = 0; BigReal goNonnative = 0; BigReal goForce = 0; register const CompAtomExt *pExt_j = pExt_1 + j; if (ComputeNonbondedUtil::goMethod == 2) { goForce = mol->get_go_force2(p_ij_x, p_ij_y, p_ij_z, pExt_i.id, pExt_j->id,&goNative,&goNonnative); } else { // Ported by JLai -- JE - added ( const BigReal r2go = square(p_ij_x, p_ij_y, p_ij_z); const BigReal rgo = sqrt(r2go); if (ComputeNonbondedUtil::goMethod == 1) { goForce = mol->get_go_force(rgo, pExt_i.id, pExt_j->id, &goNative, &goNonnative); } else if (ComputeNonbondedUtil::goMethod == 3) { goForce = mol->get_go_force_new(rgo, pExt_i.id, pExt_j->id, &goNative, &goNonnative); } else { NAMD_die("I SHOULDN'T BE HERE. DYING MELODRAMATICALLY.\n"); } } #ifndef A2_QPX fast_b += goForce; #else vec_insert(fast_b + goForce, fastv, 2); #endif { ENERGY( NOT_ALCHPAIR ( // JLai goEnergyNative += goNative; goEnergyNonnative += goNonnative; ) ) //ENERGY INT( reduction[pairVDWForceIndex_X] += force_sign * goForce * p_ij_x; reduction[pairVDWForceIndex_Y] += force_sign * goForce * p_ij_y; reduction[pairVDWForceIndex_Z] += force_sign * goForce * p_ij_z; ) } // End of INT //DebugM(3,"rgo:" << rgo << ", pExt_i.id:" << pExt_i.id << ", pExt_j->id:" << pExt_j->id << \ // ", goForce:" << goForce << ", fast_b:" << fast_b << std::endl); #endif // ) // End of GO macro /***** JE - End Go *****/ // End of port JL #endif //) // End of Normal MACRO // Combined short-range electrostatics and VdW force: #if ( NOT_ALCHPAIR(1+) 0) #ifndef A2_QPX fast_d += vdw_d; fast_c += vdw_c; fast_b += vdw_b; fast_a += vdw_a; // not used! #else fastv = vec_add(fastv, vdw_v); #endif #endif register BigReal fast_dir = (diffa * fast_d + fast_c) * diffa + fast_b; BigReal force_r = LAM(lambda_pair *) fast_dir; ALCHPAIR( force_r *= myElecLambda; force_r += alch_vdw_force; // special ALCH forces already multiplied by relevant lambda ) #ifndef NAMD_CUDA #ifndef A2_QPX register BigReal tmp_x = force_r * p_ij_x; f_i_x += tmp_x; f_j->x -= tmp_x; register BigReal tmp_y = force_r * p_ij_y; f_i_y += tmp_y; f_j->y -= tmp_y; register BigReal tmp_z = force_r * p_ij_z; f_i_z += tmp_z; f_j->z -= tmp_z; #else vector4double force_rv = vec_splats (force_r); vector4double tmp_v = vec_mul(force_rv, p_ij_v); f_i_v = vec_add(f_i_v, tmp_v); #define tmp_x vec_extract(tmp_v, 0) #define tmp_y vec_extract(tmp_v, 1) #define tmp_z vec_extract(tmp_v, 2) f_j->x -= tmp_x; f_j->y -= tmp_y; f_j->z -= tmp_z; #endif PPROF( const BigReal p_j_z = p_j->position.z; int n2 = (int)floor((p_j_z-pressureProfileMin)*invThickness); pp_clamp(n2, pressureProfileSlabs); int p_j_partition = p_j->partition; pp_reduction(pressureProfileSlabs, n1, n2, p_i_partition, p_j_partition, pressureProfileAtomTypes, tmp_x*p_ij_x, tmp_y * p_ij_y, tmp_z*p_ij_z, pressureProfileReduction); ) #endif #endif // SHORT #endif // FAST #if ( FULL (EXCLUDED( SHORT ( 1+ ) ) ) 0 ) //const BigReal* const slow_i = slow_table + 4*table_i; #define slow_i (slow_table + 4*table_i) #ifdef ARCH_POWERPC //Alignment and aliasing constraints __alignx (32, slow_table); #if ( SHORT( FAST( 1+ ) ) 0 ) #pragma disjoint (*slow_table, *f_1) #endif #pragma disjoint (*slow_table, *fullf_1) #endif //ARCH_POWERPC #endif //FULL #if ( FULL (MODIFIED( SHORT ( 1+ ) ) ) 0 ) //const BigReal* const slow_i = slow_table + 4*table_i; #define slow_i (slow_table + 4*table_i) #ifdef ARCH_POWERPC //Alignment and aliasing constraints __alignx (32, slow_table); #if ( SHORT( FAST( 1+ ) ) 0 ) #pragma disjoint (*slow_table, *f_1) #endif #pragma disjoint (*slow_table, *fullf_1) #endif //ARCH_POWERPC #endif //FULL #if ( FULL( 1+ ) 0 ) #ifndef A2_QPX BigReal slow_d = table_four_i[8 SHORT(+ 4)]; BigReal slow_c = table_four_i[9 SHORT(+ 4)]; BigReal slow_b = table_four_i[10 SHORT(+ 4)]; BigReal slow_a = table_four_i[11 SHORT(+ 4)]; EXCLUDED( SHORT( slow_a += slow_i[3]; slow_b += 2.*slow_i[2]; slow_c += 4.*slow_i[1]; slow_d += 6.*slow_i[0]; ) NOSHORT( slow_d -= table_four_i[12]; slow_c -= table_four_i[13]; slow_b -= table_four_i[14]; slow_a -= table_four_i[15]; ) ) MODIFIED( SHORT( slow_a += modf_mod * slow_i[3]; slow_b += 2.*modf_mod * slow_i[2]; slow_c += 4.*modf_mod * slow_i[1]; slow_d += 6.*modf_mod * slow_i[0]; ) NOSHORT( slow_d -= modf_mod * table_four_i[12]; slow_c -= modf_mod * table_four_i[13]; slow_b -= modf_mod * table_four_i[14]; slow_a -= modf_mod * table_four_i[15]; ) ) slow_d *= kqq; slow_c *= kqq; slow_b *= kqq; slow_a *= kqq; #else vector4double slow_v = vec_ld((8 SHORT(+ 4)) * sizeof(BigReal), (BigReal*)table_four_i); EXCLUDED( SHORT( slow_v = vec_madd(full_cnst, vec_ld(0, (BigReal*)slow_i), slow_v); ) NOSHORT( slow_v = vec_sub(slow_v, vec_ld(12*sizeof(BigReal), (BigReal*)table_four_i)); ) ); MODIFIED( SHORT( slow_v = vec_madd(full_cnst, vec_ld(0, (BigReal*)slow_i), slow_v); ) NOSHORT( slow_v = vec_nmsub(full_cnst, vec_ld(12*sizeof(BigReal), (BigReal*)table_four_i), slow_v); ) ); slow_v = vec_mul (slow_v, vec_splats(kqq)); #define slow_d vec_extract(slow_v, 0) #define slow_c vec_extract(slow_v, 1) #define slow_b vec_extract(slow_v, 2) #define slow_a vec_extract(slow_v, 3) #endif ENERGY( register BigReal slow_val = ( ( diffa * slow_d *(1/6.)+ slow_c * (1/4.)) * diffa + slow_b *(1/2.)) * diffa + slow_a; NOT_ALCHPAIR ( fullElectEnergy -= LAM(lambda_pair *) slow_val; FEP(fullElectEnergy_s -= slow_val;) ) ) // ENERGY ALCHPAIR( ENERGY(fullElectEnergy -= myElecLambda * slow_val;) FEP(fullElectEnergy_s -= myElecLambda2 * slow_val;) TI( NOENERGY(register BigReal slow_val = ( ( diffa * slow_d *(1/6.)+ slow_c * (1/4.)) * diffa + slow_b *(1/2.)) * diffa + slow_a;) ALCH1(fullElectEnergy_ti_1 -= slow_val;) ALCH2(fullElectEnergy_ti_2 -= slow_val;) ) ) INT( { register BigReal slow_dir = ( diffa * slow_d + slow_c ) * diffa + slow_b; reduction[pairElectForceIndex_X] += force_sign * slow_dir * p_ij_x; reduction[pairElectForceIndex_Y] += force_sign * slow_dir * p_ij_y; reduction[pairElectForceIndex_Z] += force_sign * slow_dir * p_ij_z; } ) #if (NOT_ALCHPAIR (1+) 0) #if (FAST(1+) 0) #if (NOSHORT(1+) 0) #ifndef A2_QPX slow_d += vdw_d; slow_c += vdw_c; slow_b += vdw_b; slow_a += vdw_a; // unused! #else slow_v = vec_add (slow_v, vdw_v); #endif #endif #endif #endif register BigReal slow_dir = (diffa * slow_d + slow_c) * diffa + slow_b; BigReal fullforce_r = slow_dir LAM(* lambda_pair); ALCHPAIR ( fullforce_r *= myElecLambda; FAST( NOSHORT( fullforce_r += alch_vdw_force; )) ) #ifndef NAMD_CUDA { #ifndef A2_QPX register BigReal ftmp_x = fullforce_r * p_ij_x; fullf_i_x += ftmp_x; fullf_j->x -= ftmp_x; register BigReal ftmp_y = fullforce_r * p_ij_y; fullf_i_y += ftmp_y; fullf_j->y -= ftmp_y; register BigReal ftmp_z = fullforce_r * p_ij_z; fullf_i_z += ftmp_z; fullf_j->z -= ftmp_z; #else vector4double fforce_rv = vec_splats (fullforce_r); vector4double ftmp_v = vec_mul(fforce_rv, p_ij_v); fullf_i_v = vec_add(fullf_i_v, ftmp_v); #define ftmp_x vec_extract(ftmp_v, 0) #define ftmp_y vec_extract(ftmp_v, 1) #define ftmp_z vec_extract(ftmp_v, 2) fullf_j->x -= ftmp_x; fullf_j->y -= ftmp_y; fullf_j->z -= ftmp_z; #endif PPROF( const BigReal p_j_z = p_j->position.z; int n2 = (int)floor((p_j_z-pressureProfileMin)*invThickness); pp_clamp(n2, pressureProfileSlabs); int p_j_partition = p_j->partition; pp_reduction(pressureProfileSlabs, n1, n2, p_i_partition, p_j_partition, pressureProfileAtomTypes, ftmp_x*p_ij_x, ftmp_y * p_ij_y, ftmp_z*p_ij_z, pressureProfileReduction); ) } #endif #endif //FULL } // for pairlist #undef p_j #undef lj_pars #undef table_four_i #undef slow_i #undef f_j #undef fullf_j

GambitReader.h

/** * @file * This file is part of PUMGen * * For conditions of distribution and use, please see the copyright * notice in the file 'COPYING' at the root directory of this package * and the copyright notice at https://github.com/SeisSol/PUMGen * * @copyright 2017 Technical University of Munich * @author Sebastian Rettenberger <sebastian.rettenberger@tum.de> */ #ifndef GAMBIT_READER_H #define GAMBIT_READER_H #include <fstream> #include <limits> #include <sstream> #include <vector> #include <map> #include "utils/stringutils.h" #include "utils/logger.h" #include "MeshReader.h" namespace puml { /** * Describes the group of an element */ struct ElementGroup { /** The element */ unsigned int element; /** The group for this element */ int group; }; /** * Describes a boundary face */ struct GambitBoundaryFace { /** The element the face belongs to */ unsigned int element; /** The face of the element */ unsigned int face; /** The type of the boundary */ int type; }; class GambitReader : public MeshReader { private: struct ElementSection : FileSection { /** Start of vertices in an element */ size_t vertexStart; /** Size per vertex id */ size_t vertexSize; }; struct GroupSection : FileSection { /** Size per element id */ size_t elementSize; /** Group number */ int group; }; struct BoundarySection : FileSection { /** Type of the boundary */ int type; /** Size per element id (only fixed line length) */ size_t elementSize; /** Size per element type (only fixed line length) */ size_t elementTypeSize; /** Size per face id (only fixed line length) */ size_t faceSize; /** Is line length variable? */ bool variableLineLength; }; // Section descriptions FileSection m_vertices; ElementSection m_elements; std::vector<GroupSection> m_groups; std::vector<BoundarySection> m_boundaries; std::map<int, int> id_map; //matches element-id in .neu file to local id, Key = id in .neu file, Value = local id public: void open(const char* meshFile) { MeshReader::open(meshFile); std::string line; // Read header information getline(m_mesh, line); // First line contains version // we ignore this line for know line.clear(); getline(m_mesh, line); utils::StringUtils::trim(line); if (line != GAMBIT_FILE_ID) logError() << "Not a Gambit mesh file:" << meshFile; std::string name; getline(m_mesh, name); // Internal name getline(m_mesh, line); // Skip line: // PROGRAM: Gambit VERSION: x.y.z getline(m_mesh, line); // Date getline(m_mesh, line); // Skip problem size names unsigned int nGroups, nBoundaries, dimensions; m_mesh >> m_vertices.nLines; m_mesh >> m_elements.nLines; m_mesh >> nGroups; m_mesh >> nBoundaries; m_mesh >> dimensions; getline(m_mesh, line); // Skip rest of the line if (dimensions != 3) logError() << "Gambit file does not contain a 3 dimensional mesh"; getline(m_mesh, line); utils::StringUtils::trim(line); if (line != ENDSECTION) logError() << "Invalid Gambit format: End of header expected, found" << line; // Find seek positions // Vertices getline(m_mesh, line); if (line.find(NODAL_COORDINATES) == std::string::npos) logError() << "Invalid Gambit format: Coordinates expected, found" << line; m_vertices.seekPosition = m_mesh.tellg(); getline(m_mesh, line); m_vertices.lineSize = line.length() + 1; m_mesh.seekg(m_vertices.seekPosition + m_vertices.nLines * m_vertices.lineSize); getline(m_mesh, line); utils::StringUtils::rtrim(line); // remove \r if (line != ENDSECTION) logError() << "Invalid Gambit format: End of coordinates expected, found" << line; // Elements getline(m_mesh, line); if (line.find(ELEMENT_CELLS) == std::string::npos) logError() << "Invalid Gambit format: Elements expected, found" << line; m_elements.seekPosition = m_mesh.tellg(); getline(m_mesh, line); m_elements.lineSize = line.length() + 1; m_mesh.seekg(m_elements.seekPosition + m_elements.nLines * m_elements.lineSize); std::istringstream ss(line); int tmp; ss >> tmp; // Element id ss >> tmp; ss >> tmp; ss.seekg(1, std::stringstream::cur); // White space m_elements.vertexStart = ss.tellg(); // TODO works only for tetrahedrals utils::StringUtils::rtrim(line); if ((line.length() - m_elements.vertexStart) % 4 != 0) logError() << "Invalid Gambit format: Mesh does not seem to contain tetrahedrals"; m_elements.vertexSize = (line.length() - m_elements.vertexStart) / 4; getline(m_mesh, line); utils::StringUtils::rtrim(line); // remove \r if (line != ENDSECTION) logError() << "Invalid Gambit format: End of elements expected, found" << line; // Groups m_groups.resize(nGroups); for (unsigned int i = 0; i < nGroups; i++) { getline(m_mesh, line); if (line.find(ELEMENT_GROUP) == std::string::npos) logError() << "Invalid Gambit format: Group expected, found" << line; getline(m_mesh, line); // Group size and material std::string y; std::istringstream ss(line); ss >> y; ss >> m_groups[i].group; ss >> y; ss >> m_groups[i].nLines; // This is not the actual number of lines // Because Gambit stores more than one element // per line. getline(m_mesh, line); getline(m_mesh, line); m_groups[i].seekPosition = m_mesh.tellg(); getline(m_mesh, line); m_groups[i].lineSize = line.size() + 1; utils::StringUtils::rtrim(line); if (line.length() % ELEMENTS_PER_LINE_GROUP != 0) logError() << "Invalid Gambit format: Mesh does not contain" << ELEMENTS_PER_LINE_GROUP << "in one group line"; m_groups[i].elementSize = line.length() / ELEMENTS_PER_LINE_GROUP; m_mesh.seekg(m_groups[i].seekPosition + (m_groups[i].nLines / ELEMENTS_PER_LINE_GROUP) * m_groups[i].lineSize); if (m_groups[i].nLines % ELEMENTS_PER_LINE_GROUP != 0) // Last line m_mesh.seekg(m_groups[i].lineSize - (ELEMENTS_PER_LINE_GROUP - m_groups[i].nLines % ELEMENTS_PER_LINE_GROUP) * m_groups[i].elementSize, std::ifstream::cur); getline(m_mesh, line); utils::StringUtils::rtrim(line); // remove \r if (line != ENDSECTION) logError() << "Invalid Gambit format: End of group expected, found" << line; } // Boundaries m_boundaries.resize(nBoundaries); for (unsigned int i = 0; i < nBoundaries; i++) { getline(m_mesh, line); if (line.find(BOUNDARY_CONDITIONS) == std::string::npos) logError() << "Invalid Gambit format: Boundaries expected, found" << line; m_boundaries[i].variableLineLength = false; getline(m_mesh, line); m_boundaries[i].seekPosition = m_mesh.tellg(); // Boundary type and size int x; std::istringstream ss(line); ss >> m_boundaries[i].type; m_boundaries[i].type %= 100; // Fix boundary type TODO not sure where this should be placed ss >> x; ss >> m_boundaries[i].nLines; // Try boundary with fixed line length getline(m_mesh, line); m_boundaries[i].lineSize = line.size() + 1; // Get element size std::istringstream ssE(line); unsigned int element, type, face; ssE >> element; m_boundaries[i].elementSize = ssE.tellg(); ssE >> type; m_boundaries[i].elementTypeSize = static_cast<size_t>(ssE.tellg()) - m_boundaries[i].elementSize; ssE >> face; if (ssE.tellg() == -1) m_boundaries[i].faceSize = line.length() - m_boundaries[i].elementSize - m_boundaries[i].elementTypeSize; else m_boundaries[i].faceSize = static_cast<size_t>(ssE.tellg()) - m_boundaries[i].elementSize - m_boundaries[i].elementTypeSize; m_mesh.seekg(m_boundaries[i].seekPosition + m_boundaries[i].nLines * m_boundaries[i].lineSize); getline(m_mesh, line); utils::StringUtils::rtrim(line); // remove \r if (line != ENDSECTION) { logWarning() << "Gambit format does not seem to have a fixed boundary line length. Trying with variable line length"; m_boundaries[i].variableLineLength = true; m_boundaries[i].lineSize = 0; // Variable line size m_boundaries[i].elementSize = 0; m_mesh.clear(); // The fixed boundary try may seek beyond the end of the file m_mesh.seekg(m_boundaries[i].seekPosition); for (size_t j = 0; j < m_boundaries[i].nLines; j++) m_mesh.ignore(std::numeric_limits<std::streamsize>::max(), '\n'); getline(m_mesh, line); utils::StringUtils::rtrim(line); // remove \r if (line != ENDSECTION) logError() << "Invalid Gambit format: End of boundaries expected, found" << line; } } } unsigned int nVertices() const { return m_vertices.nLines; } unsigned int nElements() const { return m_elements.nLines; } unsigned int nBoundaries() const { unsigned int count = 0; for (std::vector<BoundarySection>::const_iterator i = m_boundaries.begin(); i != m_boundaries.end(); i++) { count += i->nLines; } return count; } /** * @copydoc MeshReader::readVertices(unsigned int, unsigned int, double*) * * @todo Only 3 dimensional meshes are supported */ void readVertices(unsigned int start, unsigned int count, double* vertices) { m_mesh.clear(); m_mesh.seekg(m_vertices.seekPosition + start * m_vertices.lineSize + m_vertices.lineSize - 3*COORDINATE_SIZE - 1); char* buf = new char[3*COORDINATE_SIZE]; for (unsigned int i = 0; i < count; i++) { m_mesh.read(buf, 3*COORDINATE_SIZE); for (int j = 0; j < 3; j++) { std::istringstream ss(std::string(&buf[j*COORDINATE_SIZE], COORDINATE_SIZE)); ss >> vertices[i * 3 + j]; } m_mesh.seekg(m_vertices.lineSize - 3*COORDINATE_SIZE, std::fstream::cur); } delete [] buf; } /** * @copydoc MeshReader::readElements(unsigned int, unsigned int, int*) * * @todo Only tetrahedral meshes are supported * @todo Support for varying coordinate/vertexid fields */ void readElements(unsigned int start, unsigned int count, int* elements) { int value = 0; m_mesh.clear(); m_mesh.seekg(m_elements.seekPosition + start * m_elements.lineSize); //char* buf = new char[4*m_elements.vertexSize]; std::string line; for (unsigned int i = 0; i < count; i++) { getline(m_mesh, line); std::istringstream mesh_String(line); int key; //local id mesh_String >> key; int six; //a value that appears in every file but is not used again mesh_String >> six; int four; //a value that appears in every file but is not used again mesh_String >> four; id_map.insert(std::pair<int, int>(key, value)); //inserts an element, using his original id as key and his local id as value value++; //incremented, so the next id is different and again unique for (int j = 0; j < 4; j++) { mesh_String >> elements[i * 4 + j]; elements[i * 4 + j]--; mesh_String.seekg(1, std::stringstream::cur); // White space } } } /** * Reads group number for elements from start to start+count * * @param groups Buffer for storing the group numbers. The caller is responsible * for allocating the buffer. */ void readGroups(unsigned int start, unsigned int count, ElementGroup* groups) { m_mesh.clear(); // Get the group, were we should start reading std::vector<GroupSection>::const_iterator section; for (section = m_groups.begin(); section != m_groups.end() && section->nLines < start; section++) start -= section->nLines; m_mesh.seekg(section->seekPosition + (start / ELEMENTS_PER_LINE_GROUP) * section->lineSize + (start % ELEMENTS_PER_LINE_GROUP) * section->elementSize); char* buf = new char[section->elementSize]; for (unsigned int i = 0; i < count; i++) { m_mesh.read(buf, section->elementSize); std::istringstream ss(std::string(buf, section->elementSize)); ss >> groups[i].element;//read element id from file int key = groups[i].element; //save parsed id to key groups[i].element = id_map[key]; //lookup local id by using the parsed id as key groups[i].group = section->group; start++; // May need to jump from one section to the next if (start >= section->nLines) { start = 0; section++; m_mesh.seekg(section->seekPosition); } else if (start % ELEMENTS_PER_LINE_GROUP == 0) // Skip newline char at end of line m_mesh.seekg(section->lineSize - section->elementSize * ELEMENTS_PER_LINE_GROUP, std::fstream::cur); } delete [] buf; } /** * Reads all groups numbers. * In contrast to readGroups(unsigned int, unsigned int, ElementGroup*) it * returns the group numbers sorted according to the elements. */ void readGroups(int* groups) { logInfo() << "Reading group information"; ElementGroup* map = new ElementGroup[nElements()]; readGroups(0, nElements(), map); #ifdef _OPENMP #pragma omp parallel for schedule(static) #endif for (unsigned int i = 0; i < nElements(); i++) groups[map[i].element] = map[i].group; delete [] map; } /** * Reads boundaries from start to start+count from the file and stores them in * <code>boundaries</code>. * * @param elements Buffer to store boundaries. Each boundary consists of the element, the * face and the boundary type. */ void readBoundaries(unsigned int start, unsigned int count, GambitBoundaryFace* boundaries) { m_mesh.clear(); // Get the boundary, were we should start reading std::vector<BoundarySection>::const_iterator section; for (section = m_boundaries.begin(); section != m_boundaries.end() && section->nLines < start; section++) start -= section->nLines; char* buf; if (section->variableLineLength) { m_mesh.seekg(section->seekPosition); for (size_t i = 0; i < start; i++) m_mesh.ignore(std::numeric_limits<std::streamsize>::max(), '\n'); buf = 0L; } else { m_mesh.seekg(section->seekPosition + start * section->lineSize); buf = new char[section->elementSize + section->elementTypeSize + section->faceSize]; } for (unsigned int i = 0; i < count; i++) { if (start >= section->nLines) { // Are we starting a new section in this iteration? start = 0; section++; m_mesh.seekg(section->seekPosition); delete [] buf; if (section->variableLineLength) buf = 0L; else buf = new char[section->elementSize + section->elementTypeSize + section->faceSize]; } if (section->variableLineLength) { unsigned int elementType; // Ignored m_mesh >> boundaries[i].element; m_mesh >> elementType; m_mesh >> boundaries[i].face; } else { m_mesh.read(buf, section->elementSize + section->elementTypeSize + section->faceSize); std::istringstream ssE(std::string(buf, section->elementSize)); ssE >> boundaries[i].element; std::istringstream ssF(std::string(&buf[section->elementSize + section->elementTypeSize], section->faceSize)); ssF >> boundaries[i].face; // Seek to next position m_mesh.seekg(section->lineSize - (section->elementSize + section->elementTypeSize + section->faceSize), std::fstream::cur); } int key = boundaries[i].element; //save parsed element id to key boundaries[i].element = id_map[key]; //lookup local id by using parsed element id boundaries[i].face--; boundaries[i].type = section->type; start++; // Line in the current section } delete [] buf; } /** * Reads all boundaries. * * @param Boundary condition for all faces. The caller is responsible * for allocation the memory (<code>nElements()*4</code>). Only the faces * for which boundary conditions are available are modified. * * @todo Only tetrahedral meshes are supported */ void readBoundaries(int* boundaries) { logInfo() << "Reading boundary conditions"; unsigned int nBnds = nBoundaries(); GambitBoundaryFace* faces = new GambitBoundaryFace[nBoundaries()]; readBoundaries(0, nBnds, faces); for (unsigned int i = 0; i < nBnds; i++) boundaries[faces[i].element*4 + faces[i].face] = faces[i].type; delete [] faces; } private: /** Number of character required to store a coordinate */ static const size_t COORDINATE_SIZE = 20ul; /** Number of elements stored in one group line */ static const size_t ELEMENTS_PER_LINE_GROUP = 10ul; static const char* GAMBIT_FILE_ID; static const char* ENDSECTION; static const char* NODAL_COORDINATES; static const char* ELEMENT_CELLS; static const char* ELEMENT_GROUP; static const char* BOUNDARY_CONDITIONS; }; } #endif // GAMBIT_READER_H

matrix.c

/* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % M M AAA TTTTT RRRR IIIII X X % % MM MM A A T R R I X X % % M M M AAAAA T RRRR I X % % M M A A T R R I X X % % M M A A T R R IIIII X X % % % % % % MagickCore Matrix Methods % % % % Software Design % % Cristy % % August 2007 % % % % % % Copyright 1999-2017 ImageMagick Studio LLC, a non-profit organization % % dedicated to making software imaging solutions freely available. % % % % You may not use this file except in compliance with the License. You may % % obtain a copy of the License at % % % % https://www.imagemagick.org/script/license.php % % % % Unless required by applicable law or agreed to in writing, software % % distributed under the License is distributed on an "AS IS" BASIS, % % WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. % % See the License for the specific language governing permissions and % % limitations under the License. % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % */ /* Include declarations. */ #include "MagickCore/studio.h" #include "MagickCore/blob.h" #include "MagickCore/blob-private.h" #include "MagickCore/cache.h" #include "MagickCore/exception.h" #include "MagickCore/exception-private.h" #include "MagickCore/image-private.h" #include "MagickCore/matrix.h" #include "MagickCore/matrix-private.h" #include "MagickCore/memory_.h" #include "MagickCore/pixel-accessor.h" #include "MagickCore/pixel-private.h" #include "MagickCore/resource_.h" #include "MagickCore/semaphore.h" #include "MagickCore/thread-private.h" #include "MagickCore/utility.h" /* Typedef declaration. */ struct _MatrixInfo { CacheType type; size_t columns, rows, stride; MagickSizeType length; MagickBooleanType mapped, synchronize; char path[MagickPathExtent]; int file; void *elements; SemaphoreInfo *semaphore; size_t signature; }; /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % A c q u i r e M a t r i x I n f o % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % AcquireMatrixInfo() allocates the ImageInfo structure. % % The format of the AcquireMatrixInfo method is: % % MatrixInfo *AcquireMatrixInfo(const size_t columns,const size_t rows, % const size_t stride,ExceptionInfo *exception) % % A description of each parameter follows: % % o columns: the matrix columns. % % o rows: the matrix rows. % % o stride: the matrix stride. % % o exception: return any errors or warnings in this structure. % */ #if defined(SIGBUS) static void MatrixSignalHandler(int status) { ThrowFatalException(CacheFatalError,"UnableToExtendMatrixCache"); } #endif static inline MagickOffsetType WriteMatrixElements( const MatrixInfo *magick_restrict matrix_info,const MagickOffsetType offset, const MagickSizeType length,const unsigned char *magick_restrict buffer) { register MagickOffsetType i; ssize_t count; #if !defined(MAGICKCORE_HAVE_PWRITE) LockSemaphoreInfo(matrix_info->semaphore); if (lseek(matrix_info->file,offset,SEEK_SET) < 0) { UnlockSemaphoreInfo(matrix_info->semaphore); return((MagickOffsetType) -1); } #endif count=0; for (i=0; i < (MagickOffsetType) length; i+=count) { #if !defined(MAGICKCORE_HAVE_PWRITE) count=write(matrix_info->file,buffer+i,(size_t) MagickMin(length-i, (MagickSizeType) SSIZE_MAX)); #else count=pwrite(matrix_info->file,buffer+i,(size_t) MagickMin(length-i, (MagickSizeType) SSIZE_MAX),(off_t) (offset+i)); #endif if (count <= 0) { count=0; if (errno != EINTR) break; } } #if !defined(MAGICKCORE_HAVE_PWRITE) UnlockSemaphoreInfo(matrix_info->semaphore); #endif return(i); } static MagickBooleanType SetMatrixExtent( MatrixInfo *magick_restrict matrix_info,MagickSizeType length) { MagickOffsetType count, extent, offset; if (length != (MagickSizeType) ((MagickOffsetType) length)) return(MagickFalse); offset=(MagickOffsetType) lseek(matrix_info->file,0,SEEK_END); if (offset < 0) return(MagickFalse); if ((MagickSizeType) offset >= length) return(MagickTrue); extent=(MagickOffsetType) length-1; count=WriteMatrixElements(matrix_info,extent,1,(const unsigned char *) ""); #if defined(MAGICKCORE_HAVE_POSIX_FALLOCATE) if (matrix_info->synchronize != MagickFalse) (void) posix_fallocate(matrix_info->file,offset+1,extent-offset); #endif #if defined(SIGBUS) (void) signal(SIGBUS,MatrixSignalHandler); #endif return(count != (MagickOffsetType) 1 ? MagickFalse : MagickTrue); } MagickExport MatrixInfo *AcquireMatrixInfo(const size_t columns, const size_t rows,const size_t stride,ExceptionInfo *exception) { char *synchronize; MagickBooleanType status; MatrixInfo *matrix_info; matrix_info=(MatrixInfo *) AcquireMagickMemory(sizeof(*matrix_info)); if (matrix_info == (MatrixInfo *) NULL) return((MatrixInfo *) NULL); (void) ResetMagickMemory(matrix_info,0,sizeof(*matrix_info)); matrix_info->signature=MagickCoreSignature; matrix_info->columns=columns; matrix_info->rows=rows; matrix_info->stride=stride; matrix_info->semaphore=AcquireSemaphoreInfo(); synchronize=GetEnvironmentValue("MAGICK_SYNCHRONIZE"); if (synchronize != (const char *) NULL) { matrix_info->synchronize=IsStringTrue(synchronize); synchronize=DestroyString(synchronize); } matrix_info->length=(MagickSizeType) columns*rows*stride; if (matrix_info->columns != (size_t) (matrix_info->length/rows/stride)) { (void) ThrowMagickException(exception,GetMagickModule(),CacheError, "CacheResourcesExhausted","`%s'","matrix cache"); return(DestroyMatrixInfo(matrix_info)); } matrix_info->type=MemoryCache; status=AcquireMagickResource(AreaResource,matrix_info->length); if ((status != MagickFalse) && (matrix_info->length == (MagickSizeType) ((size_t) matrix_info->length))) { status=AcquireMagickResource(MemoryResource,matrix_info->length); if (status != MagickFalse) { matrix_info->mapped=MagickFalse; matrix_info->elements=AcquireMagickMemory((size_t) matrix_info->length); if (matrix_info->elements == NULL) { matrix_info->mapped=MagickTrue; matrix_info->elements=MapBlob(-1,IOMode,0,(size_t) matrix_info->length); } if (matrix_info->elements == (unsigned short *) NULL) RelinquishMagickResource(MemoryResource,matrix_info->length); } } matrix_info->file=(-1); if (matrix_info->elements == (unsigned short *) NULL) { status=AcquireMagickResource(DiskResource,matrix_info->length); if (status == MagickFalse) { (void) ThrowMagickException(exception,GetMagickModule(),CacheError, "CacheResourcesExhausted","`%s'","matrix cache"); return(DestroyMatrixInfo(matrix_info)); } matrix_info->type=DiskCache; matrix_info->file=AcquireUniqueFileResource(matrix_info->path); if (matrix_info->file == -1) return(DestroyMatrixInfo(matrix_info)); status=AcquireMagickResource(MapResource,matrix_info->length); if (status != MagickFalse) { status=SetMatrixExtent(matrix_info,matrix_info->length); if (status != MagickFalse) matrix_info->elements=(void *) MapBlob(matrix_info->file,IOMode,0, (size_t) matrix_info->length); if (matrix_info->elements != NULL) matrix_info->type=MapCache; else RelinquishMagickResource(MapResource,matrix_info->length); } } return(matrix_info); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % A c q u i r e M a g i c k M a t r i x % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % AcquireMagickMatrix() allocates and returns a matrix in the form of an % array of pointers to an array of doubles, with all values pre-set to zero. % % This used to generate the two dimensional matrix, and vectors required % for the GaussJordanElimination() method below, solving some system of % simultanious equations. % % The format of the AcquireMagickMatrix method is: % % double **AcquireMagickMatrix(const size_t number_rows, % const size_t size) % % A description of each parameter follows: % % o number_rows: the number pointers for the array of pointers % (first dimension). % % o size: the size of the array of doubles each pointer points to % (second dimension). % */ MagickExport double **AcquireMagickMatrix(const size_t number_rows, const size_t size) { double **matrix; register ssize_t i, j; matrix=(double **) AcquireQuantumMemory(number_rows,sizeof(*matrix)); if (matrix == (double **) NULL) return((double **) NULL); for (i=0; i < (ssize_t) number_rows; i++) { matrix[i]=(double *) AcquireQuantumMemory(size,sizeof(*matrix[i])); if (matrix[i] == (double *) NULL) { for (j=0; j < i; j++) matrix[j]=(double *) RelinquishMagickMemory(matrix[j]); matrix=(double **) RelinquishMagickMemory(matrix); return((double **) NULL); } for (j=0; j < (ssize_t) size; j++) matrix[i][j]=0.0; } return(matrix); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % D e s t r o y M a t r i x I n f o % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % DestroyMatrixInfo() dereferences a matrix, deallocating memory associated % with the matrix. % % The format of the DestroyImage method is: % % MatrixInfo *DestroyMatrixInfo(MatrixInfo *matrix_info) % % A description of each parameter follows: % % o matrix_info: the matrix. % */ MagickExport MatrixInfo *DestroyMatrixInfo(MatrixInfo *matrix_info) { assert(matrix_info != (MatrixInfo *) NULL); assert(matrix_info->signature == MagickCoreSignature); LockSemaphoreInfo(matrix_info->semaphore); switch (matrix_info->type) { case MemoryCache: { if (matrix_info->mapped == MagickFalse) matrix_info->elements=RelinquishMagickMemory(matrix_info->elements); else { (void) UnmapBlob(matrix_info->elements,(size_t) matrix_info->length); matrix_info->elements=(unsigned short *) NULL; } RelinquishMagickResource(MemoryResource,matrix_info->length); break; } case MapCache: { (void) UnmapBlob(matrix_info->elements,(size_t) matrix_info->length); matrix_info->elements=NULL; RelinquishMagickResource(MapResource,matrix_info->length); } case DiskCache: { if (matrix_info->file != -1) (void) close(matrix_info->file); (void) RelinquishUniqueFileResource(matrix_info->path); RelinquishMagickResource(DiskResource,matrix_info->length); break; } default: break; } UnlockSemaphoreInfo(matrix_info->semaphore); RelinquishSemaphoreInfo(&matrix_info->semaphore); return((MatrixInfo *) RelinquishMagickMemory(matrix_info)); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % + G a u s s J o r d a n E l i m i n a t i o n % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % GaussJordanElimination() returns a matrix in reduced row echelon form, % while simultaneously reducing and thus solving the augumented results % matrix. % % See also http://en.wikipedia.org/wiki/Gauss-Jordan_elimination % % The format of the GaussJordanElimination method is: % % MagickBooleanType GaussJordanElimination(double **matrix, % double **vectors,const size_t rank,const size_t number_vectors) % % A description of each parameter follows: % % o matrix: the matrix to be reduced, as an 'array of row pointers'. % % o vectors: the additional matrix argumenting the matrix for row reduction. % Producing an 'array of column vectors'. % % o rank: The size of the matrix (both rows and columns). % Also represents the number terms that need to be solved. % % o number_vectors: Number of vectors columns, argumenting the above matrix. % Usally 1, but can be more for more complex equation solving. % % Note that the 'matrix' is given as a 'array of row pointers' of rank size. % That is values can be assigned as matrix[row][column] where 'row' is % typically the equation, and 'column' is the term of the equation. % That is the matrix is in the form of a 'row first array'. % % However 'vectors' is a 'array of column pointers' which can have any number % of columns, with each column array the same 'rank' size as 'matrix'. % % This allows for simpler handling of the results, especially is only one % column 'vector' is all that is required to produce the desired solution. % % For example, the 'vectors' can consist of a pointer to a simple array of % doubles. when only one set of simultanious equations is to be solved from % the given set of coefficient weighted terms. % % double **matrix = AcquireMagickMatrix(8UL,8UL); % double coefficents[8]; % ... % GaussJordanElimination(matrix, &coefficents, 8UL, 1UL); % % However by specifing more 'columns' (as an 'array of vector columns', % you can use this function to solve a set of 'separable' equations. % % For example a distortion function where u = U(x,y) v = V(x,y) % And the functions U() and V() have separate coefficents, but are being % generated from a common x,y->u,v data set. % % Another example is generation of a color gradient from a set of colors at % specific coordients, such as a list x,y -> r,g,b,a. % % You can also use the 'vectors' to generate an inverse of the given 'matrix' % though as a 'column first array' rather than a 'row first array'. For % details see http://en.wikipedia.org/wiki/Gauss-Jordan_elimination % */ MagickPrivate MagickBooleanType GaussJordanElimination(double **matrix, double **vectors,const size_t rank,const size_t number_vectors) { #define GaussJordanSwap(x,y) \ { \ if ((x) != (y)) \ { \ (x)+=(y); \ (y)=(x)-(y); \ (x)=(x)-(y); \ } \ } double max, scale; register ssize_t i, j, k; ssize_t column, *columns, *pivots, row, *rows; columns=(ssize_t *) AcquireQuantumMemory(rank,sizeof(*columns)); rows=(ssize_t *) AcquireQuantumMemory(rank,sizeof(*rows)); pivots=(ssize_t *) AcquireQuantumMemory(rank,sizeof(*pivots)); if ((rows == (ssize_t *) NULL) || (columns == (ssize_t *) NULL) || (pivots == (ssize_t *) NULL)) { if (pivots != (ssize_t *) NULL) pivots=(ssize_t *) RelinquishMagickMemory(pivots); if (columns != (ssize_t *) NULL) columns=(ssize_t *) RelinquishMagickMemory(columns); if (rows != (ssize_t *) NULL) rows=(ssize_t *) RelinquishMagickMemory(rows); return(MagickFalse); } (void) ResetMagickMemory(columns,0,rank*sizeof(*columns)); (void) ResetMagickMemory(rows,0,rank*sizeof(*rows)); (void) ResetMagickMemory(pivots,0,rank*sizeof(*pivots)); column=0; row=0; for (i=0; i < (ssize_t) rank; i++) { max=0.0; for (j=0; j < (ssize_t) rank; j++) if (pivots[j] != 1) { for (k=0; k < (ssize_t) rank; k++) if (pivots[k] != 0) { if (pivots[k] > 1) return(MagickFalse); } else if (fabs(matrix[j][k]) >= max) { max=fabs(matrix[j][k]); row=j; column=k; } } pivots[column]++; if (row != column) { for (k=0; k < (ssize_t) rank; k++) GaussJordanSwap(matrix[row][k],matrix[column][k]); for (k=0; k < (ssize_t) number_vectors; k++) GaussJordanSwap(vectors[k][row],vectors[k][column]); } rows[i]=row; columns[i]=column; if (matrix[column][column] == 0.0) return(MagickFalse); /* sigularity */ scale=PerceptibleReciprocal(matrix[column][column]); matrix[column][column]=1.0; for (j=0; j < (ssize_t) rank; j++) matrix[column][j]*=scale; for (j=0; j < (ssize_t) number_vectors; j++) vectors[j][column]*=scale; for (j=0; j < (ssize_t) rank; j++) if (j != column) { scale=matrix[j][column]; matrix[j][column]=0.0; for (k=0; k < (ssize_t) rank; k++) matrix[j][k]-=scale*matrix[column][k]; for (k=0; k < (ssize_t) number_vectors; k++) vectors[k][j]-=scale*vectors[k][column]; } } for (j=(ssize_t) rank-1; j >= 0; j--) if (columns[j] != rows[j]) for (i=0; i < (ssize_t) rank; i++) GaussJordanSwap(matrix[i][rows[j]],matrix[i][columns[j]]); pivots=(ssize_t *) RelinquishMagickMemory(pivots); rows=(ssize_t *) RelinquishMagickMemory(rows); columns=(ssize_t *) RelinquishMagickMemory(columns); return(MagickTrue); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % G e t M a t r i x C o l u m n s % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % GetMatrixColumns() returns the number of columns in the matrix. % % The format of the GetMatrixColumns method is: % % size_t GetMatrixColumns(const MatrixInfo *matrix_info) % % A description of each parameter follows: % % o matrix_info: the matrix. % */ MagickExport size_t GetMatrixColumns(const MatrixInfo *matrix_info) { assert(matrix_info != (MatrixInfo *) NULL); assert(matrix_info->signature == MagickCoreSignature); return(matrix_info->columns); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % G e t M a t r i x E l e m e n t % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % GetMatrixElement() returns the specifed element in the matrix. % % The format of the GetMatrixElement method is: % % MagickBooleanType GetMatrixElement(const MatrixInfo *matrix_info, % const ssize_t x,const ssize_t y,void *value) % % A description of each parameter follows: % % o matrix_info: the matrix columns. % % o x: the matrix x-offset. % % o y: the matrix y-offset. % % o value: return the matrix element in this buffer. % */ static inline ssize_t EdgeX(const ssize_t x,const size_t columns) { if (x < 0L) return(0L); if (x >= (ssize_t) columns) return((ssize_t) (columns-1)); return(x); } static inline ssize_t EdgeY(const ssize_t y,const size_t rows) { if (y < 0L) return(0L); if (y >= (ssize_t) rows) return((ssize_t) (rows-1)); return(y); } static inline MagickOffsetType ReadMatrixElements( const MatrixInfo *magick_restrict matrix_info,const MagickOffsetType offset, const MagickSizeType length,unsigned char *magick_restrict buffer) { register MagickOffsetType i; ssize_t count; #if !defined(MAGICKCORE_HAVE_PREAD) LockSemaphoreInfo(matrix_info->semaphore); if (lseek(matrix_info->file,offset,SEEK_SET) < 0) { UnlockSemaphoreInfo(matrix_info->semaphore); return((MagickOffsetType) -1); } #endif count=0; for (i=0; i < (MagickOffsetType) length; i+=count) { #if !defined(MAGICKCORE_HAVE_PREAD) count=read(matrix_info->file,buffer+i,(size_t) MagickMin(length-i, (MagickSizeType) SSIZE_MAX)); #else count=pread(matrix_info->file,buffer+i,(size_t) MagickMin(length-i, (MagickSizeType) SSIZE_MAX),(off_t) (offset+i)); #endif if (count <= 0) { count=0; if (errno != EINTR) break; } } #if !defined(MAGICKCORE_HAVE_PREAD) UnlockSemaphoreInfo(matrix_info->semaphore); #endif return(i); } MagickExport MagickBooleanType GetMatrixElement(const MatrixInfo *matrix_info, const ssize_t x,const ssize_t y,void *value) { MagickOffsetType count, i; assert(matrix_info != (const MatrixInfo *) NULL); assert(matrix_info->signature == MagickCoreSignature); i=(MagickOffsetType) EdgeY(y,matrix_info->rows)*matrix_info->columns+ EdgeX(x,matrix_info->columns); if (matrix_info->type != DiskCache) { (void) memcpy(value,(unsigned char *) matrix_info->elements+i* matrix_info->stride,matrix_info->stride); return(MagickTrue); } count=ReadMatrixElements(matrix_info,i*matrix_info->stride, matrix_info->stride,(unsigned char *) value); if (count != (MagickOffsetType) matrix_info->stride) return(MagickFalse); return(MagickTrue); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % G e t M a t r i x R o w s % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % GetMatrixRows() returns the number of rows in the matrix. % % The format of the GetMatrixRows method is: % % size_t GetMatrixRows(const MatrixInfo *matrix_info) % % A description of each parameter follows: % % o matrix_info: the matrix. % */ MagickExport size_t GetMatrixRows(const MatrixInfo *matrix_info) { assert(matrix_info != (const MatrixInfo *) NULL); assert(matrix_info->signature == MagickCoreSignature); return(matrix_info->rows); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % + L e a s t S q u a r e s A d d T e r m s % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % LeastSquaresAddTerms() adds one set of terms and associate results to the % given matrix and vectors for solving using least-squares function fitting. % % The format of the AcquireMagickMatrix method is: % % void LeastSquaresAddTerms(double **matrix,double **vectors, % const double *terms,const double *results,const size_t rank, % const size_t number_vectors); % % A description of each parameter follows: % % o matrix: the square matrix to add given terms/results to. % % o vectors: the result vectors to add terms/results to. % % o terms: the pre-calculated terms (without the unknown coefficent % weights) that forms the equation being added. % % o results: the result(s) that should be generated from the given terms % weighted by the yet-to-be-solved coefficents. % % o rank: the rank or size of the dimensions of the square matrix. % Also the length of vectors, and number of terms being added. % % o number_vectors: Number of result vectors, and number or results being % added. Also represents the number of separable systems of equations % that is being solved. % % Example of use... % % 2 dimensional Affine Equations (which are separable) % c0*x + c2*y + c4*1 => u % c1*x + c3*y + c5*1 => v % % double **matrix = AcquireMagickMatrix(3UL,3UL); % double **vectors = AcquireMagickMatrix(2UL,3UL); % double terms[3], results[2]; % ... % for each given x,y -> u,v % terms[0] = x; % terms[1] = y; % terms[2] = 1; % results[0] = u; % results[1] = v; % LeastSquaresAddTerms(matrix,vectors,terms,results,3UL,2UL); % ... % if ( GaussJordanElimination(matrix,vectors,3UL,2UL) ) { % c0 = vectors[0][0]; % c2 = vectors[0][1]; % c4 = vectors[0][2]; % c1 = vectors[1][0]; % c3 = vectors[1][1]; % c5 = vectors[1][2]; % } % else % printf("Matrix unsolvable\n); % RelinquishMagickMatrix(matrix,3UL); % RelinquishMagickMatrix(vectors,2UL); % */ MagickPrivate void LeastSquaresAddTerms(double **matrix,double **vectors, const double *terms,const double *results,const size_t rank, const size_t number_vectors) { register ssize_t i, j; for (j=0; j < (ssize_t) rank; j++) { for (i=0; i < (ssize_t) rank; i++) matrix[i][j]+=terms[i]*terms[j]; for (i=0; i < (ssize_t) number_vectors; i++) vectors[i][j]+=results[i]*terms[j]; } } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % M a t r i x T o I m a g e % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % MatrixToImage() returns a matrix as an image. The matrix elements must be % of type double otherwise nonsense is returned. % % The format of the MatrixToImage method is: % % Image *MatrixToImage(const MatrixInfo *matrix_info, % ExceptionInfo *exception) % % A description of each parameter follows: % % o matrix_info: the matrix. % % o exception: return any errors or warnings in this structure. % */ MagickExport Image *MatrixToImage(const MatrixInfo *matrix_info, ExceptionInfo *exception) { CacheView *image_view; double max_value, min_value, scale_factor, value; Image *image; MagickBooleanType status; ssize_t y; assert(matrix_info != (const MatrixInfo *) NULL); assert(matrix_info->signature == MagickCoreSignature); assert(exception != (ExceptionInfo *) NULL); assert(exception->signature == MagickCoreSignature); if (matrix_info->stride < sizeof(double)) return((Image *) NULL); /* Determine range of matrix. */ (void) GetMatrixElement(matrix_info,0,0,&value); min_value=value; max_value=value; for (y=0; y < (ssize_t) matrix_info->rows; y++) { register ssize_t x; for (x=0; x < (ssize_t) matrix_info->columns; x++) { if (GetMatrixElement(matrix_info,x,y,&value) == MagickFalse) continue; if (value < min_value) min_value=value; else if (value > max_value) max_value=value; } } if ((min_value == 0.0) && (max_value == 0.0)) scale_factor=0; else if (min_value == max_value) { scale_factor=(double) QuantumRange/min_value; min_value=0; } else scale_factor=(double) QuantumRange/(max_value-min_value); /* Convert matrix to image. */ image=AcquireImage((ImageInfo *) NULL,exception); image->columns=matrix_info->columns; image->rows=matrix_info->rows; image->colorspace=GRAYColorspace; status=MagickTrue; image_view=AcquireAuthenticCacheView(image,exception); #if defined(MAGICKCORE_OPENMP_SUPPORT) #pragma omp parallel for schedule(static,4) shared(status) \ magick_number_threads(image,image,image->rows,1) #endif for (y=0; y < (ssize_t) image->rows; y++) { double value; register Quantum *q; register ssize_t x; if (status == MagickFalse) continue; q=QueueCacheViewAuthenticPixels(image_view,0,y,image->columns,1,exception); if (q == (Quantum *) NULL) { status=MagickFalse; continue; } for (x=0; x < (ssize_t) image->columns; x++) { if (GetMatrixElement(matrix_info,x,y,&value) == MagickFalse) continue; value=scale_factor*(value-min_value); *q=ClampToQuantum(value); q+=GetPixelChannels(image); } if (SyncCacheViewAuthenticPixels(image_view,exception) == MagickFalse) status=MagickFalse; } image_view=DestroyCacheView(image_view); if (status == MagickFalse) image=DestroyImage(image); return(image); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % N u l l M a t r i x % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % NullMatrix() sets all elements of the matrix to zero. % % The format of the ResetMagickMemory method is: % % MagickBooleanType *NullMatrix(MatrixInfo *matrix_info) % % A description of each parameter follows: % % o matrix_info: the matrix. % */ MagickExport MagickBooleanType NullMatrix(MatrixInfo *matrix_info) { register ssize_t x; ssize_t count, y; unsigned char value; assert(matrix_info != (const MatrixInfo *) NULL); assert(matrix_info->signature == MagickCoreSignature); if (matrix_info->type != DiskCache) { (void) ResetMagickMemory(matrix_info->elements,0,(size_t) matrix_info->length); return(MagickTrue); } value=0; (void) lseek(matrix_info->file,0,SEEK_SET); for (y=0; y < (ssize_t) matrix_info->rows; y++) { for (x=0; x < (ssize_t) matrix_info->length; x++) { count=write(matrix_info->file,&value,sizeof(value)); if (count != (ssize_t) sizeof(value)) break; } if (x < (ssize_t) matrix_info->length) break; } return(y < (ssize_t) matrix_info->rows ? MagickFalse : MagickTrue); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % R e l i n q u i s h M a g i c k M a t r i x % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % RelinquishMagickMatrix() frees the previously acquired matrix (array of % pointers to arrays of doubles). % % The format of the RelinquishMagickMatrix method is: % % double **RelinquishMagickMatrix(double **matrix, % const size_t number_rows) % % A description of each parameter follows: % % o matrix: the matrix to relinquish % % o number_rows: the first dimension of the acquired matrix (number of % pointers) % */ MagickExport double **RelinquishMagickMatrix(double **matrix, const size_t number_rows) { register ssize_t i; if (matrix == (double **) NULL ) return(matrix); for (i=0; i < (ssize_t) number_rows; i++) matrix[i]=(double *) RelinquishMagickMemory(matrix[i]); matrix=(double **) RelinquishMagickMemory(matrix); return(matrix); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % S e t M a t r i x E l e m e n t % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % SetMatrixElement() sets the specifed element in the matrix. % % The format of the SetMatrixElement method is: % % MagickBooleanType SetMatrixElement(const MatrixInfo *matrix_info, % const ssize_t x,const ssize_t y,void *value) % % A description of each parameter follows: % % o matrix_info: the matrix columns. % % o x: the matrix x-offset. % % o y: the matrix y-offset. % % o value: set the matrix element to this value. % */ MagickExport MagickBooleanType SetMatrixElement(const MatrixInfo *matrix_info, const ssize_t x,const ssize_t y,const void *value) { MagickOffsetType count, i; assert(matrix_info != (const MatrixInfo *) NULL); assert(matrix_info->signature == MagickCoreSignature); i=(MagickOffsetType) y*matrix_info->columns+x; if ((i < 0) || ((MagickSizeType) (i*matrix_info->stride) >= matrix_info->length)) return(MagickFalse); if (matrix_info->type != DiskCache) { (void) memcpy((unsigned char *) matrix_info->elements+i* matrix_info->stride,value,matrix_info->stride); return(MagickTrue); } count=WriteMatrixElements(matrix_info,i*matrix_info->stride, matrix_info->stride,(unsigned char *) value); if (count != (MagickOffsetType) matrix_info->stride) return(MagickFalse); return(MagickTrue); }

3mm.c

/** * 3mm.c: This file was adapted from PolyBench/GPU 1.0 test suite * to run on GPU with OpenMP 4.0 pragmas and OpenCL driver. * * http://www.cse.ohio-state.edu/~pouchet/software/polybench/GPU * * Contacts: Marcio M Pereira <mpereira@ic.unicamp.br> * Rafael Cardoso F Sousa <rafael.cardoso@students.ic.unicamp.br> * Luís Felipe Mattos <ra107822@students.ic.unicamp.br> */ #include <assert.h> #include <math.h> #include <stdio.h> #include <stdlib.h> #include <sys/time.h> #include <unistd.h> #ifdef _OPENMP #include <omp.h> #endif #include "BenchmarksUtil.h" // define the error threshold for the results "not matching" #define PERCENT_DIFF_ERROR_THRESHOLD 0.05 /* Problem size. */ #ifdef RUN_TEST #define SIZE 1100 #elif RUN_BENCHMARK #define SIZE 9600 #else #define SIZE 1000 #endif #define NI SIZE #define NJ SIZE #define NK SIZE #define NL SIZE #define NM SIZE /* Can switch DATA_TYPE between float and double */ typedef float DATA_TYPE; void init_array(DATA_TYPE *A, DATA_TYPE *B, DATA_TYPE *C, DATA_TYPE *D) { int i, j; for (i = 0; i < NI; i++) { for (j = 0; j < NK; j++) { A[i * NK + j] = ((DATA_TYPE)i * j) / NI; } } for (i = 0; i < NK; i++) { for (j = 0; j < NJ; j++) { B[i * NJ + j] = ((DATA_TYPE)i * (j + 1)) / NJ; } } for (i = 0; i < NJ; i++) { for (j = 0; j < NM; j++) { C[i * NM + j] = ((DATA_TYPE)i * (j + 3)) / NL; } } for (i = 0; i < NM; i++) { for (j = 0; j < NL; j++) { D[i * NL + j] = ((DATA_TYPE)i * (j + 2)) / NK; } } } int compareResults(DATA_TYPE *G, DATA_TYPE *G_outputFromGpu) { int i, j, fail; fail = 0; for (i = 0; i < NI; i++) { for (j = 0; j < NL; j++) { if (percentDiff(G[i * NL + j], G_outputFromGpu[i * NL + j]) > PERCENT_DIFF_ERROR_THRESHOLD) { fail++; } } } // print results printf("Non-Matching CPU-GPU Outputs Beyond Error Threshold of %4.2f " "Percent: %d\n", PERCENT_DIFF_ERROR_THRESHOLD, fail); return fail; } void mm3_cpu(DATA_TYPE *A, DATA_TYPE *B, DATA_TYPE *C, DATA_TYPE *D, DATA_TYPE *E, DATA_TYPE *F, DATA_TYPE *G) { int i, j, k; /* E := A*B */ for (i = 0; i < NI; i++) { for (j = 0; j < NJ; j++) { E[i * NJ + j] = 0; for (k = 0; k < NK; ++k) { E[i * NJ + j] += A[i * NK + k] * B[k * NJ + j]; } } } /* F := C*D */ for (i = 0; i < NJ; i++) { for (j = 0; j < NL; j++) { F[i * NL + j] = 0; for (k = 0; k < NM; ++k) { F[i * NL + j] += C[i * NM + k] * D[k * NL + j]; } } } /* G := E*F */ for (i = 0; i < NI; i++) { for (j = 0; j < NL; j++) { G[i * NL + j] = 0; for (k = 0; k < NJ; ++k) { G[i * NL + j] += E[i * NJ + k] * F[k * NL + j]; } } } } void mm3_OMP(DATA_TYPE *A, DATA_TYPE *B, DATA_TYPE *C, DATA_TYPE *D, DATA_TYPE *E, DATA_TYPE *F, DATA_TYPE *G) { /* E := A*B */ #pragma omp target teams map(to : A[ : NI *NK], B[ : NK *NJ], C[ : NJ *NM], D[ : NM *NL]) map(from : E[ : NI *NJ], F[ : NJ *NL], G[ : NI *NL]) device(DEVICE_ID) thread_limit(128) { #pragma omp distribute parallel for collapse(2) for (int i = 0; i < NI; i++) { for (int j = 0; j < NJ; j++) { E[i * NJ + j] = 0; for (int k = 0; k < NK; ++k) { E[i * NJ + j] += A[i * NK + k] * B[k * NJ + j]; } } } /* F := C*D */ #pragma omp distribute parallel for collapse(2) for (int i = 0; i < NJ; i++) { for (int j = 0; j < NL; j++) { F[i * NL + j] = 0; for (int k = 0; k < NM; ++k) { F[i * NL + j] += C[i * NM + k] * D[k * NL + j]; } } } /* G := E*F */ #pragma omp distribute parallel for collapse(2) for (int i = 0; i < NI; i++) { for (int j = 0; j < NL; j++) { G[i * NL + j] = 0; for (int k = 0; k < NJ; ++k) { G[i * NL + j] += E[i * NJ + k] * F[k * NL + j]; } } } } } int main(int argc, char **argv) { double t_start, t_end; int fail = 0; DATA_TYPE *A; DATA_TYPE *B; DATA_TYPE *C; DATA_TYPE *D; DATA_TYPE *E; DATA_TYPE *F; DATA_TYPE *G; DATA_TYPE *E_outputFromGpu; DATA_TYPE *F_outputFromGpu; DATA_TYPE *G_outputFromGpu; A = (DATA_TYPE *)malloc(NI * NK * sizeof(DATA_TYPE)); B = (DATA_TYPE *)malloc(NK * NJ * sizeof(DATA_TYPE)); C = (DATA_TYPE *)malloc(NJ * NM * sizeof(DATA_TYPE)); D = (DATA_TYPE *)malloc(NM * NL * sizeof(DATA_TYPE)); E = (DATA_TYPE *)malloc(NI * NJ * sizeof(DATA_TYPE)); F = (DATA_TYPE *)malloc(NJ * NL * sizeof(DATA_TYPE)); G = (DATA_TYPE *)malloc(NI * NL * sizeof(DATA_TYPE)); E_outputFromGpu = (DATA_TYPE *)calloc(NI * NJ, sizeof(DATA_TYPE)); F_outputFromGpu = (DATA_TYPE *)calloc(NJ * NL, sizeof(DATA_TYPE)); G_outputFromGpu = (DATA_TYPE *)calloc(NI * NL, sizeof(DATA_TYPE)); fprintf( stdout, "<< Linear Algebra: 3 Matrix Multiplications (E=A.B; F=C.D; G=E.F) >>\n"); init_array(A, B, C, D); t_start = rtclock(); mm3_OMP(A, B, C, D, E_outputFromGpu, F_outputFromGpu, G_outputFromGpu); t_end = rtclock(); fprintf(stdout, "GPU Runtime: %0.6lfs\n", t_end - t_start); #ifdef RUN_TEST t_start = rtclock(); mm3_cpu(A, B, C, D, E, F, G); t_end = rtclock(); fprintf(stdout, "CPU Runtime: %0.6lfs\n", t_end - t_start); fail = compareResults(G, G_outputFromGpu); #endif free(A); free(B); free(C); free(D); free(E); free(F); free(G); free(G_outputFromGpu); return fail; }

GB_binop__isle_uint32.c

//------------------------------------------------------------------------------ // GB_binop: hard-coded functions for each built-in binary operator //------------------------------------------------------------------------------ // SuiteSparse:GraphBLAS, Timothy A. Davis, (c) 2017-2021, All Rights Reserved. // SPDX-License-Identifier: Apache-2.0 //------------------------------------------------------------------------------ // If this file is in the Generated2/ folder, do not edit it // (it is auto-generated from Generator/*). #include "GB.h" #ifndef GBCOMPACT #include "GB_emult.h" #include "GB_control.h" #include "GB_ek_slice.h" #include "GB_dense.h" #include "GB_atomics.h" #include "GB_bitmap_assign_methods.h" #include "GB_binop__include.h" // C=binop(A,B) is defined by the following types and operators: // A+B function (eWiseAdd): GB (_AaddB__isle_uint32) // A.*B function (eWiseMult): GB (_AemultB_08__isle_uint32) // A.*B function (eWiseMult): GB (_AemultB_02__isle_uint32) // A.*B function (eWiseMult): GB (_AemultB_04__isle_uint32) // A.*B function (eWiseMult): GB (_AemultB_bitmap__isle_uint32) // A*D function (colscale): GB (_AxD__isle_uint32) // D*A function (rowscale): GB (_DxB__isle_uint32) // C+=B function (dense accum): GB (_Cdense_accumB__isle_uint32) // C+=b function (dense accum): GB (_Cdense_accumb__isle_uint32) // C+=A+B function (dense ewise3): GB ((none)) // C=A+B function (dense ewise3): GB (_Cdense_ewise3_noaccum__isle_uint32) // C=scalar+B GB (_bind1st__isle_uint32) // C=scalar+B' GB (_bind1st_tran__isle_uint32) // C=A+scalar GB (_bind2nd__isle_uint32) // C=A'+scalar GB (_bind2nd_tran__isle_uint32) // C type: uint32_t // A type: uint32_t // A pattern? 0 // B type: uint32_t // B pattern? 0 // BinaryOp: cij = (aij <= bij) #define GB_ATYPE \ uint32_t #define GB_BTYPE \ uint32_t #define GB_CTYPE \ uint32_t // true if the types of A and B are identical #define GB_ATYPE_IS_BTYPE \ 1 // true if the types of C and A are identical #define GB_CTYPE_IS_ATYPE \ 1 // true if the types of C and B are identical #define GB_CTYPE_IS_BTYPE \ 1 // aij = Ax [pA] #define GB_GETA(aij,Ax,pA,A_iso) \ uint32_t aij = GBX (Ax, pA, A_iso) // true if values of A are not used #define GB_A_IS_PATTERN \ 0 \ // bij = Bx [pB] #define GB_GETB(bij,Bx,pB,B_iso) \ uint32_t bij = GBX (Bx, pB, B_iso) // true if values of B are not used #define GB_B_IS_PATTERN \ 0 \ // declare scalar of the same type as C #define GB_CTYPE_SCALAR(t) \ uint32_t t // cij = Ax [pA] #define GB_COPY_A_TO_C(cij,Ax,pA,A_iso) \ cij = GBX (Ax, pA, A_iso) // cij = Bx [pB] #define GB_COPY_B_TO_C(cij,Bx,pB,B_iso) \ cij = GBX (Bx, pB, B_iso) #define GB_CX(p) Cx [p] // binary operator #define GB_BINOP(z,x,y,i,j) \ z = (x <= y) ; // true if the binop must be flipped #define GB_BINOP_FLIP \ 0 // op is second #define GB_OP_IS_SECOND \ 0 // do the numerical phases of GB_add and GB_emult #define GB_PHASE_2_OF_2 // hard-coded loops can be vectorized #define GB_PRAGMA_SIMD_VECTORIZE GB_PRAGMA_SIMD // disable this operator and use the generic case if these conditions hold #define GB_DISABLE \ (GxB_NO_ISLE || GxB_NO_UINT32 || GxB_NO_ISLE_UINT32) //------------------------------------------------------------------------------ // C += A+B, all 3 matrices dense //------------------------------------------------------------------------------ #if 0 // The op must be MIN, MAX, PLUS, MINUS, RMINUS, TIMES, DIV, or RDIV. void GB ((none)) ( GrB_Matrix C, const GrB_Matrix A, const GrB_Matrix B, const int nthreads ) { #include "GB_dense_ewise3_accum_template.c" } #endif //------------------------------------------------------------------------------ // C = A+B, all 3 matrices dense //------------------------------------------------------------------------------ void GB (_Cdense_ewise3_noaccum__isle_uint32) ( GrB_Matrix C, const GrB_Matrix A, const GrB_Matrix B, const int nthreads ) { #include "GB_dense_ewise3_noaccum_template.c" } //------------------------------------------------------------------------------ // C += B, accumulate a sparse matrix into a dense matrix //------------------------------------------------------------------------------ GrB_Info GB (_Cdense_accumB__isle_uint32) ( GrB_Matrix C, const GrB_Matrix B, const int64_t *B_ek_slicing, const int B_ntasks, const int B_nthreads ) { #if GB_DISABLE return (GrB_NO_VALUE) ; #else { #include "GB_dense_subassign_23_template.c" } return (GrB_SUCCESS) ; #endif } //------------------------------------------------------------------------------ // C += b, accumulate a scalar into a dense matrix //------------------------------------------------------------------------------ GrB_Info GB (_Cdense_accumb__isle_uint32) ( GrB_Matrix C, const GB_void *p_bwork, const int nthreads ) { #if GB_DISABLE return (GrB_NO_VALUE) ; #else { // get the scalar b for C += b, of type uint32_t uint32_t bwork = (*((uint32_t *) p_bwork)) ; #include "GB_dense_subassign_22_template.c" return (GrB_SUCCESS) ; } return (GrB_SUCCESS) ; #endif } //------------------------------------------------------------------------------ // C = A*D, column scale with diagonal D matrix //------------------------------------------------------------------------------ GrB_Info GB (_AxD__isle_uint32) ( GrB_Matrix C, const GrB_Matrix A, const GrB_Matrix D, const int64_t *A_ek_slicing, const int A_ntasks, const int A_nthreads ) { #if GB_DISABLE return (GrB_NO_VALUE) ; #else uint32_t *restrict Cx = (uint32_t *) C->x ; #include "GB_AxB_colscale_template.c" return (GrB_SUCCESS) ; #endif } //------------------------------------------------------------------------------ // C = D*B, row scale with diagonal D matrix //------------------------------------------------------------------------------ GrB_Info GB (_DxB__isle_uint32) ( GrB_Matrix C, const GrB_Matrix D, const GrB_Matrix B, int nthreads ) { #if GB_DISABLE return (GrB_NO_VALUE) ; #else uint32_t *restrict Cx = (uint32_t *) C->x ; #include "GB_AxB_rowscale_template.c" return (GrB_SUCCESS) ; #endif } //------------------------------------------------------------------------------ // eWiseAdd: C=A+B, C<M>=A+B, C<!M>=A+B //------------------------------------------------------------------------------ GrB_Info GB (_AaddB__isle_uint32) ( GrB_Matrix C, const int C_sparsity, const GrB_Matrix M, const bool Mask_struct, const bool Mask_comp, const GrB_Matrix A, const GrB_Matrix B, const bool is_eWiseUnion, const GB_void *alpha_scalar_in, const GB_void *beta_scalar_in, const bool Ch_is_Mh, const int64_t *restrict C_to_M, const int64_t *restrict C_to_A, const int64_t *restrict C_to_B, const GB_task_struct *restrict TaskList, const int C_ntasks, const int C_nthreads, GB_Context Context ) { #if GB_DISABLE return (GrB_NO_VALUE) ; #else GB_WERK_DECLARE (M_ek_slicing, int64_t) ; GB_WERK_DECLARE (A_ek_slicing, int64_t) ; GB_WERK_DECLARE (B_ek_slicing, int64_t) ; uint32_t alpha_scalar ; uint32_t beta_scalar ; if (is_eWiseUnion) { alpha_scalar = (*((uint32_t *) alpha_scalar_in)) ; beta_scalar = (*((uint32_t *) beta_scalar_in )) ; } #include "GB_add_template.c" GB_FREE_WORKSPACE ; return (GrB_SUCCESS) ; #endif } //------------------------------------------------------------------------------ // eWiseMult: C=A.*B, C<M>=A.*B, or C<M!>=A.*B where C is sparse/hyper //------------------------------------------------------------------------------ GrB_Info GB (_AemultB_08__isle_uint32) ( GrB_Matrix C, const int C_sparsity, const int ewise_method, const GrB_Matrix M, const bool Mask_struct, const bool Mask_comp, const GrB_Matrix A, const GrB_Matrix B, const int64_t *restrict C_to_M, const int64_t *restrict C_to_A, const int64_t *restrict C_to_B, const GB_task_struct *restrict TaskList, const int C_ntasks, const int C_nthreads, GB_Context Context ) { #if GB_DISABLE return (GrB_NO_VALUE) ; #else #include "GB_emult_08_meta.c" return (GrB_SUCCESS) ; #endif } //------------------------------------------------------------------------------ // eWiseMult: C<#> = A.*B when A is sparse/hyper and B is bitmap/full //------------------------------------------------------------------------------ GrB_Info GB (_AemultB_02__isle_uint32) ( GrB_Matrix C, const GrB_Matrix M, const bool Mask_struct, const bool Mask_comp, const GrB_Matrix A, const GrB_Matrix B, const bool flipxy, const int64_t *restrict Cp_kfirst, const int64_t *A_ek_slicing, const int A_ntasks, const int A_nthreads ) { #if GB_DISABLE return (GrB_NO_VALUE) ; #else #if GB_BINOP_FLIP // The operator is not commutative, and does not have a flipped // variant. For example z=atan2(y,x). if (flipxy) { // use fmult(y,x) #undef GB_FLIPPED #define GB_FLIPPED 1 #include "GB_emult_02_template.c" } else { // use fmult(x,y) #undef GB_FLIPPED #define GB_FLIPPED 0 #include "GB_emult_02_template.c" } #else // No need to handle the flip: the operator is either commutative, or // has been handled by changing z=div(y,x) to z=rdiv(x,y) for example. #undef GB_FLIPPED #define GB_FLIPPED 0 #include "GB_emult_02_template.c" #endif return (GrB_SUCCESS) ; #endif } //------------------------------------------------------------------------------ // eWiseMult: C<M> = A.*B, M sparse/hyper, A and B bitmap/full //------------------------------------------------------------------------------ GrB_Info GB (_AemultB_04__isle_uint32) ( GrB_Matrix C, const GrB_Matrix M, const bool Mask_struct, const GrB_Matrix A, const GrB_Matrix B, const int64_t *restrict Cp_kfirst, const int64_t *M_ek_slicing, const int M_ntasks, const int M_nthreads ) { #if GB_DISABLE return (GrB_NO_VALUE) ; #else #include "GB_emult_04_template.c" return (GrB_SUCCESS) ; #endif } //------------------------------------------------------------------------------ // eWiseMult: C=A.*B, C<M>=A.*B, C<!M>=A.*B where C is bitmap //------------------------------------------------------------------------------ GrB_Info GB (_AemultB_bitmap__isle_uint32) ( GrB_Matrix C, const int ewise_method, const GrB_Matrix M, const bool Mask_struct, const bool Mask_comp, const GrB_Matrix A, const GrB_Matrix B, const int64_t *M_ek_slicing, const int M_ntasks, const int M_nthreads, const int C_nthreads, GB_Context Context ) { #if GB_DISABLE return (GrB_NO_VALUE) ; #else #include "GB_bitmap_emult_template.c" return (GrB_SUCCESS) ; #endif } //------------------------------------------------------------------------------ // Cx = op (x,Bx): apply a binary operator to a matrix with scalar bind1st //------------------------------------------------------------------------------ GrB_Info GB (_bind1st__isle_uint32) ( GB_void *Cx_output, // Cx and Bx may be aliased const GB_void *x_input, const GB_void *Bx_input, const int8_t *restrict Bb, int64_t bnz, int nthreads ) { #if GB_DISABLE return (GrB_NO_VALUE) ; #else uint32_t *Cx = (uint32_t *) Cx_output ; uint32_t x = (*((uint32_t *) x_input)) ; uint32_t *Bx = (uint32_t *) Bx_input ; int64_t p ; #pragma omp parallel for num_threads(nthreads) schedule(static) for (p = 0 ; p < bnz ; p++) { if (!GBB (Bb, p)) continue ; uint32_t bij = GBX (Bx, p, false) ; Cx [p] = (x <= bij) ; } return (GrB_SUCCESS) ; #endif } //------------------------------------------------------------------------------ // Cx = op (Ax,y): apply a binary operator to a matrix with scalar bind2nd //------------------------------------------------------------------------------ GrB_Info GB (_bind2nd__isle_uint32) ( GB_void *Cx_output, // Cx and Ax may be aliased const GB_void *Ax_input, const GB_void *y_input, const int8_t *restrict Ab, int64_t anz, int nthreads ) { #if GB_DISABLE return (GrB_NO_VALUE) ; #else int64_t p ; uint32_t *Cx = (uint32_t *) Cx_output ; uint32_t *Ax = (uint32_t *) Ax_input ; uint32_t y = (*((uint32_t *) y_input)) ; #pragma omp parallel for num_threads(nthreads) schedule(static) for (p = 0 ; p < anz ; p++) { if (!GBB (Ab, p)) continue ; uint32_t aij = GBX (Ax, p, false) ; Cx [p] = (aij <= y) ; } return (GrB_SUCCESS) ; #endif } //------------------------------------------------------------------------------ // C = op (x, A'): transpose and apply a binary operator //------------------------------------------------------------------------------ // cij = op (x, aij), no typecasting (in spite of the macro name) #undef GB_CAST_OP #define GB_CAST_OP(pC,pA) \ { \ uint32_t aij = GBX (Ax, pA, false) ; \ Cx [pC] = (x <= aij) ; \ } GrB_Info GB (_bind1st_tran__isle_uint32) ( GrB_Matrix C, const GB_void *x_input, const GrB_Matrix A, int64_t *restrict *Workspaces, const int64_t *restrict A_slice, int nworkspaces, int nthreads ) { // GB_unop_transpose.c uses GB_ATYPE, but A is // the 2nd input to binary operator z=f(x,y). #undef GB_ATYPE #define GB_ATYPE \ uint32_t #if GB_DISABLE return (GrB_NO_VALUE) ; #else uint32_t x = (*((const uint32_t *) x_input)) ; #include "GB_unop_transpose.c" return (GrB_SUCCESS) ; #endif #undef GB_ATYPE #define GB_ATYPE \ uint32_t } //------------------------------------------------------------------------------ // C = op (A', y): transpose and apply a binary operator //------------------------------------------------------------------------------ // cij = op (aij, y), no typecasting (in spite of the macro name) #undef GB_CAST_OP #define GB_CAST_OP(pC,pA) \ { \ uint32_t aij = GBX (Ax, pA, false) ; \ Cx [pC] = (aij <= y) ; \ } GrB_Info GB (_bind2nd_tran__isle_uint32) ( GrB_Matrix C, const GrB_Matrix A, const GB_void *y_input, int64_t *restrict *Workspaces, const int64_t *restrict A_slice, int nworkspaces, int nthreads ) { #if GB_DISABLE return (GrB_NO_VALUE) ; #else uint32_t y = (*((const uint32_t *) y_input)) ; #include "GB_unop_transpose.c" return (GrB_SUCCESS) ; #endif } #endif

sgeswp.c

/** * * @file * * PLASMA is a software package provided by: * University of Tennessee, US, * University of Manchester, UK. * * @generated from /home/luszczek/workspace/plasma/bitbucket/plasma/compute/zgeswp.c, normal z -> s, Fri Sep 28 17:38:05 2018 * **/ #include "plasma.h" #include "plasma_async.h" #include "plasma_context.h" #include "plasma_descriptor.h" #include "plasma_internal.h" #include "plasma_tuning.h" #include "plasma_types.h" /******************************************************************************/ int plasma_sgeswp(plasma_enum_t colrow, int m, int n, float *pA, int lda, int *ipiv, int incx) { // Get PLASMA context. plasma_context_t *plasma = plasma_context_self(); if (plasma == NULL) { plasma_error("PLASMA not initialized"); return PlasmaErrorNotInitialized; } // Check input arguments. if ((colrow != PlasmaColumnwise) && (colrow != PlasmaRowwise)) { plasma_error("illegal value of colrow"); return -1; } if (m < 0) { plasma_error("illegal value of m"); return -2; } if (n < 0) { plasma_error("illegal value of n"); return -3; } if (lda < imax(1, m)) { plasma_error("illegal value of lda"); return -5; } // quick return if (imin(n, m) == 0) return PlasmaSuccess; // Tune parameters. if (plasma->tuning) plasma_tune_geswp(plasma, PlasmaRealFloat, m, n); // Set tiling parameters. int nb = plasma->nb; // Create tile matrices. plasma_desc_t A; int retval; retval = plasma_desc_general_create(PlasmaRealFloat, nb, nb, m, n, 0, 0, m, n, &A); if (retval != PlasmaSuccess) { plasma_error("plasma_general_desc_create() failed"); return retval; } // Initialize sequence. plasma_sequence_t sequence; retval = plasma_sequence_init(&sequence); // Initialize request. plasma_request_t request; retval = plasma_request_init(&request); // asynchronous block #pragma omp parallel #pragma omp master { // Translate to tile layout. plasma_omp_sge2desc(pA, lda, A, &sequence, &request); // Call tile async function. plasma_omp_sgeswp(colrow, A, ipiv, incx, &sequence, &request); // Translate back to LAPACK layout. plasma_omp_sdesc2ge(A, pA, lda, &sequence, &request); } // implicit synchronization // Free matrices in tile layout. plasma_desc_destroy(&A); // Return status. int status = sequence.status; return status; } /******************************************************************************/ void plasma_omp_sgeswp(plasma_enum_t colrow, plasma_desc_t A, int *ipiv, int incx, plasma_sequence_t *sequence, plasma_request_t *request) { // Get PLASMA context. plasma_context_t *plasma = plasma_context_self(); if (plasma == NULL) { plasma_error("PLASMA not initialized"); plasma_request_fail(sequence, request, PlasmaErrorIllegalValue); return; } // Check input arguments. if ((colrow != PlasmaColumnwise) && (colrow != PlasmaRowwise)) { plasma_error("illegal value of colrow"); plasma_request_fail(sequence, request, PlasmaErrorIllegalValue); return; } if (plasma_desc_check(A) != PlasmaSuccess) { plasma_error("invalid A"); plasma_request_fail(sequence, request, PlasmaErrorIllegalValue); return; } if (sequence == NULL) { plasma_error("NULL sequence"); plasma_request_fail(sequence, request, PlasmaErrorIllegalValue); return; } if (request == NULL) { plasma_error("NULL request"); plasma_request_fail(sequence, request, PlasmaErrorIllegalValue); return; } // quick return if (imin(A.m, A.n) == 0) return; // Call the parallel function. plasma_psgeswp(colrow, A, ipiv, incx, sequence, request); }

lloyds_par16.c

#include <stdio.h> #include <stdlib.h> #include <math.h> #include <time.h> #include <stdbool.h> #include <omp.h> #include "csvparser.h" void vector_init(double *a, int length) { for (int i = 0; i < length; i++) { a[i] = 0; } } void vector_copy(double *dst, double *src, int length) { for (int i = 0; i < length; i++) { dst[i] = src[i]; } } void vector_add(double *dst, double *a, double *b, int length) { for (int i = 0; i < length; i++) { dst[i] = a[i] + b[i]; } } void vector_elementwise_avg(double *dst, double *a, int denominator, int length) { for (int i = 0; i < length; i++) { dst[i] = a[i] / denominator; } } // Program should take K, a data set (.csv), a delimiter, // a binary flag data_contains_header, and a binary flag to drop labels int main(int argc, char *argv[]){ // Seed for consistent cluster center selection // In a working implementation, seeding would be variable (e.g. time(NULL)) srand(111); CsvParser *reader; CsvRow *row; int i,j; if(argc < 6){ printf("Incorrect number of args. Should be 5, received %d\n", argc - 1); exit(1); } int K = atoi(argv[1]); char *data_fp = argv[2]; char *delimiter = argv[3]; int has_header_row = atoi(argv[4]); int drop_labels = atoi(argv[5]); // Take in data set reader = CsvParser_new(data_fp, delimiter, has_header_row); // Get number of columns row = CsvParser_getRow(reader); int num_cols = CsvParser_getNumFields(row); CsvParser_destroy_row(row); if (drop_labels){ num_cols--; } // Get number of rows like lazy people int num_rows = 1; while ((row = CsvParser_getRow(reader))){ num_rows++; CsvParser_destroy_row(row); } // Torch the CsvParser and start again so we can read data in. CsvParser_destroy(reader); reader = CsvParser_new(data_fp, delimiter, has_header_row); double **data_matrix = malloc(num_rows * sizeof(double *)); for (int i = 0; i < num_rows; i++) { data_matrix[i] = malloc(num_cols * sizeof(double)); } int row_index = 0; while ((row = CsvParser_getRow(reader))){ const char **row_fields = CsvParser_getFields(row); for (int col_index = 0; col_index < num_cols; col_index++) { data_matrix[row_index][col_index] = atof(row_fields[col_index]); } CsvParser_destroy_row(row); row_index++; } CsvParser_destroy(reader); // Initialize some cluster centers from random rows in our data // Given the fact that we will usually have way more rows than centers, we can // probably just roll a number and reroll if we already rolled it. Collisions // should be relatively infrequent bool collided; double centers[K][num_cols]; if (argc == 7) { int center_indices[3] = {12, 67, 106}; for (i = 0; i < K; i ++) { vector_copy(centers[i], data_matrix[center_indices[i]], num_cols); } } else { for (i = 0; i < K; i++) { int center_indices[K]; collided = true; while (collided) { center_indices[i] = rand() % num_rows; collided = false; for (j = 0; j < i; j++) { if (center_indices[j] == center_indices[i]) { collided = true; break; } } vector_copy(centers[i], data_matrix[center_indices[i]], num_cols); } } } printf("Initial cluster centers:\n"); for (int i = 0; i < K; i++) { for (int j = 0; j < num_cols; j++) { printf("%f ", centers[i][j]); } printf("\n"); } printf("\n"); int num_iterations = 0; int *clusterings = calloc(num_rows, sizeof(int)); bool changes; double tstart = omp_get_wtime(); while (1) { // Assign points to cluster centers changes = false; omp_set_num_threads(16); int center, observation, new_center, col; double idx_diff, current_diff, best_diff; #pragma omp parallel for \ private(center, observation, idx_diff, current_diff, best_diff, new_center, col) \ shared(num_rows, K, data_matrix, centers) for (observation = 0; observation < num_rows; observation++) { best_diff = INFINITY; for (center = 0; center < K; center++) { current_diff = 0; for (col = 0; col < num_cols; col++) { idx_diff = data_matrix[observation][col] - centers[center][col]; current_diff += idx_diff * idx_diff; } if (current_diff < best_diff) { best_diff = current_diff; new_center = center; } } if (clusterings[observation] != new_center) { // NOTE: There is an acceptable data race on changes. Threads only ever // set it to true; lost updates are inconsequential. No need to slow // things down for safety. changes = true; clusterings[observation] = new_center; } } // If we didn't change any cluster assignments, we're at convergence if (!changes) { break; } num_iterations++; // Find cluster means and reassign centers int cluster_index, element, elements_in_cluster; double cluster_means[num_cols]; #pragma omp parallel for \ private(cluster_index, element, elements_in_cluster, cluster_means) \ shared(num_rows, clusterings, data_matrix, K) for (cluster_index = 0; cluster_index < K; cluster_index++) { elements_in_cluster = 0; vector_init(cluster_means, num_cols); // Aggregate in-cluster values we can use to take the clusterings mean for (element = 0; element < num_rows; element++) { if (clusterings[element] == cluster_index) { vector_add(cluster_means, cluster_means, data_matrix[element], num_cols); elements_in_cluster++; } } // Finish calculating cluster mean, and overwrite centers with the new value vector_elementwise_avg(cluster_means, cluster_means, elements_in_cluster, num_cols); vector_copy(centers[cluster_index], cluster_means, num_cols); } } double tend = omp_get_wtime(); printf("\nFinal cluster centers:\n"); for (int i = 0; i < K; i++) { for (int j = 0; j < num_cols; j++) { printf("%f ", centers[i][j]); } printf("\n"); } printf("\nNum iterations: %d\n", num_iterations); printf("Time taken for %d clusters: %f seconds\n", K, tend - tstart); for (int i = 0; i < num_rows; i++) { free(data_matrix[i]); } free(data_matrix); free(clusterings); exit(0); }

ChMatrix.h

// ============================================================================= // PROJECT CHRONO - http://projectchrono.org // // Copyright (c) 2014 projectchrono.org // All rights reserved. // // Use of this source code is governed by a BSD-style license that can be found // in the LICENSE file at the top level of the distribution and at // http://projectchrono.org/license-chrono.txt. // // ============================================================================= // Authors: Alessandro Tasora, Radu Serban // ============================================================================= #ifndef CHMATRIX_H #define CHMATRIX_H #include <immintrin.h> #include "chrono/core/ChCoordsys.h" #include "chrono/core/ChException.h" #include "chrono/ChConfig.h" #include "chrono/serialization/ChArchive.h" #include "chrono/serialization/ChArchiveAsciiDump.h" namespace chrono { // // FAST MACROS TO SPEEDUP CODE // #define Set33Element(a, b, val) SetElementN(((a * 3) + (b)), val) #define Get33Element(a, b) GetElementN((a * 3) + (b)) #define Set34Element(a, b, val) SetElementN(((a * 4) + (b)), val) #define Get34Element(a, b) GetElementN((a * 4) + (b)) #define Set34Row(ma, a, val0, val1, val2, val3) \ ma.SetElementN((a * 4), val0); \ ma.SetElementN((a * 4) + 1, val1); \ ma.SetElementN((a * 4) + 2, val2); \ ma.SetElementN((a * 4) + 3, val3); #define Set44Element(a, b, val) SetElementN(((a * 4) + (b)), val) #define Get44Element(a, b) GetElementN((a * 4) + (b)) // forward declaration template <class Real = double> class ChMatrixDynamic; /// /// ChMatrix: /// /// A base class for matrix objects (tables of NxM numbers). /// To access elements, the indexes start from zero, and /// you must indicate first row, then column, that is: m(2,4) /// means the element at 3rd row, 5th column. /// This is an abstract class, so you cannot instantiate /// objects from it: you must rather create matrices using the /// specialized child classes like ChMatrixDynamic, ChMatrixNM, /// ChMatrix33 and so on; all of them have this same base class. /// Warning: for optimization reasons, not all functions will /// check about boundaries of element indexes and matrix sizes (in /// some cases, if sizes are wrong, debug asserts are used). /// /// Further info at the @ref mathematical_objects manual page. template <class Real = double> class ChMatrix { protected: // // DATA // int rows; int columns; Real* address; public: // // CONSTRUCTORS (none - abstract class that must be implemented with child classes) // virtual ~ChMatrix() {} // // OPERATORS OVERLOADING // /// Parenthesis () operator, to access a single element of the matrix, by /// supplying the row and the column (indexes start from 0). /// For example: m(3,5) gets the element at the 4th row, 6th column. /// Value is returned by reference, so it can be modified, like in m(1,2)=10. Real& operator()(const int row, const int col) { assert(row >= 0 && col >= 0 && row < rows && col < columns); return (*(address + col + (row * columns))); } const Real& operator()(const int row, const int col) const { assert(row >= 0 && col >= 0 && row < rows && col < columns); return (*(address + col + (row * columns))); } /// Parenthesis () operator, to access a single element of the matrix, by /// supplying the ordinal of the element (indexes start from 0). /// For example: m(3) gets the 4th element, counting row by row. /// Mostly useful if the matrix is Nx1 sized (i.e. a N-element vector). /// Value is returned by reference, so it can be modified, like in m(1,2)=10. Real& operator()(const int el) { assert(el >= 0 && el < rows * columns); return (*(address + el)); } const Real& operator()(const int el) const { assert(el >= 0 && el < rows * columns); return (*(address + el)); } /// The [] operator returns the address of the n-th row. This is mostly /// for compatibility with old matrix programming styles (2d array-like) /// where to access an element at row i, column j, one can write mymatrix[i][j]. Real* operator[](const int row) { assert(row >= 0 && row < rows); return ((address + (row * columns))); } const Real* operator[](const int row) const { assert(row >= 0 && row < rows); return ((address + (row * columns))); } /// Multiplies this matrix by a factor, in place ChMatrix<Real>& operator*=(const Real factor) { MatrScale(factor); return *this; } /// Increments this matrix by another matrix, in place template <class RealB> ChMatrix<Real>& operator+=(const ChMatrix<RealB>& matbis) { MatrInc(matbis); return *this; } /// Decrements this matrix by another matrix, in place template <class RealB> ChMatrix<Real>& operator-=(const ChMatrix<RealB>& matbis) { MatrDec(matbis); return *this; } /// Matrices are equal? bool operator==(const ChMatrix<Real>& other) { return Equals(other); } /// Matrices are not equal? bool operator!=(const ChMatrix<Real>& other) { return !Equals(other); } /// Assignment operator ChMatrix<Real>& operator=(const ChMatrix<Real>& matbis) { if (&matbis != this) CopyFromMatrix(matbis); return *this; } template <class RealB> ChMatrix<Real>& operator=(const ChMatrix<RealB>& matbis) { CopyFromMatrix(matbis); return *this; } // // FUNCTIONS // /// Sets the element at row,col position. Indexes start with zero. void SetElement(int row, int col, Real elem) { assert(row >= 0 && col >= 0 && row < rows && col < columns); // boundary checks *(address + col + (row * columns)) = elem; } /// Gets the element at row,col position. Indexes start with zero. /// The return value is a copy of original value. Use Element() instead if you /// want to access directly by reference the original element. Real GetElement(int row, int col) { assert(row >= 0 && col >= 0 && row < rows && col < columns); // boundary checks return (*(address + col + (row * columns))); } Real GetElement(int row, int col) const { assert(row >= 0 && col >= 0 && row < rows && col < columns); // boundary checks return (*(address + col + (row * columns))); } /// Sets the Nth element, counting row after row. void SetElementN(int index, Real elem) { assert(index >= 0 && index < (rows * columns)); // boundary checks *(address + index) = elem; } /// Gets the Nth element, counting row after row. Real GetElementN(int index) { assert(index >= 0 && index < (rows * columns)); return (*(address + index)); } const Real GetElementN(int index) const { assert(index >= 0 && index < (rows * columns)); return (*(address + index)); } /// Access a single element of the matrix, by /// supplying the row and the column (indexes start from 0). /// Value is returned by reference, so it can be modified, like in m.Element(1,2)=10. Real& Element(int row, int col) { assert(row >= 0 && col >= 0 && row < rows && col < columns); return (*(address + col + (row * columns))); } const Real& Element(int row, int col) const { assert(row >= 0 && col >= 0 && row < rows && col < columns); return (*(address + col + (row * columns))); } /// Access a single element of the matrix, the Nth element, counting row after row. /// Value is returned by reference, so it can be modified, like in m.Element(5)=10. Real& ElementN(int index) { assert(index >= 0 && index < (rows * columns)); return (*(address + index)); } const Real& ElementN(int index) const { assert(index >= 0 && index < (rows * columns)); return (*(address + index)); } /// Access directly the "Real* address" buffer. Warning! this is a low level /// function, it should be used in rare cases, if really needed! Real* GetAddress() { return address; } const Real* GetAddress() const { return address; } /// Gets the number of rows int GetRows() const { return rows; } /// Gets the number of columns int GetColumns() const { return columns; } /// Reallocate memory for a new size. VIRTUAL! Must be implemented by child classes! virtual void Resize(int nrows, int ncols) {} /// Swaps the columns a and b void SwapColumns(int a, int b) { Real temp; for (int i = 0; i < rows; i++) { temp = GetElement(i, a); SetElement(i, a, GetElement(i, b)); SetElement(i, b, temp); } } /// Swap the rows a and b void SwapRows(int a, int b) { Real temp; for (int i = 0; i < columns; i++) { temp = GetElement(a, i); SetElement(a, i, GetElement(b, i)); SetElement(b, i, temp); } } /// Fill the diagonal elements, given a sample. /// Note that the matrix must already be square (no check for /// rectangular matrices!), and the extra-diagonal elements are /// not modified -this function does not set them to 0- void FillDiag(Real sample) { for (int i = 0; i < rows; ++i) SetElement(i, i, sample); } /// Fill the matrix with the same value in all elements void FillElem(Real sample) { for (int i = 0; i < rows * columns; ++i) SetElementN(i, sample); } /// Fill the matrix with random float numbers, falling within the /// "max"/"min" range. void FillRandom(Real max, Real min) { for (int i = 0; i < rows * columns; ++i) SetElementN(i, min + (Real)ChRandom() * (max - min)); } /// Resets the matrix to zero (warning: simply sets memory to 0 bytes!) void Reset() { // SetZero(rows*columns); //memset(address, 0, sizeof(Real) * rows * columns); for (int i = 0; i < rows * columns; ++i) this->address[i] = 0; } /// Reset to zeroes and (if needed) changes the size to have row and col void Reset(int nrows, int ncols) { Resize(nrows, ncols); // SetZero(rows*columns); //memset(address, 0, sizeof(Real) * rows * columns); for (int i = 0; i < rows * columns; ++i) this->address[i] = 0; } /// Reset to identity matrix (ones on diagonal, zero elsewhere) void SetIdentity() { Reset(); FillDiag(1.0); } /// Copy a matrix "matra" into this matrix. Note that /// the destination matrix will be resized if necessary. template <class RealB> void CopyFromMatrix(const ChMatrix<RealB>& matra) { Resize(matra.GetRows(), matra.GetColumns()); // ElementsCopy(address, matra.GetAddress(), rows*columns); // memcpy (address, matra.address, (sizeof(Real) * rows * columns)); for (int i = 0; i < rows * columns; ++i) address[i] = (Real)matra.GetAddress()[i]; } /// Copy the transpose of matrix "matra" into this matrix. Note that /// the destination matrix will be resized if necessary. template <class RealB> void CopyFromMatrixT(const ChMatrix<RealB>& matra) { Resize(matra.GetColumns(), matra.GetRows()); for (int i = 0; i < matra.GetRows(); ++i) for (int j = 0; j < matra.GetColumns(); ++j) SetElement(j, i, (Real)matra.Element(i, j)); } /// Copy the transposed upper triangular part of "matra" in the lower triangular /// part of this matrix. (matra must be square) /// Note that the destination matrix will be resized if necessary. template <class RealB> // _______ // void CopyTUpMatrix(const ChMatrix<RealB>& matra) // \ | |\ // { // \ A'| ---> | \ // Resize(matra.GetRows(), matra.GetColumns()); // \ | |this\ // for (int i = 0; i < matra.GetRows(); i++) { // \| |______\ // for (int j = 0; j < matra.GetRows(); j++) SetElement(j, i, (Real)matra.GetElement(i, j)); } } /// Copy the transposed lower triangulat part of "matra" in the upper triangular /// part of this matrix. (matra must be square) /// Note that the destination matrix will be resized if necessary. template <class RealB> // _______ // void CopyTLwMatrix(const ChMatrix<RealB>& matra) // |\ \ | // { // | \ ---> \this| // Resize(matra.GetRows(), matra.GetColumns()); // |A' \ \ | // for (int i = 0; i < matra.GetRows(); i++) { // |______\ \| // for (int j = 0; j < matra.GetRows(); j++) SetElement(i, j, (Real)matra.GetElement(j, i)); } } // // STREAMING // /// Method to allow serialization of transient data in archives. virtual void ArchiveOUT(ChArchiveOut& marchive) { // suggested: use versioning marchive.VersionWrite(1); // stream out all member data marchive << make_ChNameValue("rows", rows); marchive << make_ChNameValue("columns", columns); // custom output of matrix data as array if (ChArchiveAsciiDump* mascii = dynamic_cast<ChArchiveAsciiDump*>(&marchive)) { // CUSTOM row x col 'intuitive' table-like log when using ChArchiveAsciiDump: for (int i = 0; i < rows; i++) { mascii->indent(); for (int j = 0; j < columns; j++) { mascii->GetStream()->operator<<(Element(i, j)); mascii->GetStream()->operator<<(", "); } mascii->GetStream()->operator<<("\n"); } } else { // NORMAL array-based serialization: int tot_elements = GetRows() * GetColumns(); marchive.out_array_pre("data", tot_elements, typeid(Real).name()); for (int i = 0; i < tot_elements; i++) { marchive << CHNVP(ElementN(i), ""); marchive.out_array_between(tot_elements, typeid(Real).name()); } marchive.out_array_end(tot_elements, typeid(Real).name()); } } /// Method to allow de serialization of transient data from archives. virtual void ArchiveIN(ChArchiveIn& marchive) { // suggested: use versioning int version = marchive.VersionRead(); // stream in all member data int m_row, m_col; marchive >> make_ChNameValue("rows", m_row); marchive >> make_ChNameValue("columns", m_col); Reset(m_row, m_col); // custom input of matrix data as array size_t tot_elements = GetRows() * GetColumns(); marchive.in_array_pre("data", tot_elements); for (int i = 0; i < tot_elements; i++) { marchive >> CHNVP(ElementN(i)); marchive.in_array_between("data"); } marchive.in_array_end("data"); } /// Method to allow serializing transient data into in ascii /// as a readable item, for example "chrono::GetLog() << myobject;" /// ***OBSOLETE*** void StreamOUT(ChStreamOutAscii& mstream) { mstream << "\n" << "Matrix " << GetRows() << " rows, " << GetColumns() << " columns." << "\n"; for (int i = 0; i < ChMin(GetRows(), 8); i++) { for (int j = 0; j < ChMin(GetColumns(), 8); j++) mstream << GetElement(i, j) << " "; if (GetColumns() > 8) mstream << "..."; mstream << "\n"; } if (GetRows() > 8) mstream << "... \n\n"; } /// Method to allow serializing transient data into an ascii stream (ex. a file) /// as a Matlab .dat file (all numbers in a row, separated by space, then CR) void StreamOUTdenseMatlabFormat(ChStreamOutAscii& mstream) { for (int ii = 0; ii < this->GetRows(); ii++) { for (int jj = 0; jj < this->GetColumns(); jj++) { mstream << this->GetElement(ii, jj); if (jj < (this->GetColumns() - 1)) mstream << " "; } mstream << "\n"; } } // // MATH MEMBER FUNCTIONS. // For speed reasons, sometimes size checking of operands is left to the user! // /// Changes the sign of all the elements of this matrix, in place. void MatrNeg() { for (int nel = 0; nel < rows * columns; ++nel) ElementN(nel) = -ElementN(nel); } /// Sum two matrices, and stores the result in "this" matrix: [this]=[A]+[B]. template <class RealB, class RealC> void MatrAdd(const ChMatrix<RealB>& matra, const ChMatrix<RealC>& matrb) { assert(matra.GetColumns() == matrb.GetColumns() && matra.rows == matrb.GetRows()); assert(this->columns == matrb.GetColumns() && this->rows == matrb.GetRows()); for (int nel = 0; nel < rows * columns; ++nel) ElementN(nel) = (Real)(matra.ElementN(nel) + matrb.ElementN(nel)); } /// Subtract two matrices, and stores the result in "this" matrix: [this]=[A]-[B]. template <class RealB, class RealC> void MatrSub(const ChMatrix<RealB>& matra, const ChMatrix<RealC>& matrb) { assert(matra.GetColumns() == matrb.GetColumns() && matra.rows == matrb.GetRows()); assert(this->columns == matrb.GetColumns() && this->rows == matrb.GetRows()); for (int nel = 0; nel < rows * columns; ++nel) ElementN(nel) = (Real)(matra.ElementN(nel) - matrb.ElementN(nel)); } /// Increments this matrix with another matrix A, as: [this]+=[A] template <class RealB> void MatrInc(const ChMatrix<RealB>& matra) { assert(matra.GetColumns() == columns && matra.GetRows() == rows); for (int nel = 0; nel < rows * columns; ++nel) ElementN(nel) += (Real)matra.ElementN(nel); } /// Decrements this matrix with another matrix A, as: [this]-=[A] template <class RealB> void MatrDec(const ChMatrix<RealB>& matra) { assert(matra.GetColumns() == columns && matra.GetRows() == rows); for (int nel = 0; nel < rows * columns; ++nel) ElementN(nel) -= (Real)matra.ElementN(nel); } /// Scales a matrix, multiplying all elements by a constant value: [this]*=f void MatrScale(Real factor) { for (int nel = 0; nel < rows * columns; ++nel) ElementN(nel) *= factor; } /// Scales a matrix, multiplying all element by all oter elements of /// matra (it is not the classical matrix multiplication!) template <class RealB> void MatrScale(const ChMatrix<RealB>& matra) { assert(matra.GetColumns() == columns && matra.GetRows() == rows); for (int nel = 0; nel < rows * columns; ++nel) ElementN(nel) *= (Real)matra.ElementN(nel); } /// Scales a matrix, dividing all elements by a constant value: [this]/=f void MatrDivScale(Real factor) { for (int nel = 0; nel < rows * columns; ++nel) ElementN(nel) /= factor; } /// Scales a matrix, dividing all element by all oter elements of /// matra (it is not the classical matrix multiplication!) template <class RealB> void MatrDivScale(const ChMatrix<RealB>& matra) { assert(matra.GetColumns() == columns && matra.GetRows() == rows); for (int nel = 0; nel < rows * columns; ++nel) ElementN(nel) /= (Real)matra.ElementN(nel); } /// Multiplies two matrices, and stores the result in "this" matrix: [this]=[A]*[B]. template <class RealB, class RealC> void MatrMultiply(const ChMatrix<RealB>& matra, const ChMatrix<RealC>& matrb) { assert(matra.GetColumns() == matrb.GetRows()); assert(this->rows == matra.GetRows()); assert(this->columns == matrb.GetColumns()); int col, row, colres; Real sum; for (colres = 0; colres < matrb.GetColumns(); ++colres) { for (row = 0; row < matra.GetRows(); ++row) { sum = 0; for (col = 0; col < matra.GetColumns(); ++col) sum += (Real)(matra.Element(row, col) * matrb.Element(col, colres)); SetElement(row, colres, sum); } } } #ifdef CHRONO_HAS_AVX /// Multiplies two matrices, and stores the result in "this" matrix: [this]=[A]*[B]. /// AVX implementation: The speed up is marginal if size of the matrices are small, e.g. 3*3 /// Generally, as the matra.GetColumns() increases the method performs better void MatrMultiplyAVX(const ChMatrix<double>& matra, const ChMatrix<double>& matrb) { assert(matra.GetColumns() == matrb.GetRows()); assert(this->rows == matra.GetRows()); assert(this->columns == matrb.GetColumns()); int A_Nrow = matra.GetRows(); int B_Nrow = matrb.GetRows(); int A_NCol = matra.GetColumns(); int B_NCol = matrb.GetColumns(); const double* A_add = matra.GetAddress(); const double* B_add = matrb.GetAddress(); double* this_Add = this->GetAddress(); for (int rowA = 0; rowA < A_Nrow; rowA++) { for (int colB = 0; colB < B_NCol; colB += 4) { __m256d sum = _mm256_setzero_pd(); for (int elem = 0; elem < A_NCol; elem++) { __m256d ymmA = _mm256_broadcast_sd(A_add + A_NCol * rowA + elem); __m256d ymmB = _mm256_loadu_pd(B_add + elem * B_NCol + colB); __m256d prod = _mm256_mul_pd(ymmA, ymmB); sum = _mm256_add_pd(sum, prod); } _mm256_storeu_pd(this_Add + rowA * B_NCol + colB, sum); } } } /// Multiplies two matrices (the second is considered transposed): [this]=[A]*[B]' /// Note: This method is faster than MatrMultiplyT if matra.GetColumns()%4=0 && matra.GetColumns()>8 /// It is still fast if matra.GetColumns() is large enough even if matra.GetColumns()%4!=0 void MatrMultiplyTAVX(const ChMatrix<double>& matra, const ChMatrix<double>& matrb) { assert(matra.GetColumns() == matrb.GetColumns()); assert(this->GetRows() == matra.GetRows()); assert(this->GetColumns() == matrb.GetRows()); int A_Nrow = matra.GetRows(); int B_Nrow = matrb.GetRows(); int A_NCol = matra.GetColumns(); int B_NCol = matrb.GetColumns(); const double* A_add = matra.GetAddress(); const double* B_add = matrb.GetAddress(); bool NeedsPadding = (B_NCol % 4 != 0); int CorrectFAT = ((B_NCol >> 2) << 2); for (int rowA = 0; rowA < A_Nrow; rowA++) { for (int rowB = 0; rowB < B_Nrow; rowB++) { int colB; double temp_sum = 0.0; __m256d sum = _mm256_setzero_pd(); for (colB = 0; colB < CorrectFAT; colB += 4) { __m256d ymmA = _mm256_loadu_pd(A_add + rowA * A_NCol + colB); __m256d ymmB = _mm256_loadu_pd(B_add + rowB * B_NCol + colB); __m256d prod = _mm256_mul_pd(ymmA, ymmB); sum = _mm256_add_pd(sum, prod); } sum = _mm256_hadd_pd(sum, sum); temp_sum = ((double*)&sum)[0] + ((double*)&sum)[2]; if (NeedsPadding) for (colB = CorrectFAT; colB < B_NCol; colB++) { temp_sum += (matra.Element(rowA, colB) * matrb.Element(rowB, colB)); } SetElement(rowA, rowB, temp_sum); } } } #endif /// Multiplies two matrices (the second is considered transposed): [this]=[A]*[B]' /// Faster than doing B.MatrTranspose(); result.MatrMultiply(A,B); /// Note: no check on mistaken size of this! template <class RealB, class RealC> void MatrMultiplyT(const ChMatrix<RealB>& matra, const ChMatrix<RealC>& matrb) { assert(matra.GetColumns() == matrb.GetColumns()); assert(this->rows == matra.GetRows()); assert(this->columns == matrb.GetRows()); int col, row, colres; Real sum; for (colres = 0; colres < matrb.GetRows(); ++colres) { for (row = 0; row < matra.GetRows(); ++row) { sum = 0; for (col = 0; col < matra.GetColumns(); ++col) sum += (Real)(matra.Element(row, col) * matrb.Element(colres, col)); SetElement(row, colres, sum); } } } /// Multiplies two matrices (the first is considered transposed): [this]=[A]'*[B] /// Faster than doing A.MatrTranspose(); result.MatrMultiply(A,B); template <class RealB, class RealC> void MatrTMultiply(const ChMatrix<RealB>& matra, const ChMatrix<RealC>& matrb) { assert(matra.GetRows() == matrb.GetRows()); assert(this->rows == matra.GetColumns()); assert(this->columns == matrb.GetColumns()); int col, row, colres; Real sum; for (colres = 0; colres < matrb.GetColumns(); ++colres) { for (row = 0; row < matra.GetColumns(); ++row) { sum = 0; for (col = 0; col < (matra.GetRows()); ++col) sum += (Real)(matra.Element(col, row) * matrb.Element(col, colres)); SetElement(row, colres, sum); } } } /// Computes dot product between two column-matrices (vectors) with /// same size. Returns a scalar value. template <class RealB, class RealC> static Real MatrDot(const ChMatrix<RealB>& ma, const ChMatrix<RealC>& mb) { assert(ma.GetColumns() == mb.GetColumns() && ma.GetRows() == mb.GetRows()); Real tot = 0; for (int i = 0; i < ma.GetRows(); ++i) tot += (Real)(ma.ElementN(i) * mb.ElementN(i)); return tot; } /// Transpose this matrix in place void MatrTranspose() { if (columns == rows) // Square transp.is optimized { for (int row = 0; row < rows; ++row) for (int col = row; col < columns; ++col) if (row != col) { Real temp = Element(row, col); Element(row, col) = Element(col, row); Element(col, row) = temp; } int tmpr = rows; rows = columns; columns = tmpr; } else // Naive implementation for rectangular case. Not in-place. Slower. { ChMatrixDynamic<Real> matrcopy(*this); int tmpr = rows; rows = columns; columns = tmpr; // dont' realloc buffer, anyway for (int row = 0; row < rows; ++row) for (int col = 0; col < columns; ++col) Element(row, col) = matrcopy.Element(col, row); } } /// Returns the determinant of the matrix. /// Note! This method must be used only with max 4x4 matrices, /// otherwise it throws an exception. Real Det() { assert(this->GetRows() == this->GetColumns()); assert(this->GetRows() <= 4); if (this->GetRows() != this->GetColumns()) throw("Cannot compute matrix determinant because rectangular matrix"); if (this->GetRows() > 4) throw("Cannot compute matrix determinant because matr. larger than 3x3"); Real det = 0; switch (this->GetRows()) { case 1: det = (*this)(0, 0); break; case 2: det = (*this)(0, 0) * (*this)(1, 1) - (*this)(0, 1) * (*this)(1, 0); break; case 3: det = (*this)(0, 0) * (*this)(1, 1) * (*this)(2, 2) + (*this)(0, 1) * (*this)(1, 2) * (*this)(2, 0) + (*this)(0, 2) * (*this)(1, 0) * (*this)(2, 1) - (*this)(2, 0) * (*this)(1, 1) * (*this)(0, 2) - (*this)(2, 1) * (*this)(1, 2) * (*this)(0, 0) - (*this)(2, 2) * (*this)(1, 0) * (*this)(0, 1); break; case 4: det = (*this)(0, 0) * (*this)(1, 1) * (*this)(2, 2) * (*this)(3, 3) + (*this)(0, 0) * (*this)(1, 2) * (*this)(2, 3) * (*this)(3, 1) + (*this)(0, 0) * (*this)(1, 3) * (*this)(2, 1) * (*this)(3, 2) + (*this)(0, 1) * (*this)(1, 0) * (*this)(2, 3) * (*this)(3, 2) + (*this)(0, 1) * (*this)(1, 2) * (*this)(2, 0) * (*this)(3, 3) + (*this)(0, 1) * (*this)(1, 3) * (*this)(2, 2) * (*this)(3, 0) + (*this)(0, 2) * (*this)(1, 0) * (*this)(2, 1) * (*this)(3, 3) + (*this)(0, 2) * (*this)(1, 1) * (*this)(2, 3) * (*this)(3, 0) + (*this)(0, 2) * (*this)(1, 3) * (*this)(2, 0) * (*this)(3, 1) + (*this)(0, 3) * (*this)(1, 0) * (*this)(2, 2) * (*this)(3, 1) + (*this)(0, 3) * (*this)(1, 1) * (*this)(2, 0) * (*this)(3, 2) + (*this)(0, 3) * (*this)(1, 2) * (*this)(2, 1) * (*this)(3, 0) - (*this)(0, 0) * (*this)(1, 1) * (*this)(2, 3) * (*this)(3, 2) - (*this)(0, 0) * (*this)(1, 2) * (*this)(2, 1) * (*this)(3, 3) - (*this)(0, 0) * (*this)(1, 3) * (*this)(2, 2) * (*this)(3, 1) - (*this)(0, 1) * (*this)(1, 0) * (*this)(2, 2) * (*this)(3, 3) - (*this)(0, 1) * (*this)(1, 2) * (*this)(2, 3) * (*this)(3, 0) - (*this)(0, 1) * (*this)(1, 3) * (*this)(2, 0) * (*this)(3, 2) - (*this)(0, 2) * (*this)(1, 0) * (*this)(2, 3) * (*this)(3, 1) - (*this)(0, 2) * (*this)(1, 1) * (*this)(2, 0) * (*this)(3, 3) - (*this)(0, 2) * (*this)(1, 3) * (*this)(2, 1) * (*this)(3, 0) - (*this)(0, 3) * (*this)(1, 0) * (*this)(2, 1) * (*this)(3, 2) - (*this)(0, 3) * (*this)(1, 1) * (*this)(2, 2) * (*this)(3, 0) - (*this)(0, 3) * (*this)(1, 2) * (*this)(2, 0) * (*this)(3, 1); break; } return det; } /// Returns the inverse of the matrix. /// Note! This method must be used only with max 4x4 matrices, /// otherwise it throws an exception. void MatrInverse() { assert(this->GetRows() == this->GetColumns()); assert(this->GetRows() <= 4); assert(this->Det() != 0); if (this->GetRows() != this->GetColumns()) throw("Cannot compute matrix inverse because rectangular matrix"); if (this->GetRows() > 4) throw("Cannot compute matrix inverse because matr. larger than 4x4"); if (this->Det() == 0) throw("Cannot compute matrix inverse because singular matrix"); switch (this->GetRows()) { case 1: (*this)(0, 0) = (1 / (*this)(0, 0)); break; case 2: { ChMatrixDynamic<Real> inv(2, 2); inv(0, 0) = (*this)(1, 1); inv(0, 1) = -(*this)(0, 1); inv(1, 1) = (*this)(0, 0); inv(1, 0) = -(*this)(1, 0); inv.MatrDivScale(this->Det()); this->CopyFromMatrix(inv); break; } case 3: { ChMatrixDynamic<Real> inv(3, 3); inv(0, 0) = (*this)(1, 1) * (*this)(2, 2) - (*this)(1, 2) * (*this)(2, 1); inv(0, 1) = (*this)(2, 1) * (*this)(0, 2) - (*this)(0, 1) * (*this)(2, 2); inv(0, 2) = (*this)(0, 1) * (*this)(1, 2) - (*this)(0, 2) * (*this)(1, 1); inv(1, 0) = (*this)(1, 2) * (*this)(2, 0) - (*this)(1, 0) * (*this)(2, 2); inv(1, 1) = (*this)(2, 2) * (*this)(0, 0) - (*this)(2, 0) * (*this)(0, 2); inv(1, 2) = (*this)(0, 2) * (*this)(1, 0) - (*this)(1, 2) * (*this)(0, 0); inv(2, 0) = (*this)(1, 0) * (*this)(2, 1) - (*this)(1, 1) * (*this)(2, 0); inv(2, 1) = (*this)(0, 1) * (*this)(2, 0) - (*this)(0, 0) * (*this)(2, 1); inv(2, 2) = (*this)(0, 0) * (*this)(1, 1) - (*this)(0, 1) * (*this)(1, 0); inv.MatrDivScale(this->Det()); this->CopyFromMatrix(inv); break; } case 4: { ChMatrixDynamic<Real> inv(4, 4); inv.SetElement( 0, 0, (*this)(1, 2) * (*this)(2, 3) * (*this)(3, 1) - (*this)(1, 3) * (*this)(2, 2) * (*this)(3, 1) + (*this)(1, 3) * (*this)(2, 1) * (*this)(3, 2) - (*this)(1, 1) * (*this)(2, 3) * (*this)(3, 2) - (*this)(1, 2) * (*this)(2, 1) * (*this)(3, 3) + (*this)(1, 1) * (*this)(2, 2) * (*this)(3, 3)); inv.SetElement( 0, 1, (*this)(0, 3) * (*this)(2, 2) * (*this)(3, 1) - (*this)(0, 2) * (*this)(2, 3) * (*this)(3, 1) - (*this)(0, 3) * (*this)(2, 1) * (*this)(3, 2) + (*this)(0, 1) * (*this)(2, 3) * (*this)(3, 2) + (*this)(0, 2) * (*this)(2, 1) * (*this)(3, 3) - (*this)(0, 1) * (*this)(2, 2) * (*this)(3, 3)); inv.SetElement( 0, 2, (*this)(0, 2) * (*this)(1, 3) * (*this)(3, 1) - (*this)(0, 3) * (*this)(1, 2) * (*this)(3, 1) + (*this)(0, 3) * (*this)(1, 1) * (*this)(3, 2) - (*this)(0, 1) * (*this)(1, 3) * (*this)(3, 2) - (*this)(0, 2) * (*this)(1, 1) * (*this)(3, 3) + (*this)(0, 1) * (*this)(1, 2) * (*this)(3, 3)); inv.SetElement( 0, 3, (*this)(0, 3) * (*this)(1, 2) * (*this)(2, 1) - (*this)(0, 2) * (*this)(1, 3) * (*this)(2, 1) - (*this)(0, 3) * (*this)(1, 1) * (*this)(2, 2) + (*this)(0, 1) * (*this)(1, 3) * (*this)(2, 2) + (*this)(0, 2) * (*this)(1, 1) * (*this)(2, 3) - (*this)(0, 1) * (*this)(1, 2) * (*this)(2, 3)); inv.SetElement( 1, 0, (*this)(1, 3) * (*this)(2, 2) * (*this)(3, 0) - (*this)(1, 2) * (*this)(2, 3) * (*this)(3, 0) - (*this)(1, 3) * (*this)(2, 0) * (*this)(3, 2) + (*this)(1, 0) * (*this)(2, 3) * (*this)(3, 2) + (*this)(1, 2) * (*this)(2, 0) * (*this)(3, 3) - (*this)(1, 0) * (*this)(2, 2) * (*this)(3, 3)); inv.SetElement( 1, 1, (*this)(0, 2) * (*this)(2, 3) * (*this)(3, 0) - (*this)(0, 3) * (*this)(2, 2) * (*this)(3, 0) + (*this)(0, 3) * (*this)(2, 0) * (*this)(3, 2) - (*this)(0, 0) * (*this)(2, 3) * (*this)(3, 2) - (*this)(0, 2) * (*this)(2, 0) * (*this)(3, 3) + (*this)(0, 0) * (*this)(2, 2) * (*this)(3, 3)); inv.SetElement( 1, 2, (*this)(0, 3) * (*this)(1, 2) * (*this)(3, 0) - (*this)(0, 2) * (*this)(1, 3) * (*this)(3, 0) - (*this)(0, 3) * (*this)(1, 0) * (*this)(3, 2) + (*this)(0, 0) * (*this)(1, 3) * (*this)(3, 2) + (*this)(0, 2) * (*this)(1, 0) * (*this)(3, 3) - (*this)(0, 0) * (*this)(1, 2) * (*this)(3, 3)); inv.SetElement( 1, 3, (*this)(0, 2) * (*this)(1, 3) * (*this)(2, 0) - (*this)(0, 3) * (*this)(1, 2) * (*this)(2, 0) + (*this)(0, 3) * (*this)(1, 0) * (*this)(2, 2) - (*this)(0, 0) * (*this)(1, 3) * (*this)(2, 2) - (*this)(0, 2) * (*this)(1, 0) * (*this)(2, 3) + (*this)(0, 0) * (*this)(1, 2) * (*this)(2, 3)); inv.SetElement( 2, 0, (*this)(1, 1) * (*this)(2, 3) * (*this)(3, 0) - (*this)(1, 3) * (*this)(2, 1) * (*this)(3, 0) + (*this)(1, 3) * (*this)(2, 0) * (*this)(3, 1) - (*this)(1, 0) * (*this)(2, 3) * (*this)(3, 1) - (*this)(1, 1) * (*this)(2, 0) * (*this)(3, 3) + (*this)(1, 0) * (*this)(2, 1) * (*this)(3, 3)); inv.SetElement( 2, 1, (*this)(0, 3) * (*this)(2, 1) * (*this)(3, 0) - (*this)(0, 1) * (*this)(2, 3) * (*this)(3, 0) - (*this)(0, 3) * (*this)(2, 0) * (*this)(3, 1) + (*this)(0, 0) * (*this)(2, 3) * (*this)(3, 1) + (*this)(0, 1) * (*this)(2, 0) * (*this)(3, 3) - (*this)(0, 0) * (*this)(2, 1) * (*this)(3, 3)); inv.SetElement( 2, 2, (*this)(0, 1) * (*this)(1, 3) * (*this)(3, 0) - (*this)(0, 3) * (*this)(1, 1) * (*this)(3, 0) + (*this)(0, 3) * (*this)(1, 0) * (*this)(3, 1) - (*this)(0, 0) * (*this)(1, 3) * (*this)(3, 1) - (*this)(0, 1) * (*this)(1, 0) * (*this)(3, 3) + (*this)(0, 0) * (*this)(1, 1) * (*this)(3, 3)); inv.SetElement( 2, 3, (*this)(0, 3) * (*this)(1, 1) * (*this)(2, 0) - (*this)(0, 1) * (*this)(1, 3) * (*this)(2, 0) - (*this)(0, 3) * (*this)(1, 0) * (*this)(2, 1) + (*this)(0, 0) * (*this)(1, 3) * (*this)(2, 1) + (*this)(0, 1) * (*this)(1, 0) * (*this)(2, 3) - (*this)(0, 0) * (*this)(1, 1) * (*this)(2, 3)); inv.SetElement( 3, 0, (*this)(1, 2) * (*this)(2, 1) * (*this)(3, 0) - (*this)(1, 1) * (*this)(2, 2) * (*this)(3, 0) - (*this)(1, 2) * (*this)(2, 0) * (*this)(3, 1) + (*this)(1, 0) * (*this)(2, 2) * (*this)(3, 1) + (*this)(1, 1) * (*this)(2, 0) * (*this)(3, 2) - (*this)(1, 0) * (*this)(2, 1) * (*this)(3, 2)); inv.SetElement( 3, 1, (*this)(0, 1) * (*this)(2, 2) * (*this)(3, 0) - (*this)(0, 2) * (*this)(2, 1) * (*this)(3, 0) + (*this)(0, 2) * (*this)(2, 0) * (*this)(3, 1) - (*this)(0, 0) * (*this)(2, 2) * (*this)(3, 1) - (*this)(0, 1) * (*this)(2, 0) * (*this)(3, 2) + (*this)(0, 0) * (*this)(2, 1) * (*this)(3, 2)); inv.SetElement( 3, 2, (*this)(0, 2) * (*this)(1, 1) * (*this)(3, 0) - (*this)(0, 1) * (*this)(1, 2) * (*this)(3, 0) - (*this)(0, 2) * (*this)(1, 0) * (*this)(3, 1) + (*this)(0, 0) * (*this)(1, 2) * (*this)(3, 1) + (*this)(0, 1) * (*this)(1, 0) * (*this)(3, 2) - (*this)(0, 0) * (*this)(1, 1) * (*this)(3, 2)); inv.SetElement( 3, 3, (*this)(0, 1) * (*this)(1, 2) * (*this)(2, 0) - (*this)(0, 2) * (*this)(1, 1) * (*this)(2, 0) + (*this)(0, 2) * (*this)(1, 0) * (*this)(2, 1) - (*this)(0, 0) * (*this)(1, 2) * (*this)(2, 1) - (*this)(0, 1) * (*this)(1, 0) * (*this)(2, 2) + (*this)(0, 0) * (*this)(1, 1) * (*this)(2, 2)); inv.MatrDivScale(this->Det()); this->CopyFromMatrix(inv); break; } } } /// Returns true if vector is identical to other matrix bool Equals(const ChMatrix<Real>& other) { return Equals(other, 0.0); } /// Returns true if vector equals another vector, within a tolerance 'tol' bool Equals(const ChMatrix<Real>& other, Real tol) { if ((other.GetColumns() != this->columns) || (other.GetRows() != this->rows)) return false; for (int nel = 0; nel < rows * columns; ++nel) if (fabs(ElementN(nel) - other.ElementN(nel)) > tol) return false; return true; } /// Multiplies this 3x4 matrix by a quaternion, as v=[G]*q /// The matrix must be 3x4. /// \return The result of the multiplication, i.e. a vector. template <class RealB> ChVector<Real> Matr34_x_Quat(const ChQuaternion<RealB>& qua) { assert((rows == 3) && (columns == 4)); return ChVector<Real>(Get34Element(0, 0) * (Real)qua.e0() + Get34Element(0, 1) * (Real)qua.e1() + Get34Element(0, 2) * (Real)qua.e2() + Get34Element(0, 3) * (Real)qua.e3(), Get34Element(1, 0) * (Real)qua.e0() + Get34Element(1, 1) * (Real)qua.e1() + Get34Element(1, 2) * (Real)qua.e2() + Get34Element(1, 3) * (Real)qua.e3(), Get34Element(2, 0) * (Real)qua.e0() + Get34Element(2, 1) * (Real)qua.e1() + Get34Element(2, 2) * (Real)qua.e2() + Get34Element(2, 3) * (Real)qua.e3()); } /// Multiplies this 3x4 matrix (transposed) by a vector, as q=[G]'*v /// The matrix must be 3x4. /// \return The result of the multiplication, i.e. a quaternion. template <class RealB> ChQuaternion<Real> Matr34T_x_Vect(const ChVector<RealB>& va) { assert((rows == 3) && (columns == 4)); return ChQuaternion<Real>( Get34Element(0, 0) * (Real)va.x() + Get34Element(1, 0) * (Real)va.y() + Get34Element(2, 0) * (Real)va.z(), Get34Element(0, 1) * (Real)va.x() + Get34Element(1, 1) * (Real)va.y() + Get34Element(2, 1) * (Real)va.z(), Get34Element(0, 2) * (Real)va.x() + Get34Element(1, 2) * (Real)va.y() + Get34Element(2, 2) * (Real)va.z(), Get34Element(0, 3) * (Real)va.x() + Get34Element(1, 3) * (Real)va.y() + Get34Element(2, 3) * (Real)va.z()); } /// Multiplies this 4x4 matrix (transposed) by a quaternion, /// The matrix must be 4x4. /// \return The result of the multiplication, i.e. a quaternion. template <class RealB> ChQuaternion<Real> Matr44_x_Quat(const ChQuaternion<RealB>& qua) { assert((rows == 4) && (columns == 4)); return ChQuaternion<Real>(Get44Element(0, 0) * (Real)qua.e0() + Get44Element(0, 1) * (Real)qua.e1() + Get44Element(0, 2) * (Real)qua.e2() + Get44Element(0, 3) * (Real)qua.e3(), Get44Element(1, 0) * (Real)qua.e0() + Get44Element(1, 1) * (Real)qua.e1() + Get44Element(1, 2) * (Real)qua.e2() + Get44Element(1, 3) * (Real)qua.e3(), Get44Element(2, 0) * (Real)qua.e0() + Get44Element(2, 1) * (Real)qua.e1() + Get44Element(2, 2) * (Real)qua.e2() + Get44Element(2, 3) * (Real)qua.e3(), Get44Element(3, 0) * (Real)qua.e0() + Get44Element(3, 1) * (Real)qua.e1() + Get44Element(3, 2) * (Real)qua.e2() + Get44Element(3, 3) * (Real)qua.e3()); } /// Transposes only the lower-right 3x3 submatrix of a hemisymmetric 4x4 matrix, /// used when the 4x4 matrix is a "star" matrix [q] coming from a quaternion q: /// the non commutative quat. product is: /// q1 x q2 = [q1]*q2 = [q2st]*q1 /// where [q2st] is the "semi-transpose of [q2]. void MatrXq_SemiTranspose() { SetElement(1, 2, -GetElement(1, 2)); SetElement(1, 3, -GetElement(1, 3)); SetElement(2, 1, -GetElement(2, 1)); SetElement(2, 3, -GetElement(2, 3)); SetElement(3, 1, -GetElement(3, 1)); SetElement(3, 2, -GetElement(3, 2)); } /// Change the sign of the 2nd, 3rd and 4th columns of a 4x4 matrix, /// The product between a quaternion q1 and the conjugate of q2 (q2'), is: /// q1 x q2' = [q1]*q2' = [q1sn]*q2 /// where [q1sn] is the semi-negation of the 4x4 matrix [q1]. void MatrXq_SemiNeg() { for (int i = 0; i < rows; ++i) for (int j = 1; j < columns; ++j) SetElement(i, j, -GetElement(i, j)); } /// Gets the norm infinite of the matrix, i.e. the max. /// of its elements in absolute value. Real NormInf() { Real norm = 0; for (int nel = 0; nel < rows * columns; ++nel) if ((fabs(ElementN(nel))) > norm) norm = fabs(ElementN(nel)); return norm; } /// Gets the norm two of the matrix, i.e. the square root /// of the sum of the elements squared. Real NormTwo() { Real norm = 0; for (int nel = 0; nel < rows * columns; ++nel) norm += ElementN(nel) * ElementN(nel); return (sqrt(norm)); } /// Finds max value among the values of the matrix Real Max() { Real mmax = GetElement(0, 0); for (int nel = 0; nel < rows * columns; ++nel) if (ElementN(nel) > mmax) mmax = ElementN(nel); return mmax; } /// Finds min value among the values of the matrix Real Min() { Real mmin = GetElement(0, 0); for (int nel = 0; nel < rows * columns; ++nel) if (ElementN(nel) < mmin) mmin = ElementN(nel); return mmin; } /// Linear interpolation of two matrices. Parameter mx must be 0...1. /// [this] =(1-x)[A]+ (x)[B] Matrices must have the same size!! void LinInterpolate(const ChMatrix<Real>& matra, const ChMatrix<Real>& matrb, Real mx) { assert(matra.columns == matrb.columns && matra.rows == matrb.rows); for (int nel = 0; nel < rows * columns; nel++) ElementN(nel) = matra.ElementN(nel) * (1 - mx) + matrb.ElementN(nel) * (mx); } /// Fills a matrix or a vector with a bilinear interpolation, /// from corner values (as a u-v patch). void RowColInterp(Real vmin, Real vmax, Real umin, Real umax) { for (int iu = 0; iu < GetColumns(); iu++) for (int iv = 0; iv < GetRows(); iv++) { if (GetRows() > 1) Element(iv, iu) = vmin + (vmax - vmin) * ((Real)iv / ((Real)(GetRows() - 1))); if (GetColumns() > 1) Element(iv, iu) += umin + (umax - umin) * ((Real)iu / ((Real)(GetColumns() - 1))); } } // // BOOKKEEPING // /// Paste a matrix "matra" into "this", inserting at location insrow-inscol. /// Normal copy for insrow=inscol=0 template <class RealB> void PasteMatrix(const ChMatrix<RealB>& matra, int insrow, int inscol) { for (int i = 0; i < matra.GetRows(); ++i) for (int j = 0; j < matra.GetColumns(); ++j) Element(i + insrow, j + inscol) = (Real)matra.Element(i, j); } /// Paste a matrix "matra" into "this", inserting at location insrow-inscol /// and performing a sum with the preexisting values. template <class RealB> void PasteSumMatrix(const ChMatrix<RealB>& matra, int insrow, int inscol) { for (int i = 0; i < matra.GetRows(); ++i) for (int j = 0; j < matra.GetColumns(); ++j) Element(i + insrow, j + inscol) += (Real)matra.Element(i, j); } /// Paste a matrix "matra", transposed, into "this", inserting at location insrow-inscol. /// Normal copy for insrow=inscol=0 template <class RealB> void PasteTranspMatrix(const ChMatrix<RealB>& matra, int insrow, int inscol) { for (int i = 0; i < matra.GetRows(); ++i) for (int j = 0; j < matra.GetColumns(); ++j) Element(j + insrow, i + inscol) = (Real)matra.Element(i, j); } /// Paste a matrix "matra", transposed, into "this", inserting at location insrow-inscol /// and performing a sum with the preexisting values. template <class RealB> void PasteSumTranspMatrix(const ChMatrix<RealB>& matra, int insrow, int inscol) { for (int i = 0; i < matra.GetRows(); ++i) for (int j = 0; j < matra.GetColumns(); ++j) Element(j + insrow, i + inscol) += (Real)matra.Element(i, j); } /// Paste a clipped portion of the matrix "matra" into "this", /// inserting the clip (of size nrows, ncolumns) at the location insrow-inscol. template <class RealB> void PasteClippedMatrix(const ChMatrix<RealB>& matra, int cliprow, int clipcol, int nrows, int ncolumns, int insrow, int inscol) { for (int i = 0; i < nrows; ++i) for (int j = 0; j < ncolumns; ++j) Element(i + insrow, j + inscol) = (Real)matra.Element(i + cliprow, j + clipcol); } /// Paste a clipped portion of the matrix "matra" into "this", where "this" /// is a vector (of ChMatrix type), /// inserting the clip (of size nrows, ncolumns) at the location insindex. template <class RealB> void PasteClippedMatrixToVector(const ChMatrix<RealB>& matra, int cliprow, int clipcol, int nrows, int ncolumns, int insindex) { for (int i = 0; i < nrows; ++i) for (int j = 0; j < ncolumns; ++j) ElementN(insindex + i * ncolumns + j) = (Real)matra.Element(cliprow + i, clipcol + j); } /// Paste a clipped portion of a vector into "this", where "this" /// is a matrix (of ChMatrix type), /// inserting the clip (of size nrows, ncolumns) at the location insindex. template <class RealB> void PasteClippedVectorToMatrix(const ChMatrix<RealB>& matra, int cliprow, int clipcol, int nrows, int ncolumns, int insindex) { for (int i = 0; i < nrows; ++i) for (int j = 0; j < ncolumns; ++j) Element(i + cliprow, j + clipcol) = (Real)matra.ElementN(insindex + i * ncolumns + j); } /// Paste a clipped portion of the matrix "matra" into "this", performing a sum with preexisting values, /// inserting the clip (of size nrows, ncolumns) at the location insrow-inscol. template <class RealB> void PasteSumClippedMatrix(const ChMatrix<RealB>& matra, int cliprow, int clipcol, int nrows, int ncolumns, int insrow, int inscol) { for (int i = 0; i < nrows; ++i) for (int j = 0; j < ncolumns; ++j) #pragma omp atomic Element(i + insrow, j + inscol) += (Real)matra.Element(i + cliprow, j + clipcol); } /// Paste a vector "va" into the matrix. template <class RealB> void PasteVector(const ChVector<RealB>& va, int insrow, int inscol) { SetElement(insrow + 0, inscol, (Real)va.x()); SetElement(insrow + 1, inscol, (Real)va.y()); SetElement(insrow + 2, inscol, (Real)va.z()); } /// Paste a vector "va" into the matrix, summing it with preexisting values. template <class RealB> void PasteSumVector(const ChVector<RealB>& va, int insrow, int inscol) { Element(insrow + 0, inscol) += (Real)va.x(); Element(insrow + 1, inscol) += (Real)va.y(); Element(insrow + 2, inscol) += (Real)va.z(); } /// Paste a vector "va" into the matrix, subtracting it from preexisting values. template <class RealB> void PasteSubVector(const ChVector<RealB>& va, int insrow, int inscol) { Element(insrow + 0, inscol) -= (Real)va.x(); Element(insrow + 1, inscol) -= (Real)va.y(); Element(insrow + 2, inscol) -= (Real)va.z(); } /// Paste a quaternion into the matrix. template <class RealB> void PasteQuaternion(const ChQuaternion<RealB>& qa, int insrow, int inscol) { SetElement(insrow + 0, inscol, (Real)qa.e0()); SetElement(insrow + 1, inscol, (Real)qa.e1()); SetElement(insrow + 2, inscol, (Real)qa.e2()); SetElement(insrow + 3, inscol, (Real)qa.e3()); } /// Paste a quaternion into the matrix, summing it with preexisting values. template <class RealB> void PasteSumQuaternion(const ChQuaternion<RealB>& qa, int insrow, int inscol) { Element(insrow + 0, inscol) += (Real)qa.e0(); Element(insrow + 1, inscol) += (Real)qa.e1(); Element(insrow + 2, inscol) += (Real)qa.e2(); Element(insrow + 3, inscol) += (Real)qa.e3(); } /// Paste a coordsys into the matrix. template <class RealB> void PasteCoordsys(const ChCoordsys<RealB>& cs, int insrow, int inscol) { PasteVector(cs.pos, insrow, inscol); PasteQuaternion(cs.rot, insrow + 3, inscol); } /// Returns the vector clipped from insrow, inscol. ChVector<Real> ClipVector(int insrow, int inscol) const { return ChVector<Real>(Element(insrow, inscol), Element(insrow + 1, inscol), Element(insrow + 2, inscol)); } /// Returns the quaternion clipped from insrow, inscol. ChQuaternion<Real> ClipQuaternion(int insrow, int inscol) const { return ChQuaternion<Real>(Element(insrow, inscol), Element(insrow + 1, inscol), Element(insrow + 2, inscol), Element(insrow + 3, inscol)); } /// Returns the coordsys clipped from insrow, inscol. ChCoordsys<Real> ClipCoordsys(int insrow, int inscol) const { return ChCoordsys<Real>(ClipVector(insrow, inscol), ClipQuaternion(insrow + 3, inscol)); } // // MULTIBODY SPECIFIC MATH FUCTION // /// Fills a 4x4 matrix as the "star" matrix, representing quaternion cross product. /// That is, given two quaternions a and b, aXb= [Astar]*b template <class RealB> void Set_Xq_matrix(const ChQuaternion<RealB>& q) { Set44Element(0, 0, (Real)q.e0()); Set44Element(0, 1, -(Real)q.e1()); Set44Element(0, 2, -(Real)q.e2()); Set44Element(0, 3, -(Real)q.e3()); Set44Element(1, 0, (Real)q.e1()); Set44Element(1, 1, (Real)q.e0()); Set44Element(1, 2, -(Real)q.e3()); Set44Element(1, 3, (Real)q.e2()); Set44Element(2, 0, (Real)q.e2()); Set44Element(2, 1, (Real)q.e3()); Set44Element(2, 2, (Real)q.e0()); Set44Element(2, 3, -(Real)q.e1()); Set44Element(3, 0, (Real)q.e3()); Set44Element(3, 1, -(Real)q.e2()); Set44Element(3, 2, (Real)q.e1()); Set44Element(3, 3, (Real)q.e0()); } }; } // end namespace chrono #endif

par_csr_matop_device.c

/****************************************************************************** * Copyright 1998-2019 Lawrence Livermore National Security, LLC and other * HYPRE Project Developers. See the top-level COPYRIGHT file for details. * * SPDX-License-Identifier: (Apache-2.0 OR MIT) ******************************************************************************/ #include "_hypre_utilities.h" #include "hypre_hopscotch_hash.h" #include "_hypre_parcsr_mv.h" #include "_hypre_lapack.h" #include "_hypre_blas.h" #include "_hypre_utilities.hpp" #if defined(HYPRE_USING_CUDA) HYPRE_Int hypre_ParcsrGetExternalRowsDeviceInit( hypre_ParCSRMatrix *A, HYPRE_Int indices_len, HYPRE_Int *indices, hypre_ParCSRCommPkg *comm_pkg, HYPRE_Int want_data, void **request_ptr) { HYPRE_Int i, j; HYPRE_Int num_sends, num_rows_send, num_nnz_send, num_recvs, num_rows_recv, num_nnz_recv; HYPRE_Int *d_send_i, *send_i, *d_send_map, *d_recv_i, *recv_i; HYPRE_BigInt *d_send_j, *d_recv_j; HYPRE_Int *send_jstarts, *recv_jstarts; HYPRE_Complex *d_send_a = NULL, *d_recv_a = NULL; hypre_ParCSRCommPkg *comm_pkg_j; hypre_ParCSRCommHandle *comm_handle, *comm_handle_j, *comm_handle_a; /* HYPRE_Int global_num_rows = hypre_ParCSRMatrixGlobalNumRows(A); */ /* diag part of A */ hypre_CSRMatrix *A_diag = hypre_ParCSRMatrixDiag(A); HYPRE_Complex *A_diag_a = hypre_CSRMatrixData(A_diag); HYPRE_Int *A_diag_i = hypre_CSRMatrixI(A_diag); HYPRE_Int *A_diag_j = hypre_CSRMatrixJ(A_diag); /* HYPRE_Int local_num_rows = hypre_CSRMatrixNumRows(A_diag); */ /* off-diag part of A */ hypre_CSRMatrix *A_offd = hypre_ParCSRMatrixOffd(A); HYPRE_Complex *A_offd_a = hypre_CSRMatrixData(A_offd); HYPRE_Int *A_offd_i = hypre_CSRMatrixI(A_offd); HYPRE_Int *A_offd_j = hypre_CSRMatrixJ(A_offd); /* HYPRE_Int *row_starts = hypre_ParCSRMatrixRowStarts(A); */ /* HYPRE_Int first_row = hypre_ParCSRMatrixFirstRowIndex(A); */ HYPRE_Int first_col = hypre_ParCSRMatrixFirstColDiag(A); HYPRE_BigInt *col_map_offd_A = hypre_ParCSRMatrixColMapOffd(A); HYPRE_Int num_cols_A_offd = hypre_CSRMatrixNumCols(A_offd); HYPRE_BigInt *d_col_map_offd_A = hypre_ParCSRMatrixDeviceColMapOffd(A); MPI_Comm comm = hypre_ParCSRMatrixComm(A); HYPRE_Int num_procs; HYPRE_Int my_id; void **vrequest; hypre_CSRMatrix *A_ext; hypre_MPI_Comm_size(comm, &num_procs); hypre_MPI_Comm_rank(comm, &my_id); /* number of sends (#procs) */ num_sends = hypre_ParCSRCommPkgNumSends(comm_pkg); /* number of rows to send */ num_rows_send = hypre_ParCSRCommPkgSendMapStart(comm_pkg, num_sends); /* number of recvs (#procs) */ num_recvs = hypre_ParCSRCommPkgNumRecvs(comm_pkg); /* number of rows to recv */ num_rows_recv = hypre_ParCSRCommPkgRecvVecStart(comm_pkg, num_recvs); /* must be true if indices contains proper offd indices */ hypre_assert(indices_len == num_rows_recv); /* send_i/recv_i: * the arrays to send and recv: we first send and recv the row lengths */ d_send_i = hypre_TAlloc(HYPRE_Int, num_rows_send + 1, HYPRE_MEMORY_DEVICE); d_send_map = hypre_TAlloc(HYPRE_Int, num_rows_send, HYPRE_MEMORY_DEVICE); send_i = hypre_TAlloc(HYPRE_Int, num_rows_send, HYPRE_MEMORY_HOST); recv_i = hypre_TAlloc(HYPRE_Int, num_rows_recv + 1, HYPRE_MEMORY_HOST); d_recv_i = hypre_TAlloc(HYPRE_Int, num_rows_recv + 1, HYPRE_MEMORY_DEVICE); /* fill the send array with row lengths */ hypre_TMemcpy(d_send_map, hypre_ParCSRCommPkgSendMapElmts(comm_pkg), HYPRE_Int, num_rows_send, HYPRE_MEMORY_DEVICE, HYPRE_MEMORY_HOST); hypre_Memset(d_send_i, 0, sizeof(HYPRE_Int), HYPRE_MEMORY_DEVICE); hypreDevice_GetRowNnz(num_rows_send, d_send_map, A_diag_i, A_offd_i, d_send_i+1); /* send array send_i out: deviceTohost first and MPI (async) * note the shift in recv_i by one */ hypre_TMemcpy(send_i, d_send_i+1, HYPRE_Int, num_rows_send, HYPRE_MEMORY_HOST, HYPRE_MEMORY_DEVICE); comm_handle = hypre_ParCSRCommHandleCreate(11, comm_pkg, send_i, recv_i+1); hypreDevice_IntegerInclusiveScan(num_rows_send + 1, d_send_i); /* total number of nnz to send */ hypre_TMemcpy(&num_nnz_send, d_send_i+num_rows_send, HYPRE_Int, 1, HYPRE_MEMORY_HOST, HYPRE_MEMORY_DEVICE); /* prepare data to send out. overlap with the above commmunication */ d_send_j = hypre_TAlloc(HYPRE_BigInt, num_nnz_send, HYPRE_MEMORY_DEVICE); if (want_data) { d_send_a = hypre_TAlloc(HYPRE_Complex, num_nnz_send, HYPRE_MEMORY_DEVICE); } if (d_col_map_offd_A == NULL) { d_col_map_offd_A = hypre_TAlloc(HYPRE_BigInt, num_cols_A_offd, HYPRE_MEMORY_DEVICE); hypre_TMemcpy(d_col_map_offd_A, col_map_offd_A, HYPRE_BigInt, num_cols_A_offd, HYPRE_MEMORY_DEVICE, HYPRE_MEMORY_HOST); hypre_ParCSRMatrixDeviceColMapOffd(A) = d_col_map_offd_A; } /* job == 2, d_send_i is input that contains row ptrs (length num_rows_send) */ hypreDevice_CopyParCSRRows(num_rows_send, d_send_map, 2, num_procs > 1, first_col, d_col_map_offd_A, A_diag_i, A_diag_j, A_diag_a, A_offd_i, A_offd_j, A_offd_a, d_send_i, d_send_j, d_send_a); /* pointers to each proc in send_j */ send_jstarts = hypre_TAlloc(HYPRE_Int, num_sends + 1, HYPRE_MEMORY_HOST); send_jstarts[0] = 0; for (i = 1; i <= num_sends; i++) { send_jstarts[i] = send_jstarts[i-1]; for ( j = hypre_ParCSRCommPkgSendMapStart(comm_pkg, i-1); j < hypre_ParCSRCommPkgSendMapStart(comm_pkg, i); j++ ) { send_jstarts[i] += send_i[j]; } } hypre_assert(send_jstarts[num_sends] == num_nnz_send); /* finish the above communication: send_i/recv_i */ hypre_ParCSRCommHandleDestroy(comm_handle); /* adjust recv_i to ptrs */ recv_i[0] = 0; for (i = 1; i <= num_rows_recv; i++) { recv_i[i] += recv_i[i-1]; } num_nnz_recv = recv_i[num_rows_recv]; /* allocate device memory for j and a */ d_recv_j = hypre_TAlloc(HYPRE_BigInt, num_nnz_recv, HYPRE_MEMORY_DEVICE); if (want_data) { d_recv_a = hypre_TAlloc(HYPRE_Complex, num_nnz_recv, HYPRE_MEMORY_DEVICE); } recv_jstarts = hypre_TAlloc(HYPRE_Int, num_recvs + 1, HYPRE_MEMORY_HOST); recv_jstarts[0] = 0; for (i = 1; i <= num_recvs; i++) { j = hypre_ParCSRCommPkgRecvVecStart(comm_pkg, i); recv_jstarts[i] = recv_i[j]; } /* ready to send and recv: create a communication package for data */ comm_pkg_j = hypre_CTAlloc(hypre_ParCSRCommPkg, 1, HYPRE_MEMORY_HOST); hypre_ParCSRCommPkgComm (comm_pkg_j) = comm; hypre_ParCSRCommPkgNumSends (comm_pkg_j) = num_sends; hypre_ParCSRCommPkgSendProcs (comm_pkg_j) = hypre_ParCSRCommPkgSendProcs(comm_pkg); hypre_ParCSRCommPkgSendMapStarts(comm_pkg_j) = send_jstarts; hypre_ParCSRCommPkgNumRecvs (comm_pkg_j) = num_recvs; hypre_ParCSRCommPkgRecvProcs (comm_pkg_j) = hypre_ParCSRCommPkgRecvProcs(comm_pkg); hypre_ParCSRCommPkgRecvVecStarts(comm_pkg_j) = recv_jstarts; /* init communication */ /* ja */ comm_handle_j = hypre_ParCSRCommHandleCreate_v2(21, comm_pkg_j, HYPRE_MEMORY_DEVICE, d_send_j, HYPRE_MEMORY_DEVICE, d_recv_j); if (want_data) { /* a */ comm_handle_a = hypre_ParCSRCommHandleCreate_v2(1, comm_pkg_j, HYPRE_MEMORY_DEVICE, d_send_a, HYPRE_MEMORY_DEVICE, d_recv_a); } else { comm_handle_a = NULL; } hypre_TMemcpy(d_recv_i, recv_i, HYPRE_Int, num_rows_recv+1, HYPRE_MEMORY_DEVICE, HYPRE_MEMORY_HOST); /* create A_ext: on device */ A_ext = hypre_CSRMatrixCreate(num_rows_recv, hypre_ParCSRMatrixGlobalNumCols(A), num_nnz_recv); hypre_CSRMatrixI (A_ext) = d_recv_i; hypre_CSRMatrixBigJ(A_ext) = d_recv_j; hypre_CSRMatrixData(A_ext) = d_recv_a; hypre_CSRMatrixMemoryLocation(A_ext) = HYPRE_MEMORY_DEVICE; /* output */ vrequest = hypre_TAlloc(void *, 3, HYPRE_MEMORY_HOST); vrequest[0] = (void *) comm_handle_j; vrequest[1] = (void *) comm_handle_a; vrequest[2] = (void *) A_ext; *request_ptr = (void *) vrequest; /* free */ hypre_TFree(send_i, HYPRE_MEMORY_HOST); hypre_TFree(recv_i, HYPRE_MEMORY_HOST); hypre_TFree(d_send_i, HYPRE_MEMORY_DEVICE); hypre_TFree(d_send_map, HYPRE_MEMORY_DEVICE); hypre_TFree(hypre_ParCSRCommPkgSendMapStarts(comm_pkg_j), HYPRE_MEMORY_HOST); hypre_TFree(hypre_ParCSRCommPkgRecvVecStarts(comm_pkg_j), HYPRE_MEMORY_HOST); hypre_TFree(comm_pkg_j, HYPRE_MEMORY_HOST); return hypre_error_flag; } hypre_CSRMatrix* hypre_ParcsrGetExternalRowsDeviceWait(void *vrequest) { void **request = (void **) vrequest; hypre_ParCSRCommHandle *comm_handle_j = (hypre_ParCSRCommHandle *) request[0]; hypre_ParCSRCommHandle *comm_handle_a = (hypre_ParCSRCommHandle *) request[1]; hypre_CSRMatrix *A_ext = (hypre_CSRMatrix *) request[2]; HYPRE_BigInt *send_j = comm_handle_j ? (HYPRE_BigInt *) hypre_ParCSRCommHandleSendData(comm_handle_j) : NULL; HYPRE_Complex *send_a = comm_handle_a ? (HYPRE_Complex *) hypre_ParCSRCommHandleSendData(comm_handle_a) : NULL; hypre_ParCSRCommHandleDestroy(comm_handle_j); hypre_ParCSRCommHandleDestroy(comm_handle_a); hypre_TFree(send_j, HYPRE_MEMORY_DEVICE); hypre_TFree(send_a, HYPRE_MEMORY_DEVICE); hypre_TFree(request, HYPRE_MEMORY_HOST); return A_ext; } hypre_CSRMatrix* hypre_MergeDiagAndOffdDevice(hypre_ParCSRMatrix *A) { MPI_Comm comm = hypre_ParCSRMatrixComm(A); hypre_CSRMatrix *A_diag = hypre_ParCSRMatrixDiag(A); HYPRE_Complex *A_diag_a = hypre_CSRMatrixData(A_diag); HYPRE_Int *A_diag_i = hypre_CSRMatrixI(A_diag); HYPRE_Int *A_diag_j = hypre_CSRMatrixJ(A_diag); hypre_CSRMatrix *A_offd = hypre_ParCSRMatrixOffd(A); HYPRE_Complex *A_offd_a = hypre_CSRMatrixData(A_offd); HYPRE_Int *A_offd_i = hypre_CSRMatrixI(A_offd); HYPRE_Int *A_offd_j = hypre_CSRMatrixJ(A_offd); HYPRE_Int local_num_rows = hypre_CSRMatrixNumRows(A_diag); HYPRE_BigInt glbal_num_cols = hypre_ParCSRMatrixGlobalNumCols(A); HYPRE_BigInt first_col = hypre_ParCSRMatrixFirstColDiag(A); HYPRE_Int num_cols_A_offd = hypre_CSRMatrixNumCols(A_offd); HYPRE_BigInt *col_map_offd_A = hypre_ParCSRMatrixColMapOffd(A); HYPRE_BigInt *d_col_map_offd_A = hypre_ParCSRMatrixDeviceColMapOffd(A); hypre_CSRMatrix *B; HYPRE_Int B_nrows = local_num_rows; HYPRE_BigInt B_ncols = glbal_num_cols; HYPRE_Int *B_i = hypre_TAlloc(HYPRE_Int, B_nrows + 1, HYPRE_MEMORY_DEVICE); HYPRE_BigInt *B_j; HYPRE_Complex *B_a; HYPRE_Int B_nnz; HYPRE_Int num_procs; hypre_MPI_Comm_size(comm, &num_procs); hypre_Memset(B_i, 0, sizeof(HYPRE_Int), HYPRE_MEMORY_DEVICE); hypreDevice_GetRowNnz(B_nrows, NULL, A_diag_i, A_offd_i, B_i+1); hypreDevice_IntegerInclusiveScan(B_nrows+1, B_i); /* total number of nnz */ hypre_TMemcpy(&B_nnz, B_i+B_nrows, HYPRE_Int, 1, HYPRE_MEMORY_HOST, HYPRE_MEMORY_DEVICE); B_j = hypre_TAlloc(HYPRE_BigInt, B_nnz, HYPRE_MEMORY_DEVICE); B_a = hypre_TAlloc(HYPRE_Complex, B_nnz, HYPRE_MEMORY_DEVICE); if (d_col_map_offd_A == NULL) { d_col_map_offd_A = hypre_TAlloc(HYPRE_BigInt, num_cols_A_offd, HYPRE_MEMORY_DEVICE); hypre_TMemcpy(d_col_map_offd_A, col_map_offd_A, HYPRE_BigInt, num_cols_A_offd, HYPRE_MEMORY_DEVICE, HYPRE_MEMORY_HOST); hypre_ParCSRMatrixDeviceColMapOffd(A) = d_col_map_offd_A; } hypreDevice_CopyParCSRRows(B_nrows, NULL, 2, num_procs > 1, first_col, d_col_map_offd_A, A_diag_i, A_diag_j, A_diag_a, A_offd_i, A_offd_j, A_offd_a, B_i, B_j, B_a); /* output */ B = hypre_CSRMatrixCreate(B_nrows, B_ncols, B_nnz); hypre_CSRMatrixI (B) = B_i; hypre_CSRMatrixBigJ(B) = B_j; hypre_CSRMatrixData(B) = B_a; hypre_CSRMatrixMemoryLocation(B) = HYPRE_MEMORY_DEVICE; hypre_SyncCudaComputeStream(hypre_handle()); return B; } HYPRE_Int hypre_ExchangeExternalRowsDeviceInit( hypre_CSRMatrix *B_ext, hypre_ParCSRCommPkg *comm_pkg_A, void **request_ptr) { MPI_Comm comm = hypre_ParCSRCommPkgComm(comm_pkg_A); HYPRE_Int num_recvs = hypre_ParCSRCommPkgNumRecvs(comm_pkg_A); HYPRE_Int *recv_procs = hypre_ParCSRCommPkgRecvProcs(comm_pkg_A); HYPRE_Int *recv_vec_starts = hypre_ParCSRCommPkgRecvVecStarts(comm_pkg_A); HYPRE_Int num_sends = hypre_ParCSRCommPkgNumSends(comm_pkg_A); HYPRE_Int *send_procs = hypre_ParCSRCommPkgSendProcs(comm_pkg_A); HYPRE_Int *send_map_starts = hypre_ParCSRCommPkgSendMapStarts(comm_pkg_A); HYPRE_Int num_elmts_send = send_map_starts[num_sends]; HYPRE_Int num_elmts_recv = recv_vec_starts[num_recvs]; HYPRE_Int *B_ext_i_d = hypre_CSRMatrixI(B_ext); HYPRE_BigInt *B_ext_j_d = hypre_CSRMatrixBigJ(B_ext); HYPRE_Complex *B_ext_a_d = hypre_CSRMatrixData(B_ext); HYPRE_Int B_ext_ncols = hypre_CSRMatrixNumCols(B_ext); HYPRE_Int B_ext_nrows = hypre_CSRMatrixNumRows(B_ext); HYPRE_Int B_ext_nnz = hypre_CSRMatrixNumNonzeros(B_ext); HYPRE_Int *B_ext_rownnz_d = hypre_TAlloc(HYPRE_Int, B_ext_nrows + 1, HYPRE_MEMORY_DEVICE); HYPRE_Int *B_ext_rownnz_h = hypre_TAlloc(HYPRE_Int, B_ext_nrows, HYPRE_MEMORY_HOST); HYPRE_Int *B_ext_i_h = hypre_TAlloc(HYPRE_Int, B_ext_nrows + 1, HYPRE_MEMORY_HOST); hypre_assert(num_elmts_recv == B_ext_nrows); /* output matrix */ hypre_CSRMatrix *B_int_d; HYPRE_Int B_int_nrows = num_elmts_send; HYPRE_Int B_int_ncols = B_ext_ncols; HYPRE_Int *B_int_i_h = hypre_TAlloc(HYPRE_Int, B_int_nrows + 1, HYPRE_MEMORY_HOST); HYPRE_Int *B_int_i_d = hypre_TAlloc(HYPRE_Int, B_int_nrows + 1, HYPRE_MEMORY_DEVICE); HYPRE_BigInt *B_int_j_d = NULL; HYPRE_Complex *B_int_a_d = NULL; HYPRE_Int B_int_nnz; hypre_ParCSRCommHandle *comm_handle, *comm_handle_j, *comm_handle_a; hypre_ParCSRCommPkg *comm_pkg_j; HYPRE_Int *jdata_recv_vec_starts; HYPRE_Int *jdata_send_map_starts; HYPRE_Int i; HYPRE_Int num_procs, my_id; void **vrequest; hypre_MPI_Comm_size(comm, &num_procs); hypre_MPI_Comm_rank(comm, &my_id); jdata_send_map_starts = hypre_TAlloc(HYPRE_Int, num_sends+1, HYPRE_MEMORY_HOST); /*-------------------------------------------------------------------------- * B_ext_rownnz contains the number of elements of row j * (to be determined through send_map_elmnts on the receiving end) *--------------------------------------------------------------------------*/ HYPRE_THRUST_CALL(adjacent_difference, B_ext_i_d, B_ext_i_d + B_ext_nrows + 1, B_ext_rownnz_d); hypre_TMemcpy(B_ext_rownnz_h, B_ext_rownnz_d + 1, HYPRE_Int, B_ext_nrows, HYPRE_MEMORY_HOST, HYPRE_MEMORY_DEVICE); /*-------------------------------------------------------------------------- * initialize communication: send/recv the row nnz * (note the use of comm_pkg_A, mode 12, as in transpose matvec *--------------------------------------------------------------------------*/ comm_handle = hypre_ParCSRCommHandleCreate(12, comm_pkg_A, B_ext_rownnz_h, B_int_i_h + 1); jdata_recv_vec_starts = hypre_TAlloc(HYPRE_Int, num_recvs + 1, HYPRE_MEMORY_HOST); jdata_recv_vec_starts[0] = 0; B_ext_i_h[0] = 0; hypre_TMemcpy(B_ext_i_h + 1, B_ext_rownnz_h, HYPRE_Int, B_ext_nrows, HYPRE_MEMORY_HOST, HYPRE_MEMORY_HOST); for (i = 1; i <= B_ext_nrows; i++) { B_ext_i_h[i] += B_ext_i_h[i-1]; } hypre_assert(B_ext_i_h[B_ext_nrows] == B_ext_nnz); for (i = 1; i <= num_recvs; i++) { jdata_recv_vec_starts[i] = B_ext_i_h[recv_vec_starts[i]]; } comm_pkg_j = hypre_CTAlloc(hypre_ParCSRCommPkg, 1, HYPRE_MEMORY_HOST); hypre_ParCSRCommPkgComm(comm_pkg_j) = comm; hypre_ParCSRCommPkgNumSends(comm_pkg_j) = num_recvs; hypre_ParCSRCommPkgNumRecvs(comm_pkg_j) = num_sends; hypre_ParCSRCommPkgSendProcs(comm_pkg_j) = recv_procs; hypre_ParCSRCommPkgRecvProcs(comm_pkg_j) = send_procs; hypre_ParCSRCommHandleDestroy(comm_handle); /*-------------------------------------------------------------------------- * compute B_int: row nnz to row ptrs *--------------------------------------------------------------------------*/ B_int_i_h[0] = 0; for (i = 1; i <= B_int_nrows; i++) { B_int_i_h[i] += B_int_i_h[i-1]; } B_int_nnz = B_int_i_h[B_int_nrows]; B_int_j_d = hypre_TAlloc(HYPRE_BigInt, B_int_nnz, HYPRE_MEMORY_DEVICE); B_int_a_d = hypre_TAlloc(HYPRE_Complex, B_int_nnz, HYPRE_MEMORY_DEVICE); for (i = 0; i <= num_sends; i++) { jdata_send_map_starts[i] = B_int_i_h[send_map_starts[i]]; } /* note the order of send/recv is reversed */ hypre_ParCSRCommPkgRecvVecStarts(comm_pkg_j) = jdata_send_map_starts; hypre_ParCSRCommPkgSendMapStarts(comm_pkg_j) = jdata_recv_vec_starts; /* send/recv CSR rows */ comm_handle_a = hypre_ParCSRCommHandleCreate_v2( 1, comm_pkg_j, HYPRE_MEMORY_DEVICE, B_ext_a_d, HYPRE_MEMORY_DEVICE, B_int_a_d ); comm_handle_j = hypre_ParCSRCommHandleCreate_v2(21, comm_pkg_j, HYPRE_MEMORY_DEVICE, B_ext_j_d, HYPRE_MEMORY_DEVICE, B_int_j_d ); hypre_TMemcpy(B_int_i_d, B_int_i_h, HYPRE_Int, B_int_nrows+1, HYPRE_MEMORY_DEVICE, HYPRE_MEMORY_HOST); /* create CSR: on device */ B_int_d = hypre_CSRMatrixCreate(B_int_nrows, B_int_ncols, B_int_nnz); hypre_CSRMatrixI(B_int_d) = B_int_i_d; hypre_CSRMatrixBigJ(B_int_d) = B_int_j_d; hypre_CSRMatrixData(B_int_d) = B_int_a_d; hypre_CSRMatrixMemoryLocation(B_int_d) = HYPRE_MEMORY_DEVICE; /* output */ vrequest = hypre_TAlloc(void *, 3, HYPRE_MEMORY_HOST); vrequest[0] = (void *) comm_handle_j; vrequest[1] = (void *) comm_handle_a; vrequest[2] = (void *) B_int_d; *request_ptr = (void *) vrequest; /* free */ hypre_TFree(B_ext_rownnz_d, HYPRE_MEMORY_DEVICE); hypre_TFree(B_ext_rownnz_h, HYPRE_MEMORY_HOST); hypre_TFree(B_ext_i_h, HYPRE_MEMORY_HOST); hypre_TFree(hypre_ParCSRCommPkgSendMapStarts(comm_pkg_j), HYPRE_MEMORY_HOST); hypre_TFree(hypre_ParCSRCommPkgRecvVecStarts(comm_pkg_j), HYPRE_MEMORY_HOST); hypre_TFree(comm_pkg_j, HYPRE_MEMORY_HOST); return hypre_error_flag; } hypre_CSRMatrix* hypre_ExchangeExternalRowsDeviceWait(void *vrequest) { void **request = (void **) vrequest; hypre_ParCSRCommHandle *comm_handle_j = (hypre_ParCSRCommHandle *) request[0]; hypre_ParCSRCommHandle *comm_handle_a = (hypre_ParCSRCommHandle *) request[1]; hypre_CSRMatrix *B_int_d = (hypre_CSRMatrix *) request[2]; /* communication done */ hypre_ParCSRCommHandleDestroy(comm_handle_j); hypre_ParCSRCommHandleDestroy(comm_handle_a); hypre_TFree(request, HYPRE_MEMORY_HOST); return B_int_d; } /* - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - */ /* - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - */ /* - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - - */ HYPRE_Int hypre_ParCSRMatrixExtractBExtDeviceInit( hypre_ParCSRMatrix *B, hypre_ParCSRMatrix *A, HYPRE_Int want_data, void **request_ptr) { hypre_assert( hypre_CSRMatrixMemoryLocation(hypre_ParCSRMatrixDiag(B)) == hypre_CSRMatrixMemoryLocation(hypre_ParCSRMatrixOffd(B)) ); /* hypre_assert( hypre_GetActualMemLocation( hypre_CSRMatrixMemoryLocation(hypre_ParCSRMatrixDiag(B))) == HYPRE_MEMORY_DEVICE ); */ hypre_ParcsrGetExternalRowsDeviceInit(B, hypre_CSRMatrixNumCols(hypre_ParCSRMatrixOffd(A)), hypre_ParCSRMatrixColMapOffd(A), hypre_ParCSRMatrixCommPkg(A), want_data, request_ptr); return hypre_error_flag; } hypre_CSRMatrix* hypre_ParCSRMatrixExtractBExtDeviceWait(void *request) { return hypre_ParcsrGetExternalRowsDeviceWait(request); } hypre_CSRMatrix* hypre_ParCSRMatrixExtractBExtDevice( hypre_ParCSRMatrix *B, hypre_ParCSRMatrix *A, HYPRE_Int want_data ) { void *request; hypre_ParCSRMatrixExtractBExtDeviceInit(B, A, want_data, &request); return hypre_ParCSRMatrixExtractBExtDeviceWait(request); } /*--------------------------- *---------------------------*/ typedef thrust::tuple<HYPRE_Int, HYPRE_Int> Tuple; //typedef thrust::tuple<HYPRE_Int, HYPRE_Int, HYPRe_Int> Tuple3; struct FFFC_functor : public thrust::unary_function<Tuple, HYPRE_BigInt> { HYPRE_BigInt CF_first[2]; FFFC_functor(HYPRE_BigInt F_first_, HYPRE_BigInt C_first_) { CF_first[1] = F_first_; CF_first[0] = C_first_; } __host__ __device__ HYPRE_BigInt operator()(const Tuple& t) const { const HYPRE_Int local_idx = thrust::get<0>(t); const HYPRE_Int cf_marker = thrust::get<1>(t); const HYPRE_Int s = cf_marker < 0; const HYPRE_Int m = 1 - 2*s; return m*(local_idx + CF_first[s] + s); } }; template<bool FCOL, typename T> struct FFFC_pred : public thrust::unary_function<Tuple, bool> { HYPRE_Int *row_CF_marker; T *col_CF_marker; FFFC_pred(HYPRE_Int *row_CF_marker_, T *col_CF_marker_) { row_CF_marker = row_CF_marker_; col_CF_marker = col_CF_marker_; } __host__ __device__ bool operator()(const Tuple& t) const { const HYPRE_Int i = thrust::get<0>(t); const HYPRE_Int j = thrust::get<1>(t); if (FCOL) { /* AFF */ return row_CF_marker[i] < 0 && (j == -2 || j >= 0 && col_CF_marker[j] < 0); } else { /* AFC */ return row_CF_marker[i] < 0 && (j >= 0 && col_CF_marker[j] >= 0); } } }; HYPRE_Int hypre_ParCSRMatrixGenerateFFFCDevice( hypre_ParCSRMatrix *A, HYPRE_Int *CF_marker_host, HYPRE_BigInt *cpts_starts, hypre_ParCSRMatrix *S, hypre_ParCSRMatrix **AFC_ptr, hypre_ParCSRMatrix **AFF_ptr ) { MPI_Comm comm = hypre_ParCSRMatrixComm(A); hypre_ParCSRCommPkg *comm_pkg = hypre_ParCSRMatrixCommPkg(A); hypre_ParCSRCommHandle *comm_handle; HYPRE_Int num_sends = hypre_ParCSRCommPkgNumSends(comm_pkg); HYPRE_Int num_elem_send = hypre_ParCSRCommPkgSendMapStart(comm_pkg, num_sends); //HYPRE_MemoryLocation memory_location = hypre_ParCSRMatrixMemoryLocation(A); /* diag part of A */ hypre_CSRMatrix *A_diag = hypre_ParCSRMatrixDiag(A); HYPRE_Complex *A_diag_a = hypre_CSRMatrixData(A_diag); HYPRE_Int *A_diag_i = hypre_CSRMatrixI(A_diag); HYPRE_Int *A_diag_j = hypre_CSRMatrixJ(A_diag); HYPRE_Int A_diag_nnz = hypre_CSRMatrixNumNonzeros(A_diag); /* offd part of A */ hypre_CSRMatrix *A_offd = hypre_ParCSRMatrixOffd(A); HYPRE_Complex *A_offd_a = hypre_CSRMatrixData(A_offd); HYPRE_Int *A_offd_i = hypre_CSRMatrixI(A_offd); //HYPRE_Int *A_offd_j = hypre_CSRMatrixJ(A_offd); HYPRE_Int A_offd_nnz = hypre_CSRMatrixNumNonzeros(A_offd); HYPRE_Int num_cols_A_offd = hypre_CSRMatrixNumCols(A_offd); /* SoC */ HYPRE_Int *Soc_diag_j = hypre_ParCSRMatrixSocDiagJ(S); HYPRE_Int *Soc_offd_j = hypre_ParCSRMatrixSocOffdJ(S); /* MPI size and rank*/ HYPRE_Int my_id, num_procs; /* nF and nC */ HYPRE_Int n_local, nF_local, nC_local; HYPRE_BigInt *fpts_starts, *row_starts; HYPRE_BigInt n_global, nF_global, nC_global; HYPRE_BigInt F_first, C_first; HYPRE_Int *CF_marker; /* AFF */ HYPRE_Int AFF_diag_nnz, AFF_offd_nnz; HYPRE_Int *AFF_diag_ii, *AFF_diag_i, *AFF_diag_j; HYPRE_Complex *AFF_diag_a; HYPRE_Int *AFF_offd_ii, *AFF_offd_i, *AFF_offd_j; HYPRE_Complex *AFF_offd_a; hypre_ParCSRMatrix *AFF; hypre_CSRMatrix *AFF_diag, *AFF_offd; HYPRE_BigInt *col_map_offd_AFF; HYPRE_Int num_cols_AFF_offd; /* AFC */ HYPRE_Int AFC_diag_nnz, AFC_offd_nnz; HYPRE_Int *AFC_diag_ii, *AFC_diag_i, *AFC_diag_j; HYPRE_Complex *AFC_diag_a; HYPRE_Int *AFC_offd_ii, *AFC_offd_i, *AFC_offd_j; HYPRE_Complex *AFC_offd_a; hypre_ParCSRMatrix *AFC; hypre_CSRMatrix *AFC_diag, *AFC_offd; HYPRE_BigInt *col_map_offd_AFC; HYPRE_Int num_cols_AFC_offd; /* work arrays */ HYPRE_Int *map2FC, *itmp, *A_diag_ii, *A_offd_ii, *tmp_j, *offd_mark; HYPRE_BigInt *send_buf, *recv_buf; hypre_MPI_Comm_size(comm, &num_procs); hypre_MPI_Comm_rank(comm, &my_id); n_global = hypre_ParCSRMatrixGlobalNumRows(A); n_local = hypre_ParCSRMatrixNumRows(A); row_starts = hypre_ParCSRMatrixRowStarts(A); map2FC = hypre_TAlloc(HYPRE_Int, n_local, HYPRE_MEMORY_DEVICE); itmp = hypre_TAlloc(HYPRE_Int, n_local, HYPRE_MEMORY_DEVICE);; recv_buf = hypre_TAlloc(HYPRE_BigInt, num_cols_A_offd, HYPRE_MEMORY_DEVICE); #ifdef HYPRE_NO_GLOBAL_PARTITION if (my_id == (num_procs -1)) { nC_global = cpts_starts[1]; } hypre_MPI_Bcast(&nC_global, 1, HYPRE_MPI_BIG_INT, num_procs-1, comm); nC_local = (HYPRE_Int) (cpts_starts[1] - cpts_starts[0]); fpts_starts = hypre_TAlloc(HYPRE_BigInt, 2, HYPRE_MEMORY_HOST); fpts_starts[0] = row_starts[0] - cpts_starts[0]; fpts_starts[1] = row_starts[1] - cpts_starts[1]; F_first = fpts_starts[0]; C_first = cpts_starts[0]; #else nC_global = cpts_starts[num_procs]; nC_local = (HYPRE_Int)(cpts_starts[my_id+1] - cpts_starts[my_id]); fpts_starts = hypre_TAlloc(HYPRE_BigInt, num_procs+1, HYPRE_MEMORY_HOST); for (i = 0; i <= num_procs; i++) { fpts_starts[i] = row_starts[i] - cpts_starts[i]; } F_first = fpts_starts[myid]; C_first = cpts_starts[myid]; #endif nF_local = n_local - nC_local; nF_global = n_global - nC_global; CF_marker = hypre_TAlloc(HYPRE_Int, n_local, HYPRE_MEMORY_DEVICE); hypre_TMemcpy( CF_marker, CF_marker_host, HYPRE_Int, n_local, HYPRE_MEMORY_DEVICE, HYPRE_MEMORY_HOST ); /* map from F+C to F/C indices */ HYPRE_THRUST_CALL( exclusive_scan, thrust::make_transform_iterator(CF_marker, is_negative<HYPRE_Int>()), thrust::make_transform_iterator(CF_marker + n_local, is_negative<HYPRE_Int>()), map2FC ); /* F */ HYPRE_THRUST_CALL( exclusive_scan, thrust::make_transform_iterator(CF_marker, is_nonnegative<HYPRE_Int>()), thrust::make_transform_iterator(CF_marker + n_local, is_nonnegative<HYPRE_Int>()), itmp ); /* C */ HYPRE_THRUST_CALL( scatter_if, itmp, itmp + n_local, thrust::counting_iterator<HYPRE_Int>(0), thrust::make_transform_iterator(CF_marker, is_nonnegative<HYPRE_Int>()), map2FC ); /* FC combined */ hypre_TFree(itmp, HYPRE_MEMORY_DEVICE); /* send_buf: global F/C indices. Note F-pts are saved as "-x-1" */ send_buf = hypre_TAlloc(HYPRE_BigInt, num_elem_send, HYPRE_MEMORY_DEVICE); hypre_ParCSRCommPkgCopySendMapElmtsToDevice(comm_pkg); FFFC_functor functor(F_first, C_first); HYPRE_THRUST_CALL( gather, hypre_ParCSRCommPkgDeviceSendMapElmts(comm_pkg), hypre_ParCSRCommPkgDeviceSendMapElmts(comm_pkg) + num_elem_send, thrust::make_transform_iterator(thrust::make_zip_iterator(thrust::make_tuple(map2FC, CF_marker)), functor), send_buf ); comm_handle = hypre_ParCSRCommHandleCreate_v2(21, comm_pkg, HYPRE_MEMORY_DEVICE, send_buf, HYPRE_MEMORY_DEVICE, recv_buf); hypre_ParCSRCommHandleDestroy(comm_handle); hypre_TFree(send_buf, HYPRE_MEMORY_DEVICE); /* Diag */ thrust::zip_iterator< thrust::tuple<HYPRE_Int*, HYPRE_Int*, HYPRE_Complex*> > new_end; A_diag_ii = hypre_TAlloc(HYPRE_Int, A_diag_nnz, HYPRE_MEMORY_DEVICE); hypreDevice_CsrRowPtrsToIndices_v2(n_local, A_diag_nnz, A_diag_i, A_diag_ii); /* AFF Diag */ FFFC_pred<true, HYPRE_Int> AFF_pred_diag(CF_marker, CF_marker); AFF_diag_nnz = HYPRE_THRUST_CALL( count_if, thrust::make_zip_iterator(thrust::make_tuple(A_diag_ii, Soc_diag_j)), thrust::make_zip_iterator(thrust::make_tuple(A_diag_ii, Soc_diag_j)) + A_diag_nnz, AFF_pred_diag ); AFF_diag_ii = hypre_TAlloc(HYPRE_Int, AFF_diag_nnz, HYPRE_MEMORY_DEVICE); AFF_diag_j = hypre_TAlloc(HYPRE_Int, AFF_diag_nnz, HYPRE_MEMORY_DEVICE); AFF_diag_a = hypre_TAlloc(HYPRE_Complex, AFF_diag_nnz, HYPRE_MEMORY_DEVICE); new_end = HYPRE_THRUST_CALL( copy_if, thrust::make_zip_iterator(thrust::make_tuple(A_diag_ii, A_diag_j, A_diag_a)), thrust::make_zip_iterator(thrust::make_tuple(A_diag_ii, A_diag_j, A_diag_a)) + A_diag_nnz, thrust::make_zip_iterator(thrust::make_tuple(A_diag_ii, Soc_diag_j)), thrust::make_zip_iterator(thrust::make_tuple(AFF_diag_ii, AFF_diag_j, AFF_diag_a)), AFF_pred_diag ); hypre_assert( thrust::get<0>(new_end.get_iterator_tuple()) == AFF_diag_ii + AFF_diag_nnz ); HYPRE_THRUST_CALL ( gather, AFF_diag_j, AFF_diag_j + AFF_diag_nnz, map2FC, AFF_diag_j ); HYPRE_THRUST_CALL ( gather, AFF_diag_ii, AFF_diag_ii + AFF_diag_nnz, map2FC, AFF_diag_ii ); AFF_diag_i = hypreDevice_CsrRowIndicesToPtrs(nF_local, AFF_diag_nnz, AFF_diag_ii); hypre_TFree(AFF_diag_ii, HYPRE_MEMORY_DEVICE); /* AFC Diag */ FFFC_pred<false, HYPRE_Int> AFC_pred_diag(CF_marker, CF_marker); AFC_diag_nnz = HYPRE_THRUST_CALL( count_if, thrust::make_zip_iterator(thrust::make_tuple(A_diag_ii, Soc_diag_j)), thrust::make_zip_iterator(thrust::make_tuple(A_diag_ii, Soc_diag_j)) + A_diag_nnz, AFC_pred_diag ); AFC_diag_ii = hypre_TAlloc(HYPRE_Int, AFC_diag_nnz, HYPRE_MEMORY_DEVICE); AFC_diag_j = hypre_TAlloc(HYPRE_Int, AFC_diag_nnz, HYPRE_MEMORY_DEVICE); AFC_diag_a = hypre_TAlloc(HYPRE_Complex, AFC_diag_nnz, HYPRE_MEMORY_DEVICE); new_end = HYPRE_THRUST_CALL( copy_if, thrust::make_zip_iterator(thrust::make_tuple(A_diag_ii, Soc_diag_j, A_diag_a)), thrust::make_zip_iterator(thrust::make_tuple(A_diag_ii, Soc_diag_j, A_diag_a)) + A_diag_nnz, thrust::make_zip_iterator(thrust::make_tuple(A_diag_ii, Soc_diag_j)), thrust::make_zip_iterator(thrust::make_tuple(AFC_diag_ii, AFC_diag_j, AFC_diag_a)), AFC_pred_diag ); hypre_TFree(A_diag_ii, HYPRE_MEMORY_DEVICE); hypre_assert( thrust::get<0>(new_end.get_iterator_tuple()) == AFC_diag_ii + AFC_diag_nnz ); HYPRE_THRUST_CALL ( gather, AFC_diag_j, AFC_diag_j + AFC_diag_nnz, map2FC, AFC_diag_j ); HYPRE_THRUST_CALL ( gather, AFC_diag_ii, AFC_diag_ii + AFC_diag_nnz, map2FC, AFC_diag_ii ); AFC_diag_i = hypreDevice_CsrRowIndicesToPtrs(nF_local, AFC_diag_nnz, AFC_diag_ii); hypre_TFree(AFC_diag_ii, HYPRE_MEMORY_DEVICE); /* Offd */ A_offd_ii = hypre_TAlloc(HYPRE_Int, A_offd_nnz, HYPRE_MEMORY_DEVICE); hypreDevice_CsrRowPtrsToIndices_v2(n_local, A_offd_nnz, A_offd_i, A_offd_ii); /* AFF Offd */ FFFC_pred<true, HYPRE_BigInt> AFF_pred_offd(CF_marker, recv_buf); AFF_offd_nnz = HYPRE_THRUST_CALL( count_if, thrust::make_zip_iterator(thrust::make_tuple(A_offd_ii, Soc_offd_j)), thrust::make_zip_iterator(thrust::make_tuple(A_offd_ii, Soc_offd_j)) + A_offd_nnz, AFF_pred_offd ); AFF_offd_ii = hypre_TAlloc(HYPRE_Int, AFF_offd_nnz, HYPRE_MEMORY_DEVICE); AFF_offd_j = hypre_TAlloc(HYPRE_Int, AFF_offd_nnz, HYPRE_MEMORY_DEVICE); AFF_offd_a = hypre_TAlloc(HYPRE_Complex, AFF_offd_nnz, HYPRE_MEMORY_DEVICE); new_end = HYPRE_THRUST_CALL( copy_if, thrust::make_zip_iterator(thrust::make_tuple(A_offd_ii, Soc_offd_j, A_offd_a)), thrust::make_zip_iterator(thrust::make_tuple(A_offd_ii, Soc_offd_j, A_offd_a)) + A_offd_nnz, thrust::make_zip_iterator(thrust::make_tuple(A_offd_ii, Soc_offd_j)), thrust::make_zip_iterator(thrust::make_tuple(AFF_offd_ii, AFF_offd_j, AFF_offd_a)), AFF_pred_offd ); hypre_assert( thrust::get<0>(new_end.get_iterator_tuple()) == AFF_offd_ii + AFF_offd_nnz ); HYPRE_THRUST_CALL ( gather, AFF_offd_ii, AFF_offd_ii + AFF_offd_nnz, map2FC, AFF_offd_ii ); AFF_offd_i = hypreDevice_CsrRowIndicesToPtrs(nF_local, AFF_offd_nnz, AFF_offd_ii); hypre_TFree(AFF_offd_ii, HYPRE_MEMORY_DEVICE); /* AFC Offd */ FFFC_pred<false, HYPRE_BigInt> AFC_pred_offd(CF_marker, recv_buf); AFC_offd_nnz = HYPRE_THRUST_CALL( count_if, thrust::make_zip_iterator(thrust::make_tuple(A_offd_ii, Soc_offd_j)), thrust::make_zip_iterator(thrust::make_tuple(A_offd_ii, Soc_offd_j)) + A_offd_nnz, AFC_pred_offd ); AFC_offd_ii = hypre_TAlloc(HYPRE_Int, AFC_offd_nnz, HYPRE_MEMORY_DEVICE); AFC_offd_j = hypre_TAlloc(HYPRE_Int, AFC_offd_nnz, HYPRE_MEMORY_DEVICE); AFC_offd_a = hypre_TAlloc(HYPRE_Complex, AFC_offd_nnz, HYPRE_MEMORY_DEVICE); new_end = HYPRE_THRUST_CALL( copy_if, thrust::make_zip_iterator(thrust::make_tuple(A_offd_ii, Soc_offd_j, A_offd_a)), thrust::make_zip_iterator(thrust::make_tuple(A_offd_ii, Soc_offd_j, A_offd_a)) + A_offd_nnz, thrust::make_zip_iterator(thrust::make_tuple(A_offd_ii, Soc_offd_j)), thrust::make_zip_iterator(thrust::make_tuple(AFC_offd_ii, AFC_offd_j, AFC_offd_a)), AFC_pred_offd ); hypre_TFree(A_offd_ii, HYPRE_MEMORY_DEVICE); hypre_assert( thrust::get<0>(new_end.get_iterator_tuple()) == AFC_offd_ii + AFC_offd_nnz ); HYPRE_THRUST_CALL ( gather, AFC_offd_ii, AFC_offd_ii + AFC_offd_nnz, map2FC, AFC_offd_ii ); AFC_offd_i = hypreDevice_CsrRowIndicesToPtrs(nF_local, AFC_offd_nnz, AFC_offd_ii); hypre_TFree(AFC_offd_ii, HYPRE_MEMORY_DEVICE); hypre_TFree(CF_marker, HYPRE_MEMORY_DEVICE); hypre_TFree(map2FC, HYPRE_MEMORY_DEVICE); /* col_map_offd_AFF */ HYPRE_Int tmp_j_size = hypre_max(hypre_max(AFF_offd_nnz, AFC_offd_nnz), num_cols_A_offd); tmp_j = hypre_TAlloc(HYPRE_Int, tmp_j_size, HYPRE_MEMORY_DEVICE); offd_mark = hypre_TAlloc(HYPRE_Int, num_cols_A_offd, HYPRE_MEMORY_DEVICE); HYPRE_Int *tmp_end; hypre_TMemcpy(tmp_j, AFF_offd_j, HYPRE_Int, AFF_offd_nnz, HYPRE_MEMORY_DEVICE, HYPRE_MEMORY_DEVICE); HYPRE_THRUST_CALL(sort, tmp_j, tmp_j + AFF_offd_nnz); tmp_end = HYPRE_THRUST_CALL(unique, tmp_j, tmp_j + AFF_offd_nnz); num_cols_AFF_offd = tmp_end - tmp_j; HYPRE_THRUST_CALL(fill_n, offd_mark, num_cols_A_offd, 0); hypreDevice_ScatterConstant(offd_mark, num_cols_AFF_offd, tmp_j, 1); HYPRE_THRUST_CALL(exclusive_scan, offd_mark, offd_mark + num_cols_A_offd, tmp_j); HYPRE_THRUST_CALL(gather, AFF_offd_j, AFF_offd_j + AFF_offd_nnz, tmp_j, AFF_offd_j); col_map_offd_AFF = hypre_TAlloc(HYPRE_Int, num_cols_AFF_offd, HYPRE_MEMORY_DEVICE); tmp_end = HYPRE_THRUST_CALL( copy_if, thrust::make_transform_iterator(recv_buf, -_1-1), thrust::make_transform_iterator(recv_buf, -_1-1) + num_cols_A_offd, offd_mark, col_map_offd_AFF, thrust::identity<HYPRE_Int>() ); hypre_assert(tmp_end - col_map_offd_AFF == num_cols_AFF_offd); /* col_map_offd_AFC */ hypre_TMemcpy(tmp_j, AFC_offd_j, HYPRE_Int, AFC_offd_nnz, HYPRE_MEMORY_DEVICE, HYPRE_MEMORY_DEVICE); HYPRE_THRUST_CALL(sort, tmp_j, tmp_j + AFC_offd_nnz); tmp_end = HYPRE_THRUST_CALL(unique, tmp_j, tmp_j + AFC_offd_nnz); num_cols_AFC_offd = tmp_end - tmp_j; HYPRE_THRUST_CALL(fill_n, offd_mark, num_cols_A_offd, 0); hypreDevice_ScatterConstant(offd_mark, num_cols_AFC_offd, tmp_j, 1); HYPRE_THRUST_CALL(exclusive_scan, offd_mark, offd_mark + num_cols_A_offd, tmp_j); HYPRE_THRUST_CALL(gather, AFC_offd_j, AFC_offd_j + AFC_offd_nnz, tmp_j, AFC_offd_j); col_map_offd_AFC = hypre_TAlloc(HYPRE_Int, num_cols_AFC_offd, HYPRE_MEMORY_DEVICE); tmp_end = HYPRE_THRUST_CALL( copy_if, recv_buf, recv_buf + num_cols_A_offd, offd_mark, col_map_offd_AFC, thrust::identity<HYPRE_Int>()); hypre_assert(tmp_end - col_map_offd_AFC == num_cols_AFC_offd); hypre_TFree(tmp_j, HYPRE_MEMORY_DEVICE); hypre_TFree(offd_mark, HYPRE_MEMORY_DEVICE); hypre_TFree(recv_buf, HYPRE_MEMORY_DEVICE); //printf("AFF_diag_nnz %d, AFF_offd_nnz %d, AFC_diag_nnz %d, AFC_offd_nnz %d\n", AFF_diag_nnz, AFF_offd_nnz, AFC_diag_nnz, AFC_offd_nnz); /* AFF */ AFF = hypre_ParCSRMatrixCreate(comm, nF_global, nF_global, fpts_starts, fpts_starts, num_cols_AFF_offd, AFF_diag_nnz, AFF_offd_nnz); hypre_ParCSRMatrixOwnsRowStarts(AFF) = 1; hypre_ParCSRMatrixOwnsColStarts(AFF) = 0; AFF_diag = hypre_ParCSRMatrixDiag(AFF); hypre_CSRMatrixData(AFF_diag) = AFF_diag_a; hypre_CSRMatrixI(AFF_diag) = AFF_diag_i; hypre_CSRMatrixJ(AFF_diag) = AFF_diag_j; AFF_offd = hypre_ParCSRMatrixOffd(AFF); hypre_CSRMatrixData(AFF_offd) = AFF_offd_a; hypre_CSRMatrixI(AFF_offd) = AFF_offd_i; hypre_CSRMatrixJ(AFF_offd) = AFF_offd_j; hypre_CSRMatrixMemoryLocation(AFF_diag) = HYPRE_MEMORY_DEVICE; hypre_CSRMatrixMemoryLocation(AFF_offd) = HYPRE_MEMORY_DEVICE; hypre_ParCSRMatrixDeviceColMapOffd(AFF) = col_map_offd_AFF; hypre_ParCSRMatrixColMapOffd(AFF) = hypre_TAlloc(HYPRE_BigInt, num_cols_AFF_offd, HYPRE_MEMORY_HOST); hypre_TMemcpy(hypre_ParCSRMatrixColMapOffd(AFF), col_map_offd_AFF, HYPRE_BigInt, num_cols_AFF_offd, HYPRE_MEMORY_HOST, HYPRE_MEMORY_DEVICE); hypre_ParCSRMatrixSetNumNonzeros(AFF); hypre_ParCSRMatrixDNumNonzeros(AFF) = (HYPRE_Real) hypre_ParCSRMatrixNumNonzeros(AFF); hypre_MatvecCommPkgCreate(AFF); /* AFC */ AFC = hypre_ParCSRMatrixCreate(comm, nF_global, nC_global, fpts_starts, cpts_starts, num_cols_AFC_offd, AFC_diag_nnz, AFC_offd_nnz); hypre_ParCSRMatrixOwnsRowStarts(AFC) = 0; hypre_ParCSRMatrixOwnsColStarts(AFC) = 0; AFC_diag = hypre_ParCSRMatrixDiag(AFC); hypre_CSRMatrixData(AFC_diag) = AFC_diag_a; hypre_CSRMatrixI(AFC_diag) = AFC_diag_i; hypre_CSRMatrixJ(AFC_diag) = AFC_diag_j; AFC_offd = hypre_ParCSRMatrixOffd(AFC); hypre_CSRMatrixData(AFC_offd) = AFC_offd_a; hypre_CSRMatrixI(AFC_offd) = AFC_offd_i; hypre_CSRMatrixJ(AFC_offd) = AFC_offd_j; hypre_CSRMatrixMemoryLocation(AFC_diag) = HYPRE_MEMORY_DEVICE; hypre_CSRMatrixMemoryLocation(AFC_offd) = HYPRE_MEMORY_DEVICE; hypre_ParCSRMatrixDeviceColMapOffd(AFC) = col_map_offd_AFC; hypre_ParCSRMatrixColMapOffd(AFC) = hypre_TAlloc(HYPRE_BigInt, num_cols_AFC_offd, HYPRE_MEMORY_HOST); hypre_TMemcpy(hypre_ParCSRMatrixColMapOffd(AFC), col_map_offd_AFC, HYPRE_BigInt, num_cols_AFC_offd, HYPRE_MEMORY_HOST, HYPRE_MEMORY_DEVICE); hypre_ParCSRMatrixSetNumNonzeros(AFC); hypre_ParCSRMatrixDNumNonzeros(AFC) = (HYPRE_Real) hypre_ParCSRMatrixNumNonzeros(AFC); hypre_MatvecCommPkgCreate(AFC); *AFC_ptr = AFC; *AFF_ptr = AFF; return hypre_error_flag; } /* return B = [Adiag, Aoffd] */ #if 1 __global__ void hypreCUDAKernel_ConcatDiagAndOffd(HYPRE_Int nrows, HYPRE_Int diag_ncol, HYPRE_Int *d_diag_i, HYPRE_Int *d_diag_j, HYPRE_Complex *d_diag_a, HYPRE_Int *d_offd_i, HYPRE_Int *d_offd_j, HYPRE_Complex *d_offd_a, HYPRE_Int *cols_offd_map, HYPRE_Int *d_ib, HYPRE_Int *d_jb, HYPRE_Complex *d_ab) { const HYPRE_Int row = hypre_cuda_get_grid_warp_id<1,1>(); if (row >= nrows) { return; } /* lane id inside the warp */ const HYPRE_Int lane_id = hypre_cuda_get_lane_id<1>(); HYPRE_Int i, j, k, p, istart, iend, bstart; /* diag part */ if (lane_id < 2) { j = read_only_load(d_diag_i + row + lane_id); } if (lane_id == 0) { k = read_only_load(d_ib + row); } istart = __shfl_sync(HYPRE_WARP_FULL_MASK, j, 0); iend = __shfl_sync(HYPRE_WARP_FULL_MASK, j, 1); bstart = __shfl_sync(HYPRE_WARP_FULL_MASK, k, 0); p = bstart - istart; for (i = istart + lane_id; i < iend; i += HYPRE_WARP_SIZE) { d_jb[p+i] = read_only_load(d_diag_j + i); d_ab[p+i] = read_only_load(d_diag_a + i); } /* offd part */ if (lane_id < 2) { j = read_only_load(d_offd_i + row + lane_id); } bstart += iend - istart; istart = __shfl_sync(HYPRE_WARP_FULL_MASK, j, 0); iend = __shfl_sync(HYPRE_WARP_FULL_MASK, j, 1); p = bstart - istart; for (i = istart + lane_id; i < iend; i += HYPRE_WARP_SIZE) { const HYPRE_Int t = read_only_load(d_offd_j + i); d_jb[p+i] = (cols_offd_map ? read_only_load(&cols_offd_map[t]) : t) + diag_ncol; d_ab[p+i] = read_only_load(d_offd_a + i); } } hypre_CSRMatrix* hypre_ConcatDiagAndOffdDevice(hypre_ParCSRMatrix *A) { hypre_CSRMatrix *A_diag = hypre_ParCSRMatrixDiag(A); hypre_CSRMatrix *A_offd = hypre_ParCSRMatrixOffd(A); hypre_CSRMatrix *B = hypre_CSRMatrixCreate( hypre_CSRMatrixNumRows(A_diag), hypre_CSRMatrixNumCols(A_diag) + hypre_CSRMatrixNumCols(A_offd), hypre_CSRMatrixNumNonzeros(A_diag) + hypre_CSRMatrixNumNonzeros(A_offd) ); hypre_CSRMatrixInitialize_v2(B, 0, HYPRE_MEMORY_DEVICE); hypreDevice_GetRowNnz(hypre_CSRMatrixNumRows(B), NULL, hypre_CSRMatrixI(A_diag), hypre_CSRMatrixI(A_offd), hypre_CSRMatrixI(B)); HYPRE_THRUST_CALL( exclusive_scan, hypre_CSRMatrixI(B), hypre_CSRMatrixI(B) + hypre_CSRMatrixNumRows(B) + 1, hypre_CSRMatrixI(B) ); const dim3 bDim = hypre_GetDefaultCUDABlockDimension(); const dim3 gDim = hypre_GetDefaultCUDAGridDimension(hypre_CSRMatrixNumRows(A_diag), "warp", bDim); HYPRE_CUDA_LAUNCH( hypreCUDAKernel_ConcatDiagAndOffd, gDim, bDim, hypre_CSRMatrixNumRows(A_diag), hypre_CSRMatrixNumCols(A_diag), hypre_CSRMatrixI(A_diag), hypre_CSRMatrixJ(A_diag), hypre_CSRMatrixData(A_diag), hypre_CSRMatrixI(A_offd), hypre_CSRMatrixJ(A_offd), hypre_CSRMatrixData(A_offd), NULL, hypre_CSRMatrixI(B), hypre_CSRMatrixJ(B), hypre_CSRMatrixData(B) ); return B; } #else hypre_CSRMatrix* hypre_ConcatDiagAndOffdDevice(hypre_ParCSRMatrix *A) { hypre_CSRMatrix *A_diag = hypre_ParCSRMatrixDiag(A); HYPRE_Int *A_diag_i = hypre_CSRMatrixI(A_diag); HYPRE_Int *A_diag_j = hypre_CSRMatrixJ(A_diag); HYPRE_Complex *A_diag_a = hypre_CSRMatrixData(A_diag); HYPRE_Int A_diag_nnz = hypre_CSRMatrixNumNonzeros(A_diag); hypre_CSRMatrix *A_offd = hypre_ParCSRMatrixOffd(A); HYPRE_Int *A_offd_i = hypre_CSRMatrixI(A_offd); HYPRE_Int *A_offd_j = hypre_CSRMatrixJ(A_offd); HYPRE_Complex *A_offd_a = hypre_CSRMatrixData(A_offd); HYPRE_Int A_offd_nnz = hypre_CSRMatrixNumNonzeros(A_offd); hypre_CSRMatrix *B; HYPRE_Int B_nrows = hypre_CSRMatrixNumRows(A_diag); HYPRE_Int B_ncols = hypre_CSRMatrixNumCols(A_diag) + hypre_CSRMatrixNumCols(A_offd); HYPRE_Int B_nnz = A_diag_nnz + A_offd_nnz; HYPRE_Int *B_ii = hypre_TAlloc(HYPRE_Int, B_nnz, HYPRE_MEMORY_DEVICE); HYPRE_Int *B_j = hypre_TAlloc(HYPRE_Int, B_nnz, HYPRE_MEMORY_DEVICE); HYPRE_Complex *B_a = hypre_TAlloc(HYPRE_Complex, B_nnz, HYPRE_MEMORY_DEVICE); // Adiag HYPRE_Int *A_diag_ii = hypreDevice_CsrRowPtrsToIndices(B_nrows, A_diag_nnz, A_diag_i); HYPRE_THRUST_CALL( copy_n, thrust::make_zip_iterator(thrust::make_tuple(A_diag_ii, A_diag_j, A_diag_a)), A_diag_nnz, thrust::make_zip_iterator(thrust::make_tuple(B_ii, B_j, B_a)) ); hypre_TFree(A_diag_ii, HYPRE_MEMORY_DEVICE); // Aoffd HYPRE_Int *A_offd_ii = hypreDevice_CsrRowPtrsToIndices(B_nrows, A_offd_nnz, A_offd_i); HYPRE_THRUST_CALL( copy_n, thrust::make_zip_iterator(thrust::make_tuple(A_offd_ii, A_offd_a)), A_offd_nnz, thrust::make_zip_iterator(thrust::make_tuple(B_ii, B_a)) + A_diag_nnz ); hypre_TFree(A_offd_ii, HYPRE_MEMORY_DEVICE); HYPRE_THRUST_CALL( transform, A_offd_j, A_offd_j + A_offd_nnz, thrust::make_constant_iterator(hypre_CSRMatrixNumCols(A_diag)), B_j + A_diag_nnz, thrust::plus<HYPRE_Int>() ); // B HYPRE_THRUST_CALL( stable_sort_by_key, B_ii, B_ii + B_nnz, thrust::make_zip_iterator(thrust::make_tuple(B_j, B_a)) ); HYPRE_Int *B_i = hypreDevice_CsrRowIndicesToPtrs(B_nrows, B_nnz, B_ii); hypre_TFree(B_ii, HYPRE_MEMORY_DEVICE); B = hypre_CSRMatrixCreate(B_nrows, B_ncols, B_nnz); hypre_CSRMatrixI(B) = B_i; hypre_CSRMatrixJ(B) = B_j; hypre_CSRMatrixData(B) = B_a; hypre_CSRMatrixMemoryLocation(B) = HYPRE_MEMORY_DEVICE; return B; } #endif /* return B = [Adiag, Aoffd; E] */ #if 1 HYPRE_Int hypre_ConcatDiagOffdAndExtDevice(hypre_ParCSRMatrix *A, hypre_CSRMatrix *E, hypre_CSRMatrix **B_ptr, HYPRE_Int *num_cols_offd_ptr, HYPRE_BigInt **cols_map_offd_ptr) { hypre_CSRMatrix *A_diag = hypre_ParCSRMatrixDiag(A); hypre_CSRMatrix *A_offd = hypre_ParCSRMatrixOffd(A); hypre_CSRMatrix *E_diag, *E_offd, *B; HYPRE_Int *cols_offd_map, num_cols_offd; HYPRE_BigInt *cols_map_offd; hypre_CSRMatrixSplitDevice(E, hypre_ParCSRMatrixFirstColDiag(A), hypre_ParCSRMatrixLastColDiag(A), hypre_CSRMatrixNumCols(A_offd), hypre_ParCSRMatrixDeviceColMapOffd(A), &cols_offd_map, &num_cols_offd, &cols_map_offd, &E_diag, &E_offd); B = hypre_CSRMatrixCreate(hypre_ParCSRMatrixNumRows(A) + hypre_CSRMatrixNumRows(E), hypre_ParCSRMatrixNumCols(A) + num_cols_offd, hypre_CSRMatrixNumNonzeros(A_diag) + hypre_CSRMatrixNumNonzeros(A_offd) + hypre_CSRMatrixNumNonzeros(E)); hypre_CSRMatrixInitialize_v2(B, 0, HYPRE_MEMORY_DEVICE); hypreDevice_GetRowNnz(hypre_ParCSRMatrixNumRows(A), NULL, hypre_CSRMatrixI(A_diag), hypre_CSRMatrixI(A_offd), hypre_CSRMatrixI(B)); HYPRE_THRUST_CALL( exclusive_scan, hypre_CSRMatrixI(B), hypre_CSRMatrixI(B) + hypre_ParCSRMatrixNumRows(A) + 1, hypre_CSRMatrixI(B) ); dim3 bDim = hypre_GetDefaultCUDABlockDimension(); dim3 gDim = hypre_GetDefaultCUDAGridDimension(hypre_ParCSRMatrixNumRows(A), "warp", bDim); HYPRE_CUDA_LAUNCH( hypreCUDAKernel_ConcatDiagAndOffd, gDim, bDim, hypre_CSRMatrixNumRows(A_diag), hypre_CSRMatrixNumCols(A_diag), hypre_CSRMatrixI(A_diag), hypre_CSRMatrixJ(A_diag), hypre_CSRMatrixData(A_diag), hypre_CSRMatrixI(A_offd), hypre_CSRMatrixJ(A_offd), hypre_CSRMatrixData(A_offd), cols_offd_map, hypre_CSRMatrixI(B), hypre_CSRMatrixJ(B), hypre_CSRMatrixData(B) ); hypre_TFree(cols_offd_map, HYPRE_MEMORY_DEVICE); hypre_TMemcpy(hypre_CSRMatrixI(B) + hypre_ParCSRMatrixNumRows(A) + 1, hypre_CSRMatrixI(E) + 1, HYPRE_Int, hypre_CSRMatrixNumRows(E), HYPRE_MEMORY_DEVICE, HYPRE_MEMORY_DEVICE); HYPRE_THRUST_CALL( transform, hypre_CSRMatrixI(B) + hypre_ParCSRMatrixNumRows(A) + 1, hypre_CSRMatrixI(B) + hypre_ParCSRMatrixNumRows(A) + hypre_CSRMatrixNumRows(E) + 1, thrust::make_constant_iterator(hypre_CSRMatrixNumNonzeros(A_diag) + hypre_CSRMatrixNumNonzeros(A_offd)), hypre_CSRMatrixI(B) + hypre_ParCSRMatrixNumRows(A) + 1, thrust::plus<HYPRE_Int>() ); gDim = hypre_GetDefaultCUDAGridDimension(hypre_CSRMatrixNumRows(E), "warp", bDim); hypre_assert(hypre_CSRMatrixNumCols(E_diag) == hypre_CSRMatrixNumCols(A_diag)); HYPRE_CUDA_LAUNCH( hypreCUDAKernel_ConcatDiagAndOffd, gDim, bDim, hypre_CSRMatrixNumRows(E_diag), hypre_CSRMatrixNumCols(E_diag), hypre_CSRMatrixI(E_diag), hypre_CSRMatrixJ(E_diag), hypre_CSRMatrixData(E_diag), hypre_CSRMatrixI(E_offd), hypre_CSRMatrixJ(E_offd), hypre_CSRMatrixData(E_offd), NULL, hypre_CSRMatrixI(B) + hypre_ParCSRMatrixNumRows(A), hypre_CSRMatrixJ(B), hypre_CSRMatrixData(B) ); hypre_CSRMatrixDestroy(E_diag); hypre_CSRMatrixDestroy(E_offd); *B_ptr = B; *num_cols_offd_ptr = num_cols_offd; *cols_map_offd_ptr = cols_map_offd; return hypre_error_flag; } #else HYPRE_Int hypre_ConcatDiagOffdAndExtDevice(hypre_ParCSRMatrix *A, hypre_CSRMatrix *E, hypre_CSRMatrix **B_ptr, HYPRE_Int *num_cols_offd_ptr, HYPRE_BigInt **cols_map_offd_ptr) { hypre_CSRMatrix *A_diag = hypre_ParCSRMatrixDiag(A); HYPRE_Int A_nrows = hypre_CSRMatrixNumRows(A_diag); HYPRE_Int A_ncols = hypre_CSRMatrixNumCols(A_diag); HYPRE_Int *A_diag_i = hypre_CSRMatrixI(A_diag); HYPRE_Int *A_diag_j = hypre_CSRMatrixJ(A_diag); HYPRE_Complex *A_diag_a = hypre_CSRMatrixData(A_diag); HYPRE_Int A_diag_nnz = hypre_CSRMatrixNumNonzeros(A_diag); hypre_CSRMatrix *A_offd = hypre_ParCSRMatrixOffd(A); HYPRE_Int *A_offd_i = hypre_CSRMatrixI(A_offd); HYPRE_Int *A_offd_j = hypre_CSRMatrixJ(A_offd); HYPRE_Complex *A_offd_a = hypre_CSRMatrixData(A_offd); HYPRE_Int A_offd_nnz = hypre_CSRMatrixNumNonzeros(A_offd); HYPRE_BigInt first_col_A = hypre_ParCSRMatrixFirstColDiag(A); HYPRE_BigInt last_col_A = hypre_ParCSRMatrixLastColDiag(A); HYPRE_Int num_cols_offd_A = hypre_CSRMatrixNumCols(A_offd); HYPRE_BigInt *col_map_offd_A = hypre_ParCSRMatrixDeviceColMapOffd(A); HYPRE_Int *E_i = hypre_CSRMatrixI(E); HYPRE_BigInt *E_bigj = hypre_CSRMatrixBigJ(E); HYPRE_Complex *E_a = hypre_CSRMatrixData(E); HYPRE_Int E_nrows = hypre_CSRMatrixNumRows(E); HYPRE_Int E_nnz = hypre_CSRMatrixNumNonzeros(E); HYPRE_Int E_diag_nnz, E_offd_nnz; hypre_CSRMatrix *B; HYPRE_Int B_nnz = A_diag_nnz + A_offd_nnz + E_nnz; HYPRE_Int *B_ii = hypre_TAlloc(HYPRE_Int, B_nnz, HYPRE_MEMORY_DEVICE); HYPRE_Int *B_j = hypre_TAlloc(HYPRE_Int, B_nnz, HYPRE_MEMORY_DEVICE); HYPRE_Complex *B_a = hypre_TAlloc(HYPRE_Complex, B_nnz, HYPRE_MEMORY_DEVICE); // E hypre_CSRMatrixSplitDevice_core(0, E_nrows, E_nnz, NULL, E_bigj, NULL, NULL, first_col_A, last_col_A, num_cols_offd_A, NULL, NULL, NULL, NULL, &E_diag_nnz, NULL, NULL, NULL, NULL, &E_offd_nnz, NULL, NULL, NULL, NULL); HYPRE_Int *cols_offd_map, num_cols_offd; HYPRE_BigInt *cols_map_offd; HYPRE_Int *E_ii = hypreDevice_CsrRowPtrsToIndices(E_nrows, E_nnz, E_i); hypre_CSRMatrixSplitDevice_core(1, E_nrows, E_nnz, E_ii, E_bigj, E_a, NULL, first_col_A, last_col_A, num_cols_offd_A, col_map_offd_A, &cols_offd_map, &num_cols_offd, &cols_map_offd, &E_diag_nnz, B_ii + A_diag_nnz + A_offd_nnz, B_j + A_diag_nnz + A_offd_nnz, B_a + A_diag_nnz + A_offd_nnz, NULL, &E_offd_nnz, B_ii + A_diag_nnz + A_offd_nnz + E_diag_nnz, B_j + A_diag_nnz + A_offd_nnz + E_diag_nnz, B_a + A_diag_nnz + A_offd_nnz + E_diag_nnz, NULL); hypre_TFree(E_ii, HYPRE_MEMORY_DEVICE); HYPRE_THRUST_CALL( transform, B_ii + A_diag_nnz + A_offd_nnz, B_ii + B_nnz, thrust::make_constant_iterator(A_nrows), B_ii + A_diag_nnz + A_offd_nnz, thrust::plus<HYPRE_Int>() ); // Adiag HYPRE_Int *A_diag_ii = hypreDevice_CsrRowPtrsToIndices(A_nrows, A_diag_nnz, A_diag_i); HYPRE_THRUST_CALL( copy_n, thrust::make_zip_iterator(thrust::make_tuple(A_diag_ii, A_diag_j, A_diag_a)), A_diag_nnz, thrust::make_zip_iterator(thrust::make_tuple(B_ii, B_j, B_a)) ); hypre_TFree(A_diag_ii, HYPRE_MEMORY_DEVICE); // Aoffd HYPRE_Int *A_offd_ii = hypreDevice_CsrRowPtrsToIndices(A_nrows, A_offd_nnz, A_offd_i); HYPRE_THRUST_CALL( copy_n, thrust::make_zip_iterator(thrust::make_tuple(A_offd_ii, A_offd_a)), A_offd_nnz, thrust::make_zip_iterator(thrust::make_tuple(B_ii, B_a)) + A_diag_nnz ); hypre_TFree(A_offd_ii, HYPRE_MEMORY_DEVICE); HYPRE_THRUST_CALL( gather, A_offd_j, A_offd_j + A_offd_nnz, cols_offd_map, B_j + A_diag_nnz); hypre_TFree(cols_offd_map, HYPRE_MEMORY_DEVICE); HYPRE_THRUST_CALL( transform, B_j + A_diag_nnz, B_j + A_diag_nnz + A_offd_nnz, thrust::make_constant_iterator(A_ncols), B_j + A_diag_nnz, thrust::plus<HYPRE_Int>() ); HYPRE_THRUST_CALL( transform, B_j + A_diag_nnz + A_offd_nnz + E_diag_nnz, B_j + B_nnz, thrust::make_constant_iterator(A_ncols), B_j + A_diag_nnz + A_offd_nnz + E_diag_nnz, thrust::plus<HYPRE_Int>() ); // B HYPRE_THRUST_CALL( stable_sort_by_key, B_ii, B_ii + B_nnz, thrust::make_zip_iterator(thrust::make_tuple(B_j, B_a)) ); HYPRE_Int *B_i = hypreDevice_CsrRowIndicesToPtrs(A_nrows + E_nrows, B_nnz, B_ii); hypre_TFree(B_ii, HYPRE_MEMORY_DEVICE); B = hypre_CSRMatrixCreate(A_nrows + E_nrows, A_ncols + num_cols_offd, B_nnz); hypre_CSRMatrixI(B) = B_i; hypre_CSRMatrixJ(B) = B_j; hypre_CSRMatrixData(B) = B_a; hypre_CSRMatrixMemoryLocation(B) = HYPRE_MEMORY_DEVICE; *B_ptr = B; *num_cols_offd_ptr = num_cols_offd; *cols_map_offd_ptr = cols_map_offd; return hypre_error_flag; } #endif HYPRE_Int hypre_ParCSRMatrixGetRowDevice( hypre_ParCSRMatrix *mat, HYPRE_BigInt row, HYPRE_Int *size, HYPRE_BigInt **col_ind, HYPRE_Complex **values ) { HYPRE_Int nrows, local_row; HYPRE_BigInt row_start, row_end; hypre_CSRMatrix *Aa; hypre_CSRMatrix *Ba; if (!mat) { hypre_error_in_arg(1); return hypre_error_flag; } Aa = (hypre_CSRMatrix *) hypre_ParCSRMatrixDiag(mat); Ba = (hypre_CSRMatrix *) hypre_ParCSRMatrixOffd(mat); if (hypre_ParCSRMatrixGetrowactive(mat)) { return(-1); } hypre_ParCSRMatrixGetrowactive(mat) = 1; #ifdef HYPRE_NO_GLOBAL_PARTITION row_start = hypre_ParCSRMatrixFirstRowIndex(mat); row_end = hypre_ParCSRMatrixLastRowIndex(mat) + 1; #else HYPRE_Int my_id; hypre_MPI_Comm_rank(hypre_ParCSRMatrixComm(mat), &my_id); row_end = hypre_ParCSRMatrixRowStarts(mat)[ my_id + 1 ]; row_start = hypre_ParCSRMatrixRowStarts(mat)[ my_id ]; #endif nrows = row_end - row_start; if (row < row_start || row >= row_end) { return(-1); } local_row = row - row_start; /* if buffer is not allocated and some information is requested, allocate buffer with the max row_nnz */ if ( !hypre_ParCSRMatrixRowvalues(mat) && (col_ind || values) ) { HYPRE_Int max_row_nnz; HYPRE_Int *row_nnz = hypre_TAlloc(HYPRE_Int, nrows, HYPRE_MEMORY_DEVICE); hypreDevice_GetRowNnz(nrows, NULL, hypre_CSRMatrixI(Aa), hypre_CSRMatrixI(Ba), row_nnz); hypre_TMemcpy(size, row_nnz + local_row, HYPRE_Int, 1, HYPRE_MEMORY_HOST, HYPRE_MEMORY_DEVICE); max_row_nnz = HYPRE_THRUST_CALL(reduce, row_nnz, row_nnz + nrows, 0, thrust::maximum<HYPRE_Int>()); /* HYPRE_Int *max_row_nnz_d = HYPRE_THRUST_CALL(max_element, row_nnz, row_nnz + nrows); hypre_TMemcpy( &max_row_nnz, max_row_nnz_d, HYPRE_Int, 1, HYPRE_MEMORY_HOST, HYPRE_MEMORY_DEVICE ); */ hypre_TFree(row_nnz, HYPRE_MEMORY_DEVICE); hypre_ParCSRMatrixRowvalues(mat) = (HYPRE_Complex *) hypre_TAlloc(HYPRE_Complex, max_row_nnz, hypre_ParCSRMatrixMemoryLocation(mat)); hypre_ParCSRMatrixRowindices(mat) = (HYPRE_BigInt *) hypre_TAlloc(HYPRE_BigInt, max_row_nnz, hypre_ParCSRMatrixMemoryLocation(mat)); } else { HYPRE_Int *size_d = hypre_TAlloc(HYPRE_Int, 1, HYPRE_MEMORY_DEVICE); hypreDevice_GetRowNnz(1, NULL, hypre_CSRMatrixI(Aa) + local_row, hypre_CSRMatrixI(Ba) + local_row, size_d); hypre_TMemcpy(size, size_d, HYPRE_Int, 1, HYPRE_MEMORY_HOST, HYPRE_MEMORY_DEVICE); hypre_TFree(size_d, HYPRE_MEMORY_DEVICE); } if (col_ind || values) { if (hypre_ParCSRMatrixDeviceColMapOffd(mat) == NULL) { hypre_ParCSRMatrixDeviceColMapOffd(mat) = hypre_TAlloc(HYPRE_BigInt, hypre_CSRMatrixNumCols(Ba), HYPRE_MEMORY_DEVICE); hypre_TMemcpy( hypre_ParCSRMatrixDeviceColMapOffd(mat), hypre_ParCSRMatrixColMapOffd(mat), HYPRE_BigInt, hypre_CSRMatrixNumCols(Ba), HYPRE_MEMORY_DEVICE, HYPRE_MEMORY_HOST ); } hypreDevice_CopyParCSRRows( 1, NULL, -1, Ba != NULL, hypre_ParCSRMatrixFirstColDiag(mat), hypre_ParCSRMatrixDeviceColMapOffd(mat), hypre_CSRMatrixI(Aa) + local_row, hypre_CSRMatrixJ(Aa), hypre_CSRMatrixData(Aa), hypre_CSRMatrixI(Ba) + local_row, hypre_CSRMatrixJ(Ba), hypre_CSRMatrixData(Ba), NULL, hypre_ParCSRMatrixRowindices(mat), hypre_ParCSRMatrixRowvalues(mat) ); } if (col_ind) { *col_ind = hypre_ParCSRMatrixRowindices(mat); } if (values) { *values = hypre_ParCSRMatrixRowvalues(mat); } hypre_SyncCudaComputeStream(hypre_handle()); return hypre_error_flag; } #endif // #if defined(HYPRE_USING_CUDA) /*-------------------------------------------------------------------------- * HYPRE_ParCSRDiagScale *--------------------------------------------------------------------------*/ HYPRE_Int hypre_ParCSRDiagScale( HYPRE_ParCSRMatrix HA, HYPRE_ParVector Hy, HYPRE_ParVector Hx ) { hypre_ParCSRMatrix *A = (hypre_ParCSRMatrix *) HA; hypre_ParVector *y = (hypre_ParVector *) Hy; hypre_ParVector *x = (hypre_ParVector *) Hx; HYPRE_Real *x_data = hypre_VectorData(hypre_ParVectorLocalVector(x)); HYPRE_Real *y_data = hypre_VectorData(hypre_ParVectorLocalVector(y)); HYPRE_Real *A_data = hypre_CSRMatrixData(hypre_ParCSRMatrixDiag(A)); HYPRE_Int *A_i = hypre_CSRMatrixI(hypre_ParCSRMatrixDiag(A)); HYPRE_Int local_size = hypre_VectorSize(hypre_ParVectorLocalVector(x)); HYPRE_Int ierr = 0; #if defined(HYPRE_USING_CUDA) hypreDevice_DiagScaleVector(local_size, A_i, A_data, y_data, x_data); //hypre_SyncCudaComputeStream(hypre_handle()); #else /* #if defined(HYPRE_USING_CUDA) */ HYPRE_Int i; #if defined(HYPRE_USING_DEVICE_OPENMP) #pragma omp target teams distribute parallel for private(i) is_device_ptr(x_data,y_data,A_data,A_i) #elif defined(HYPRE_USING_OPENMP) #pragma omp parallel for private(i) HYPRE_SMP_SCHEDULE #endif for (i = 0; i < local_size; i++) { x_data[i] = y_data[i]/A_data[A_i[i]]; } #endif /* #if defined(HYPRE_USING_CUDA) */ return ierr; }

GB_binop__plus_fc32.c

//------------------------------------------------------------------------------ // GB_binop: hard-coded functions for each built-in binary operator //------------------------------------------------------------------------------ // SuiteSparse:GraphBLAS, Timothy A. Davis, (c) 2017-2021, All Rights Reserved. // SPDX-License-Identifier: Apache-2.0 //------------------------------------------------------------------------------ // If this file is in the Generated2/ folder, do not edit it // (it is auto-generated from Generator/*). #include "GB.h" #ifndef GBCOMPACT #include "GB_emult.h" #include "GB_control.h" #include "GB_ek_slice.h" #include "GB_dense.h" #include "GB_atomics.h" #include "GB_bitmap_assign_methods.h" #include "GB_binop__include.h" // C=binop(A,B) is defined by the following types and operators: // A+B function (eWiseAdd): GB (_AaddB__plus_fc32) // A.*B function (eWiseMult): GB (_AemultB_01__plus_fc32) // A.*B function (eWiseMult): GB (_AemultB_02__plus_fc32) // A.*B function (eWiseMult): GB (_AemultB_03__plus_fc32) // A.*B function (eWiseMult): GB (_AemultB_bitmap__plus_fc32) // A*D function (colscale): GB (_AxD__plus_fc32) // D*A function (rowscale): GB (_DxB__plus_fc32) // C+=B function (dense accum): GB (_Cdense_accumB__plus_fc32) // C+=b function (dense accum): GB (_Cdense_accumb__plus_fc32) // C+=A+B function (dense ewise3): GB (_Cdense_ewise3_accum__plus_fc32) // C=A+B function (dense ewise3): GB (_Cdense_ewise3_noaccum__plus_fc32) // C=scalar+B GB (_bind1st__plus_fc32) // C=scalar+B' GB (_bind1st_tran__plus_fc32) // C=A+scalar GB (_bind2nd__plus_fc32) // C=A'+scalar GB (_bind2nd_tran__plus_fc32) // C type: GxB_FC32_t // A type: GxB_FC32_t // B,b type: GxB_FC32_t // BinaryOp: cij = GB_FC32_add (aij, bij) #define GB_ATYPE \ GxB_FC32_t #define GB_BTYPE \ GxB_FC32_t #define GB_CTYPE \ GxB_FC32_t // true if the types of A and B are identical #define GB_ATYPE_IS_BTYPE \ 1 // true if the types of C and A are identical #define GB_CTYPE_IS_ATYPE \ 1 // true if the types of C and B are identical #define GB_CTYPE_IS_BTYPE \ 1 // aij = Ax [pA] #define GB_GETA(aij,Ax,pA,A_iso) \ GxB_FC32_t aij = GBX (Ax, pA, A_iso) // bij = Bx [pB] #define GB_GETB(bij,Bx,pB,B_iso) \ GxB_FC32_t bij = GBX (Bx, pB, B_iso) // declare scalar of the same type as C #define GB_CTYPE_SCALAR(t) \ GxB_FC32_t t // cij = Ax [pA] #define GB_COPY_A_TO_C(cij,Ax,pA,A_iso) \ cij = GBX (Ax, pA, A_iso) // cij = Bx [pB] #define GB_COPY_B_TO_C(cij,Bx,pB,B_iso) \ cij = GBX (Bx, pB, B_iso) #define GB_CX(p) Cx [p] // binary operator #define GB_BINOP(z,x,y,i,j) \ z = GB_FC32_add (x, y) ; // true if the binop must be flipped #define GB_BINOP_FLIP \ 0 // op is second #define GB_OP_IS_SECOND \ 0 // do the numerical phases of GB_add and GB_emult #define GB_PHASE_2_OF_2 // hard-coded loops can be vectorized #define GB_PRAGMA_SIMD_VECTORIZE GB_PRAGMA_SIMD // disable this operator and use the generic case if these conditions hold #define GB_DISABLE \ (GxB_NO_PLUS || GxB_NO_FC32 || GxB_NO_PLUS_FC32) //------------------------------------------------------------------------------ // C += A+B, all 3 matrices dense //------------------------------------------------------------------------------ // The op must be MIN, MAX, PLUS, MINUS, RMINUS, TIMES, DIV, or RDIV. void GB (_Cdense_ewise3_accum__plus_fc32) ( GrB_Matrix C, const GrB_Matrix A, const GrB_Matrix B, const int nthreads ) { #include "GB_dense_ewise3_accum_template.c" } //------------------------------------------------------------------------------ // C = A+B, all 3 matrices dense //------------------------------------------------------------------------------ GrB_Info GB (_Cdense_ewise3_noaccum__plus_fc32) ( GrB_Matrix C, const GrB_Matrix A, const GrB_Matrix B, const int nthreads ) { #if GB_DISABLE return (GrB_NO_VALUE) ; #else #include "GB_dense_ewise3_noaccum_template.c" return (GrB_SUCCESS) ; #endif } //------------------------------------------------------------------------------ // C += B, accumulate a sparse matrix into a dense matrix //------------------------------------------------------------------------------ GrB_Info GB (_Cdense_accumB__plus_fc32) ( GrB_Matrix C, const GrB_Matrix B, const int64_t *B_ek_slicing, const int B_ntasks, const int B_nthreads ) { #if GB_DISABLE return (GrB_NO_VALUE) ; #else { #include "GB_dense_subassign_23_template.c" } return (GrB_SUCCESS) ; #endif } //------------------------------------------------------------------------------ // C += b, accumulate a scalar into a dense matrix //------------------------------------------------------------------------------ GrB_Info GB (_Cdense_accumb__plus_fc32) ( GrB_Matrix C, const GB_void *p_bwork, const int nthreads ) { #if GB_DISABLE return (GrB_NO_VALUE) ; #else { // get the scalar b for C += b, of type GxB_FC32_t GxB_FC32_t bwork = (*((GxB_FC32_t *) p_bwork)) ; #include "GB_dense_subassign_22_template.c" return (GrB_SUCCESS) ; } return (GrB_SUCCESS) ; #endif } //------------------------------------------------------------------------------ // C = A*D, column scale with diagonal D matrix //------------------------------------------------------------------------------ GrB_Info GB (_AxD__plus_fc32) ( GrB_Matrix C, const GrB_Matrix A, bool A_is_pattern, const GrB_Matrix D, bool D_is_pattern, const int64_t *A_ek_slicing, const int A_ntasks, const int A_nthreads ) { #if GB_DISABLE return (GrB_NO_VALUE) ; #else GxB_FC32_t *restrict Cx = (GxB_FC32_t *) C->x ; #include "GB_AxB_colscale_template.c" return (GrB_SUCCESS) ; #endif } //------------------------------------------------------------------------------ // C = D*B, row scale with diagonal D matrix //------------------------------------------------------------------------------ GrB_Info GB (_DxB__plus_fc32) ( GrB_Matrix C, const GrB_Matrix D, bool D_is_pattern, const GrB_Matrix B, bool B_is_pattern, int nthreads ) { #if GB_DISABLE return (GrB_NO_VALUE) ; #else GxB_FC32_t *restrict Cx = (GxB_FC32_t *) C->x ; #include "GB_AxB_rowscale_template.c" return (GrB_SUCCESS) ; #endif } //------------------------------------------------------------------------------ // eWiseAdd: C = A+B or C<M> = A+B //------------------------------------------------------------------------------ GrB_Info GB (_AaddB__plus_fc32) ( GrB_Matrix C, const int C_sparsity, const GrB_Matrix M, const bool Mask_struct, const bool Mask_comp, const GrB_Matrix A, const GrB_Matrix B, const bool Ch_is_Mh, const int64_t *restrict C_to_M, const int64_t *restrict C_to_A, const int64_t *restrict C_to_B, const GB_task_struct *restrict TaskList, const int C_ntasks, const int C_nthreads, GB_Context Context ) { #if GB_DISABLE return (GrB_NO_VALUE) ; #else GB_WERK_DECLARE (M_ek_slicing, int64_t) ; GB_WERK_DECLARE (A_ek_slicing, int64_t) ; GB_WERK_DECLARE (B_ek_slicing, int64_t) ; #include "GB_add_template.c" GB_FREE_WORK ; return (GrB_SUCCESS) ; #endif } //------------------------------------------------------------------------------ // eWiseMult: C = A.*B or C<M> = A.*B //------------------------------------------------------------------------------ GrB_Info GB (_AemultB_01__plus_fc32) ( GrB_Matrix C, const int C_sparsity, const int ewise_method, const GrB_Matrix M, const bool Mask_struct, const bool Mask_comp, const GrB_Matrix A, const GrB_Matrix B, const int64_t *restrict C_to_M, const int64_t *restrict C_to_A, const int64_t *restrict C_to_B, const GB_task_struct *restrict TaskList, const int C_ntasks, const int C_nthreads, GB_Context Context ) { #if GB_DISABLE return (GrB_NO_VALUE) ; #else #include "GB_emult_01_meta.c" return (GrB_SUCCESS) ; #endif } //------------------------------------------------------------------------------ // eWiseMult: C<#> = A.*B when A is sparse/hyper and B is bitmap/full //------------------------------------------------------------------------------ GrB_Info GB (_AemultB_02__plus_fc32) ( GrB_Matrix C, const GrB_Matrix M, const bool Mask_struct, const bool Mask_comp, const GrB_Matrix A, const GrB_Matrix B, const bool flipxy, const int64_t *restrict Cp_kfirst, const int64_t *A_ek_slicing, const int A_ntasks, const int A_nthreads ) { #if GB_DISABLE return (GrB_NO_VALUE) ; #else #if GB_BINOP_FLIP // The operator is not commutative, and does not have a flipped // variant. For example z=atan2(y,x). if (flipxy) { // use fmult(y,x) #undef GB_FLIPPED #define GB_FLIPPED 1 #include "GB_emult_02_template.c" } else { // use fmult(x,y) #undef GB_FLIPPED #define GB_FLIPPED 0 #include "GB_emult_02_template.c" } #else // No need to handle the flip: the operator is either commutative, or // has been handled by changing z=div(y,x) to z=rdiv(x,y) for example. #undef GB_FLIPPED #define GB_FLIPPED 0 #include "GB_emult_02_template.c" #endif return (GrB_SUCCESS) ; #endif } //------------------------------------------------------------------------------ // eWiseMult: C<M> = A.*B, M sparse/hyper, A and B bitmap/full //------------------------------------------------------------------------------ GrB_Info GB (_AemultB_03__plus_fc32) ( GrB_Matrix C, const GrB_Matrix M, const bool Mask_struct, const GrB_Matrix A, const GrB_Matrix B, const int64_t *restrict Cp_kfirst, const int64_t *M_ek_slicing, const int M_ntasks, const int M_nthreads ) { #if GB_DISABLE return (GrB_NO_VALUE) ; #else #include "GB_emult_03_template.c" return (GrB_SUCCESS) ; #endif } //------------------------------------------------------------------------------ // eWiseMult: C=A.*B, C<M>=A.*B, C<!M>=A.*B where C is bitmap //------------------------------------------------------------------------------ GrB_Info GB (_AemultB_bitmap__plus_fc32) ( GrB_Matrix C, const int ewise_method, const GrB_Matrix M, const bool Mask_struct, const bool Mask_comp, const GrB_Matrix A, const GrB_Matrix B, const int64_t *M_ek_slicing, const int M_ntasks, const int M_nthreads, const int C_nthreads, GB_Context Context ) { #if GB_DISABLE return (GrB_NO_VALUE) ; #else #include "GB_bitmap_emult_template.c" return (GrB_SUCCESS) ; #endif } //------------------------------------------------------------------------------ // Cx = op (x,Bx): apply a binary operator to a matrix with scalar bind1st //------------------------------------------------------------------------------ GrB_Info GB (_bind1st__plus_fc32) ( GB_void *Cx_output, // Cx and Bx may be aliased const GB_void *x_input, const GB_void *Bx_input, const int8_t *restrict Bb, int64_t bnz, int nthreads ) { #if GB_DISABLE return (GrB_NO_VALUE) ; #else GxB_FC32_t *Cx = (GxB_FC32_t *) Cx_output ; GxB_FC32_t x = (*((GxB_FC32_t *) x_input)) ; GxB_FC32_t *Bx = (GxB_FC32_t *) Bx_input ; int64_t p ; #pragma omp parallel for num_threads(nthreads) schedule(static) for (p = 0 ; p < bnz ; p++) { if (!GBB (Bb, p)) continue ; GxB_FC32_t bij = GBX (Bx, p, false) ; Cx [p] = GB_FC32_add (x, bij) ; } return (GrB_SUCCESS) ; #endif } //------------------------------------------------------------------------------ // Cx = op (Ax,y): apply a binary operator to a matrix with scalar bind2nd //------------------------------------------------------------------------------ GrB_Info GB (_bind2nd__plus_fc32) ( GB_void *Cx_output, // Cx and Ax may be aliased const GB_void *Ax_input, const GB_void *y_input, const int8_t *restrict Ab, int64_t anz, int nthreads ) { #if GB_DISABLE return (GrB_NO_VALUE) ; #else int64_t p ; GxB_FC32_t *Cx = (GxB_FC32_t *) Cx_output ; GxB_FC32_t *Ax = (GxB_FC32_t *) Ax_input ; GxB_FC32_t y = (*((GxB_FC32_t *) y_input)) ; #pragma omp parallel for num_threads(nthreads) schedule(static) for (p = 0 ; p < anz ; p++) { if (!GBB (Ab, p)) continue ; GxB_FC32_t aij = GBX (Ax, p, false) ; Cx [p] = GB_FC32_add (aij, y) ; } return (GrB_SUCCESS) ; #endif } //------------------------------------------------------------------------------ // C = op (x, A'): transpose and apply a binary operator //------------------------------------------------------------------------------ // cij = op (x, aij), no typecasting (in spite of the macro name) #undef GB_CAST_OP #define GB_CAST_OP(pC,pA) \ { \ GxB_FC32_t aij = GBX (Ax, pA, false) ; \ Cx [pC] = GB_FC32_add (x, aij) ; \ } GrB_Info GB (_bind1st_tran__plus_fc32) ( GrB_Matrix C, const GB_void *x_input, const GrB_Matrix A, int64_t *restrict *Workspaces, const int64_t *restrict A_slice, int nworkspaces, int nthreads ) { // GB_unop_transpose.c uses GB_ATYPE, but A is // the 2nd input to binary operator z=f(x,y). #undef GB_ATYPE #define GB_ATYPE \ GxB_FC32_t #if GB_DISABLE return (GrB_NO_VALUE) ; #else GxB_FC32_t x = (*((const GxB_FC32_t *) x_input)) ; #include "GB_unop_transpose.c" return (GrB_SUCCESS) ; #endif #undef GB_ATYPE #define GB_ATYPE \ GxB_FC32_t } //------------------------------------------------------------------------------ // C = op (A', y): transpose and apply a binary operator //------------------------------------------------------------------------------ // cij = op (aij, y), no typecasting (in spite of the macro name) #undef GB_CAST_OP #define GB_CAST_OP(pC,pA) \ { \ GxB_FC32_t aij = GBX (Ax, pA, false) ; \ Cx [pC] = GB_FC32_add (aij, y) ; \ } GrB_Info GB (_bind2nd_tran__plus_fc32) ( GrB_Matrix C, const GrB_Matrix A, const GB_void *y_input, int64_t *restrict *Workspaces, const int64_t *restrict A_slice, int nworkspaces, int nthreads ) { #if GB_DISABLE return (GrB_NO_VALUE) ; #else GxB_FC32_t y = (*((const GxB_FC32_t *) y_input)) ; #include "GB_unop_transpose.c" return (GrB_SUCCESS) ; #endif } #endif

ParallelHelper.h

/** * This file contains (modified) code from the Eigen library. * Eigen License: * * Copyright (C) 2008 Gael Guennebaud <gael.guennebaud@inria.fr> * Copyright (C) 2007-2011 Benoit Jacob <jacob.benoit.1@gmail.com> * * This Source Code Form is subject to the terms of the Mozilla * Public License v. 2.0. If a copy of the MPL was not distributed * with this file, You can obtain one at http://mozilla.org/MPL/2.0/. * * * ====================== * * The modifications are part of the Eigen Recursive Matrix Extension (ERME). * ERME License: * * Copyright (c) 2019 Darius Rückert * Licensed under the MIT License. */ #pragma once #include "MatrixScalar.h" #include <numeric> namespace Eigen { namespace Recursive { template <typename T, typename T2> inline void squaredNorm_omp_local(const T& v, T2& result) { // using Scalar = typename BaseScalar<T>::type; result = 0; #pragma omp for for (int i = 0; i < v.rows(); ++i) { result += v(i).get().squaredNorm(); } } template <typename T, typename T2> inline void dot_omp_local(const T& a, const T& b, T2& result) { // using Scalar = typename BaseScalar<T>::type; result = 0; #pragma omp for for (int i = 0; i < a.rows(); ++i) { result += a(i).get().dot(b(i).get()); } } template <typename SparseLhsType, typename DenseRhsType, typename DenseResType> inline void sparse_mv_omp(const SparseLhsType& lhs, const DenseRhsType& rhs, DenseResType& res) { typedef typename internal::remove_all<SparseLhsType>::type Lhs; typedef Eigen::internal::evaluator<Lhs> LhsEval; typedef typename Eigen::internal::evaluator<Lhs>::InnerIterator LhsInnerIterator; //#pragma omp single { LhsEval lhsEval(lhs); Index n = lhs.outerSize(); // for (Index c = 0; c < rhs.cols(); ++c) { #pragma omp for for (Index i = 0; i < n; ++i) { res.coeffRef(i).get().setZero(); for (LhsInnerIterator it(lhs, i); it; ++it) { auto& vlhs = it.value().get(); auto& vrhs = rhs.coeff(it.index()).get(); res.coeffRef(i).get() += vlhs * vrhs; } } } } } } // namespace Recursive } // namespace Eigen

single.c

#include <omp.h> #include <stdio.h> main() { int x; x = 0; #pragma omp parallel shared(x) { #pragma omp single { int id = omp_get_thread_num(); printf("I am thread #%d\n",id); x = x + 1; } } /* end of parallel section */ printf("out of the parallel region : X = %d\n",x); }

segment.c

/* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % SSSSS EEEEE GGGG M M EEEEE N N TTTTT % % SS E G MM MM E NN N T % % SSS EEE G GGG M M M EEE N N N T % % SS E G G M M E N NN T % % SSSSS EEEEE GGGG M M EEEEE N N T % % % % % % MagickCore Methods to Segment an Image with Thresholding Fuzzy c-Means % % % % Software Design % % Cristy % % April 1993 % % % % % % Copyright 1999-2020 ImageMagick Studio LLC, a non-profit organization % % dedicated to making software imaging solutions freely available. % % % % You may not use this file except in compliance with the License. You may % % obtain a copy of the License at % % % % https://imagemagick.org/script/license.php % % % % Unless required by applicable law or agreed to in writing, software % % distributed under the License is distributed on an "AS IS" BASIS, % % WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. % % See the License for the specific language governing permissions and % % limitations under the License. % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % Segment segments an image by analyzing the histograms of the color % components and identifying units that are homogeneous with the fuzzy % c-means technique. The scale-space filter analyzes the histograms of % the three color components of the image and identifies a set of % classes. The extents of each class is used to coarsely segment the % image with thresholding. The color associated with each class is % determined by the mean color of all pixels within the extents of a % particular class. Finally, any unclassified pixels are assigned to % the closest class with the fuzzy c-means technique. % % The fuzzy c-Means algorithm can be summarized as follows: % % o Build a histogram, one for each color component of the image. % % o For each histogram, successively apply the scale-space filter and % build an interval tree of zero crossings in the second derivative % at each scale. Analyze this scale-space ``fingerprint'' to % determine which peaks and valleys in the histogram are most % predominant. % % o The fingerprint defines intervals on the axis of the histogram. % Each interval contains either a minima or a maxima in the original % signal. If each color component lies within the maxima interval, % that pixel is considered ``classified'' and is assigned an unique % class number. % % o Any pixel that fails to be classified in the above thresholding % pass is classified using the fuzzy c-Means technique. It is % assigned to one of the classes discovered in the histogram analysis % phase. % % The fuzzy c-Means technique attempts to cluster a pixel by finding % the local minima of the generalized within group sum of squared error % objective function. A pixel is assigned to the closest class of % which the fuzzy membership has a maximum value. % % Segment is strongly based on software written by Andy Gallo, % University of Delaware. % % The following reference was used in creating this program: % % Young Won Lim, Sang Uk Lee, "On The Color Image Segmentation % Algorithm Based on the Thresholding and the Fuzzy c-Means % Techniques", Pattern Recognition, Volume 23, Number 9, pages % 935-952, 1990. % % */ #include "magick/studio.h" #include "magick/cache.h" #include "magick/color.h" #include "magick/colormap.h" #include "magick/colorspace.h" #include "magick/colorspace-private.h" #include "magick/exception.h" #include "magick/exception-private.h" #include "magick/image.h" #include "magick/image-private.h" #include "magick/memory_.h" #include "magick/memory-private.h" #include "magick/monitor.h" #include "magick/monitor-private.h" #include "magick/quantize.h" #include "magick/quantum.h" #include "magick/quantum-private.h" #include "magick/resource_.h" #include "magick/segment.h" #include "magick/string_.h" #include "magick/thread-private.h" /* Define declarations. */ #define MaxDimension 3 #define DeltaTau 0.5f #if defined(FastClassify) #define WeightingExponent 2.0 #define SegmentPower(ratio) (ratio) #else #define WeightingExponent 2.5 #define SegmentPower(ratio) pow(ratio,(double) (1.0/(weighting_exponent-1.0))); #endif #define Tau 5.2f /* Typedef declarations. */ typedef struct _ExtentPacket { MagickRealType center; ssize_t index, left, right; } ExtentPacket; typedef struct _Cluster { struct _Cluster *next; ExtentPacket red, green, blue; ssize_t count, id; } Cluster; typedef struct _IntervalTree { MagickRealType tau; ssize_t left, right; MagickRealType mean_stability, stability; struct _IntervalTree *sibling, *child; } IntervalTree; typedef struct _ZeroCrossing { MagickRealType tau, histogram[256]; short crossings[256]; } ZeroCrossing; /* Constant declarations. */ static const int Blue = 2, Green = 1, Red = 0, SafeMargin = 3, TreeLength = 600; /* Method prototypes. */ static MagickRealType OptimalTau(const ssize_t *,const double,const double,const double, const double,short *); static ssize_t DefineRegion(const short *,ExtentPacket *); static void FreeNodes(IntervalTree *), InitializeHistogram(const Image *,ssize_t **,ExceptionInfo *), ScaleSpace(const ssize_t *,const MagickRealType,MagickRealType *), ZeroCrossHistogram(MagickRealType *,const MagickRealType,short *); /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % + C l a s s i f y % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % Classify() defines one or more classes. Each pixel is thresholded to % determine which class it belongs to. If the class is not identified it is % assigned to the closest class based on the fuzzy c-Means technique. % % The format of the Classify method is: % % MagickBooleanType Classify(Image *image,short **extrema, % const MagickRealType cluster_threshold, % const MagickRealType weighting_exponent, % const MagickBooleanType verbose) % % A description of each parameter follows. % % o image: the image. % % o extrema: Specifies a pointer to an array of integers. They % represent the peaks and valleys of the histogram for each color % component. % % o cluster_threshold: This MagickRealType represents the minimum number of % pixels contained in a hexahedra before it can be considered valid % (expressed as a percentage). % % o weighting_exponent: Specifies the membership weighting exponent. % % o verbose: A value greater than zero prints detailed information about % the identified classes. % */ static MagickBooleanType Classify(Image *image,short **extrema, const MagickRealType cluster_threshold, const MagickRealType weighting_exponent,const MagickBooleanType verbose) { #define SegmentImageTag "Segment/Image" #define ThrowClassifyException(severity,tag,label) \ {\ for (cluster=head; cluster != (Cluster *) NULL; cluster=next_cluster) \ { \ next_cluster=cluster->next; \ cluster=(Cluster *) RelinquishMagickMemory(cluster); \ } \ if (squares != (double *) NULL) \ { \ squares-=255; \ free_squares=squares; \ free_squares=(double *) RelinquishMagickMemory(free_squares); \ } \ ThrowBinaryException(severity,tag,label); \ } CacheView *image_view; Cluster *cluster, *head, *last_cluster, *next_cluster; ExceptionInfo *exception; ExtentPacket blue, green, red; MagickOffsetType progress; MagickRealType *free_squares; MagickStatusType status; register ssize_t i; register MagickRealType *squares; size_t number_clusters; ssize_t count, y; /* Form clusters. */ cluster=(Cluster *) NULL; head=(Cluster *) NULL; squares=(double *) NULL; (void) memset(&red,0,sizeof(red)); (void) memset(&green,0,sizeof(green)); (void) memset(&blue,0,sizeof(blue)); exception=(&image->exception); while (DefineRegion(extrema[Red],&red) != 0) { green.index=0; while (DefineRegion(extrema[Green],&green) != 0) { blue.index=0; while (DefineRegion(extrema[Blue],&blue) != 0) { /* Allocate a new class. */ if (head != (Cluster *) NULL) { cluster->next=(Cluster *) AcquireMagickMemory( sizeof(*cluster->next)); cluster=cluster->next; } else { cluster=(Cluster *) AcquireMagickMemory(sizeof(*cluster)); head=cluster; } if (cluster == (Cluster *) NULL) ThrowClassifyException(ResourceLimitError,"MemoryAllocationFailed", image->filename); /* Initialize a new class. */ cluster->count=0; cluster->red=red; cluster->green=green; cluster->blue=blue; cluster->next=(Cluster *) NULL; } } } if (head == (Cluster *) NULL) { /* No classes were identified-- create one. */ cluster=(Cluster *) AcquireMagickMemory(sizeof(*cluster)); if (cluster == (Cluster *) NULL) ThrowClassifyException(ResourceLimitError,"MemoryAllocationFailed", image->filename); /* Initialize a new class. */ cluster->count=0; cluster->red=red; cluster->green=green; cluster->blue=blue; cluster->next=(Cluster *) NULL; head=cluster; } /* Count the pixels for each cluster. */ status=MagickTrue; count=0; progress=0; image_view=AcquireVirtualCacheView(image,exception); for (y=0; y < (ssize_t) image->rows; y++) { register const PixelPacket *p; register ssize_t x; p=GetCacheViewVirtualPixels(image_view,0,y,image->columns,1,exception); if (p == (const PixelPacket *) NULL) break; for (x=0; x < (ssize_t) image->columns; x++) { for (cluster=head; cluster != (Cluster *) NULL; cluster=cluster->next) if (((ssize_t) ScaleQuantumToChar(GetPixelRed(p)) >= (cluster->red.left-SafeMargin)) && ((ssize_t) ScaleQuantumToChar(GetPixelRed(p)) <= (cluster->red.right+SafeMargin)) && ((ssize_t) ScaleQuantumToChar(GetPixelGreen(p)) >= (cluster->green.left-SafeMargin)) && ((ssize_t) ScaleQuantumToChar(GetPixelGreen(p)) <= (cluster->green.right+SafeMargin)) && ((ssize_t) ScaleQuantumToChar(GetPixelBlue(p)) >= (cluster->blue.left-SafeMargin)) && ((ssize_t) ScaleQuantumToChar(GetPixelBlue(p)) <= (cluster->blue.right+SafeMargin))) { /* Count this pixel. */ count++; cluster->red.center+=(MagickRealType) ScaleQuantumToChar(GetPixelRed(p)); cluster->green.center+=(MagickRealType) ScaleQuantumToChar(GetPixelGreen(p)); cluster->blue.center+=(MagickRealType) ScaleQuantumToChar(GetPixelBlue(p)); cluster->count++; break; } p++; } if (image->progress_monitor != (MagickProgressMonitor) NULL) { MagickBooleanType proceed; #if defined(MAGICKCORE_OPENMP_SUPPORT) #pragma omp atomic #endif progress++; proceed=SetImageProgress(image,SegmentImageTag,progress,2*image->rows); if (proceed == MagickFalse) status=MagickFalse; } } image_view=DestroyCacheView(image_view); /* Remove clusters that do not meet minimum cluster threshold. */ count=0; last_cluster=head; next_cluster=head; for (cluster=head; cluster != (Cluster *) NULL; cluster=next_cluster) { next_cluster=cluster->next; if ((cluster->count > 0) && (cluster->count >= (count*cluster_threshold/100.0))) { /* Initialize cluster. */ cluster->id=count; cluster->red.center/=cluster->count; cluster->green.center/=cluster->count; cluster->blue.center/=cluster->count; count++; last_cluster=cluster; continue; } /* Delete cluster. */ if (cluster == head) head=next_cluster; else last_cluster->next=next_cluster; cluster=(Cluster *) RelinquishMagickMemory(cluster); } number_clusters=(size_t) count; if (verbose != MagickFalse) { /* Print cluster statistics. */ (void) FormatLocaleFile(stdout,"Fuzzy C-means Statistics\n"); (void) FormatLocaleFile(stdout,"===================\n\n"); (void) FormatLocaleFile(stdout,"\tCluster Threshold = %g\n",(double) cluster_threshold); (void) FormatLocaleFile(stdout,"\tWeighting Exponent = %g\n",(double) weighting_exponent); (void) FormatLocaleFile(stdout,"\tTotal Number of Clusters = %.20g\n\n", (double) number_clusters); /* Print the total number of points per cluster. */ (void) FormatLocaleFile(stdout,"\n\nNumber of Vectors Per Cluster\n"); (void) FormatLocaleFile(stdout,"=============================\n\n"); for (cluster=head; cluster != (Cluster *) NULL; cluster=cluster->next) (void) FormatLocaleFile(stdout,"Cluster #%.20g = %.20g\n",(double) cluster->id,(double) cluster->count); /* Print the cluster extents. */ (void) FormatLocaleFile(stdout, "\n\n\nCluster Extents: (Vector Size: %d)\n",MaxDimension); (void) FormatLocaleFile(stdout,"================"); for (cluster=head; cluster != (Cluster *) NULL; cluster=cluster->next) { (void) FormatLocaleFile(stdout,"\n\nCluster #%.20g\n\n",(double) cluster->id); (void) FormatLocaleFile(stdout, "%.20g-%.20g %.20g-%.20g %.20g-%.20g\n",(double) cluster->red.left,(double) cluster->red.right,(double) cluster->green.left,(double) cluster->green.right,(double) cluster->blue.left,(double) cluster->blue.right); } /* Print the cluster center values. */ (void) FormatLocaleFile(stdout, "\n\n\nCluster Center Values: (Vector Size: %d)\n",MaxDimension); (void) FormatLocaleFile(stdout,"====================="); for (cluster=head; cluster != (Cluster *) NULL; cluster=cluster->next) { (void) FormatLocaleFile(stdout,"\n\nCluster #%.20g\n\n",(double) cluster->id); (void) FormatLocaleFile(stdout,"%g %g %g\n",(double) cluster->red.center,(double) cluster->green.center,(double) cluster->blue.center); } (void) FormatLocaleFile(stdout,"\n"); } if (number_clusters > 256) ThrowClassifyException(ImageError,"TooManyClusters",image->filename); /* Speed up distance calculations. */ squares=(MagickRealType *) AcquireQuantumMemory(513UL,sizeof(*squares)); if (squares == (MagickRealType *) NULL) ThrowClassifyException(ResourceLimitError,"MemoryAllocationFailed", image->filename); squares+=255; for (i=(-255); i <= 255; i++) squares[i]=(MagickRealType) i*(MagickRealType) i; /* Allocate image colormap. */ if (AcquireImageColormap(image,number_clusters) == MagickFalse) ThrowClassifyException(ResourceLimitError,"MemoryAllocationFailed", image->filename); i=0; for (cluster=head; cluster != (Cluster *) NULL; cluster=cluster->next) { image->colormap[i].red=ScaleCharToQuantum((unsigned char) (cluster->red.center+0.5)); image->colormap[i].green=ScaleCharToQuantum((unsigned char) (cluster->green.center+0.5)); image->colormap[i].blue=ScaleCharToQuantum((unsigned char) (cluster->blue.center+0.5)); i++; } /* Do course grain classes. */ exception=(&image->exception); image_view=AcquireAuthenticCacheView(image,exception); #if defined(MAGICKCORE_OPENMP_SUPPORT) #pragma omp parallel for schedule(static) shared(progress,status) \ magick_number_threads(image,image,image->rows,1) #endif for (y=0; y < (ssize_t) image->rows; y++) { Cluster *cluster; register const PixelPacket *magick_restrict p; register IndexPacket *magick_restrict indexes; register ssize_t x; register PixelPacket *magick_restrict q; if (status == MagickFalse) continue; q=GetCacheViewAuthenticPixels(image_view,0,y,image->columns,1,exception); if (q == (PixelPacket *) NULL) { status=MagickFalse; continue; } indexes=GetCacheViewAuthenticIndexQueue(image_view); for (x=0; x < (ssize_t) image->columns; x++) { SetPixelIndex(indexes+x,0); for (cluster=head; cluster != (Cluster *) NULL; cluster=cluster->next) { if (((ssize_t) ScaleQuantumToChar(q->red) >= (cluster->red.left-SafeMargin)) && ((ssize_t) ScaleQuantumToChar(q->red) <= (cluster->red.right+SafeMargin)) && ((ssize_t) ScaleQuantumToChar(q->green) >= (cluster->green.left-SafeMargin)) && ((ssize_t) ScaleQuantumToChar(q->green) <= (cluster->green.right+SafeMargin)) && ((ssize_t) ScaleQuantumToChar(q->blue) >= (cluster->blue.left-SafeMargin)) && ((ssize_t) ScaleQuantumToChar(q->blue) <= (cluster->blue.right+SafeMargin))) { /* Classify this pixel. */ SetPixelIndex(indexes+x,cluster->id); break; } } if (cluster == (Cluster *) NULL) { MagickRealType distance_squared, local_minima, numerator, ratio, sum; register ssize_t j, k; /* Compute fuzzy membership. */ local_minima=0.0; for (j=0; j < (ssize_t) image->colors; j++) { sum=0.0; p=image->colormap+j; distance_squared=squares[(ssize_t) ScaleQuantumToChar(q->red)- (ssize_t) ScaleQuantumToChar(GetPixelRed(p))]+ squares[(ssize_t) ScaleQuantumToChar(q->green)- (ssize_t) ScaleQuantumToChar(GetPixelGreen(p))]+ squares[(ssize_t) ScaleQuantumToChar(q->blue)- (ssize_t) ScaleQuantumToChar(GetPixelBlue(p))]; numerator=distance_squared; for (k=0; k < (ssize_t) image->colors; k++) { p=image->colormap+k; distance_squared=squares[(ssize_t) ScaleQuantumToChar(q->red)- (ssize_t) ScaleQuantumToChar(GetPixelRed(p))]+ squares[(ssize_t) ScaleQuantumToChar(q->green)- (ssize_t) ScaleQuantumToChar(GetPixelGreen(p))]+ squares[(ssize_t) ScaleQuantumToChar(q->blue)- (ssize_t) ScaleQuantumToChar(GetPixelBlue(p))]; ratio=numerator/distance_squared; sum+=SegmentPower(ratio); } if ((sum != 0.0) && ((1.0/sum) > local_minima)) { /* Classify this pixel. */ local_minima=1.0/sum; SetPixelIndex(indexes+x,j); } } } q++; } if (SyncCacheViewAuthenticPixels(image_view,exception) == MagickFalse) status=MagickFalse; if (image->progress_monitor != (MagickProgressMonitor) NULL) { MagickBooleanType proceed; #if defined(MAGICKCORE_OPENMP_SUPPORT) #pragma omp atomic #endif progress++; proceed=SetImageProgress(image,SegmentImageTag,progress,2*image->rows); if (proceed == MagickFalse) status=MagickFalse; } } image_view=DestroyCacheView(image_view); status&=SyncImage(image); /* Relinquish resources. */ for (cluster=head; cluster != (Cluster *) NULL; cluster=next_cluster) { next_cluster=cluster->next; cluster=(Cluster *) RelinquishMagickMemory(cluster); } squares-=255; free_squares=squares; free_squares=(MagickRealType *) RelinquishMagickMemory(free_squares); return(MagickTrue); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % + C o n s o l i d a t e C r o s s i n g s % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % ConsolidateCrossings() guarantees that an even number of zero crossings % always lie between two crossings. % % The format of the ConsolidateCrossings method is: % % ConsolidateCrossings(ZeroCrossing *zero_crossing, % const size_t number_crossings) % % A description of each parameter follows. % % o zero_crossing: Specifies an array of structures of type ZeroCrossing. % % o number_crossings: This size_t specifies the number of elements % in the zero_crossing array. % */ static void ConsolidateCrossings(ZeroCrossing *zero_crossing, const size_t number_crossings) { register ssize_t i, j, k, l; ssize_t center, correct, count, left, right; /* Consolidate zero crossings. */ for (i=(ssize_t) number_crossings-1; i >= 0; i--) for (j=0; j <= 255; j++) { if (zero_crossing[i].crossings[j] == 0) continue; /* Find the entry that is closest to j and still preserves the property that there are an even number of crossings between intervals. */ for (k=j-1; k > 0; k--) if (zero_crossing[i+1].crossings[k] != 0) break; left=MagickMax(k,0); center=j; for (k=j+1; k < 255; k++) if (zero_crossing[i+1].crossings[k] != 0) break; right=MagickMin(k,255); /* K is the zero crossing just left of j. */ for (k=j-1; k > 0; k--) if (zero_crossing[i].crossings[k] != 0) break; if (k < 0) k=0; /* Check center for an even number of crossings between k and j. */ correct=(-1); if (zero_crossing[i+1].crossings[j] != 0) { count=0; for (l=k+1; l < center; l++) if (zero_crossing[i+1].crossings[l] != 0) count++; if (((count % 2) == 0) && (center != k)) correct=center; } /* Check left for an even number of crossings between k and j. */ if (correct == -1) { count=0; for (l=k+1; l < left; l++) if (zero_crossing[i+1].crossings[l] != 0) count++; if (((count % 2) == 0) && (left != k)) correct=left; } /* Check right for an even number of crossings between k and j. */ if (correct == -1) { count=0; for (l=k+1; l < right; l++) if (zero_crossing[i+1].crossings[l] != 0) count++; if (((count % 2) == 0) && (right != k)) correct=right; } l=(ssize_t) zero_crossing[i].crossings[j]; zero_crossing[i].crossings[j]=0; if (correct != -1) zero_crossing[i].crossings[correct]=(short) l; } } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % + D e f i n e R e g i o n % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % DefineRegion() defines the left and right boundaries of a peak region. % % The format of the DefineRegion method is: % % ssize_t DefineRegion(const short *extrema,ExtentPacket *extents) % % A description of each parameter follows. % % o extrema: Specifies a pointer to an array of integers. They % represent the peaks and valleys of the histogram for each color % component. % % o extents: This pointer to an ExtentPacket represent the extends % of a particular peak or valley of a color component. % */ static ssize_t DefineRegion(const short *extrema,ExtentPacket *extents) { /* Initialize to default values. */ extents->left=0; extents->center=0.0; extents->right=255; /* Find the left side (maxima). */ for ( ; extents->index <= 255; extents->index++) if (extrema[extents->index] > 0) break; if (extents->index > 255) return(MagickFalse); /* no left side - no region exists */ extents->left=extents->index; /* Find the right side (minima). */ for ( ; extents->index <= 255; extents->index++) if (extrema[extents->index] < 0) break; extents->right=extents->index-1; return(MagickTrue); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % + D e r i v a t i v e H i s t o g r a m % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % DerivativeHistogram() determines the derivative of the histogram using % central differencing. % % The format of the DerivativeHistogram method is: % % DerivativeHistogram(const MagickRealType *histogram, % MagickRealType *derivative) % % A description of each parameter follows. % % o histogram: Specifies an array of MagickRealTypes representing the number % of pixels for each intensity of a particular color component. % % o derivative: This array of MagickRealTypes is initialized by % DerivativeHistogram to the derivative of the histogram using central % differencing. % */ static void DerivativeHistogram(const MagickRealType *histogram, MagickRealType *derivative) { register ssize_t i, n; /* Compute endpoints using second order polynomial interpolation. */ n=255; derivative[0]=(-1.5*histogram[0]+2.0*histogram[1]-0.5*histogram[2]); derivative[n]=(0.5*histogram[n-2]-2.0*histogram[n-1]+1.5*histogram[n]); /* Compute derivative using central differencing. */ for (i=1; i < n; i++) derivative[i]=(histogram[i+1]-histogram[i-1])/2.0; return; } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % + G e t I m a g e D y n a m i c T h r e s h o l d % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % GetImageDynamicThreshold() returns the dynamic threshold for an image. % % The format of the GetImageDynamicThreshold method is: % % MagickBooleanType GetImageDynamicThreshold(const Image *image, % const double cluster_threshold,const double smooth_threshold, % MagickPixelPacket *pixel,ExceptionInfo *exception) % % A description of each parameter follows. % % o image: the image. % % o cluster_threshold: This MagickRealType represents the minimum number of % pixels contained in a hexahedra before it can be considered valid % (expressed as a percentage). % % o smooth_threshold: the smoothing threshold eliminates noise in the second % derivative of the histogram. As the value is increased, you can expect a % smoother second derivative. % % o pixel: return the dynamic threshold here. % % o exception: return any errors or warnings in this structure. % */ MagickExport MagickBooleanType GetImageDynamicThreshold(const Image *image, const double cluster_threshold,const double smooth_threshold, MagickPixelPacket *pixel,ExceptionInfo *exception) { Cluster *background, *cluster, *object, *head, *last_cluster, *next_cluster; ExtentPacket blue, green, red; MagickBooleanType proceed; MagickRealType threshold; register const PixelPacket *p; register ssize_t i, x; short *extrema[MaxDimension]; ssize_t count, *histogram[MaxDimension], y; /* Allocate histogram and extrema. */ assert(image != (Image *) NULL); assert(image->signature == MagickCoreSignature); if (image->debug != MagickFalse) (void) LogMagickEvent(TraceEvent,GetMagickModule(),"%s",image->filename); GetMagickPixelPacket(image,pixel); for (i=0; i < MaxDimension; i++) { histogram[i]=(ssize_t *) AcquireQuantumMemory(256UL,sizeof(**histogram)); extrema[i]=(short *) AcquireQuantumMemory(256UL,sizeof(**histogram)); if ((histogram[i] == (ssize_t *) NULL) || (extrema[i] == (short *) NULL)) { for (i-- ; i >= 0; i--) { extrema[i]=(short *) RelinquishMagickMemory(extrema[i]); histogram[i]=(ssize_t *) RelinquishMagickMemory(histogram[i]); } (void) ThrowMagickException(exception,GetMagickModule(), ResourceLimitError,"MemoryAllocationFailed","`%s'",image->filename); return(MagickFalse); } } /* Initialize histogram. */ InitializeHistogram(image,histogram,exception); (void) OptimalTau(histogram[Red],Tau,0.2f,DeltaTau, (smooth_threshold == 0.0f ? 1.0f : smooth_threshold),extrema[Red]); (void) OptimalTau(histogram[Green],Tau,0.2f,DeltaTau, (smooth_threshold == 0.0f ? 1.0f : smooth_threshold),extrema[Green]); (void) OptimalTau(histogram[Blue],Tau,0.2f,DeltaTau, (smooth_threshold == 0.0f ? 1.0f : smooth_threshold),extrema[Blue]); /* Form clusters. */ cluster=(Cluster *) NULL; head=(Cluster *) NULL; (void) memset(&red,0,sizeof(red)); (void) memset(&green,0,sizeof(green)); (void) memset(&blue,0,sizeof(blue)); while (DefineRegion(extrema[Red],&red) != 0) { green.index=0; while (DefineRegion(extrema[Green],&green) != 0) { blue.index=0; while (DefineRegion(extrema[Blue],&blue) != 0) { /* Allocate a new class. */ if (head != (Cluster *) NULL) { cluster->next=(Cluster *) AcquireMagickMemory( sizeof(*cluster->next)); cluster=cluster->next; } else { cluster=(Cluster *) AcquireMagickMemory(sizeof(*cluster)); head=cluster; } if (cluster == (Cluster *) NULL) { (void) ThrowMagickException(exception,GetMagickModule(), ResourceLimitError,"MemoryAllocationFailed","`%s'", image->filename); return(MagickFalse); } /* Initialize a new class. */ cluster->count=0; cluster->red=red; cluster->green=green; cluster->blue=blue; cluster->next=(Cluster *) NULL; } } } if (head == (Cluster *) NULL) { /* No classes were identified-- create one. */ cluster=(Cluster *) AcquireMagickMemory(sizeof(*cluster)); if (cluster == (Cluster *) NULL) { (void) ThrowMagickException(exception,GetMagickModule(), ResourceLimitError,"MemoryAllocationFailed","`%s'",image->filename); return(MagickFalse); } /* Initialize a new class. */ cluster->count=0; cluster->red=red; cluster->green=green; cluster->blue=blue; cluster->next=(Cluster *) NULL; head=cluster; } /* Count the pixels for each cluster. */ count=0; for (y=0; y < (ssize_t) image->rows; y++) { p=GetVirtualPixels(image,0,y,image->columns,1,exception); if (p == (const PixelPacket *) NULL) break; for (x=0; x < (ssize_t) image->columns; x++) { for (cluster=head; cluster != (Cluster *) NULL; cluster=cluster->next) if (((ssize_t) ScaleQuantumToChar(GetPixelRed(p)) >= (cluster->red.left-SafeMargin)) && ((ssize_t) ScaleQuantumToChar(GetPixelRed(p)) <= (cluster->red.right+SafeMargin)) && ((ssize_t) ScaleQuantumToChar(GetPixelGreen(p)) >= (cluster->green.left-SafeMargin)) && ((ssize_t) ScaleQuantumToChar(GetPixelGreen(p)) <= (cluster->green.right+SafeMargin)) && ((ssize_t) ScaleQuantumToChar(GetPixelBlue(p)) >= (cluster->blue.left-SafeMargin)) && ((ssize_t) ScaleQuantumToChar(GetPixelBlue(p)) <= (cluster->blue.right+SafeMargin))) { /* Count this pixel. */ count++; cluster->red.center+=(MagickRealType) ScaleQuantumToChar(GetPixelRed(p)); cluster->green.center+=(MagickRealType) ScaleQuantumToChar(GetPixelGreen(p)); cluster->blue.center+=(MagickRealType) ScaleQuantumToChar(GetPixelBlue(p)); cluster->count++; break; } p++; } proceed=SetImageProgress(image,SegmentImageTag,(MagickOffsetType) y, 2*image->rows); if (proceed == MagickFalse) break; } /* Remove clusters that do not meet minimum cluster threshold. */ count=0; last_cluster=head; next_cluster=head; for (cluster=head; cluster != (Cluster *) NULL; cluster=next_cluster) { next_cluster=cluster->next; if ((cluster->count > 0) && (cluster->count >= (count*cluster_threshold/100.0))) { /* Initialize cluster. */ cluster->id=count; cluster->red.center/=cluster->count; cluster->green.center/=cluster->count; cluster->blue.center/=cluster->count; count++; last_cluster=cluster; continue; } /* Delete cluster. */ if (cluster == head) head=next_cluster; else last_cluster->next=next_cluster; cluster=(Cluster *) RelinquishMagickMemory(cluster); } object=head; background=head; if (count > 1) { object=head->next; for (cluster=object; cluster->next != (Cluster *) NULL; ) { if (cluster->count < object->count) object=cluster; cluster=cluster->next; } background=head->next; for (cluster=background; cluster->next != (Cluster *) NULL; ) { if (cluster->count > background->count) background=cluster; cluster=cluster->next; } } if (background != (Cluster *) NULL) { threshold=(background->red.center+object->red.center)/2.0; pixel->red=(MagickRealType) ScaleCharToQuantum((unsigned char) (threshold+0.5)); threshold=(background->green.center+object->green.center)/2.0; pixel->green=(MagickRealType) ScaleCharToQuantum((unsigned char) (threshold+0.5)); threshold=(background->blue.center+object->blue.center)/2.0; pixel->blue=(MagickRealType) ScaleCharToQuantum((unsigned char) (threshold+0.5)); } /* Relinquish resources. */ for (cluster=head; cluster != (Cluster *) NULL; cluster=next_cluster) { next_cluster=cluster->next; cluster=(Cluster *) RelinquishMagickMemory(cluster); } for (i=0; i < MaxDimension; i++) { extrema[i]=(short *) RelinquishMagickMemory(extrema[i]); histogram[i]=(ssize_t *) RelinquishMagickMemory(histogram[i]); } return(MagickTrue); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % + I n i t i a l i z e H i s t o g r a m % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % InitializeHistogram() computes the histogram for an image. % % The format of the InitializeHistogram method is: % % InitializeHistogram(const Image *image,ssize_t **histogram) % % A description of each parameter follows. % % o image: Specifies a pointer to an Image structure; returned from % ReadImage. % % o histogram: Specifies an array of integers representing the number % of pixels for each intensity of a particular color component. % */ static void InitializeHistogram(const Image *image,ssize_t **histogram, ExceptionInfo *exception) { register const PixelPacket *p; register ssize_t i, x; ssize_t y; /* Initialize histogram. */ for (i=0; i <= 255; i++) { histogram[Red][i]=0; histogram[Green][i]=0; histogram[Blue][i]=0; } for (y=0; y < (ssize_t) image->rows; y++) { p=GetVirtualPixels(image,0,y,image->columns,1,exception); if (p == (const PixelPacket *) NULL) break; for (x=0; x < (ssize_t) image->columns; x++) { histogram[Red][(ssize_t) ScaleQuantumToChar(GetPixelRed(p))]++; histogram[Green][(ssize_t) ScaleQuantumToChar(GetPixelGreen(p))]++; histogram[Blue][(ssize_t) ScaleQuantumToChar(GetPixelBlue(p))]++; p++; } } } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % + I n i t i a l i z e I n t e r v a l T r e e % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % InitializeIntervalTree() initializes an interval tree from the lists of % zero crossings. % % The format of the InitializeIntervalTree method is: % % InitializeIntervalTree(IntervalTree **list,ssize_t *number_nodes, % IntervalTree *node) % % A description of each parameter follows. % % o zero_crossing: Specifies an array of structures of type ZeroCrossing. % % o number_crossings: This size_t specifies the number of elements % in the zero_crossing array. % */ static void InitializeList(IntervalTree **list,ssize_t *number_nodes, IntervalTree *node) { if (node == (IntervalTree *) NULL) return; if (node->child == (IntervalTree *) NULL) list[(*number_nodes)++]=node; InitializeList(list,number_nodes,node->sibling); InitializeList(list,number_nodes,node->child); } static void MeanStability(IntervalTree *node) { register IntervalTree *child; if (node == (IntervalTree *) NULL) return; node->mean_stability=0.0; child=node->child; if (child != (IntervalTree *) NULL) { register ssize_t count; register MagickRealType sum; sum=0.0; count=0; for ( ; child != (IntervalTree *) NULL; child=child->sibling) { sum+=child->stability; count++; } node->mean_stability=sum/(MagickRealType) count; } MeanStability(node->sibling); MeanStability(node->child); } static void Stability(IntervalTree *node) { if (node == (IntervalTree *) NULL) return; if (node->child == (IntervalTree *) NULL) node->stability=0.0; else node->stability=node->tau-(node->child)->tau; Stability(node->sibling); Stability(node->child); } static IntervalTree *InitializeIntervalTree(const ZeroCrossing *zero_crossing, const size_t number_crossings) { IntervalTree *head, **list, *node, *root; register ssize_t i; ssize_t j, k, left, number_nodes; /* Allocate interval tree. */ list=(IntervalTree **) AcquireQuantumMemory((size_t) TreeLength, sizeof(*list)); if (list == (IntervalTree **) NULL) return((IntervalTree *) NULL); /* The root is the entire histogram. */ root=(IntervalTree *) AcquireCriticalMemory(sizeof(*root)); root->child=(IntervalTree *) NULL; root->sibling=(IntervalTree *) NULL; root->tau=0.0; root->left=0; root->right=255; root->mean_stability=0.0; root->stability=0.0; (void) memset(list,0,TreeLength*sizeof(*list)); for (i=(-1); i < (ssize_t) number_crossings; i++) { /* Initialize list with all nodes with no children. */ number_nodes=0; InitializeList(list,&number_nodes,root); /* Split list. */ for (j=0; j < number_nodes; j++) { head=list[j]; left=head->left; node=head; for (k=head->left+1; k < head->right; k++) { if (zero_crossing[i+1].crossings[k] != 0) { if (node == head) { node->child=(IntervalTree *) AcquireMagickMemory( sizeof(*node->child)); node=node->child; } else { node->sibling=(IntervalTree *) AcquireMagickMemory( sizeof(*node->sibling)); node=node->sibling; } if (node == (IntervalTree *) NULL) { list=(IntervalTree **) RelinquishMagickMemory(list); FreeNodes(root); return((IntervalTree *) NULL); } node->tau=zero_crossing[i+1].tau; node->child=(IntervalTree *) NULL; node->sibling=(IntervalTree *) NULL; node->left=left; node->right=k; left=k; } } if (left != head->left) { node->sibling=(IntervalTree *) AcquireMagickMemory( sizeof(*node->sibling)); node=node->sibling; if (node == (IntervalTree *) NULL) { list=(IntervalTree **) RelinquishMagickMemory(list); FreeNodes(root); return((IntervalTree *) NULL); } node->tau=zero_crossing[i+1].tau; node->child=(IntervalTree *) NULL; node->sibling=(IntervalTree *) NULL; node->left=left; node->right=head->right; } } } /* Determine the stability: difference between a nodes tau and its child. */ Stability(root->child); MeanStability(root->child); list=(IntervalTree **) RelinquishMagickMemory(list); return(root); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % + O p t i m a l T a u % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % OptimalTau() finds the optimal tau for each band of the histogram. % % The format of the OptimalTau method is: % % MagickRealType OptimalTau(const ssize_t *histogram,const double max_tau, % const double min_tau,const double delta_tau, % const double smooth_threshold,short *extrema) % % A description of each parameter follows. % % o histogram: Specifies an array of integers representing the number % of pixels for each intensity of a particular color component. % % o extrema: Specifies a pointer to an array of integers. They % represent the peaks and valleys of the histogram for each color % component. % */ static void ActiveNodes(IntervalTree **list,ssize_t *number_nodes, IntervalTree *node) { if (node == (IntervalTree *) NULL) return; if (node->stability >= node->mean_stability) { list[(*number_nodes)++]=node; ActiveNodes(list,number_nodes,node->sibling); } else { ActiveNodes(list,number_nodes,node->sibling); ActiveNodes(list,number_nodes,node->child); } } static void FreeNodes(IntervalTree *node) { if (node == (IntervalTree *) NULL) return; FreeNodes(node->sibling); FreeNodes(node->child); node=(IntervalTree *) RelinquishMagickMemory(node); } static MagickRealType OptimalTau(const ssize_t *histogram,const double max_tau, const double min_tau,const double delta_tau,const double smooth_threshold, short *extrema) { IntervalTree **list, *node, *root; MagickBooleanType peak; MagickRealType average_tau, *derivative, *second_derivative, tau, value; register ssize_t i, x; size_t count, number_crossings; ssize_t index, j, k, number_nodes; ZeroCrossing *zero_crossing; /* Allocate interval tree. */ list=(IntervalTree **) AcquireQuantumMemory((size_t) TreeLength, sizeof(*list)); if (list == (IntervalTree **) NULL) return(0.0); /* Allocate zero crossing list. */ count=(size_t) ((max_tau-min_tau)/delta_tau)+2; zero_crossing=(ZeroCrossing *) AcquireQuantumMemory((size_t) count, sizeof(*zero_crossing)); if (zero_crossing == (ZeroCrossing *) NULL) { list=(IntervalTree **) RelinquishMagickMemory(list); return(0.0); } for (i=0; i < (ssize_t) count; i++) zero_crossing[i].tau=(-1.0); /* Initialize zero crossing list. */ derivative=(MagickRealType *) AcquireCriticalMemory(256*sizeof(*derivative)); second_derivative=(MagickRealType *) AcquireCriticalMemory(256* sizeof(*second_derivative)); i=0; for (tau=max_tau; tau >= min_tau; tau-=delta_tau) { zero_crossing[i].tau=tau; ScaleSpace(histogram,tau,zero_crossing[i].histogram); DerivativeHistogram(zero_crossing[i].histogram,derivative); DerivativeHistogram(derivative,second_derivative); ZeroCrossHistogram(second_derivative,smooth_threshold, zero_crossing[i].crossings); i++; } /* Add an entry for the original histogram. */ zero_crossing[i].tau=0.0; for (j=0; j <= 255; j++) zero_crossing[i].histogram[j]=(MagickRealType) histogram[j]; DerivativeHistogram(zero_crossing[i].histogram,derivative); DerivativeHistogram(derivative,second_derivative); ZeroCrossHistogram(second_derivative,smooth_threshold, zero_crossing[i].crossings); number_crossings=(size_t) i; derivative=(MagickRealType *) RelinquishMagickMemory(derivative); second_derivative=(MagickRealType *) RelinquishMagickMemory(second_derivative); /* Ensure the scale-space fingerprints form lines in scale-space, not loops. */ ConsolidateCrossings(zero_crossing,number_crossings); /* Force endpoints to be included in the interval. */ for (i=0; i <= (ssize_t) number_crossings; i++) { for (j=0; j < 255; j++) if (zero_crossing[i].crossings[j] != 0) break; zero_crossing[i].crossings[0]=(-zero_crossing[i].crossings[j]); for (j=255; j > 0; j--) if (zero_crossing[i].crossings[j] != 0) break; zero_crossing[i].crossings[255]=(-zero_crossing[i].crossings[j]); } /* Initialize interval tree. */ root=InitializeIntervalTree(zero_crossing,number_crossings); if (root == (IntervalTree *) NULL) { zero_crossing=(ZeroCrossing *) RelinquishMagickMemory(zero_crossing); list=(IntervalTree **) RelinquishMagickMemory(list); return(0.0); } /* Find active nodes: stability is greater (or equal) to the mean stability of its children. */ number_nodes=0; ActiveNodes(list,&number_nodes,root->child); /* Initialize extrema. */ for (i=0; i <= 255; i++) extrema[i]=0; for (i=0; i < number_nodes; i++) { /* Find this tau in zero crossings list. */ k=0; node=list[i]; for (j=0; j <= (ssize_t) number_crossings; j++) if (zero_crossing[j].tau == node->tau) k=j; /* Find the value of the peak. */ peak=zero_crossing[k].crossings[node->right] == -1 ? MagickTrue : MagickFalse; index=node->left; value=zero_crossing[k].histogram[index]; for (x=node->left; x <= node->right; x++) { if (peak != MagickFalse) { if (zero_crossing[k].histogram[x] > value) { value=zero_crossing[k].histogram[x]; index=x; } } else if (zero_crossing[k].histogram[x] < value) { value=zero_crossing[k].histogram[x]; index=x; } } for (x=node->left; x <= node->right; x++) { if (index == 0) index=256; if (peak != MagickFalse) extrema[x]=(short) index; else extrema[x]=(short) (-index); } } /* Determine the average tau. */ average_tau=0.0; for (i=0; i < number_nodes; i++) average_tau+=list[i]->tau; average_tau*=PerceptibleReciprocal((MagickRealType) number_nodes); /* Relinquish resources. */ FreeNodes(root); zero_crossing=(ZeroCrossing *) RelinquishMagickMemory(zero_crossing); list=(IntervalTree **) RelinquishMagickMemory(list); return(average_tau); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % + S c a l e S p a c e % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % ScaleSpace() performs a scale-space filter on the 1D histogram. % % The format of the ScaleSpace method is: % % ScaleSpace(const ssize_t *histogram,const MagickRealType tau, % MagickRealType *scale_histogram) % % A description of each parameter follows. % % o histogram: Specifies an array of MagickRealTypes representing the number % of pixels for each intensity of a particular color component. % */ static void ScaleSpace(const ssize_t *histogram,const MagickRealType tau, MagickRealType *scale_histogram) { double alpha, beta, *gamma, sum; register ssize_t u, x; gamma=(double *) AcquireQuantumMemory(256,sizeof(*gamma)); if (gamma == (double *) NULL) ThrowFatalException(ResourceLimitFatalError,"UnableToAllocateGammaMap"); alpha=1.0/(tau*sqrt(2.0*MagickPI)); beta=(-1.0/(2.0*tau*tau)); for (x=0; x <= 255; x++) gamma[x]=0.0; for (x=0; x <= 255; x++) { gamma[x]=exp((double) beta*x*x); if (gamma[x] < MagickEpsilon) break; } for (x=0; x <= 255; x++) { sum=0.0; for (u=0; u <= 255; u++) sum+=(double) histogram[u]*gamma[MagickAbsoluteValue(x-u)]; scale_histogram[x]=(MagickRealType) (alpha*sum); } gamma=(double *) RelinquishMagickMemory(gamma); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % S e g m e n t I m a g e % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % SegmentImage() segment an image by analyzing the histograms of the color % components and identifying units that are homogeneous with the fuzzy % C-means technique. % % The format of the SegmentImage method is: % % MagickBooleanType SegmentImage(Image *image, % const ColorspaceType colorspace,const MagickBooleanType verbose, % const double cluster_threshold,const double smooth_threshold) % % A description of each parameter follows. % % o image: the image. % % o colorspace: Indicate the colorspace. % % o verbose: Set to MagickTrue to print detailed information about the % identified classes. % % o cluster_threshold: This represents the minimum number of pixels % contained in a hexahedra before it can be considered valid (expressed % as a percentage). % % o smooth_threshold: the smoothing threshold eliminates noise in the second % derivative of the histogram. As the value is increased, you can expect a % smoother second derivative. % */ MagickExport MagickBooleanType SegmentImage(Image *image, const ColorspaceType colorspace,const MagickBooleanType verbose, const double cluster_threshold,const double smooth_threshold) { ColorspaceType previous_colorspace; MagickBooleanType status; register ssize_t i; short *extrema[MaxDimension]; ssize_t *histogram[MaxDimension]; /* Allocate histogram and extrema. */ assert(image != (Image *) NULL); assert(image->signature == MagickCoreSignature); if (image->debug != MagickFalse) (void) LogMagickEvent(TraceEvent,GetMagickModule(),"%s",image->filename); for (i=0; i < MaxDimension; i++) { histogram[i]=(ssize_t *) AcquireQuantumMemory(256,sizeof(**histogram)); extrema[i]=(short *) AcquireQuantumMemory(256,sizeof(**extrema)); if ((histogram[i] == (ssize_t *) NULL) || (extrema[i] == (short *) NULL)) { for (i-- ; i >= 0; i--) { extrema[i]=(short *) RelinquishMagickMemory(extrema[i]); histogram[i]=(ssize_t *) RelinquishMagickMemory(histogram[i]); } ThrowBinaryImageException(ResourceLimitError,"MemoryAllocationFailed", image->filename) } } /* Initialize histogram. */ previous_colorspace=image->colorspace; (void) TransformImageColorspace(image,colorspace); InitializeHistogram(image,histogram,&image->exception); (void) OptimalTau(histogram[Red],Tau,0.2,DeltaTau, smooth_threshold == 0.0 ? 1.0 : smooth_threshold,extrema[Red]); (void) OptimalTau(histogram[Green],Tau,0.2,DeltaTau, smooth_threshold == 0.0 ? 1.0 : smooth_threshold,extrema[Green]); (void) OptimalTau(histogram[Blue],Tau,0.2,DeltaTau, smooth_threshold == 0.0 ? 1.0 : smooth_threshold,extrema[Blue]); /* Classify using the fuzzy c-Means technique. */ status=Classify(image,extrema,cluster_threshold,WeightingExponent,verbose); (void) TransformImageColorspace(image,previous_colorspace); /* Relinquish resources. */ for (i=0; i < MaxDimension; i++) { extrema[i]=(short *) RelinquishMagickMemory(extrema[i]); histogram[i]=(ssize_t *) RelinquishMagickMemory(histogram[i]); } return(status); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % + Z e r o C r o s s H i s t o g r a m % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % ZeroCrossHistogram() find the zero crossings in a histogram and marks % directions as: 1 is negative to positive; 0 is zero crossing; and -1 % is positive to negative. % % The format of the ZeroCrossHistogram method is: % % ZeroCrossHistogram(MagickRealType *second_derivative, % const MagickRealType smooth_threshold,short *crossings) % % A description of each parameter follows. % % o second_derivative: Specifies an array of MagickRealTypes representing the % second derivative of the histogram of a particular color component. % % o crossings: This array of integers is initialized with % -1, 0, or 1 representing the slope of the first derivative of the % of a particular color component. % */ static void ZeroCrossHistogram(MagickRealType *second_derivative, const MagickRealType smooth_threshold,short *crossings) { register ssize_t i; ssize_t parity; /* Merge low numbers to zero to help prevent noise. */ for (i=0; i <= 255; i++) if ((second_derivative[i] < smooth_threshold) && (second_derivative[i] >= -smooth_threshold)) second_derivative[i]=0.0; /* Mark zero crossings. */ parity=0; for (i=0; i <= 255; i++) { crossings[i]=0; if (second_derivative[i] < 0.0) { if (parity > 0) crossings[i]=(-1); parity=1; } else if (second_derivative[i] > 0.0) { if (parity < 0) crossings[i]=1; parity=(-1); } } }

questao01.c

#include <stdio.h> #include <stdlib.h> #include "omp.h" int valida_primo(int numero); int main() { int num_inicio = 1, num_fim = 10; omp_set_num_threads(3); #pragma omp parallel { int thread_num = omp_get_thread_num(); int i; #pragma omp sections nowait { #pragma omp section { printf("\nthread: %d - ", thread_num); for(i=num_inicio - 1; i<=num_fim; i = i + 2) { printf("%d ", i); } } #pragma omp section { printf("\nthread: %d - ", thread_num); for(i=num_inicio; i<=num_fim; i = i + 2) { printf("%d ", i); } } #pragma omp section { printf("\nthread: %d - ", thread_num); for(i=num_inicio; i<=num_fim; i++) { if(valida_primo(i)) { printf("%d ", i); } } } } } return 0; } int valida_primo(int numero) { int i; for(i = 2; i < numero; i++) { if(numero % i == 0) { return 0; } } return 1; }

fourier.c

/* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % FFFFF OOO U U RRRR IIIII EEEEE RRRR % % F O O U U R R I E R R % % FFF O O U U RRRR I EEE RRRR % % F O O U U R R I E R R % % F OOO UUU R R IIIII EEEEE R R % % % % % % MagickCore Discrete Fourier Transform Methods % % % % Software Design % % Sean Burke % % Fred Weinhaus % % Cristy % % July 2009 % % % % % % Copyright @ 2009 ImageMagick Studio LLC, a non-profit organization % % dedicated to making software imaging solutions freely available. % % % % You may not use this file except in compliance with the License. You may % % obtain a copy of the License at % % % % https://imagemagick.org/script/license.php % % % % Unless required by applicable law or agreed to in writing, software % % distributed under the License is distributed on an "AS IS" BASIS, % % WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. % % See the License for the specific language governing permissions and % % limitations under the License. % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % */ /* Include declarations. */ #include "MagickCore/studio.h" #include "MagickCore/artifact.h" #include "MagickCore/attribute.h" #include "MagickCore/blob.h" #include "MagickCore/cache.h" #include "MagickCore/image.h" #include "MagickCore/image-private.h" #include "MagickCore/list.h" #include "MagickCore/fourier.h" #include "MagickCore/log.h" #include "MagickCore/memory_.h" #include "MagickCore/monitor.h" #include "MagickCore/monitor-private.h" #include "MagickCore/pixel-accessor.h" #include "MagickCore/property.h" #include "MagickCore/quantum-private.h" #include "MagickCore/resource_.h" #include "MagickCore/string-private.h" #include "MagickCore/thread-private.h" #if defined(MAGICKCORE_FFTW_DELEGATE) #if defined(MAGICKCORE_HAVE_COMPLEX_H) #include <complex.h> #endif #include <fftw3.h> #if !defined(MAGICKCORE_HAVE_CABS) #define cabs(z) (sqrt(z[0]*z[0]+z[1]*z[1])) #endif #if !defined(MAGICKCORE_HAVE_CARG) #define carg(z) (atan2(cimag(z),creal(z))) #endif #if !defined(MAGICKCORE_HAVE_CIMAG) #define cimag(z) (z[1]) #endif #if !defined(MAGICKCORE_HAVE_CREAL) #define creal(z) (z[0]) #endif #endif /* Typedef declarations. */ typedef struct _FourierInfo { PixelChannel channel; MagickBooleanType modulus; size_t width, height; ssize_t center; } FourierInfo; /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % C o m p l e x I m a g e s % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % ComplexImages() performs complex mathematics on an image sequence. % % The format of the ComplexImages method is: % % MagickBooleanType ComplexImages(Image *images,const ComplexOperator op, % ExceptionInfo *exception) % % A description of each parameter follows: % % o image: the image. % % o op: A complex operator. % % o exception: return any errors or warnings in this structure. % */ MagickExport Image *ComplexImages(const Image *images,const ComplexOperator op, ExceptionInfo *exception) { #define ComplexImageTag "Complex/Image" CacheView *Ai_view, *Ar_view, *Bi_view, *Br_view, *Ci_view, *Cr_view; const char *artifact; const Image *Ai_image, *Ar_image, *Bi_image, *Br_image; double snr; Image *Ci_image, *complex_images, *Cr_image, *image; MagickBooleanType status; MagickOffsetType progress; size_t columns, number_channels, rows; ssize_t y; assert(images != (Image *) NULL); assert(images->signature == MagickCoreSignature); if (images->debug != MagickFalse) (void) LogMagickEvent(TraceEvent,GetMagickModule(),"%s",images->filename); assert(exception != (ExceptionInfo *) NULL); assert(exception->signature == MagickCoreSignature); if (images->next == (Image *) NULL) { (void) ThrowMagickException(exception,GetMagickModule(),ImageError, "ImageSequenceRequired","`%s'",images->filename); return((Image *) NULL); } image=CloneImage(images,0,0,MagickTrue,exception); if (image == (Image *) NULL) return((Image *) NULL); if (SetImageStorageClass(image,DirectClass,exception) == MagickFalse) { image=DestroyImageList(image); return(image); } image->depth=32UL; complex_images=NewImageList(); AppendImageToList(&complex_images,image); image=CloneImage(images->next,0,0,MagickTrue,exception); if (image == (Image *) NULL) { complex_images=DestroyImageList(complex_images); return(complex_images); } image->depth=32UL; AppendImageToList(&complex_images,image); if (SetImageStorageClass(image,DirectClass,exception) == MagickFalse) { complex_images=DestroyImageList(complex_images); return(complex_images); } /* Apply complex mathematics to image pixels. */ artifact=GetImageArtifact(images,"complex:snr"); snr=0.0; if (artifact != (const char *) NULL) snr=StringToDouble(artifact,(char **) NULL); Ar_image=images; Ai_image=images->next; Br_image=images; Bi_image=images->next; if ((images->next->next != (Image *) NULL) && (images->next->next->next != (Image *) NULL)) { Br_image=images->next->next; Bi_image=images->next->next->next; } Cr_image=complex_images; Ci_image=complex_images->next; number_channels=MagickMin(MagickMin(MagickMin( Ar_image->number_channels,Ai_image->number_channels),MagickMin( Br_image->number_channels,Bi_image->number_channels)),MagickMin( Cr_image->number_channels,Ci_image->number_channels)); Ar_view=AcquireVirtualCacheView(Ar_image,exception); Ai_view=AcquireVirtualCacheView(Ai_image,exception); Br_view=AcquireVirtualCacheView(Br_image,exception); Bi_view=AcquireVirtualCacheView(Bi_image,exception); Cr_view=AcquireAuthenticCacheView(Cr_image,exception); Ci_view=AcquireAuthenticCacheView(Ci_image,exception); status=MagickTrue; progress=0; columns=MagickMin(Cr_image->columns,Ci_image->columns); rows=MagickMin(Cr_image->rows,Ci_image->rows); #if defined(MAGICKCORE_OPENMP_SUPPORT) #pragma omp parallel for schedule(static) shared(progress,status) \ magick_number_threads(Cr_image,complex_images,rows,1L) #endif for (y=0; y < (ssize_t) rows; y++) { const Quantum *magick_restrict Ai, *magick_restrict Ar, *magick_restrict Bi, *magick_restrict Br; Quantum *magick_restrict Ci, *magick_restrict Cr; ssize_t x; if (status == MagickFalse) continue; Ar=GetCacheViewVirtualPixels(Ar_view,0,y,columns,1,exception); Ai=GetCacheViewVirtualPixels(Ai_view,0,y,columns,1,exception); Br=GetCacheViewVirtualPixels(Br_view,0,y,columns,1,exception); Bi=GetCacheViewVirtualPixels(Bi_view,0,y,columns,1,exception); Cr=QueueCacheViewAuthenticPixels(Cr_view,0,y,columns,1,exception); Ci=QueueCacheViewAuthenticPixels(Ci_view,0,y,columns,1,exception); if ((Ar == (const Quantum *) NULL) || (Ai == (const Quantum *) NULL) || (Br == (const Quantum *) NULL) || (Bi == (const Quantum *) NULL) || (Cr == (Quantum *) NULL) || (Ci == (Quantum *) NULL)) { status=MagickFalse; continue; } for (x=0; x < (ssize_t) columns; x++) { ssize_t i; for (i=0; i < (ssize_t) number_channels; i++) { switch (op) { case AddComplexOperator: { Cr[i]=Ar[i]+Br[i]; Ci[i]=Ai[i]+Bi[i]; break; } case ConjugateComplexOperator: default: { Cr[i]=Ar[i]; Ci[i]=(-Ai[i]); break; } case DivideComplexOperator: { double gamma; gamma=QuantumRange*PerceptibleReciprocal(QuantumScale*Br[i]*Br[i]+ QuantumScale*Bi[i]*Bi[i]+snr); Cr[i]=gamma*(QuantumScale*Ar[i]*Br[i]+QuantumScale*Ai[i]*Bi[i]); Ci[i]=gamma*(QuantumScale*Ai[i]*Br[i]-QuantumScale*Ar[i]*Bi[i]); break; } case MagnitudePhaseComplexOperator: { Cr[i]=sqrt(QuantumScale*Ar[i]*Ar[i]+QuantumScale*Ai[i]*Ai[i]); Ci[i]=atan2((double) Ai[i],(double) Ar[i])/(2.0*MagickPI)+0.5; break; } case MultiplyComplexOperator: { Cr[i]=(QuantumScale*Ar[i]*Br[i]-QuantumScale*Ai[i]*Bi[i]); Ci[i]=(QuantumScale*Ai[i]*Br[i]+QuantumScale*Ar[i]*Bi[i]); break; } case RealImaginaryComplexOperator: { Cr[i]=Ar[i]*cos(2.0*MagickPI*(Ai[i]-0.5)); Ci[i]=Ar[i]*sin(2.0*MagickPI*(Ai[i]-0.5)); break; } case SubtractComplexOperator: { Cr[i]=Ar[i]-Br[i]; Ci[i]=Ai[i]-Bi[i]; break; } } } Ar+=GetPixelChannels(Ar_image); Ai+=GetPixelChannels(Ai_image); Br+=GetPixelChannels(Br_image); Bi+=GetPixelChannels(Bi_image); Cr+=GetPixelChannels(Cr_image); Ci+=GetPixelChannels(Ci_image); } if (SyncCacheViewAuthenticPixels(Ci_view,exception) == MagickFalse) status=MagickFalse; if (SyncCacheViewAuthenticPixels(Cr_view,exception) == MagickFalse) status=MagickFalse; if (images->progress_monitor != (MagickProgressMonitor) NULL) { MagickBooleanType proceed; #if defined(MAGICKCORE_OPENMP_SUPPORT) #pragma omp atomic #endif progress++; proceed=SetImageProgress(images,ComplexImageTag,progress,images->rows); if (proceed == MagickFalse) status=MagickFalse; } } Cr_view=DestroyCacheView(Cr_view); Ci_view=DestroyCacheView(Ci_view); Br_view=DestroyCacheView(Br_view); Bi_view=DestroyCacheView(Bi_view); Ar_view=DestroyCacheView(Ar_view); Ai_view=DestroyCacheView(Ai_view); if (status == MagickFalse) complex_images=DestroyImageList(complex_images); return(complex_images); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % F o r w a r d F o u r i e r T r a n s f o r m I m a g e % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % ForwardFourierTransformImage() implements the discrete Fourier transform % (DFT) of the image either as a magnitude / phase or real / imaginary image % pair. % % The format of the ForwadFourierTransformImage method is: % % Image *ForwardFourierTransformImage(const Image *image, % const MagickBooleanType modulus,ExceptionInfo *exception) % % A description of each parameter follows: % % o image: the image. % % o modulus: if true, return as transform as a magnitude / phase pair % otherwise a real / imaginary image pair. % % o exception: return any errors or warnings in this structure. % */ #if defined(MAGICKCORE_FFTW_DELEGATE) static MagickBooleanType RollFourier(const size_t width,const size_t height, const ssize_t x_offset,const ssize_t y_offset,double *roll_pixels) { double *source_pixels; MemoryInfo *source_info; ssize_t i, x; ssize_t u, v, y; /* Move zero frequency (DC, average color) from (0,0) to (width/2,height/2). */ source_info=AcquireVirtualMemory(width,height*sizeof(*source_pixels)); if (source_info == (MemoryInfo *) NULL) return(MagickFalse); source_pixels=(double *) GetVirtualMemoryBlob(source_info); i=0L; for (y=0L; y < (ssize_t) height; y++) { if (y_offset < 0L) v=((y+y_offset) < 0L) ? y+y_offset+(ssize_t) height : y+y_offset; else v=((y+y_offset) > ((ssize_t) height-1L)) ? y+y_offset-(ssize_t) height : y+y_offset; for (x=0L; x < (ssize_t) width; x++) { if (x_offset < 0L) u=((x+x_offset) < 0L) ? x+x_offset+(ssize_t) width : x+x_offset; else u=((x+x_offset) > ((ssize_t) width-1L)) ? x+x_offset-(ssize_t) width : x+x_offset; source_pixels[v*width+u]=roll_pixels[i++]; } } (void) memcpy(roll_pixels,source_pixels,height*width*sizeof(*source_pixels)); source_info=RelinquishVirtualMemory(source_info); return(MagickTrue); } static MagickBooleanType ForwardQuadrantSwap(const size_t width, const size_t height,double *source_pixels,double *forward_pixels) { MagickBooleanType status; ssize_t x; ssize_t center, y; /* Swap quadrants. */ center=(ssize_t) (width/2L)+1L; status=RollFourier((size_t) center,height,0L,(ssize_t) height/2L, source_pixels); if (status == MagickFalse) return(MagickFalse); for (y=0L; y < (ssize_t) height; y++) for (x=0L; x < (ssize_t) (width/2L); x++) forward_pixels[y*width+x+width/2L]=source_pixels[y*center+x]; for (y=1; y < (ssize_t) height; y++) for (x=0L; x < (ssize_t) (width/2L); x++) forward_pixels[(height-y)*width+width/2L-x-1L]= source_pixels[y*center+x+1L]; for (x=0L; x < (ssize_t) (width/2L); x++) forward_pixels[width/2L-x-1L]=source_pixels[x+1L]; return(MagickTrue); } static void CorrectPhaseLHS(const size_t width,const size_t height, double *fourier_pixels) { ssize_t x; ssize_t y; for (y=0L; y < (ssize_t) height; y++) for (x=0L; x < (ssize_t) (width/2L); x++) fourier_pixels[y*width+x]*=(-1.0); } static MagickBooleanType ForwardFourier(const FourierInfo *fourier_info, Image *image,double *magnitude,double *phase,ExceptionInfo *exception) { CacheView *magnitude_view, *phase_view; double *magnitude_pixels, *phase_pixels; Image *magnitude_image, *phase_image; MagickBooleanType status; MemoryInfo *magnitude_info, *phase_info; Quantum *q; ssize_t x; ssize_t i, y; magnitude_image=GetFirstImageInList(image); phase_image=GetNextImageInList(image); if (phase_image == (Image *) NULL) { (void) ThrowMagickException(exception,GetMagickModule(),ImageError, "ImageSequenceRequired","`%s'",image->filename); return(MagickFalse); } /* Create "Fourier Transform" image from constituent arrays. */ magnitude_info=AcquireVirtualMemory((size_t) fourier_info->width, fourier_info->height*sizeof(*magnitude_pixels)); phase_info=AcquireVirtualMemory((size_t) fourier_info->width, fourier_info->height*sizeof(*phase_pixels)); if ((magnitude_info == (MemoryInfo *) NULL) || (phase_info == (MemoryInfo *) NULL)) { if (phase_info != (MemoryInfo *) NULL) phase_info=RelinquishVirtualMemory(phase_info); if (magnitude_info != (MemoryInfo *) NULL) magnitude_info=RelinquishVirtualMemory(magnitude_info); (void) ThrowMagickException(exception,GetMagickModule(), ResourceLimitError,"MemoryAllocationFailed","`%s'",image->filename); return(MagickFalse); } magnitude_pixels=(double *) GetVirtualMemoryBlob(magnitude_info); (void) memset(magnitude_pixels,0,fourier_info->width* fourier_info->height*sizeof(*magnitude_pixels)); phase_pixels=(double *) GetVirtualMemoryBlob(phase_info); (void) memset(phase_pixels,0,fourier_info->width* fourier_info->height*sizeof(*phase_pixels)); status=ForwardQuadrantSwap(fourier_info->width,fourier_info->height, magnitude,magnitude_pixels); if (status != MagickFalse) status=ForwardQuadrantSwap(fourier_info->width,fourier_info->height,phase, phase_pixels); CorrectPhaseLHS(fourier_info->width,fourier_info->height,phase_pixels); if (fourier_info->modulus != MagickFalse) { i=0L; for (y=0L; y < (ssize_t) fourier_info->height; y++) for (x=0L; x < (ssize_t) fourier_info->width; x++) { phase_pixels[i]/=(2.0*MagickPI); phase_pixels[i]+=0.5; i++; } } magnitude_view=AcquireAuthenticCacheView(magnitude_image,exception); i=0L; for (y=0L; y < (ssize_t) fourier_info->height; y++) { q=GetCacheViewAuthenticPixels(magnitude_view,0L,y,fourier_info->width,1UL, exception); if (q == (Quantum *) NULL) break; for (x=0L; x < (ssize_t) fourier_info->width; x++) { switch (fourier_info->channel) { case RedPixelChannel: default: { SetPixelRed(magnitude_image,ClampToQuantum(QuantumRange* magnitude_pixels[i]),q); break; } case GreenPixelChannel: { SetPixelGreen(magnitude_image,ClampToQuantum(QuantumRange* magnitude_pixels[i]),q); break; } case BluePixelChannel: { SetPixelBlue(magnitude_image,ClampToQuantum(QuantumRange* magnitude_pixels[i]),q); break; } case BlackPixelChannel: { SetPixelBlack(magnitude_image,ClampToQuantum(QuantumRange* magnitude_pixels[i]),q); break; } case AlphaPixelChannel: { SetPixelAlpha(magnitude_image,ClampToQuantum(QuantumRange* magnitude_pixels[i]),q); break; } } i++; q+=GetPixelChannels(magnitude_image); } status=SyncCacheViewAuthenticPixels(magnitude_view,exception); if (status == MagickFalse) break; } magnitude_view=DestroyCacheView(magnitude_view); i=0L; phase_view=AcquireAuthenticCacheView(phase_image,exception); for (y=0L; y < (ssize_t) fourier_info->height; y++) { q=GetCacheViewAuthenticPixels(phase_view,0L,y,fourier_info->width,1UL, exception); if (q == (Quantum *) NULL) break; for (x=0L; x < (ssize_t) fourier_info->width; x++) { switch (fourier_info->channel) { case RedPixelChannel: default: { SetPixelRed(phase_image,ClampToQuantum(QuantumRange* phase_pixels[i]),q); break; } case GreenPixelChannel: { SetPixelGreen(phase_image,ClampToQuantum(QuantumRange* phase_pixels[i]),q); break; } case BluePixelChannel: { SetPixelBlue(phase_image,ClampToQuantum(QuantumRange* phase_pixels[i]),q); break; } case BlackPixelChannel: { SetPixelBlack(phase_image,ClampToQuantum(QuantumRange* phase_pixels[i]),q); break; } case AlphaPixelChannel: { SetPixelAlpha(phase_image,ClampToQuantum(QuantumRange* phase_pixels[i]),q); break; } } i++; q+=GetPixelChannels(phase_image); } status=SyncCacheViewAuthenticPixels(phase_view,exception); if (status == MagickFalse) break; } phase_view=DestroyCacheView(phase_view); phase_info=RelinquishVirtualMemory(phase_info); magnitude_info=RelinquishVirtualMemory(magnitude_info); return(status); } static MagickBooleanType ForwardFourierTransform(FourierInfo *fourier_info, const Image *image,double *magnitude_pixels,double *phase_pixels, ExceptionInfo *exception) { CacheView *image_view; const char *value; double *source_pixels; fftw_complex *forward_pixels; fftw_plan fftw_r2c_plan; MemoryInfo *forward_info, *source_info; const Quantum *p; ssize_t i, x; ssize_t y; /* Generate the forward Fourier transform. */ source_info=AcquireVirtualMemory((size_t) fourier_info->width, fourier_info->height*sizeof(*source_pixels)); if (source_info == (MemoryInfo *) NULL) { (void) ThrowMagickException(exception,GetMagickModule(), ResourceLimitError,"MemoryAllocationFailed","`%s'",image->filename); return(MagickFalse); } source_pixels=(double *) GetVirtualMemoryBlob(source_info); memset(source_pixels,0,fourier_info->width*fourier_info->height* sizeof(*source_pixels)); i=0L; image_view=AcquireVirtualCacheView(image,exception); for (y=0L; y < (ssize_t) fourier_info->height; y++) { p=GetCacheViewVirtualPixels(image_view,0L,y,fourier_info->width,1UL, exception); if (p == (const Quantum *) NULL) break; for (x=0L; x < (ssize_t) fourier_info->width; x++) { switch (fourier_info->channel) { case RedPixelChannel: default: { source_pixels[i]=QuantumScale*GetPixelRed(image,p); break; } case GreenPixelChannel: { source_pixels[i]=QuantumScale*GetPixelGreen(image,p); break; } case BluePixelChannel: { source_pixels[i]=QuantumScale*GetPixelBlue(image,p); break; } case BlackPixelChannel: { source_pixels[i]=QuantumScale*GetPixelBlack(image,p); break; } case AlphaPixelChannel: { source_pixels[i]=QuantumScale*GetPixelAlpha(image,p); break; } } i++; p+=GetPixelChannels(image); } } image_view=DestroyCacheView(image_view); forward_info=AcquireVirtualMemory((size_t) fourier_info->width, (fourier_info->height/2+1)*sizeof(*forward_pixels)); if (forward_info == (MemoryInfo *) NULL) { (void) ThrowMagickException(exception,GetMagickModule(), ResourceLimitError,"MemoryAllocationFailed","`%s'",image->filename); source_info=(MemoryInfo *) RelinquishVirtualMemory(source_info); return(MagickFalse); } forward_pixels=(fftw_complex *) GetVirtualMemoryBlob(forward_info); #if defined(MAGICKCORE_OPENMP_SUPPORT) #pragma omp critical (MagickCore_ForwardFourierTransform) #endif fftw_r2c_plan=fftw_plan_dft_r2c_2d(fourier_info->width,fourier_info->height, source_pixels,forward_pixels,FFTW_ESTIMATE); fftw_execute_dft_r2c(fftw_r2c_plan,source_pixels,forward_pixels); fftw_destroy_plan(fftw_r2c_plan); source_info=(MemoryInfo *) RelinquishVirtualMemory(source_info); value=GetImageArtifact(image,"fourier:normalize"); if ((value == (const char *) NULL) || (LocaleCompare(value,"forward") == 0)) { double gamma; /* Normalize forward transform. */ i=0L; gamma=PerceptibleReciprocal((double) fourier_info->width* fourier_info->height); for (y=0L; y < (ssize_t) fourier_info->height; y++) for (x=0L; x < (ssize_t) fourier_info->center; x++) { #if defined(MAGICKCORE_HAVE_COMPLEX_H) forward_pixels[i]*=gamma; #else forward_pixels[i][0]*=gamma; forward_pixels[i][1]*=gamma; #endif i++; } } /* Generate magnitude and phase (or real and imaginary). */ i=0L; if (fourier_info->modulus != MagickFalse) for (y=0L; y < (ssize_t) fourier_info->height; y++) for (x=0L; x < (ssize_t) fourier_info->center; x++) { magnitude_pixels[i]=cabs(forward_pixels[i]); phase_pixels[i]=carg(forward_pixels[i]); i++; } else for (y=0L; y < (ssize_t) fourier_info->height; y++) for (x=0L; x < (ssize_t) fourier_info->center; x++) { magnitude_pixels[i]=creal(forward_pixels[i]); phase_pixels[i]=cimag(forward_pixels[i]); i++; } forward_info=(MemoryInfo *) RelinquishVirtualMemory(forward_info); return(MagickTrue); } static MagickBooleanType ForwardFourierTransformChannel(const Image *image, const PixelChannel channel,const MagickBooleanType modulus, Image *fourier_image,ExceptionInfo *exception) { double *magnitude_pixels, *phase_pixels; FourierInfo fourier_info; MagickBooleanType status; MemoryInfo *magnitude_info, *phase_info; fourier_info.width=image->columns; fourier_info.height=image->rows; if ((image->columns != image->rows) || ((image->columns % 2) != 0) || ((image->rows % 2) != 0)) { size_t extent=image->columns < image->rows ? image->rows : image->columns; fourier_info.width=(extent & 0x01) == 1 ? extent+1UL : extent; } fourier_info.height=fourier_info.width; fourier_info.center=(ssize_t) (fourier_info.width/2L)+1L; fourier_info.channel=channel; fourier_info.modulus=modulus; magnitude_info=AcquireVirtualMemory((size_t) fourier_info.width, (fourier_info.height/2+1)*sizeof(*magnitude_pixels)); phase_info=AcquireVirtualMemory((size_t) fourier_info.width, (fourier_info.height/2+1)*sizeof(*phase_pixels)); if ((magnitude_info == (MemoryInfo *) NULL) || (phase_info == (MemoryInfo *) NULL)) { if (phase_info != (MemoryInfo *) NULL) phase_info=RelinquishVirtualMemory(phase_info); if (magnitude_info == (MemoryInfo *) NULL) magnitude_info=RelinquishVirtualMemory(magnitude_info); (void) ThrowMagickException(exception,GetMagickModule(), ResourceLimitError,"MemoryAllocationFailed","`%s'",image->filename); return(MagickFalse); } magnitude_pixels=(double *) GetVirtualMemoryBlob(magnitude_info); phase_pixels=(double *) GetVirtualMemoryBlob(phase_info); status=ForwardFourierTransform(&fourier_info,image,magnitude_pixels, phase_pixels,exception); if (status != MagickFalse) status=ForwardFourier(&fourier_info,fourier_image,magnitude_pixels, phase_pixels,exception); phase_info=RelinquishVirtualMemory(phase_info); magnitude_info=RelinquishVirtualMemory(magnitude_info); return(status); } #endif MagickExport Image *ForwardFourierTransformImage(const Image *image, const MagickBooleanType modulus,ExceptionInfo *exception) { Image *fourier_image; fourier_image=NewImageList(); #if !defined(MAGICKCORE_FFTW_DELEGATE) (void) modulus; (void) ThrowMagickException(exception,GetMagickModule(), MissingDelegateWarning,"DelegateLibrarySupportNotBuiltIn","`%s' (FFTW)", image->filename); #else { Image *magnitude_image; size_t height, width; width=image->columns; height=image->rows; if ((image->columns != image->rows) || ((image->columns % 2) != 0) || ((image->rows % 2) != 0)) { size_t extent=image->columns < image->rows ? image->rows : image->columns; width=(extent & 0x01) == 1 ? extent+1UL : extent; } height=width; magnitude_image=CloneImage(image,width,height,MagickTrue,exception); if (magnitude_image != (Image *) NULL) { Image *phase_image; magnitude_image->storage_class=DirectClass; magnitude_image->depth=32UL; phase_image=CloneImage(image,width,height,MagickTrue,exception); if (phase_image == (Image *) NULL) magnitude_image=DestroyImage(magnitude_image); else { MagickBooleanType is_gray, status; phase_image->storage_class=DirectClass; phase_image->depth=32UL; AppendImageToList(&fourier_image,magnitude_image); AppendImageToList(&fourier_image,phase_image); status=MagickTrue; is_gray=IsImageGray(image); #if defined(MAGICKCORE_OPENMP_SUPPORT) #pragma omp parallel sections #endif { #if defined(MAGICKCORE_OPENMP_SUPPORT) #pragma omp section #endif { MagickBooleanType thread_status; if (is_gray != MagickFalse) thread_status=ForwardFourierTransformChannel(image, GrayPixelChannel,modulus,fourier_image,exception); else thread_status=ForwardFourierTransformChannel(image, RedPixelChannel,modulus,fourier_image,exception); if (thread_status == MagickFalse) status=thread_status; } #if defined(MAGICKCORE_OPENMP_SUPPORT) #pragma omp section #endif { MagickBooleanType thread_status; thread_status=MagickTrue; if (is_gray == MagickFalse) thread_status=ForwardFourierTransformChannel(image, GreenPixelChannel,modulus,fourier_image,exception); if (thread_status == MagickFalse) status=thread_status; } #if defined(MAGICKCORE_OPENMP_SUPPORT) #pragma omp section #endif { MagickBooleanType thread_status; thread_status=MagickTrue; if (is_gray == MagickFalse) thread_status=ForwardFourierTransformChannel(image, BluePixelChannel,modulus,fourier_image,exception); if (thread_status == MagickFalse) status=thread_status; } #if defined(MAGICKCORE_OPENMP_SUPPORT) #pragma omp section #endif { MagickBooleanType thread_status; thread_status=MagickTrue; if (image->colorspace == CMYKColorspace) thread_status=ForwardFourierTransformChannel(image, BlackPixelChannel,modulus,fourier_image,exception); if (thread_status == MagickFalse) status=thread_status; } #if defined(MAGICKCORE_OPENMP_SUPPORT) #pragma omp section #endif { MagickBooleanType thread_status; thread_status=MagickTrue; if (image->alpha_trait != UndefinedPixelTrait) thread_status=ForwardFourierTransformChannel(image, AlphaPixelChannel,modulus,fourier_image,exception); if (thread_status == MagickFalse) status=thread_status; } } if (status == MagickFalse) fourier_image=DestroyImageList(fourier_image); fftw_cleanup(); } } } #endif return(fourier_image); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % I n v e r s e F o u r i e r T r a n s f o r m I m a g e % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % InverseFourierTransformImage() implements the inverse discrete Fourier % transform (DFT) of the image either as a magnitude / phase or real / % imaginary image pair. % % The format of the InverseFourierTransformImage method is: % % Image *InverseFourierTransformImage(const Image *magnitude_image, % const Image *phase_image,const MagickBooleanType modulus, % ExceptionInfo *exception) % % A description of each parameter follows: % % o magnitude_image: the magnitude or real image. % % o phase_image: the phase or imaginary image. % % o modulus: if true, return transform as a magnitude / phase pair % otherwise a real / imaginary image pair. % % o exception: return any errors or warnings in this structure. % */ #if defined(MAGICKCORE_FFTW_DELEGATE) static MagickBooleanType InverseQuadrantSwap(const size_t width, const size_t height,const double *source,double *destination) { ssize_t x; ssize_t center, y; /* Swap quadrants. */ center=(ssize_t) (width/2L)+1L; for (y=1L; y < (ssize_t) height; y++) for (x=0L; x < (ssize_t) (width/2L+1L); x++) destination[(height-y)*center-x+width/2L]=source[y*width+x]; for (y=0L; y < (ssize_t) height; y++) destination[y*center]=source[y*width+width/2L]; for (x=0L; x < center; x++) destination[x]=source[center-x-1L]; return(RollFourier(center,height,0L,(ssize_t) height/-2L,destination)); } static MagickBooleanType InverseFourier(FourierInfo *fourier_info, const Image *magnitude_image,const Image *phase_image, fftw_complex *fourier_pixels,ExceptionInfo *exception) { CacheView *magnitude_view, *phase_view; double *inverse_pixels, *magnitude_pixels, *phase_pixels; MagickBooleanType status; MemoryInfo *inverse_info, *magnitude_info, *phase_info; const Quantum *p; ssize_t i, x; ssize_t y; /* Inverse fourier - read image and break down into a double array. */ magnitude_info=AcquireVirtualMemory((size_t) fourier_info->width, fourier_info->height*sizeof(*magnitude_pixels)); phase_info=AcquireVirtualMemory((size_t) fourier_info->width, fourier_info->height*sizeof(*phase_pixels)); inverse_info=AcquireVirtualMemory((size_t) fourier_info->width, (fourier_info->height/2+1)*sizeof(*inverse_pixels)); if ((magnitude_info == (MemoryInfo *) NULL) || (phase_info == (MemoryInfo *) NULL) || (inverse_info == (MemoryInfo *) NULL)) { if (magnitude_info != (MemoryInfo *) NULL) magnitude_info=RelinquishVirtualMemory(magnitude_info); if (phase_info != (MemoryInfo *) NULL) phase_info=RelinquishVirtualMemory(phase_info); if (inverse_info != (MemoryInfo *) NULL) inverse_info=RelinquishVirtualMemory(inverse_info); (void) ThrowMagickException(exception,GetMagickModule(), ResourceLimitError,"MemoryAllocationFailed","`%s'", magnitude_image->filename); return(MagickFalse); } magnitude_pixels=(double *) GetVirtualMemoryBlob(magnitude_info); phase_pixels=(double *) GetVirtualMemoryBlob(phase_info); inverse_pixels=(double *) GetVirtualMemoryBlob(inverse_info); i=0L; magnitude_view=AcquireVirtualCacheView(magnitude_image,exception); for (y=0L; y < (ssize_t) fourier_info->height; y++) { p=GetCacheViewVirtualPixels(magnitude_view,0L,y,fourier_info->width,1UL, exception); if (p == (const Quantum *) NULL) break; for (x=0L; x < (ssize_t) fourier_info->width; x++) { switch (fourier_info->channel) { case RedPixelChannel: default: { magnitude_pixels[i]=QuantumScale*GetPixelRed(magnitude_image,p); break; } case GreenPixelChannel: { magnitude_pixels[i]=QuantumScale*GetPixelGreen(magnitude_image,p); break; } case BluePixelChannel: { magnitude_pixels[i]=QuantumScale*GetPixelBlue(magnitude_image,p); break; } case BlackPixelChannel: { magnitude_pixels[i]=QuantumScale*GetPixelBlack(magnitude_image,p); break; } case AlphaPixelChannel: { magnitude_pixels[i]=QuantumScale*GetPixelAlpha(magnitude_image,p); break; } } i++; p+=GetPixelChannels(magnitude_image); } } magnitude_view=DestroyCacheView(magnitude_view); status=InverseQuadrantSwap(fourier_info->width,fourier_info->height, magnitude_pixels,inverse_pixels); (void) memcpy(magnitude_pixels,inverse_pixels,fourier_info->height* fourier_info->center*sizeof(*magnitude_pixels)); i=0L; phase_view=AcquireVirtualCacheView(phase_image,exception); for (y=0L; y < (ssize_t) fourier_info->height; y++) { p=GetCacheViewVirtualPixels(phase_view,0,y,fourier_info->width,1, exception); if (p == (const Quantum *) NULL) break; for (x=0L; x < (ssize_t) fourier_info->width; x++) { switch (fourier_info->channel) { case RedPixelChannel: default: { phase_pixels[i]=QuantumScale*GetPixelRed(phase_image,p); break; } case GreenPixelChannel: { phase_pixels[i]=QuantumScale*GetPixelGreen(phase_image,p); break; } case BluePixelChannel: { phase_pixels[i]=QuantumScale*GetPixelBlue(phase_image,p); break; } case BlackPixelChannel: { phase_pixels[i]=QuantumScale*GetPixelBlack(phase_image,p); break; } case AlphaPixelChannel: { phase_pixels[i]=QuantumScale*GetPixelAlpha(phase_image,p); break; } } i++; p+=GetPixelChannels(phase_image); } } if (fourier_info->modulus != MagickFalse) { i=0L; for (y=0L; y < (ssize_t) fourier_info->height; y++) for (x=0L; x < (ssize_t) fourier_info->width; x++) { phase_pixels[i]-=0.5; phase_pixels[i]*=(2.0*MagickPI); i++; } } phase_view=DestroyCacheView(phase_view); CorrectPhaseLHS(fourier_info->width,fourier_info->height,phase_pixels); if (status != MagickFalse) status=InverseQuadrantSwap(fourier_info->width,fourier_info->height, phase_pixels,inverse_pixels); (void) memcpy(phase_pixels,inverse_pixels,fourier_info->height* fourier_info->center*sizeof(*phase_pixels)); inverse_info=RelinquishVirtualMemory(inverse_info); /* Merge two sets. */ i=0L; if (fourier_info->modulus != MagickFalse) for (y=0L; y < (ssize_t) fourier_info->height; y++) for (x=0L; x < (ssize_t) fourier_info->center; x++) { #if defined(MAGICKCORE_HAVE_COMPLEX_H) fourier_pixels[i]=magnitude_pixels[i]*cos(phase_pixels[i])+I* magnitude_pixels[i]*sin(phase_pixels[i]); #else fourier_pixels[i][0]=magnitude_pixels[i]*cos(phase_pixels[i]); fourier_pixels[i][1]=magnitude_pixels[i]*sin(phase_pixels[i]); #endif i++; } else for (y=0L; y < (ssize_t) fourier_info->height; y++) for (x=0L; x < (ssize_t) fourier_info->center; x++) { #if defined(MAGICKCORE_HAVE_COMPLEX_H) fourier_pixels[i]=magnitude_pixels[i]+I*phase_pixels[i]; #else fourier_pixels[i][0]=magnitude_pixels[i]; fourier_pixels[i][1]=phase_pixels[i]; #endif i++; } magnitude_info=RelinquishVirtualMemory(magnitude_info); phase_info=RelinquishVirtualMemory(phase_info); return(status); } static MagickBooleanType InverseFourierTransform(FourierInfo *fourier_info, fftw_complex *fourier_pixels,Image *image,ExceptionInfo *exception) { CacheView *image_view; const char *value; double *source_pixels; fftw_plan fftw_c2r_plan; MemoryInfo *source_info; Quantum *q; ssize_t i, x; ssize_t y; source_info=AcquireVirtualMemory((size_t) fourier_info->width, fourier_info->height*sizeof(*source_pixels)); if (source_info == (MemoryInfo *) NULL) { (void) ThrowMagickException(exception,GetMagickModule(), ResourceLimitError,"MemoryAllocationFailed","`%s'",image->filename); return(MagickFalse); } source_pixels=(double *) GetVirtualMemoryBlob(source_info); value=GetImageArtifact(image,"fourier:normalize"); if (LocaleCompare(value,"inverse") == 0) { double gamma; /* Normalize inverse transform. */ i=0L; gamma=PerceptibleReciprocal((double) fourier_info->width* fourier_info->height); for (y=0L; y < (ssize_t) fourier_info->height; y++) for (x=0L; x < (ssize_t) fourier_info->center; x++) { #if defined(MAGICKCORE_HAVE_COMPLEX_H) fourier_pixels[i]*=gamma; #else fourier_pixels[i][0]*=gamma; fourier_pixels[i][1]*=gamma; #endif i++; } } #if defined(MAGICKCORE_OPENMP_SUPPORT) #pragma omp critical (MagickCore_InverseFourierTransform) #endif fftw_c2r_plan=fftw_plan_dft_c2r_2d(fourier_info->width,fourier_info->height, fourier_pixels,source_pixels,FFTW_ESTIMATE); fftw_execute_dft_c2r(fftw_c2r_plan,fourier_pixels,source_pixels); fftw_destroy_plan(fftw_c2r_plan); i=0L; image_view=AcquireAuthenticCacheView(image,exception); for (y=0L; y < (ssize_t) fourier_info->height; y++) { if (y >= (ssize_t) image->rows) break; q=GetCacheViewAuthenticPixels(image_view,0L,y,fourier_info->width > image->columns ? image->columns : fourier_info->width,1UL,exception); if (q == (Quantum *) NULL) break; for (x=0L; x < (ssize_t) fourier_info->width; x++) { if (x < (ssize_t) image->columns) switch (fourier_info->channel) { case RedPixelChannel: default: { SetPixelRed(image,ClampToQuantum(QuantumRange*source_pixels[i]),q); break; } case GreenPixelChannel: { SetPixelGreen(image,ClampToQuantum(QuantumRange*source_pixels[i]), q); break; } case BluePixelChannel: { SetPixelBlue(image,ClampToQuantum(QuantumRange*source_pixels[i]), q); break; } case BlackPixelChannel: { SetPixelBlack(image,ClampToQuantum(QuantumRange*source_pixels[i]), q); break; } case AlphaPixelChannel: { SetPixelAlpha(image,ClampToQuantum(QuantumRange*source_pixels[i]), q); break; } } i++; q+=GetPixelChannels(image); } if (SyncCacheViewAuthenticPixels(image_view,exception) == MagickFalse) break; } image_view=DestroyCacheView(image_view); source_info=RelinquishVirtualMemory(source_info); return(MagickTrue); } static MagickBooleanType InverseFourierTransformChannel( const Image *magnitude_image,const Image *phase_image, const PixelChannel channel,const MagickBooleanType modulus, Image *fourier_image,ExceptionInfo *exception) { fftw_complex *inverse_pixels; FourierInfo fourier_info; MagickBooleanType status; MemoryInfo *inverse_info; fourier_info.width=magnitude_image->columns; fourier_info.height=magnitude_image->rows; if ((magnitude_image->columns != magnitude_image->rows) || ((magnitude_image->columns % 2) != 0) || ((magnitude_image->rows % 2) != 0)) { size_t extent=magnitude_image->columns < magnitude_image->rows ? magnitude_image->rows : magnitude_image->columns; fourier_info.width=(extent & 0x01) == 1 ? extent+1UL : extent; } fourier_info.height=fourier_info.width; fourier_info.center=(ssize_t) (fourier_info.width/2L)+1L; fourier_info.channel=channel; fourier_info.modulus=modulus; inverse_info=AcquireVirtualMemory((size_t) fourier_info.width, (fourier_info.height/2+1)*sizeof(*inverse_pixels)); if (inverse_info == (MemoryInfo *) NULL) { (void) ThrowMagickException(exception,GetMagickModule(), ResourceLimitError,"MemoryAllocationFailed","`%s'", magnitude_image->filename); return(MagickFalse); } inverse_pixels=(fftw_complex *) GetVirtualMemoryBlob(inverse_info); status=InverseFourier(&fourier_info,magnitude_image,phase_image, inverse_pixels,exception); if (status != MagickFalse) status=InverseFourierTransform(&fourier_info,inverse_pixels,fourier_image, exception); inverse_info=RelinquishVirtualMemory(inverse_info); return(status); } #endif MagickExport Image *InverseFourierTransformImage(const Image *magnitude_image, const Image *phase_image,const MagickBooleanType modulus, ExceptionInfo *exception) { Image *fourier_image; assert(magnitude_image != (Image *) NULL); assert(magnitude_image->signature == MagickCoreSignature); if (magnitude_image->debug != MagickFalse) (void) LogMagickEvent(TraceEvent,GetMagickModule(),"%s", magnitude_image->filename); if (phase_image == (Image *) NULL) { (void) ThrowMagickException(exception,GetMagickModule(),ImageError, "ImageSequenceRequired","`%s'",magnitude_image->filename); return((Image *) NULL); } #if !defined(MAGICKCORE_FFTW_DELEGATE) fourier_image=(Image *) NULL; (void) modulus; (void) ThrowMagickException(exception,GetMagickModule(), MissingDelegateWarning,"DelegateLibrarySupportNotBuiltIn","`%s' (FFTW)", magnitude_image->filename); #else { fourier_image=CloneImage(magnitude_image,magnitude_image->columns, magnitude_image->rows,MagickTrue,exception); if (fourier_image != (Image *) NULL) { MagickBooleanType is_gray, status; status=MagickTrue; is_gray=IsImageGray(magnitude_image); if (is_gray != MagickFalse) is_gray=IsImageGray(phase_image); #if defined(MAGICKCORE_OPENMP_SUPPORT) #pragma omp parallel sections #endif { #if defined(MAGICKCORE_OPENMP_SUPPORT) #pragma omp section #endif { MagickBooleanType thread_status; if (is_gray != MagickFalse) thread_status=InverseFourierTransformChannel(magnitude_image, phase_image,GrayPixelChannel,modulus,fourier_image,exception); else thread_status=InverseFourierTransformChannel(magnitude_image, phase_image,RedPixelChannel,modulus,fourier_image,exception); if (thread_status == MagickFalse) status=thread_status; } #if defined(MAGICKCORE_OPENMP_SUPPORT) #pragma omp section #endif { MagickBooleanType thread_status; thread_status=MagickTrue; if (is_gray == MagickFalse) thread_status=InverseFourierTransformChannel(magnitude_image, phase_image,GreenPixelChannel,modulus,fourier_image,exception); if (thread_status == MagickFalse) status=thread_status; } #if defined(MAGICKCORE_OPENMP_SUPPORT) #pragma omp section #endif { MagickBooleanType thread_status; thread_status=MagickTrue; if (is_gray == MagickFalse) thread_status=InverseFourierTransformChannel(magnitude_image, phase_image,BluePixelChannel,modulus,fourier_image,exception); if (thread_status == MagickFalse) status=thread_status; } #if defined(MAGICKCORE_OPENMP_SUPPORT) #pragma omp section #endif { MagickBooleanType thread_status; thread_status=MagickTrue; if (magnitude_image->colorspace == CMYKColorspace) thread_status=InverseFourierTransformChannel(magnitude_image, phase_image,BlackPixelChannel,modulus,fourier_image,exception); if (thread_status == MagickFalse) status=thread_status; } #if defined(MAGICKCORE_OPENMP_SUPPORT) #pragma omp section #endif { MagickBooleanType thread_status; thread_status=MagickTrue; if (magnitude_image->alpha_trait != UndefinedPixelTrait) thread_status=InverseFourierTransformChannel(magnitude_image, phase_image,AlphaPixelChannel,modulus,fourier_image,exception); if (thread_status == MagickFalse) status=thread_status; } } if (status == MagickFalse) fourier_image=DestroyImage(fourier_image); } fftw_cleanup(); } #endif return(fourier_image); }

GB_unop__acos_fc64_fc64.c

//------------------------------------------------------------------------------ // GB_unop: hard-coded functions for each built-in unary operator //------------------------------------------------------------------------------ // SuiteSparse:GraphBLAS, Timothy A. Davis, (c) 2017-2021, All Rights Reserved. // SPDX-License-Identifier: Apache-2.0 //------------------------------------------------------------------------------ // If this file is in the Generated/ folder, do not edit it (auto-generated). #include "GB.h" #ifndef GBCOMPACT #include "GB_control.h" #include "GB_atomics.h" #include "GB_unop__include.h" // C=unop(A) is defined by the following types and operators: // op(A) function: GB (_unop_apply__acos_fc64_fc64) // op(A') function: GB (_unop_tran__acos_fc64_fc64) // C type: GxB_FC64_t // A type: GxB_FC64_t // cast: GxB_FC64_t cij = aij // unaryop: cij = cacos (aij) #define GB_ATYPE \ GxB_FC64_t #define GB_CTYPE \ GxB_FC64_t // aij = Ax [pA] #define GB_GETA(aij,Ax,pA) \ GxB_FC64_t aij = Ax [pA] #define GB_CX(p) Cx [p] // unary operator #define GB_OP(z, x) \ z = cacos (x) ; // casting #define GB_CAST(z, aij) \ GxB_FC64_t z = aij ; // cij = op (aij) #define GB_CAST_OP(pC,pA) \ { \ /* aij = Ax [pA] */ \ GxB_FC64_t aij = Ax [pA] ; \ /* Cx [pC] = op (cast (aij)) */ \ GxB_FC64_t z = aij ; \ Cx [pC] = cacos (z) ; \ } // true if operator is the identity op with no typecasting #define GB_OP_IS_IDENTITY_WITH_NO_TYPECAST \ 0 // disable this operator and use the generic case if these conditions hold #define GB_DISABLE \ (GxB_NO_ACOS || GxB_NO_FC64) //------------------------------------------------------------------------------ // Cx = op (cast (Ax)): apply a unary operator //------------------------------------------------------------------------------ GrB_Info GB (_unop_apply__acos_fc64_fc64) ( GxB_FC64_t *Cx, // Cx and Ax may be aliased const GxB_FC64_t *Ax, const int8_t *restrict Ab, // A->b if A is bitmap int64_t anz, int nthreads ) { #if GB_DISABLE return (GrB_NO_VALUE) ; #else int64_t p ; // TODO: if OP is ONE and uniform-valued matrices are exploited, then // do this in O(1) time if (Ab == NULL) { #if ( GB_OP_IS_IDENTITY_WITH_NO_TYPECAST ) GB_memcpy (Cx, Ax, anz * sizeof (GxB_FC64_t), nthreads) ; #else #pragma omp parallel for num_threads(nthreads) schedule(static) for (p = 0 ; p < anz ; p++) { GxB_FC64_t aij = Ax [p] ; GxB_FC64_t z = aij ; Cx [p] = cacos (z) ; } #endif } else { // bitmap case, no transpose; A->b already memcpy'd into C->b #pragma omp parallel for num_threads(nthreads) schedule(static) for (p = 0 ; p < anz ; p++) { if (!Ab [p]) continue ; GxB_FC64_t aij = Ax [p] ; GxB_FC64_t z = aij ; Cx [p] = cacos (z) ; } } return (GrB_SUCCESS) ; #endif } //------------------------------------------------------------------------------ // C = op (cast (A')): transpose, typecast, and apply a unary operator //------------------------------------------------------------------------------ GrB_Info GB (_unop_tran__acos_fc64_fc64) ( GrB_Matrix C, const GrB_Matrix A, int64_t *restrict *Workspaces, const int64_t *restrict A_slice, int nworkspaces, int nthreads ) { #if GB_DISABLE return (GrB_NO_VALUE) ; #else #include "GB_unop_transpose.c" return (GrB_SUCCESS) ; #endif } #endif

critical.c

////////////////////////////////////////////////////////////// // // critical.c // // Copyright (c) 2017, Hassan Salehe Matar // All rights reserved. // // This file is part of Clanomp. For details, see // https://github.com/hassansalehe/Clanomp. Please also // see the LICENSE file for additional BSD notice // // Redistribution and use in source and binary forms, with // or without modification, are permitted provided that // the following conditions are met: // // * Redistributions of source code must retain the above // copyright notice, this list of conditions and the // following disclaimer. // // * Redistributions in binary form must reproduce the // above copyright notice, this list of conditions and // the following disclaimer in the documentation and/or // other materials provided with the distribution. // // * Neither the name of the copyright holder nor the names // of its contributors may be used to endorse or promote // products derived from this software without specific // prior written permission. // // THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND // CONTRIBUTORS "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, // INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF // MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE // DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT HOLDER OR // CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, // SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, // BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR // SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS // INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, // WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING // NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE // OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF // SUCH DAMAGE. // ////////////////////////////////////////////////////////////// // From the OpenMP specification: // The critical construct restricts execution of the // associated structured block to a single thread at a time. // // References: // 1. http://www.openmp.org/wp-content/uploads/openmp-examples-4.5.0.pdf // 2. http://www.openmp.org/wp-content/uploads/openmp-4.5.pdf #include <stdio.h> #include <omp.h> int main() { int count = 0; #pragma omp parallel shared(count) { #pragma omp critical { count++; } } printf("Value of count: %d, construct: <critical>\n", count); return 0; }

GB_binop__isge_uint8.c

//------------------------------------------------------------------------------ // GB_binop: hard-coded functions for each built-in binary operator //------------------------------------------------------------------------------ // SuiteSparse:GraphBLAS, Timothy A. Davis, (c) 2017-2020, All Rights Reserved. // http://suitesparse.com See GraphBLAS/Doc/License.txt for license. //------------------------------------------------------------------------------ // If this file is in the Generated/ folder, do not edit it (auto-generated). #include "GB.h" #ifndef GBCOMPACT #include "GB_control.h" #include "GB_ek_slice.h" #include "GB_dense.h" #include "GB_mkl.h" #include "GB_binop__include.h" // C=binop(A,B) is defined by the following types and operators: // A+B function (eWiseAdd): GB_AaddB__isge_uint8 // A.*B function (eWiseMult): GB_AemultB__isge_uint8 // A*D function (colscale): GB_AxD__isge_uint8 // D*A function (rowscale): GB_DxB__isge_uint8 // C+=B function (dense accum): GB_Cdense_accumB__isge_uint8 // C+=b function (dense accum): GB_Cdense_accumb__isge_uint8 // C+=A+B function (dense ewise3): (none) // C=A+B function (dense ewise3): GB_Cdense_ewise3_noaccum__isge_uint8 // C=scalar+B GB_bind1st__isge_uint8 // C=scalar+B' GB_bind1st_tran__isge_uint8 // C=A+scalar GB_bind2nd__isge_uint8 // C=A'+scalar GB_bind2nd_tran__isge_uint8 // C type: uint8_t // A type: uint8_t // B,b type: uint8_t // BinaryOp: cij = (aij >= bij) #define GB_ATYPE \ uint8_t #define GB_BTYPE \ uint8_t #define GB_CTYPE \ uint8_t // true if the types of A and B are identical #define GB_ATYPE_IS_BTYPE \ 1 // true if the types of C and A are identical #define GB_CTYPE_IS_ATYPE \ 1 // true if the types of C and B are identical #define GB_CTYPE_IS_BTYPE \ 1 // aij = Ax [pA] #define GB_GETA(aij,Ax,pA) \ uint8_t aij = Ax [pA] // bij = Bx [pB] #define GB_GETB(bij,Bx,pB) \ uint8_t bij = Bx [pB] // declare scalar of the same type as C #define GB_CTYPE_SCALAR(t) \ uint8_t t // cij = Ax [pA] #define GB_COPY_A_TO_C(cij,Ax,pA) \ cij = Ax [pA] // cij = Bx [pB] #define GB_COPY_B_TO_C(cij,Bx,pB) \ cij = Bx [pB] #define GB_CX(p) Cx [p] // binary operator #define GB_BINOP(z, x, y) \ z = (x >= y) ; // op is second #define GB_OP_IS_SECOND \ 0 // op is plus_fp32 or plus_fp64 #define GB_OP_IS_PLUS_REAL \ 0 // op is minus_fp32 or minus_fp64 #define GB_OP_IS_MINUS_REAL \ 0 // GB_cblas_*axpy gateway routine, if it exists for this operator and type: #define GB_CBLAS_AXPY \ (none) // do the numerical phases of GB_add and GB_emult #define GB_PHASE_2_OF_2 // hard-coded loops can be vectorized #define GB_PRAGMA_SIMD_VECTORIZE GB_PRAGMA_SIMD // disable this operator and use the generic case if these conditions hold #define GB_DISABLE \ (GxB_NO_ISGE || GxB_NO_UINT8 || GxB_NO_ISGE_UINT8) //------------------------------------------------------------------------------ // C += A+B, all 3 matrices dense //------------------------------------------------------------------------------ #if 0 // The op must be MIN, MAX, PLUS, MINUS, RMINUS, TIMES, DIV, or RDIV. void (none) ( GrB_Matrix C, const GrB_Matrix A, const GrB_Matrix B, const int nthreads ) { #include "GB_dense_ewise3_accum_template.c" } #endif //------------------------------------------------------------------------------ // C = A+B, all 3 matrices dense //------------------------------------------------------------------------------ GrB_Info GB_Cdense_ewise3_noaccum__isge_uint8 ( GrB_Matrix C, const GrB_Matrix A, const GrB_Matrix B, const int nthreads ) { #if GB_DISABLE return (GrB_NO_VALUE) ; #else #include "GB_dense_ewise3_noaccum_template.c" return (GrB_SUCCESS) ; #endif } //------------------------------------------------------------------------------ // C += B, accumulate a sparse matrix into a dense matrix //------------------------------------------------------------------------------ GrB_Info GB_Cdense_accumB__isge_uint8 ( GrB_Matrix C, const GrB_Matrix B, const int64_t *GB_RESTRICT kfirst_slice, const int64_t *GB_RESTRICT klast_slice, const int64_t *GB_RESTRICT pstart_slice, const int ntasks, const int nthreads ) { #if GB_DISABLE return (GrB_NO_VALUE) ; #else { #include "GB_dense_subassign_23_template.c" } return (GrB_SUCCESS) ; #endif } //------------------------------------------------------------------------------ // C += b, accumulate a scalar into a dense matrix //------------------------------------------------------------------------------ GrB_Info GB_Cdense_accumb__isge_uint8 ( GrB_Matrix C, const GB_void *p_bwork, const int nthreads ) { #if GB_DISABLE return (GrB_NO_VALUE) ; #else { // get the scalar b for C += b, of type uint8_t uint8_t bwork = (*((uint8_t *) p_bwork)) ; #include "GB_dense_subassign_22_template.c" return (GrB_SUCCESS) ; } return (GrB_SUCCESS) ; #endif } //------------------------------------------------------------------------------ // C = A*D, column scale with diagonal D matrix //------------------------------------------------------------------------------ GrB_Info GB_AxD__isge_uint8 ( GrB_Matrix C, const GrB_Matrix A, bool A_is_pattern, const GrB_Matrix D, bool D_is_pattern, const int64_t *GB_RESTRICT kfirst_slice, const int64_t *GB_RESTRICT klast_slice, const int64_t *GB_RESTRICT pstart_slice, const int ntasks, const int nthreads ) { #if GB_DISABLE return (GrB_NO_VALUE) ; #else uint8_t *GB_RESTRICT Cx = (uint8_t *) C->x ; #include "GB_AxB_colscale_meta.c" return (GrB_SUCCESS) ; #endif } //------------------------------------------------------------------------------ // C = D*B, row scale with diagonal D matrix //------------------------------------------------------------------------------ GrB_Info GB_DxB__isge_uint8 ( GrB_Matrix C, const GrB_Matrix D, bool D_is_pattern, const GrB_Matrix B, bool B_is_pattern, int nthreads ) { #if GB_DISABLE return (GrB_NO_VALUE) ; #else uint8_t *GB_RESTRICT Cx = (uint8_t *) C->x ; #include "GB_AxB_rowscale_meta.c" return (GrB_SUCCESS) ; #endif } //------------------------------------------------------------------------------ // eWiseAdd: C = A+B or C<M> = A+B //------------------------------------------------------------------------------ GrB_Info GB_AaddB__isge_uint8 ( GrB_Matrix C, const GrB_Matrix M, const bool Mask_struct, const GrB_Matrix A, const GrB_Matrix B, const bool Ch_is_Mh, const int64_t *GB_RESTRICT C_to_M, const int64_t *GB_RESTRICT C_to_A, const int64_t *GB_RESTRICT C_to_B, const GB_task_struct *GB_RESTRICT TaskList, const int ntasks, const int nthreads ) { #if GB_DISABLE return (GrB_NO_VALUE) ; #else #include "GB_add_template.c" return (GrB_SUCCESS) ; #endif } //------------------------------------------------------------------------------ // eWiseMult: C = A.*B or C<M> = A.*B //------------------------------------------------------------------------------ GrB_Info GB_AemultB__isge_uint8 ( GrB_Matrix C, const GrB_Matrix M, const bool Mask_struct, const GrB_Matrix A, const GrB_Matrix B, const int64_t *GB_RESTRICT C_to_M, const int64_t *GB_RESTRICT C_to_A, const int64_t *GB_RESTRICT C_to_B, const GB_task_struct *GB_RESTRICT TaskList, const int ntasks, const int nthreads ) { #if GB_DISABLE return (GrB_NO_VALUE) ; #else #include "GB_emult_template.c" return (GrB_SUCCESS) ; #endif } //------------------------------------------------------------------------------ // Cx = op (x,Bx): apply a binary operator to a matrix with scalar bind1st //------------------------------------------------------------------------------ GrB_Info GB_bind1st__isge_uint8 ( GB_void *Cx_output, // Cx and Bx may be aliased const GB_void *x_input, const GB_void *Bx_input, int64_t anz, int nthreads ) { #if GB_DISABLE return (GrB_NO_VALUE) ; #else uint8_t *Cx = (uint8_t *) Cx_output ; uint8_t x = (*((uint8_t *) x_input)) ; uint8_t *Bx = (uint8_t *) Bx_input ; int64_t p ; #pragma omp parallel for num_threads(nthreads) schedule(static) for (p = 0 ; p < anz ; p++) { uint8_t bij = Bx [p] ; Cx [p] = (x >= bij) ; } return (GrB_SUCCESS) ; #endif } //------------------------------------------------------------------------------ // Cx = op (Ax,y): apply a binary operator to a matrix with scalar bind2nd //------------------------------------------------------------------------------ GrB_Info GB_bind2nd__isge_uint8 ( GB_void *Cx_output, // Cx and Ax may be aliased const GB_void *Ax_input, const GB_void *y_input, int64_t anz, int nthreads ) { #if GB_DISABLE return (GrB_NO_VALUE) ; #else int64_t p ; uint8_t *Cx = (uint8_t *) Cx_output ; uint8_t *Ax = (uint8_t *) Ax_input ; uint8_t y = (*((uint8_t *) y_input)) ; #pragma omp parallel for num_threads(nthreads) schedule(static) for (p = 0 ; p < anz ; p++) { uint8_t aij = Ax [p] ; Cx [p] = (aij >= y) ; } return (GrB_SUCCESS) ; #endif } //------------------------------------------------------------------------------ // C = op (x, A'): transpose and apply a binary operator //------------------------------------------------------------------------------ // cij = op (x, aij), no typcasting (in spite of the macro name) #undef GB_CAST_OP #define GB_CAST_OP(pC,pA) \ { \ uint8_t aij = Ax [pA] ; \ Cx [pC] = (x >= aij) ; \ } GrB_Info GB_bind1st_tran__isge_uint8 ( GrB_Matrix C, const GB_void *x_input, const GrB_Matrix A, int64_t *GB_RESTRICT *Rowcounts, GBI_single_iterator Iter, const int64_t *GB_RESTRICT A_slice, int naslice ) { // GB_unop_transpose.c uses GB_ATYPE, but A is // the 2nd input to binary operator z=f(x,y). #undef GB_ATYPE #define GB_ATYPE \ uint8_t #if GB_DISABLE return (GrB_NO_VALUE) ; #else uint8_t x = (*((const uint8_t *) x_input)) ; #define GB_PHASE_2_OF_2 #include "GB_unop_transpose.c" return (GrB_SUCCESS) ; #endif #undef GB_ATYPE #define GB_ATYPE \ uint8_t } //------------------------------------------------------------------------------ // C = op (A', y): transpose and apply a binary operator //------------------------------------------------------------------------------ // cij = op (aij, y), no typcasting (in spite of the macro name) #undef GB_CAST_OP #define GB_CAST_OP(pC,pA) \ { \ uint8_t aij = Ax [pA] ; \ Cx [pC] = (aij >= y) ; \ } GrB_Info GB_bind2nd_tran__isge_uint8 ( GrB_Matrix C, const GrB_Matrix A, const GB_void *y_input, int64_t *GB_RESTRICT *Rowcounts, GBI_single_iterator Iter, const int64_t *GB_RESTRICT A_slice, int naslice ) { #if GB_DISABLE return (GrB_NO_VALUE) ; #else uint8_t y = (*((const uint8_t *) y_input)) ; #define GB_PHASE_2_OF_2 #include "GB_unop_transpose.c" return (GrB_SUCCESS) ; #endif } #endif

weird_another_fmt_plug.c

/* Hacked together during March, 2013 by Dhiru Kholia <dhiru.kholia at gmail.com>. * * This software is Copyright (c) 2013, Dhiru Kholia <dhiru.kholia at gmail.com>, * and it is hereby released to the general public under the following terms: * Redistribution and use in source and binary forms, with or without modification, * are permitted. * * Algorithm : md5(md5(t)+md5(e)+md5(s)+md5(t)) for "test" */ #if FMT_EXTERNS_H extern struct fmt_main weird_fmt; #elif FMT_REGISTERS_H john_register_one(&weird_fmt); #else #include <unistd.h> #ifdef _OPENMP static int omp_t = 1; #include <omp.h> #define OMP_SCALE 64 #endif #include <string.h> #include <assert.h> #include <errno.h> #include "arch.h" #include "md5.h" #include "misc.h" #include "common.h" #include "formats.h" #include "params.h" #include "options.h" #include "memdbg.h" #define FORMAT_LABEL "weird" #define FORMAT_NAME "weird md5(md5(t)+md5(e)+md5(s)+md5(t)) for \"test\"" #define ALGORITHM_NAME "32/" ARCH_BITS_STR #define BENCHMARK_COMMENT "" #define BENCHMARK_LENGTH -1 #define PLAINTEXT_LENGTH 25 #define BINARY_SIZE 16 #define SALT_SIZE 0 #define MIN_KEYS_PER_CRYPT 1 #define MAX_KEYS_PER_CRYPT 1 unsigned char map[256][33]; static struct fmt_tests weird_tests[] = { {"$weird$46d37e540dbfda624c38e3cc70bb5fa7", "password"}, {"$weird$be6d87f17a719b57518c61d40ce0b72d", "071883"}, {NULL} }; static inline void hex_encode(unsigned char *str, int len, unsigned char *out) { int i; for (i = 0; i < len; ++i) { out[0] = itoa16[str[i]>>4]; out[1] = itoa16[str[i]&0xF]; out += 2; } } static char (*saved_key)[PLAINTEXT_LENGTH + 1]; static ARCH_WORD_32 (*crypt_out)[BINARY_SIZE / sizeof(ARCH_WORD_32)]; static void init(struct fmt_main *self) { MD5_CTX ctx; int i; unsigned char c; unsigned char hash[16]; unsigned char out[33]; #ifdef _OPENMP omp_t = omp_get_max_threads(); self->params.min_keys_per_crypt *= omp_t; omp_t *= OMP_SCALE; self->params.max_keys_per_crypt *= omp_t; #endif saved_key = mem_calloc_tiny(sizeof(*saved_key) * self->params.max_keys_per_crypt, MEM_ALIGN_WORD); crypt_out = mem_calloc_tiny(sizeof(*crypt_out) * self->params.max_keys_per_crypt, MEM_ALIGN_WORD); for(i = 0; i < 256; i++) { c = i; MD5_Init(&ctx); MD5_Update(&ctx, &c, 1); MD5_Final(hash, &ctx); hex_encode(hash, 16, out); memcpy(map[i], out, 32); } } static int valid(char *ciphertext, struct fmt_main *self) { if (strncmp(ciphertext, "$weird$", 7) != 0) return 0; return 1; } static void *get_binary(char *ciphertext) { static union { unsigned char c[BINARY_SIZE]; ARCH_WORD dummy; } buf; unsigned char *out = buf.c; char *p; int i; p = strrchr(ciphertext, '$') + 1; for (i = 0; i < BINARY_SIZE; i++) { out[i] = (atoi16[ARCH_INDEX(*p)] << 4) | atoi16[ARCH_INDEX(p[1])]; p += 2; } return out; } static int binary_hash_0(void *binary) { return *(ARCH_WORD_32 *)binary & 0xf; } static int binary_hash_1(void *binary) { return *(ARCH_WORD_32 *)binary & 0xff; } static int binary_hash_2(void *binary) { return *(ARCH_WORD_32 *)binary & 0xfff; } static int binary_hash_3(void *binary) { return *(ARCH_WORD_32 *)binary & 0xffff; } static int binary_hash_4(void *binary) { return *(ARCH_WORD_32 *)binary & 0xfffff; } static int binary_hash_5(void *binary) { return *(ARCH_WORD_32 *)binary & 0xffffff; } static int binary_hash_6(void *binary) { return *(ARCH_WORD_32 *)binary & 0x7ffffff; } static int get_hash_0(int index) { return crypt_out[index][0] & 0xf; } static int get_hash_1(int index) { return crypt_out[index][0] & 0xff; } static int get_hash_2(int index) { return crypt_out[index][0] & 0xfff; } static int get_hash_3(int index) { return crypt_out[index][0] & 0xffff; } static int get_hash_4(int index) { return crypt_out[index][0] & 0xfffff; } static int get_hash_5(int index) { return crypt_out[index][0] & 0xffffff; } static int get_hash_6(int index) { return crypt_out[index][0] & 0x7ffffff; } static void crypt_all(int count) { int index = 0; #ifdef _OPENMP #pragma omp parallel for for (index = 0; index < count; index++) #endif { int i; MD5_CTX ctx; unsigned char hash[16]; unsigned char store[PLAINTEXT_LENGTH * 16 * 2] = { 0 }; unsigned char *p = store; int idx; for(i = 0; i < strlen(saved_key[index]); i++) { idx = saved_key[index][i]; memcpy(p, map[idx], 32); p += 32; } MD5_Init(&ctx); MD5_Update(&ctx, store, strlen(saved_key[index]) * 32); MD5_Final(hash, &ctx); memcpy(crypt_out[index], hash, 16); } } static int cmp_all(void *binary, int count) { int index = 0; #ifdef _OPENMP for (; index < count; index++) #endif if (!memcmp(binary, crypt_out[index], 15)) return 1; return 0; } static int cmp_one(void *binary, int index) { return !memcmp(binary, crypt_out[index], 15); } static int cmp_exact(char *source, int index) { return 1; } static void weird_set_key(char *key, int index) { int saved_key_length = strlen(key); if (saved_key_length > PLAINTEXT_LENGTH) saved_key_length = PLAINTEXT_LENGTH; memcpy(saved_key[index], key, saved_key_length); saved_key[index][saved_key_length] = 0; } static char *get_key(int index) { return saved_key[index]; } struct fmt_main weird_fmt = { { FORMAT_LABEL, FORMAT_NAME, ALGORITHM_NAME, BENCHMARK_COMMENT, BENCHMARK_LENGTH, PLAINTEXT_LENGTH, BINARY_SIZE, BINARY_ALIGN, SALT_SIZE, SALT_ALIGN, MIN_KEYS_PER_CRYPT, MAX_KEYS_PER_CRYPT, FMT_CASE | FMT_8_BIT | FMT_OMP, #if FMT_MAIN_VERSION > 11 { NULL }, #endif weird_tests }, { init, fmt_default_prepare, valid, fmt_default_split, get_binary, fmt_default_salt, #if FMT_MAIN_VERSION > 11 { NULL }, #endif fmt_default_source, { binary_hash_0, binary_hash_1, binary_hash_2, binary_hash_3, binary_hash_4, binary_hash_5, binary_hash_6 }, fmt_default_salt_hash, fmt_default_set_salt, weird_set_key, get_key, fmt_default_clear_keys, crypt_all, { get_hash_0, get_hash_1, get_hash_2, get_hash_3, get_hash_4, get_hash_5, get_hash_6 }, cmp_all, cmp_one, cmp_exact } }; #endif /* plugin stanza */

stencil.c

// RUN: ${CATO_ROOT}/src/scripts/cexecute_pass.py %s -o %t // RUN: diff <(mpirun -np 4 %t) %s.reference_output #include <stdlib.h> #include <stdio.h> #include <omp.h> #define DIM 10 int main() { float** Matrix = (float**)malloc(sizeof(float*) * DIM); float** Matrix2 = (float**)malloc(sizeof(float*) * DIM); for(int i = 0; i < DIM; i++) { Matrix[i] = (float*)malloc(sizeof(float) * DIM); Matrix2[i] = (float*)malloc(sizeof(float) * DIM); } for(int i = 0; i < DIM; i++) { Matrix[0][i] = 1.0; Matrix[DIM-1][i] = 1.0; Matrix[i][0] = 1.0; Matrix[i][DIM-1] = 1.0; Matrix2[0][i] = 1.0; Matrix2[DIM-1][i] = 1.0; Matrix2[i][0] = 1.0; Matrix2[i][DIM-1] = 1.0; } #pragma omp parallel for { for(int i = 1; i < DIM-1; i++) { for(int j = 1; j < DIM-1; j++) { float star = 4 * Matrix[i][j] - Matrix[i-1][j] - Matrix[i+1][j] - Matrix[i][j-1] - Matrix[i][j+1]; Matrix2[i][j] = star * star; } } } #pragma omp parallel { if(omp_get_thread_num() == 0) { for(int i = 0; i < DIM; i++) { for(int j = 0; j < DIM; j++) { printf("%.4f ", Matrix2[i][j]); } printf("\n"); } } } for(int i = 0; i < DIM; i++) { free(Matrix[i]); free(Matrix2[i]); } free(Matrix); free(Matrix2); return 0; }

orphan1.c

#include <stdio.h> #include <stdlib.h> #include <omp.h> #include "update.c" double val1,val2; int update(int n, int iter); int main(int argc, char **argv) { int n=10; int max, locmax; max = -999; int count = 0; #pragma omp parallel num_threads(4) default(none) shared(n, max,count) private(locmax) reduction(+: val2) for (int iter=0; iter<3; iter++) { count++; #pragma omp single { printf("---iteration %d---\n", iter); } #pragma omp barrier locmax = update(n, iter); #pragma omp critical { if (locmax > max) max=locmax; } #pragma omp barrier #pragma omp flush #pragma omp single printf("---iteration %d's max value = %d---\n", iter, max); } printf("%d", count); return 0; }

quantize.c

/* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % QQQ U U AAA N N TTTTT IIIII ZZZZZ EEEEE % % Q Q U U A A NN N T I ZZ E % % Q Q U U AAAAA N N N T I ZZZ EEEEE % % Q QQ U U A A N NN T I ZZ E % % QQQQ UUU A A N N T IIIII ZZZZZ EEEEE % % % % % % MagickCore Methods to Reduce the Number of Unique Colors in an Image % % % % Software Design % % Cristy % % July 1992 % % % % % % Copyright 1999-2021 ImageMagick Studio LLC, a non-profit organization % % dedicated to making software imaging solutions freely available. % % % % You may not use this file except in compliance with the License. You may % % obtain a copy of the License at % % % % https://imagemagick.org/script/license.php % % % % Unless required by applicable law or agreed to in writing, software % % distributed under the License is distributed on an "AS IS" BASIS, % % WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. % % See the License for the specific language governing permissions and % % limitations under the License. % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % Realism in computer graphics typically requires using 24 bits/pixel to % generate an image. Yet many graphic display devices do not contain the % amount of memory necessary to match the spatial and color resolution of % the human eye. The Quantize methods takes a 24 bit image and reduces % the number of colors so it can be displayed on raster device with less % bits per pixel. In most instances, the quantized image closely % resembles the original reference image. % % A reduction of colors in an image is also desirable for image % transmission and real-time animation. % % QuantizeImage() takes a standard RGB or monochrome images and quantizes % them down to some fixed number of colors. % % For purposes of color allocation, an image is a set of n pixels, where % each pixel is a point in RGB space. RGB space is a 3-dimensional % vector space, and each pixel, Pi, is defined by an ordered triple of % red, green, and blue coordinates, (Ri, Gi, Bi). % % Each primary color component (red, green, or blue) represents an % intensity which varies linearly from 0 to a maximum value, Cmax, which % corresponds to full saturation of that color. Color allocation is % defined over a domain consisting of the cube in RGB space with opposite % vertices at (0,0,0) and (Cmax, Cmax, Cmax). QUANTIZE requires Cmax = % 255. % % The algorithm maps this domain onto a tree in which each node % represents a cube within that domain. In the following discussion % these cubes are defined by the coordinate of two opposite vertices (vertex % nearest the origin in RGB space and the vertex farthest from the origin). % % The tree's root node represents the entire domain, (0,0,0) through % (Cmax,Cmax,Cmax). Each lower level in the tree is generated by % subdividing one node's cube into eight smaller cubes of equal size. % This corresponds to bisecting the parent cube with planes passing % through the midpoints of each edge. % % The basic algorithm operates in three phases: Classification, % Reduction, and Assignment. Classification builds a color description % tree for the image. Reduction collapses the tree until the number it % represents, at most, the number of colors desired in the output image. % Assignment defines the output image's color map and sets each pixel's % color by restorage_class in the reduced tree. Our goal is to minimize % the numerical discrepancies between the original colors and quantized % colors (quantization error). % % Classification begins by initializing a color description tree of % sufficient depth to represent each possible input color in a leaf. % However, it is impractical to generate a fully-formed color description % tree in the storage_class phase for realistic values of Cmax. If % colors components in the input image are quantized to k-bit precision, % so that Cmax= 2k-1, the tree would need k levels below the root node to % allow representing each possible input color in a leaf. This becomes % prohibitive because the tree's total number of nodes is 1 + % sum(i=1, k, 8k). % % A complete tree would require 19,173,961 nodes for k = 8, Cmax = 255. % Therefore, to avoid building a fully populated tree, QUANTIZE: (1) % Initializes data structures for nodes only as they are needed; (2) % Chooses a maximum depth for the tree as a function of the desired % number of colors in the output image (currently log2(colormap size)). % % For each pixel in the input image, storage_class scans downward from % the root of the color description tree. At each level of the tree it % identifies the single node which represents a cube in RGB space % containing the pixel's color. It updates the following data for each % such node: % % n1: Number of pixels whose color is contained in the RGB cube which % this node represents; % % n2: Number of pixels whose color is not represented in a node at % lower depth in the tree; initially, n2 = 0 for all nodes except % leaves of the tree. % % Sr, Sg, Sb: Sums of the red, green, and blue component values for all % pixels not classified at a lower depth. The combination of these sums % and n2 will ultimately characterize the mean color of a set of pixels % represented by this node. % % E: the distance squared in RGB space between each pixel contained % within a node and the nodes' center. This represents the % quantization error for a node. % % Reduction repeatedly prunes the tree until the number of nodes with n2 % > 0 is less than or equal to the maximum number of colors allowed in % the output image. On any given iteration over the tree, it selects % those nodes whose E count is minimal for pruning and merges their color % statistics upward. It uses a pruning threshold, Ep, to govern node % selection as follows: % % Ep = 0 % while number of nodes with (n2 > 0) > required maximum number of colors % prune all nodes such that E <= Ep % Set Ep to minimum E in remaining nodes % % This has the effect of minimizing any quantization error when merging % two nodes together. % % When a node to be pruned has offspring, the pruning procedure invokes % itself recursively in order to prune the tree from the leaves upward. % n2, Sr, Sg, and Sb in a node being pruned are always added to the % corresponding data in that node's parent. This retains the pruned % node's color characteristics for later averaging. % % For each node, n2 pixels exist for which that node represents the % smallest volume in RGB space containing those pixel's colors. When n2 % > 0 the node will uniquely define a color in the output image. At the % beginning of reduction, n2 = 0 for all nodes except a the leaves of % the tree which represent colors present in the input image. % % The other pixel count, n1, indicates the total number of colors within % the cubic volume which the node represents. This includes n1 - n2 % pixels whose colors should be defined by nodes at a lower level in the % tree. % % Assignment generates the output image from the pruned tree. The output % image consists of two parts: (1) A color map, which is an array of % color descriptions (RGB triples) for each color present in the output % image; (2) A pixel array, which represents each pixel as an index % into the color map array. % % First, the assignment phase makes one pass over the pruned color % description tree to establish the image's color map. For each node % with n2 > 0, it divides Sr, Sg, and Sb by n2 . This produces the mean % color of all pixels that classify no lower than this node. Each of % these colors becomes an entry in the color map. % % Finally, the assignment phase reclassifies each pixel in the pruned % tree to identify the deepest node containing the pixel's color. The % pixel's value in the pixel array becomes the index of this node's mean % color in the color map. % % This method is based on a similar algorithm written by Paul Raveling. % */ /* Include declarations. */ #include "MagickCore/studio.h" #include "MagickCore/artifact.h" #include "MagickCore/attribute.h" #include "MagickCore/cache-view.h" #include "MagickCore/color.h" #include "MagickCore/color-private.h" #include "MagickCore/colormap.h" #include "MagickCore/colorspace.h" #include "MagickCore/colorspace-private.h" #include "MagickCore/compare.h" #include "MagickCore/enhance.h" #include "MagickCore/exception.h" #include "MagickCore/exception-private.h" #include "MagickCore/histogram.h" #include "MagickCore/image.h" #include "MagickCore/image-private.h" #include "MagickCore/list.h" #include "MagickCore/memory_.h" #include "MagickCore/memory-private.h" #include "MagickCore/monitor.h" #include "MagickCore/monitor-private.h" #include "MagickCore/option.h" #include "MagickCore/pixel-accessor.h" #include "MagickCore/pixel-private.h" #include "MagickCore/quantize.h" #include "MagickCore/quantum.h" #include "MagickCore/quantum-private.h" #include "MagickCore/random_.h" #include "MagickCore/resource_.h" #include "MagickCore/string_.h" #include "MagickCore/string-private.h" #include "MagickCore/thread-private.h" /* Define declarations. */ #if !defined(__APPLE__) && !defined(TARGET_OS_IPHONE) #define CacheShift 2 #else #define CacheShift 3 #endif #define ErrorQueueLength 16 #define ErrorRelativeWeight PerceptibleReciprocal(16) #define MaxNodes 266817 #define MaxTreeDepth 8 #define NodesInAList 1920 /* Typdef declarations. */ typedef struct _DoublePixelPacket { double red, green, blue, alpha; } DoublePixelPacket; typedef struct _NodeInfo { struct _NodeInfo *parent, *child[16]; MagickSizeType number_unique; DoublePixelPacket total_color; double quantize_error; size_t color_number, id, level; } NodeInfo; typedef struct _Nodes { NodeInfo *nodes; struct _Nodes *next; } Nodes; typedef struct _CubeInfo { NodeInfo *root; size_t colors, maximum_colors; ssize_t transparent_index; MagickSizeType transparent_pixels; DoublePixelPacket target; double distance, pruning_threshold, next_threshold; size_t nodes, free_nodes, color_number; NodeInfo *next_node; Nodes *node_queue; MemoryInfo *memory_info; ssize_t *cache; DoublePixelPacket error[ErrorQueueLength]; double diffusion, weights[ErrorQueueLength]; QuantizeInfo *quantize_info; MagickBooleanType associate_alpha; ssize_t x, y; size_t depth; MagickOffsetType offset; MagickSizeType span; } CubeInfo; /* Method prototypes. */ static CubeInfo *GetCubeInfo(const QuantizeInfo *,const size_t,const size_t); static NodeInfo *GetNodeInfo(CubeInfo *,const size_t,const size_t,NodeInfo *); static MagickBooleanType AssignImageColors(Image *,CubeInfo *,ExceptionInfo *), ClassifyImageColors(CubeInfo *,const Image *,ExceptionInfo *), DitherImage(Image *,CubeInfo *,ExceptionInfo *), SetGrayscaleImage(Image *,ExceptionInfo *), SetImageColormap(Image *,CubeInfo *,ExceptionInfo *); static void ClosestColor(const Image *,CubeInfo *,const NodeInfo *), DefineImageColormap(Image *,CubeInfo *,NodeInfo *), DestroyCubeInfo(CubeInfo *), PruneLevel(CubeInfo *,const NodeInfo *), PruneToCubeDepth(CubeInfo *,const NodeInfo *), ReduceImageColors(const Image *,CubeInfo *); /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % A c q u i r e Q u a n t i z e I n f o % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % AcquireQuantizeInfo() allocates the QuantizeInfo structure. % % The format of the AcquireQuantizeInfo method is: % % QuantizeInfo *AcquireQuantizeInfo(const ImageInfo *image_info) % % A description of each parameter follows: % % o image_info: the image info. % */ MagickExport QuantizeInfo *AcquireQuantizeInfo(const ImageInfo *image_info) { QuantizeInfo *quantize_info; quantize_info=(QuantizeInfo *) AcquireCriticalMemory(sizeof(*quantize_info)); GetQuantizeInfo(quantize_info); if (image_info != (ImageInfo *) NULL) { const char *option; quantize_info->dither_method=image_info->dither == MagickFalse ? NoDitherMethod : RiemersmaDitherMethod; option=GetImageOption(image_info,"dither"); if (option != (const char *) NULL) quantize_info->dither_method=(DitherMethod) ParseCommandOption( MagickDitherOptions,MagickFalse,option); quantize_info->measure_error=image_info->verbose; } return(quantize_info); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % + A s s i g n I m a g e C o l o r s % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % AssignImageColors() generates the output image from the pruned tree. The % output image consists of two parts: (1) A color map, which is an array % of color descriptions (RGB triples) for each color present in the % output image; (2) A pixel array, which represents each pixel as an % index into the color map array. % % First, the assignment phase makes one pass over the pruned color % description tree to establish the image's color map. For each node % with n2 > 0, it divides Sr, Sg, and Sb by n2 . This produces the mean % color of all pixels that classify no lower than this node. Each of % these colors becomes an entry in the color map. % % Finally, the assignment phase reclassifies each pixel in the pruned % tree to identify the deepest node containing the pixel's color. The % pixel's value in the pixel array becomes the index of this node's mean % color in the color map. % % The format of the AssignImageColors() method is: % % MagickBooleanType AssignImageColors(Image *image,CubeInfo *cube_info) % % A description of each parameter follows. % % o image: the image. % % o cube_info: A pointer to the Cube structure. % */ static inline void AssociateAlphaPixel(const Image *image, const CubeInfo *cube_info,const Quantum *pixel,DoublePixelPacket *alpha_pixel) { double alpha; if ((cube_info->associate_alpha == MagickFalse) || (GetPixelAlpha(image,pixel) == OpaqueAlpha)) { alpha_pixel->red=(double) GetPixelRed(image,pixel); alpha_pixel->green=(double) GetPixelGreen(image,pixel); alpha_pixel->blue=(double) GetPixelBlue(image,pixel); alpha_pixel->alpha=(double) GetPixelAlpha(image,pixel); return; } alpha=(double) (QuantumScale*GetPixelAlpha(image,pixel)); alpha_pixel->red=alpha*GetPixelRed(image,pixel); alpha_pixel->green=alpha*GetPixelGreen(image,pixel); alpha_pixel->blue=alpha*GetPixelBlue(image,pixel); alpha_pixel->alpha=(double) GetPixelAlpha(image,pixel); } static inline void AssociateAlphaPixelInfo(const CubeInfo *cube_info, const PixelInfo *pixel,DoublePixelPacket *alpha_pixel) { double alpha; if ((cube_info->associate_alpha == MagickFalse) || (pixel->alpha == OpaqueAlpha)) { alpha_pixel->red=(double) pixel->red; alpha_pixel->green=(double) pixel->green; alpha_pixel->blue=(double) pixel->blue; alpha_pixel->alpha=(double) pixel->alpha; return; } alpha=(double) (QuantumScale*pixel->alpha); alpha_pixel->red=alpha*pixel->red; alpha_pixel->green=alpha*pixel->green; alpha_pixel->blue=alpha*pixel->blue; alpha_pixel->alpha=(double) pixel->alpha; } static inline size_t ColorToNodeId(const CubeInfo *cube_info, const DoublePixelPacket *pixel,size_t index) { size_t id; id=(size_t) (((ScaleQuantumToChar(ClampPixel(pixel->red)) >> index) & 0x01) | ((ScaleQuantumToChar(ClampPixel(pixel->green)) >> index) & 0x01) << 1 | ((ScaleQuantumToChar(ClampPixel(pixel->blue)) >> index) & 0x01) << 2); if (cube_info->associate_alpha != MagickFalse) id|=((ScaleQuantumToChar(ClampPixel(pixel->alpha)) >> index) & 0x1) << 3; return(id); } static MagickBooleanType AssignImageColors(Image *image,CubeInfo *cube_info, ExceptionInfo *exception) { #define AssignImageTag "Assign/Image" ColorspaceType colorspace; ssize_t y; /* Allocate image colormap. */ colorspace=image->colorspace; if (cube_info->quantize_info->colorspace != UndefinedColorspace) (void) TransformImageColorspace(image,cube_info->quantize_info->colorspace, exception); cube_info->transparent_pixels=0; cube_info->transparent_index=(-1); if (SetImageColormap(image,cube_info,exception) == MagickFalse) return(MagickFalse); /* Create a reduced color image. */ if (cube_info->quantize_info->dither_method != NoDitherMethod) (void) DitherImage(image,cube_info,exception); else { CacheView *image_view; MagickBooleanType status; status=MagickTrue; image_view=AcquireAuthenticCacheView(image,exception); #if defined(MAGICKCORE_OPENMP_SUPPORT) #pragma omp parallel for schedule(static) shared(status) \ magick_number_threads(image,image,image->rows,1) #endif for (y=0; y < (ssize_t) image->rows; y++) { CubeInfo cube; Quantum *magick_restrict q; ssize_t count, x; if (status == MagickFalse) continue; q=GetCacheViewAuthenticPixels(image_view,0,y,image->columns,1, exception); if (q == (Quantum *) NULL) { status=MagickFalse; continue; } cube=(*cube_info); for (x=0; x < (ssize_t) image->columns; x+=count) { DoublePixelPacket pixel; const NodeInfo *node_info; ssize_t i; size_t id, index; /* Identify the deepest node containing the pixel's color. */ for (count=1; (x+count) < (ssize_t) image->columns; count++) { PixelInfo packet; GetPixelInfoPixel(image,q+count*GetPixelChannels(image),&packet); if (IsPixelEquivalent(image,q,&packet) == MagickFalse) break; } AssociateAlphaPixel(image,&cube,q,&pixel); node_info=cube.root; for (index=MaxTreeDepth-1; (ssize_t) index > 0; index--) { id=ColorToNodeId(&cube,&pixel,index); if (node_info->child[id] == (NodeInfo *) NULL) break; node_info=node_info->child[id]; } /* Find closest color among siblings and their children. */ cube.target=pixel; cube.distance=(double) (4.0*(QuantumRange+1.0)*(QuantumRange+1.0)+ 1.0); ClosestColor(image,&cube,node_info->parent); index=cube.color_number; for (i=0; i < (ssize_t) count; i++) { if (image->storage_class == PseudoClass) SetPixelIndex(image,(Quantum) index,q); if (cube.quantize_info->measure_error == MagickFalse) { SetPixelRed(image,ClampToQuantum( image->colormap[index].red),q); SetPixelGreen(image,ClampToQuantum( image->colormap[index].green),q); SetPixelBlue(image,ClampToQuantum( image->colormap[index].blue),q); if (cube.associate_alpha != MagickFalse) SetPixelAlpha(image,ClampToQuantum( image->colormap[index].alpha),q); } q+=GetPixelChannels(image); } } if (SyncCacheViewAuthenticPixels(image_view,exception) == MagickFalse) status=MagickFalse; if (image->progress_monitor != (MagickProgressMonitor) NULL) { MagickBooleanType proceed; proceed=SetImageProgress(image,AssignImageTag,(MagickOffsetType) y, image->rows); if (proceed == MagickFalse) status=MagickFalse; } } image_view=DestroyCacheView(image_view); } if (cube_info->quantize_info->measure_error != MagickFalse) (void) GetImageQuantizeError(image,exception); if ((cube_info->quantize_info->number_colors == 2) && (IsGrayColorspace(cube_info->quantize_info->colorspace))) { double intensity; /* Monochrome image. */ intensity=GetPixelInfoLuma(image->colormap+0) < QuantumRange/2.0 ? 0.0 : QuantumRange; if (image->colors > 1) { intensity=0.0; if (GetPixelInfoLuma(image->colormap+0) > GetPixelInfoLuma(image->colormap+1)) intensity=(double) QuantumRange; } image->colormap[0].red=intensity; image->colormap[0].green=intensity; image->colormap[0].blue=intensity; if (image->colors > 1) { image->colormap[1].red=(double) QuantumRange-intensity; image->colormap[1].green=(double) QuantumRange-intensity; image->colormap[1].blue=(double) QuantumRange-intensity; } } (void) SyncImage(image,exception); if ((cube_info->quantize_info->colorspace != UndefinedColorspace) && (IssRGBCompatibleColorspace(colorspace) == MagickFalse)) (void) TransformImageColorspace(image,colorspace,exception); return(MagickTrue); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % + C l a s s i f y I m a g e C o l o r s % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % ClassifyImageColors() begins by initializing a color description tree % of sufficient depth to represent each possible input color in a leaf. % However, it is impractical to generate a fully-formed color % description tree in the storage_class phase for realistic values of % Cmax. If colors components in the input image are quantized to k-bit % precision, so that Cmax= 2k-1, the tree would need k levels below the % root node to allow representing each possible input color in a leaf. % This becomes prohibitive because the tree's total number of nodes is % 1 + sum(i=1,k,8k). % % A complete tree would require 19,173,961 nodes for k = 8, Cmax = 255. % Therefore, to avoid building a fully populated tree, QUANTIZE: (1) % Initializes data structures for nodes only as they are needed; (2) % Chooses a maximum depth for the tree as a function of the desired % number of colors in the output image (currently log2(colormap size)). % % For each pixel in the input image, storage_class scans downward from % the root of the color description tree. At each level of the tree it % identifies the single node which represents a cube in RGB space % containing It updates the following data for each such node: % % n1 : Number of pixels whose color is contained in the RGB cube % which this node represents; % % n2 : Number of pixels whose color is not represented in a node at % lower depth in the tree; initially, n2 = 0 for all nodes except % leaves of the tree. % % Sr, Sg, Sb : Sums of the red, green, and blue component values for % all pixels not classified at a lower depth. The combination of % these sums and n2 will ultimately characterize the mean color of a % set of pixels represented by this node. % % E: the distance squared in RGB space between each pixel contained % within a node and the nodes' center. This represents the quantization % error for a node. % % The format of the ClassifyImageColors() method is: % % MagickBooleanType ClassifyImageColors(CubeInfo *cube_info, % const Image *image,ExceptionInfo *exception) % % A description of each parameter follows. % % o cube_info: A pointer to the Cube structure. % % o image: the image. % */ static inline void SetAssociatedAlpha(const Image *image,CubeInfo *cube_info) { MagickBooleanType associate_alpha; associate_alpha=image->alpha_trait != UndefinedPixelTrait ? MagickTrue : MagickFalse; if ((cube_info->quantize_info->number_colors == 2) && ((cube_info->quantize_info->colorspace == LinearGRAYColorspace) || (cube_info->quantize_info->colorspace == GRAYColorspace))) associate_alpha=MagickFalse; cube_info->associate_alpha=associate_alpha; } static MagickBooleanType ClassifyImageColors(CubeInfo *cube_info, const Image *image,ExceptionInfo *exception) { #define ClassifyImageTag "Classify/Image" CacheView *image_view; double bisect; DoublePixelPacket error, mid, midpoint, pixel; MagickBooleanType proceed; NodeInfo *node_info; size_t count, id, index, level; ssize_t y; /* Classify the first cube_info->maximum_colors colors to a tree depth of 8. */ SetAssociatedAlpha(image,cube_info); if (cube_info->quantize_info->colorspace != image->colorspace) { if ((cube_info->quantize_info->colorspace != UndefinedColorspace) && (cube_info->quantize_info->colorspace != CMYKColorspace)) (void) TransformImageColorspace((Image *) image, cube_info->quantize_info->colorspace,exception); else if (IssRGBCompatibleColorspace(image->colorspace) == MagickFalse) (void) TransformImageColorspace((Image *) image,sRGBColorspace, exception); } midpoint.red=(double) QuantumRange/2.0; midpoint.green=(double) QuantumRange/2.0; midpoint.blue=(double) QuantumRange/2.0; midpoint.alpha=(double) QuantumRange/2.0; error.alpha=0.0; image_view=AcquireVirtualCacheView(image,exception); for (y=0; y < (ssize_t) image->rows; y++) { const Quantum *magick_restrict p; ssize_t x; p=GetCacheViewVirtualPixels(image_view,0,y,image->columns,1,exception); if (p == (const Quantum *) NULL) break; if (cube_info->nodes > MaxNodes) { /* Prune one level if the color tree is too large. */ PruneLevel(cube_info,cube_info->root); cube_info->depth--; } for (x=0; x < (ssize_t) image->columns; x+=(ssize_t) count) { /* Start at the root and descend the color cube tree. */ for (count=1; (x+(ssize_t) count) < (ssize_t) image->columns; count++) { PixelInfo packet; GetPixelInfoPixel(image,p+count*GetPixelChannels(image),&packet); if (IsPixelEquivalent(image,p,&packet) == MagickFalse) break; } AssociateAlphaPixel(image,cube_info,p,&pixel); index=MaxTreeDepth-1; bisect=((double) QuantumRange+1.0)/2.0; mid=midpoint; node_info=cube_info->root; for (level=1; level <= MaxTreeDepth; level++) { double distance; bisect*=0.5; id=ColorToNodeId(cube_info,&pixel,index); mid.red+=(id & 1) != 0 ? bisect : -bisect; mid.green+=(id & 2) != 0 ? bisect : -bisect; mid.blue+=(id & 4) != 0 ? bisect : -bisect; mid.alpha+=(id & 8) != 0 ? bisect : -bisect; if (node_info->child[id] == (NodeInfo *) NULL) { /* Set colors of new node to contain pixel. */ node_info->child[id]=GetNodeInfo(cube_info,id,level,node_info); if (node_info->child[id] == (NodeInfo *) NULL) { (void) ThrowMagickException(exception,GetMagickModule(), ResourceLimitError,"MemoryAllocationFailed","`%s'", image->filename); continue; } if (level == MaxTreeDepth) cube_info->colors++; } /* Approximate the quantization error represented by this node. */ node_info=node_info->child[id]; error.red=QuantumScale*(pixel.red-mid.red); error.green=QuantumScale*(pixel.green-mid.green); error.blue=QuantumScale*(pixel.blue-mid.blue); if (cube_info->associate_alpha != MagickFalse) error.alpha=QuantumScale*(pixel.alpha-mid.alpha); distance=(double) (error.red*error.red+error.green*error.green+ error.blue*error.blue+error.alpha*error.alpha); if (IsNaN(distance) != 0) distance=0.0; node_info->quantize_error+=count*sqrt(distance); cube_info->root->quantize_error+=node_info->quantize_error; index--; } /* Sum RGB for this leaf for later derivation of the mean cube color. */ node_info->number_unique+=count; node_info->total_color.red+=count*QuantumScale*ClampPixel(pixel.red); node_info->total_color.green+=count*QuantumScale*ClampPixel(pixel.green); node_info->total_color.blue+=count*QuantumScale*ClampPixel(pixel.blue); if (cube_info->associate_alpha != MagickFalse) node_info->total_color.alpha+=count*QuantumScale* ClampPixel(pixel.alpha); else node_info->total_color.alpha+=count*QuantumScale* ClampPixel((MagickRealType) OpaqueAlpha); p+=count*GetPixelChannels(image); } if (cube_info->colors > cube_info->maximum_colors) { PruneToCubeDepth(cube_info,cube_info->root); break; } proceed=SetImageProgress(image,ClassifyImageTag,(MagickOffsetType) y, image->rows); if (proceed == MagickFalse) break; } for (y++; y < (ssize_t) image->rows; y++) { const Quantum *magick_restrict p; ssize_t x; p=GetCacheViewVirtualPixels(image_view,0,y,image->columns,1,exception); if (p == (const Quantum *) NULL) break; if (cube_info->nodes > MaxNodes) { /* Prune one level if the color tree is too large. */ PruneLevel(cube_info,cube_info->root); cube_info->depth--; } for (x=0; x < (ssize_t) image->columns; x+=(ssize_t) count) { /* Start at the root and descend the color cube tree. */ for (count=1; (x+(ssize_t) count) < (ssize_t) image->columns; count++) { PixelInfo packet; GetPixelInfoPixel(image,p+count*GetPixelChannels(image),&packet); if (IsPixelEquivalent(image,p,&packet) == MagickFalse) break; } AssociateAlphaPixel(image,cube_info,p,&pixel); index=MaxTreeDepth-1; bisect=((double) QuantumRange+1.0)/2.0; mid=midpoint; node_info=cube_info->root; for (level=1; level <= cube_info->depth; level++) { double distance; bisect*=0.5; id=ColorToNodeId(cube_info,&pixel,index); mid.red+=(id & 1) != 0 ? bisect : -bisect; mid.green+=(id & 2) != 0 ? bisect : -bisect; mid.blue+=(id & 4) != 0 ? bisect : -bisect; mid.alpha+=(id & 8) != 0 ? bisect : -bisect; if (node_info->child[id] == (NodeInfo *) NULL) { /* Set colors of new node to contain pixel. */ node_info->child[id]=GetNodeInfo(cube_info,id,level,node_info); if (node_info->child[id] == (NodeInfo *) NULL) { (void) ThrowMagickException(exception,GetMagickModule(), ResourceLimitError,"MemoryAllocationFailed","%s", image->filename); continue; } if (level == cube_info->depth) cube_info->colors++; } /* Approximate the quantization error represented by this node. */ node_info=node_info->child[id]; error.red=QuantumScale*(pixel.red-mid.red); error.green=QuantumScale*(pixel.green-mid.green); error.blue=QuantumScale*(pixel.blue-mid.blue); if (cube_info->associate_alpha != MagickFalse) error.alpha=QuantumScale*(pixel.alpha-mid.alpha); distance=(double) (error.red*error.red+error.green*error.green+ error.blue*error.blue+error.alpha*error.alpha); if (IsNaN(distance) != 0) distance=0.0; node_info->quantize_error+=count*sqrt(distance); cube_info->root->quantize_error+=node_info->quantize_error; index--; } /* Sum RGB for this leaf for later derivation of the mean cube color. */ node_info->number_unique+=count; node_info->total_color.red+=count*QuantumScale*ClampPixel(pixel.red); node_info->total_color.green+=count*QuantumScale*ClampPixel(pixel.green); node_info->total_color.blue+=count*QuantumScale*ClampPixel(pixel.blue); if (cube_info->associate_alpha != MagickFalse) node_info->total_color.alpha+=count*QuantumScale* ClampPixel(pixel.alpha); else node_info->total_color.alpha+=count*QuantumScale* ClampPixel((MagickRealType) OpaqueAlpha); p+=count*GetPixelChannels(image); } proceed=SetImageProgress(image,ClassifyImageTag,(MagickOffsetType) y, image->rows); if (proceed == MagickFalse) break; } image_view=DestroyCacheView(image_view); if (cube_info->quantize_info->colorspace != image->colorspace) if ((cube_info->quantize_info->colorspace != UndefinedColorspace) && (cube_info->quantize_info->colorspace != CMYKColorspace)) (void) TransformImageColorspace((Image *) image,sRGBColorspace,exception); return(y < (ssize_t) image->rows ? MagickFalse : MagickTrue); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % C l o n e Q u a n t i z e I n f o % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % CloneQuantizeInfo() makes a duplicate of the given quantize info structure, % or if quantize info is NULL, a new one. % % The format of the CloneQuantizeInfo method is: % % QuantizeInfo *CloneQuantizeInfo(const QuantizeInfo *quantize_info) % % A description of each parameter follows: % % o clone_info: Method CloneQuantizeInfo returns a duplicate of the given % quantize info, or if image info is NULL a new one. % % o quantize_info: a structure of type info. % */ MagickExport QuantizeInfo *CloneQuantizeInfo(const QuantizeInfo *quantize_info) { QuantizeInfo *clone_info; clone_info=(QuantizeInfo *) AcquireCriticalMemory(sizeof(*clone_info)); GetQuantizeInfo(clone_info); if (quantize_info == (QuantizeInfo *) NULL) return(clone_info); clone_info->number_colors=quantize_info->number_colors; clone_info->tree_depth=quantize_info->tree_depth; clone_info->dither_method=quantize_info->dither_method; clone_info->colorspace=quantize_info->colorspace; clone_info->measure_error=quantize_info->measure_error; return(clone_info); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % + C l o s e s t C o l o r % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % ClosestColor() traverses the color cube tree at a particular node and % determines which colormap entry best represents the input color. % % The format of the ClosestColor method is: % % void ClosestColor(const Image *image,CubeInfo *cube_info, % const NodeInfo *node_info) % % A description of each parameter follows. % % o image: the image. % % o cube_info: A pointer to the Cube structure. % % o node_info: the address of a structure of type NodeInfo which points to a % node in the color cube tree that is to be pruned. % */ static void ClosestColor(const Image *image,CubeInfo *cube_info, const NodeInfo *node_info) { size_t number_children; ssize_t i; /* Traverse any children. */ number_children=cube_info->associate_alpha == MagickFalse ? 8UL : 16UL; for (i=0; i < (ssize_t) number_children; i++) if (node_info->child[i] != (NodeInfo *) NULL) ClosestColor(image,cube_info,node_info->child[i]); if (node_info->number_unique != 0) { double alpha, beta, distance, pixel; DoublePixelPacket *magick_restrict q; PixelInfo *magick_restrict p; /* Determine if this color is "closest". */ p=image->colormap+node_info->color_number; q=(&cube_info->target); alpha=1.0; beta=1.0; if (cube_info->associate_alpha != MagickFalse) { alpha=(MagickRealType) (QuantumScale*p->alpha); beta=(MagickRealType) (QuantumScale*q->alpha); } pixel=alpha*p->red-beta*q->red; distance=pixel*pixel; if (distance <= cube_info->distance) { pixel=alpha*p->green-beta*q->green; distance+=pixel*pixel; if (distance <= cube_info->distance) { pixel=alpha*p->blue-beta*q->blue; distance+=pixel*pixel; if (distance <= cube_info->distance) { if (cube_info->associate_alpha != MagickFalse) { pixel=p->alpha-q->alpha; distance+=pixel*pixel; } if (distance <= cube_info->distance) { cube_info->distance=distance; cube_info->color_number=node_info->color_number; } } } } } } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % C o m p r e s s I m a g e C o l o r m a p % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % CompressImageColormap() compresses an image colormap by removing any % duplicate or unused color entries. % % The format of the CompressImageColormap method is: % % MagickBooleanType CompressImageColormap(Image *image, % ExceptionInfo *exception) % % A description of each parameter follows: % % o image: the image. % % o exception: return any errors or warnings in this structure. % */ MagickExport MagickBooleanType CompressImageColormap(Image *image, ExceptionInfo *exception) { QuantizeInfo quantize_info; assert(image != (Image *) NULL); assert(image->signature == MagickCoreSignature); if (image->debug != MagickFalse) (void) LogMagickEvent(TraceEvent,GetMagickModule(),"%s",image->filename); if (IsPaletteImage(image) == MagickFalse) return(MagickFalse); GetQuantizeInfo(&quantize_info); quantize_info.number_colors=image->colors; quantize_info.tree_depth=MaxTreeDepth; return(QuantizeImage(&quantize_info,image,exception)); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % + D e f i n e I m a g e C o l o r m a p % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % DefineImageColormap() traverses the color cube tree and notes each colormap % entry. A colormap entry is any node in the color cube tree where the % of unique colors is not zero. % % The format of the DefineImageColormap method is: % % void DefineImageColormap(Image *image,CubeInfo *cube_info, % NodeInfo *node_info) % % A description of each parameter follows. % % o image: the image. % % o cube_info: A pointer to the Cube structure. % % o node_info: the address of a structure of type NodeInfo which points to a % node in the color cube tree that is to be pruned. % */ static void DefineImageColormap(Image *image,CubeInfo *cube_info, NodeInfo *node_info) { size_t number_children; ssize_t i; /* Traverse any children. */ number_children=cube_info->associate_alpha == MagickFalse ? 8UL : 16UL; for (i=0; i < (ssize_t) number_children; i++) if (node_info->child[i] != (NodeInfo *) NULL) DefineImageColormap(image,cube_info,node_info->child[i]); if (node_info->number_unique != 0) { double alpha; PixelInfo *magick_restrict q; /* Colormap entry is defined by the mean color in this cube. */ q=image->colormap+image->colors; alpha=(double) ((MagickOffsetType) node_info->number_unique); alpha=PerceptibleReciprocal(alpha); if (cube_info->associate_alpha == MagickFalse) { q->red=(double) ClampToQuantum(alpha*QuantumRange* node_info->total_color.red); q->green=(double) ClampToQuantum(alpha*QuantumRange* node_info->total_color.green); q->blue=(double) ClampToQuantum(alpha*QuantumRange* node_info->total_color.blue); q->alpha=(double) OpaqueAlpha; } else { double opacity; opacity=(double) (alpha*QuantumRange*node_info->total_color.alpha); q->alpha=(double) ClampToQuantum(opacity); if (q->alpha == OpaqueAlpha) { q->red=(double) ClampToQuantum(alpha*QuantumRange* node_info->total_color.red); q->green=(double) ClampToQuantum(alpha*QuantumRange* node_info->total_color.green); q->blue=(double) ClampToQuantum(alpha*QuantumRange* node_info->total_color.blue); } else { double gamma; gamma=(double) (QuantumScale*q->alpha); gamma=PerceptibleReciprocal(gamma); q->red=(double) ClampToQuantum(alpha*gamma*QuantumRange* node_info->total_color.red); q->green=(double) ClampToQuantum(alpha*gamma*QuantumRange* node_info->total_color.green); q->blue=(double) ClampToQuantum(alpha*gamma*QuantumRange* node_info->total_color.blue); if (node_info->number_unique > cube_info->transparent_pixels) { cube_info->transparent_pixels=node_info->number_unique; cube_info->transparent_index=(ssize_t) image->colors; } } } node_info->color_number=image->colors++; } } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % + D e s t r o y C u b e I n f o % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % DestroyCubeInfo() deallocates memory associated with an image. % % The format of the DestroyCubeInfo method is: % % DestroyCubeInfo(CubeInfo *cube_info) % % A description of each parameter follows: % % o cube_info: the address of a structure of type CubeInfo. % */ static void DestroyCubeInfo(CubeInfo *cube_info) { Nodes *nodes; /* Release color cube tree storage. */ do { nodes=cube_info->node_queue->next; cube_info->node_queue->nodes=(NodeInfo *) RelinquishMagickMemory( cube_info->node_queue->nodes); cube_info->node_queue=(Nodes *) RelinquishMagickMemory( cube_info->node_queue); cube_info->node_queue=nodes; } while (cube_info->node_queue != (Nodes *) NULL); if (cube_info->memory_info != (MemoryInfo *) NULL) cube_info->memory_info=RelinquishVirtualMemory(cube_info->memory_info); cube_info->quantize_info=DestroyQuantizeInfo(cube_info->quantize_info); cube_info=(CubeInfo *) RelinquishMagickMemory(cube_info); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % D e s t r o y Q u a n t i z e I n f o % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % DestroyQuantizeInfo() deallocates memory associated with an QuantizeInfo % structure. % % The format of the DestroyQuantizeInfo method is: % % QuantizeInfo *DestroyQuantizeInfo(QuantizeInfo *quantize_info) % % A description of each parameter follows: % % o quantize_info: Specifies a pointer to an QuantizeInfo structure. % */ MagickExport QuantizeInfo *DestroyQuantizeInfo(QuantizeInfo *quantize_info) { (void) LogMagickEvent(TraceEvent,GetMagickModule(),"..."); assert(quantize_info != (QuantizeInfo *) NULL); assert(quantize_info->signature == MagickCoreSignature); quantize_info->signature=(~MagickCoreSignature); quantize_info=(QuantizeInfo *) RelinquishMagickMemory(quantize_info); return(quantize_info); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % + D i t h e r I m a g e % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % DitherImage() distributes the difference between an original image and % the corresponding color reduced algorithm to neighboring pixels using % serpentine-scan Floyd-Steinberg error diffusion. DitherImage returns % MagickTrue if the image is dithered otherwise MagickFalse. % % The format of the DitherImage method is: % % MagickBooleanType DitherImage(Image *image,CubeInfo *cube_info, % ExceptionInfo *exception) % % A description of each parameter follows. % % o image: the image. % % o cube_info: A pointer to the Cube structure. % % o exception: return any errors or warnings in this structure. % */ static DoublePixelPacket **DestroyPixelThreadSet(DoublePixelPacket **pixels) { ssize_t i; assert(pixels != (DoublePixelPacket **) NULL); for (i=0; i < (ssize_t) GetMagickResourceLimit(ThreadResource); i++) if (pixels[i] != (DoublePixelPacket *) NULL) pixels[i]=(DoublePixelPacket *) RelinquishMagickMemory(pixels[i]); pixels=(DoublePixelPacket **) RelinquishMagickMemory(pixels); return(pixels); } static DoublePixelPacket **AcquirePixelThreadSet(const size_t count) { DoublePixelPacket **pixels; size_t number_threads; ssize_t i; number_threads=(size_t) GetMagickResourceLimit(ThreadResource); pixels=(DoublePixelPacket **) AcquireQuantumMemory(number_threads, sizeof(*pixels)); if (pixels == (DoublePixelPacket **) NULL) return((DoublePixelPacket **) NULL); (void) memset(pixels,0,number_threads*sizeof(*pixels)); for (i=0; i < (ssize_t) number_threads; i++) { pixels[i]=(DoublePixelPacket *) AcquireQuantumMemory(count,2* sizeof(**pixels)); if (pixels[i] == (DoublePixelPacket *) NULL) return(DestroyPixelThreadSet(pixels)); } return(pixels); } static inline ssize_t CacheOffset(CubeInfo *cube_info, const DoublePixelPacket *pixel) { #define RedShift(pixel) (((pixel) >> CacheShift) << (0*(8-CacheShift))) #define GreenShift(pixel) (((pixel) >> CacheShift) << (1*(8-CacheShift))) #define BlueShift(pixel) (((pixel) >> CacheShift) << (2*(8-CacheShift))) #define AlphaShift(pixel) (((pixel) >> CacheShift) << (3*(8-CacheShift))) ssize_t offset; offset=(ssize_t) (RedShift(ScaleQuantumToChar(ClampPixel(pixel->red))) | GreenShift(ScaleQuantumToChar(ClampPixel(pixel->green))) | BlueShift(ScaleQuantumToChar(ClampPixel(pixel->blue)))); if (cube_info->associate_alpha != MagickFalse) offset|=AlphaShift(ScaleQuantumToChar(ClampPixel(pixel->alpha))); return(offset); } static MagickBooleanType FloydSteinbergDither(Image *image,CubeInfo *cube_info, ExceptionInfo *exception) { #define DitherImageTag "Dither/Image" CacheView *image_view; DoublePixelPacket **pixels; MagickBooleanType status; ssize_t y; /* Distribute quantization error using Floyd-Steinberg. */ pixels=AcquirePixelThreadSet(image->columns); if (pixels == (DoublePixelPacket **) NULL) return(MagickFalse); status=MagickTrue; image_view=AcquireAuthenticCacheView(image,exception); for (y=0; y < (ssize_t) image->rows; y++) { const int id = GetOpenMPThreadId(); CubeInfo cube; DoublePixelPacket *current, *previous; Quantum *magick_restrict q; size_t index; ssize_t x, v; if (status == MagickFalse) continue; q=GetCacheViewAuthenticPixels(image_view,0,y,image->columns,1,exception); if (q == (Quantum *) NULL) { status=MagickFalse; continue; } cube=(*cube_info); current=pixels[id]+(y & 0x01)*image->columns; previous=pixels[id]+((y+1) & 0x01)*image->columns; v=(ssize_t) ((y & 0x01) != 0 ? -1 : 1); for (x=0; x < (ssize_t) image->columns; x++) { DoublePixelPacket color, pixel; ssize_t i; ssize_t u; u=(y & 0x01) != 0 ? (ssize_t) image->columns-1-x : x; AssociateAlphaPixel(image,&cube,q+u*GetPixelChannels(image),&pixel); if (x > 0) { pixel.red+=7.0*cube_info->diffusion*current[u-v].red/16; pixel.green+=7.0*cube_info->diffusion*current[u-v].green/16; pixel.blue+=7.0*cube_info->diffusion*current[u-v].blue/16; if (cube.associate_alpha != MagickFalse) pixel.alpha+=7.0*cube_info->diffusion*current[u-v].alpha/16; } if (y > 0) { if (x < (ssize_t) (image->columns-1)) { pixel.red+=cube_info->diffusion*previous[u+v].red/16; pixel.green+=cube_info->diffusion*previous[u+v].green/16; pixel.blue+=cube_info->diffusion*previous[u+v].blue/16; if (cube.associate_alpha != MagickFalse) pixel.alpha+=cube_info->diffusion*previous[u+v].alpha/16; } pixel.red+=5.0*cube_info->diffusion*previous[u].red/16; pixel.green+=5.0*cube_info->diffusion*previous[u].green/16; pixel.blue+=5.0*cube_info->diffusion*previous[u].blue/16; if (cube.associate_alpha != MagickFalse) pixel.alpha+=5.0*cube_info->diffusion*previous[u].alpha/16; if (x > 0) { pixel.red+=3.0*cube_info->diffusion*previous[u-v].red/16; pixel.green+=3.0*cube_info->diffusion*previous[u-v].green/16; pixel.blue+=3.0*cube_info->diffusion*previous[u-v].blue/16; if (cube.associate_alpha != MagickFalse) pixel.alpha+=3.0*cube_info->diffusion*previous[u-v].alpha/16; } } pixel.red=(double) ClampPixel(pixel.red); pixel.green=(double) ClampPixel(pixel.green); pixel.blue=(double) ClampPixel(pixel.blue); if (cube.associate_alpha != MagickFalse) pixel.alpha=(double) ClampPixel(pixel.alpha); i=CacheOffset(&cube,&pixel); if (cube.cache[i] < 0) { NodeInfo *node_info; size_t node_id; /* Identify the deepest node containing the pixel's color. */ node_info=cube.root; for (index=MaxTreeDepth-1; (ssize_t) index > 0; index--) { node_id=ColorToNodeId(&cube,&pixel,index); if (node_info->child[node_id] == (NodeInfo *) NULL) break; node_info=node_info->child[node_id]; } /* Find closest color among siblings and their children. */ cube.target=pixel; cube.distance=(double) (4.0*(QuantumRange+1.0)*(QuantumRange+1.0)+ 1.0); ClosestColor(image,&cube,node_info->parent); cube.cache[i]=(ssize_t) cube.color_number; } /* Assign pixel to closest colormap entry. */ index=(size_t) cube.cache[i]; if (image->storage_class == PseudoClass) SetPixelIndex(image,(Quantum) index,q+u*GetPixelChannels(image)); if (cube.quantize_info->measure_error == MagickFalse) { SetPixelRed(image,ClampToQuantum(image->colormap[index].red), q+u*GetPixelChannels(image)); SetPixelGreen(image,ClampToQuantum(image->colormap[index].green), q+u*GetPixelChannels(image)); SetPixelBlue(image,ClampToQuantum(image->colormap[index].blue), q+u*GetPixelChannels(image)); if (cube.associate_alpha != MagickFalse) SetPixelAlpha(image,ClampToQuantum(image->colormap[index].alpha), q+u*GetPixelChannels(image)); } if (SyncCacheViewAuthenticPixels(image_view,exception) == MagickFalse) status=MagickFalse; /* Store the error. */ AssociateAlphaPixelInfo(&cube,image->colormap+index,&color); current[u].red=pixel.red-color.red; current[u].green=pixel.green-color.green; current[u].blue=pixel.blue-color.blue; if (cube.associate_alpha != MagickFalse) current[u].alpha=pixel.alpha-color.alpha; if (image->progress_monitor != (MagickProgressMonitor) NULL) { MagickBooleanType proceed; proceed=SetImageProgress(image,DitherImageTag,(MagickOffsetType) y, image->rows); if (proceed == MagickFalse) status=MagickFalse; } } } image_view=DestroyCacheView(image_view); pixels=DestroyPixelThreadSet(pixels); return(MagickTrue); } static MagickBooleanType RiemersmaDither(Image *image,CacheView *image_view, CubeInfo *cube_info,const unsigned int direction,ExceptionInfo *exception) { #define DitherImageTag "Dither/Image" CubeInfo *p; DoublePixelPacket color, pixel; MagickBooleanType proceed; size_t index; p=cube_info; if ((p->x >= 0) && (p->x < (ssize_t) image->columns) && (p->y >= 0) && (p->y < (ssize_t) image->rows)) { Quantum *magick_restrict q; ssize_t i; /* Distribute error. */ q=GetCacheViewAuthenticPixels(image_view,p->x,p->y,1,1,exception); if (q == (Quantum *) NULL) return(MagickFalse); AssociateAlphaPixel(image,cube_info,q,&pixel); for (i=0; i < ErrorQueueLength; i++) { pixel.red+=ErrorRelativeWeight*cube_info->diffusion*p->weights[i]* p->error[i].red; pixel.green+=ErrorRelativeWeight*cube_info->diffusion*p->weights[i]* p->error[i].green; pixel.blue+=ErrorRelativeWeight*cube_info->diffusion*p->weights[i]* p->error[i].blue; if (cube_info->associate_alpha != MagickFalse) pixel.alpha+=ErrorRelativeWeight*cube_info->diffusion*p->weights[i]* p->error[i].alpha; } pixel.red=(double) ClampPixel(pixel.red); pixel.green=(double) ClampPixel(pixel.green); pixel.blue=(double) ClampPixel(pixel.blue); if (cube_info->associate_alpha != MagickFalse) pixel.alpha=(double) ClampPixel(pixel.alpha); i=CacheOffset(cube_info,&pixel); if (p->cache[i] < 0) { NodeInfo *node_info; size_t id; /* Identify the deepest node containing the pixel's color. */ node_info=p->root; for (index=MaxTreeDepth-1; (ssize_t) index > 0; index--) { id=ColorToNodeId(cube_info,&pixel,index); if (node_info->child[id] == (NodeInfo *) NULL) break; node_info=node_info->child[id]; } /* Find closest color among siblings and their children. */ p->target=pixel; p->distance=(double) (4.0*(QuantumRange+1.0)*((double) QuantumRange+1.0)+1.0); ClosestColor(image,p,node_info->parent); p->cache[i]=(ssize_t) p->color_number; } /* Assign pixel to closest colormap entry. */ index=(size_t) p->cache[i]; if (image->storage_class == PseudoClass) SetPixelIndex(image,(Quantum) index,q); if (cube_info->quantize_info->measure_error == MagickFalse) { SetPixelRed(image,ClampToQuantum(image->colormap[index].red),q); SetPixelGreen(image,ClampToQuantum(image->colormap[index].green),q); SetPixelBlue(image,ClampToQuantum(image->colormap[index].blue),q); if (cube_info->associate_alpha != MagickFalse) SetPixelAlpha(image,ClampToQuantum(image->colormap[index].alpha),q); } if (SyncCacheViewAuthenticPixels(image_view,exception) == MagickFalse) return(MagickFalse); /* Propagate the error as the last entry of the error queue. */ (void) memmove(p->error,p->error+1,(ErrorQueueLength-1)* sizeof(p->error[0])); AssociateAlphaPixelInfo(cube_info,image->colormap+index,&color); p->error[ErrorQueueLength-1].red=pixel.red-color.red; p->error[ErrorQueueLength-1].green=pixel.green-color.green; p->error[ErrorQueueLength-1].blue=pixel.blue-color.blue; if (cube_info->associate_alpha != MagickFalse) p->error[ErrorQueueLength-1].alpha=pixel.alpha-color.alpha; proceed=SetImageProgress(image,DitherImageTag,p->offset,p->span); if (proceed == MagickFalse) return(MagickFalse); p->offset++; } switch (direction) { case WestGravity: p->x--; break; case EastGravity: p->x++; break; case NorthGravity: p->y--; break; case SouthGravity: p->y++; break; } return(MagickTrue); } static MagickBooleanType Riemersma(Image *image,CacheView *image_view, CubeInfo *cube_info,const size_t level,const unsigned int direction, ExceptionInfo *exception) { MagickBooleanType status; status=MagickTrue; if (level == 1) switch (direction) { case WestGravity: { status=RiemersmaDither(image,image_view,cube_info,EastGravity, exception); if (status != MagickFalse) status=RiemersmaDither(image,image_view,cube_info,SouthGravity, exception); if (status != MagickFalse) status=RiemersmaDither(image,image_view,cube_info,WestGravity, exception); break; } case EastGravity: { status=RiemersmaDither(image,image_view,cube_info,WestGravity, exception); if (status != MagickFalse) status=RiemersmaDither(image,image_view,cube_info,NorthGravity, exception); if (status != MagickFalse) status=RiemersmaDither(image,image_view,cube_info,EastGravity, exception); break; } case NorthGravity: { status=RiemersmaDither(image,image_view,cube_info,SouthGravity, exception); if (status != MagickFalse) status=RiemersmaDither(image,image_view,cube_info,EastGravity, exception); if (status != MagickFalse) status=RiemersmaDither(image,image_view,cube_info,NorthGravity, exception); break; } case SouthGravity: { status=RiemersmaDither(image,image_view,cube_info,NorthGravity, exception); if (status != MagickFalse) status=RiemersmaDither(image,image_view,cube_info,WestGravity, exception); if (status != MagickFalse) status=RiemersmaDither(image,image_view,cube_info,SouthGravity, exception); break; } default: break; } else switch (direction) { case WestGravity: { status=Riemersma(image,image_view,cube_info,level-1,NorthGravity, exception); if (status != MagickFalse) status=RiemersmaDither(image,image_view,cube_info,EastGravity, exception); if (status != MagickFalse) status=Riemersma(image,image_view,cube_info,level-1,WestGravity, exception); if (status != MagickFalse) status=RiemersmaDither(image,image_view,cube_info,SouthGravity, exception); if (status != MagickFalse) status=Riemersma(image,image_view,cube_info,level-1,WestGravity, exception); if (status != MagickFalse) status=RiemersmaDither(image,image_view,cube_info,WestGravity, exception); if (status != MagickFalse) status=Riemersma(image,image_view,cube_info,level-1,SouthGravity, exception); break; } case EastGravity: { status=Riemersma(image,image_view,cube_info,level-1,SouthGravity, exception); if (status != MagickFalse) status=RiemersmaDither(image,image_view,cube_info,WestGravity, exception); if (status != MagickFalse) status=Riemersma(image,image_view,cube_info,level-1,EastGravity, exception); if (status != MagickFalse) status=RiemersmaDither(image,image_view,cube_info,NorthGravity, exception); if (status != MagickFalse) status=Riemersma(image,image_view,cube_info,level-1,EastGravity, exception); if (status != MagickFalse) status=RiemersmaDither(image,image_view,cube_info,EastGravity, exception); if (status != MagickFalse) status=Riemersma(image,image_view,cube_info,level-1,NorthGravity, exception); break; } case NorthGravity: { status=Riemersma(image,image_view,cube_info,level-1,WestGravity, exception); if (status != MagickFalse) status=RiemersmaDither(image,image_view,cube_info,SouthGravity, exception); if (status != MagickFalse) status=Riemersma(image,image_view,cube_info,level-1,NorthGravity, exception); if (status != MagickFalse) status=RiemersmaDither(image,image_view,cube_info,EastGravity, exception); if (status != MagickFalse) status=Riemersma(image,image_view,cube_info,level-1,NorthGravity, exception); if (status != MagickFalse) status=RiemersmaDither(image,image_view,cube_info,NorthGravity, exception); if (status != MagickFalse) status=Riemersma(image,image_view,cube_info,level-1,EastGravity, exception); break; } case SouthGravity: { status=Riemersma(image,image_view,cube_info,level-1,EastGravity, exception); if (status != MagickFalse) status=RiemersmaDither(image,image_view,cube_info,NorthGravity, exception); if (status != MagickFalse) status=Riemersma(image,image_view,cube_info,level-1,SouthGravity, exception); if (status != MagickFalse) status=RiemersmaDither(image,image_view,cube_info,WestGravity, exception); if (status != MagickFalse) status=Riemersma(image,image_view,cube_info,level-1,SouthGravity, exception); if (status != MagickFalse) status=RiemersmaDither(image,image_view,cube_info,SouthGravity, exception); if (status != MagickFalse) status=Riemersma(image,image_view,cube_info,level-1,WestGravity, exception); break; } default: break; } return(status); } static MagickBooleanType DitherImage(Image *image,CubeInfo *cube_info, ExceptionInfo *exception) { CacheView *image_view; const char *artifact; MagickBooleanType status; size_t extent, level; artifact=GetImageArtifact(image,"dither:diffusion-amount"); if (artifact != (const char *) NULL) cube_info->diffusion=StringToDoubleInterval(artifact,1.0); if (cube_info->quantize_info->dither_method != RiemersmaDitherMethod) return(FloydSteinbergDither(image,cube_info,exception)); /* Distribute quantization error along a Hilbert curve. */ (void) memset(cube_info->error,0,ErrorQueueLength*sizeof(*cube_info->error)); cube_info->x=0; cube_info->y=0; extent=MagickMax(image->columns,image->rows); level=(size_t) log2((double) extent); if (((size_t) 1UL << level) < extent) level++; cube_info->offset=0; cube_info->span=(MagickSizeType) image->columns*image->rows; image_view=AcquireAuthenticCacheView(image,exception); status=MagickTrue; if (level > 0) status=Riemersma(image,image_view,cube_info,level,NorthGravity,exception); if (status != MagickFalse) status=RiemersmaDither(image,image_view,cube_info,ForgetGravity,exception); image_view=DestroyCacheView(image_view); return(status); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % + G e t C u b e I n f o % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % GetCubeInfo() initialize the Cube data structure. % % The format of the GetCubeInfo method is: % % CubeInfo GetCubeInfo(const QuantizeInfo *quantize_info, % const size_t depth,const size_t maximum_colors) % % A description of each parameter follows. % % o quantize_info: Specifies a pointer to an QuantizeInfo structure. % % o depth: Normally, this integer value is zero or one. A zero or % one tells Quantize to choose a optimal tree depth of Log4(number_colors). % A tree of this depth generally allows the best representation of the % reference image with the least amount of memory and the fastest % computational speed. In some cases, such as an image with low color % dispersion (a few number of colors), a value other than % Log4(number_colors) is required. To expand the color tree completely, % use a value of 8. % % o maximum_colors: maximum colors. % */ static CubeInfo *GetCubeInfo(const QuantizeInfo *quantize_info, const size_t depth,const size_t maximum_colors) { CubeInfo *cube_info; double weight; size_t length; ssize_t i; /* Initialize tree to describe color cube_info. */ cube_info=(CubeInfo *) AcquireMagickMemory(sizeof(*cube_info)); if (cube_info == (CubeInfo *) NULL) return((CubeInfo *) NULL); (void) memset(cube_info,0,sizeof(*cube_info)); cube_info->depth=depth; if (cube_info->depth > MaxTreeDepth) cube_info->depth=MaxTreeDepth; if (cube_info->depth < 2) cube_info->depth=2; cube_info->maximum_colors=maximum_colors; /* Initialize root node. */ cube_info->root=GetNodeInfo(cube_info,0,0,(NodeInfo *) NULL); if (cube_info->root == (NodeInfo *) NULL) return((CubeInfo *) NULL); cube_info->root->parent=cube_info->root; cube_info->quantize_info=CloneQuantizeInfo(quantize_info); if (cube_info->quantize_info->dither_method == NoDitherMethod) return(cube_info); /* Initialize dither resources. */ length=(size_t) (1UL << (4*(8-CacheShift))); cube_info->memory_info=AcquireVirtualMemory(length,sizeof(*cube_info->cache)); if (cube_info->memory_info == (MemoryInfo *) NULL) return((CubeInfo *) NULL); cube_info->cache=(ssize_t *) GetVirtualMemoryBlob(cube_info->memory_info); /* Initialize color cache. */ (void) memset(cube_info->cache,(-1),sizeof(*cube_info->cache)*length); /* Distribute weights along a curve of exponential decay. */ weight=1.0; for (i=0; i < ErrorQueueLength; i++) { cube_info->weights[i]=PerceptibleReciprocal(weight); weight*=exp(log(1.0/ErrorRelativeWeight)/(ErrorQueueLength-1.0)); } cube_info->diffusion=1.0; return(cube_info); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % + G e t N o d e I n f o % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % GetNodeInfo() allocates memory for a new node in the color cube tree and % presets all fields to zero. % % The format of the GetNodeInfo method is: % % NodeInfo *GetNodeInfo(CubeInfo *cube_info,const size_t id, % const size_t level,NodeInfo *parent) % % A description of each parameter follows. % % o node: The GetNodeInfo method returns a pointer to a queue of nodes. % % o id: Specifies the child number of the node. % % o level: Specifies the level in the storage_class the node resides. % */ static NodeInfo *GetNodeInfo(CubeInfo *cube_info,const size_t id, const size_t level,NodeInfo *parent) { NodeInfo *node_info; if (cube_info->free_nodes == 0) { Nodes *nodes; /* Allocate a new queue of nodes. */ nodes=(Nodes *) AcquireMagickMemory(sizeof(*nodes)); if (nodes == (Nodes *) NULL) return((NodeInfo *) NULL); nodes->nodes=(NodeInfo *) AcquireQuantumMemory(NodesInAList, sizeof(*nodes->nodes)); if (nodes->nodes == (NodeInfo *) NULL) return((NodeInfo *) NULL); nodes->next=cube_info->node_queue; cube_info->node_queue=nodes; cube_info->next_node=nodes->nodes; cube_info->free_nodes=NodesInAList; } cube_info->nodes++; cube_info->free_nodes--; node_info=cube_info->next_node++; (void) memset(node_info,0,sizeof(*node_info)); node_info->parent=parent; node_info->id=id; node_info->level=level; return(node_info); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % G e t I m a g e Q u a n t i z e E r r o r % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % GetImageQuantizeError() measures the difference between the original % and quantized images. This difference is the total quantization error. % The error is computed by summing over all pixels in an image the distance % squared in RGB space between each reference pixel value and its quantized % value. These values are computed: % % o mean_error_per_pixel: This value is the mean error for any single % pixel in the image. % % o normalized_mean_square_error: This value is the normalized mean % quantization error for any single pixel in the image. This distance % measure is normalized to a range between 0 and 1. It is independent % of the range of red, green, and blue values in the image. % % o normalized_maximum_square_error: Thsi value is the normalized % maximum quantization error for any single pixel in the image. This % distance measure is normalized to a range between 0 and 1. It is % independent of the range of red, green, and blue values in your image. % % The format of the GetImageQuantizeError method is: % % MagickBooleanType GetImageQuantizeError(Image *image, % ExceptionInfo *exception) % % A description of each parameter follows. % % o image: the image. % % o exception: return any errors or warnings in this structure. % */ MagickExport MagickBooleanType GetImageQuantizeError(Image *image, ExceptionInfo *exception) { CacheView *image_view; double alpha, area, beta, distance, maximum_error, mean_error, mean_error_per_pixel; ssize_t index, y; assert(image != (Image *) NULL); assert(image->signature == MagickCoreSignature); if (image->debug != MagickFalse) (void) LogMagickEvent(TraceEvent,GetMagickModule(),"%s",image->filename); image->total_colors=GetNumberColors(image,(FILE *) NULL,exception); (void) memset(&image->error,0,sizeof(image->error)); if (image->storage_class == DirectClass) return(MagickTrue); alpha=1.0; beta=1.0; area=3.0*image->columns*image->rows; maximum_error=0.0; mean_error_per_pixel=0.0; mean_error=0.0; image_view=AcquireVirtualCacheView(image,exception); for (y=0; y < (ssize_t) image->rows; y++) { const Quantum *magick_restrict p; ssize_t x; p=GetCacheViewVirtualPixels(image_view,0,y,image->columns,1,exception); if (p == (const Quantum *) NULL) break; for (x=0; x < (ssize_t) image->columns; x++) { index=(ssize_t) GetPixelIndex(image,p); if (image->alpha_trait != UndefinedPixelTrait) { alpha=(double) (QuantumScale*GetPixelAlpha(image,p)); beta=(double) (QuantumScale*image->colormap[index].alpha); } distance=fabs((double) (alpha*GetPixelRed(image,p)-beta* image->colormap[index].red)); mean_error_per_pixel+=distance; mean_error+=distance*distance; if (distance > maximum_error) maximum_error=distance; distance=fabs((double) (alpha*GetPixelGreen(image,p)-beta* image->colormap[index].green)); mean_error_per_pixel+=distance; mean_error+=distance*distance; if (distance > maximum_error) maximum_error=distance; distance=fabs((double) (alpha*GetPixelBlue(image,p)-beta* image->colormap[index].blue)); mean_error_per_pixel+=distance; mean_error+=distance*distance; if (distance > maximum_error) maximum_error=distance; p+=GetPixelChannels(image); } } image_view=DestroyCacheView(image_view); image->error.mean_error_per_pixel=(double) mean_error_per_pixel/area; image->error.normalized_mean_error=(double) QuantumScale*QuantumScale* mean_error/area; image->error.normalized_maximum_error=(double) QuantumScale*maximum_error; return(MagickTrue); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % G e t Q u a n t i z e I n f o % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % GetQuantizeInfo() initializes the QuantizeInfo structure. % % The format of the GetQuantizeInfo method is: % % GetQuantizeInfo(QuantizeInfo *quantize_info) % % A description of each parameter follows: % % o quantize_info: Specifies a pointer to a QuantizeInfo structure. % */ MagickExport void GetQuantizeInfo(QuantizeInfo *quantize_info) { (void) LogMagickEvent(TraceEvent,GetMagickModule(),"..."); assert(quantize_info != (QuantizeInfo *) NULL); (void) memset(quantize_info,0,sizeof(*quantize_info)); quantize_info->number_colors=256; quantize_info->dither_method=RiemersmaDitherMethod; quantize_info->colorspace=UndefinedColorspace; quantize_info->measure_error=MagickFalse; quantize_info->signature=MagickCoreSignature; } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % K m e a n s I m a g e % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % KmeansImage() applies k-means color reduction to an image. This is a % colorspace clustering or segmentation technique. % % The format of the KmeansImage method is: % % MagickBooleanType KmeansImage(Image *image,const size_t number_colors, % const size_t max_iterations,const double tolerance, % ExceptionInfo *exception) % % A description of each parameter follows: % % o image: the image. % % o number_colors: number of colors to use as seeds. % % o max_iterations: maximum number of iterations while converging. % % o tolerance: the maximum tolerance. % % o exception: return any errors or warnings in this structure. % */ typedef struct _KmeansInfo { double red, green, blue, alpha, black, count, distortion; } KmeansInfo; static KmeansInfo **DestroyKmeansThreadSet(KmeansInfo **kmeans_info) { ssize_t i; assert(kmeans_info != (KmeansInfo **) NULL); for (i=0; i < (ssize_t) GetMagickResourceLimit(ThreadResource); i++) if (kmeans_info[i] != (KmeansInfo *) NULL) kmeans_info[i]=(KmeansInfo *) RelinquishMagickMemory(kmeans_info[i]); kmeans_info=(KmeansInfo **) RelinquishMagickMemory(kmeans_info); return(kmeans_info); } static KmeansInfo **AcquireKmeansThreadSet(const size_t number_colors) { KmeansInfo **kmeans_info; ssize_t i; size_t number_threads; number_threads=(size_t) GetMagickResourceLimit(ThreadResource); kmeans_info=(KmeansInfo **) AcquireQuantumMemory(number_threads, sizeof(*kmeans_info)); if (kmeans_info == (KmeansInfo **) NULL) return((KmeansInfo **) NULL); (void) memset(kmeans_info,0,number_threads*sizeof(*kmeans_info)); for (i=0; i < (ssize_t) number_threads; i++) { kmeans_info[i]=(KmeansInfo *) AcquireQuantumMemory(number_colors, sizeof(**kmeans_info)); if (kmeans_info[i] == (KmeansInfo *) NULL) return(DestroyKmeansThreadSet(kmeans_info)); } return(kmeans_info); } static inline double KmeansMetric(const Image *magick_restrict image, const Quantum *magick_restrict p,const PixelInfo *magick_restrict q) { double gamma, metric, pixel; gamma=1.0; metric=0.0; if ((image->alpha_trait != UndefinedPixelTrait) || (q->alpha_trait != UndefinedPixelTrait)) { pixel=GetPixelAlpha(image,p)-(q->alpha_trait != UndefinedPixelTrait ? q->alpha : OpaqueAlpha); metric+=pixel*pixel; if (image->alpha_trait != UndefinedPixelTrait) gamma*=QuantumScale*GetPixelAlpha(image,p); if (q->alpha_trait != UndefinedPixelTrait) gamma*=QuantumScale*q->alpha; } if (image->colorspace == CMYKColorspace) { pixel=QuantumScale*(GetPixelBlack(image,p)-q->black); metric+=gamma*pixel*pixel; gamma*=QuantumScale*(QuantumRange-GetPixelBlack(image,p)); gamma*=QuantumScale*(QuantumRange-q->black); } metric*=3.0; pixel=QuantumScale*(GetPixelRed(image,p)-q->red); if (IsHueCompatibleColorspace(image->colorspace) != MagickFalse) { if (fabs((double) pixel) > 0.5) pixel-=0.5; pixel*=2.0; } metric+=gamma*pixel*pixel; pixel=QuantumScale*(GetPixelGreen(image,p)-q->green); metric+=gamma*pixel*pixel; pixel=QuantumScale*(GetPixelBlue(image,p)-q->blue); metric+=gamma*pixel*pixel; return(metric); } MagickExport MagickBooleanType KmeansImage(Image *image, const size_t number_colors,const size_t max_iterations,const double tolerance, ExceptionInfo *exception) { #define KmeansImageTag "Kmeans/Image" #define RandomColorComponent(info) (QuantumRange*GetPseudoRandomValue(info)) CacheView *image_view; const char *colors; double previous_tolerance; KmeansInfo **kmeans_pixels; MagickBooleanType verbose, status; ssize_t n; size_t number_threads; assert(image != (Image *) NULL); assert(image->signature == MagickCoreSignature); if (image->debug != MagickFalse) (void) LogMagickEvent(TraceEvent,GetMagickModule(),"%s",image->filename); assert(exception != (ExceptionInfo *) NULL); assert(exception->signature == MagickCoreSignature); colors=GetImageArtifact(image,"kmeans:seed-colors"); if (colors == (const char *) NULL) { CubeInfo *cube_info; QuantizeInfo *quantize_info; size_t depth; /* Seed clusters from color quantization. */ quantize_info=AcquireQuantizeInfo((ImageInfo *) NULL); quantize_info->colorspace=image->colorspace; quantize_info->number_colors=number_colors; quantize_info->dither_method=NoDitherMethod; n=number_colors; for (depth=1; n != 0; depth++) n>>=2; cube_info=GetCubeInfo(quantize_info,depth,number_colors); if (cube_info == (CubeInfo *) NULL) { quantize_info=DestroyQuantizeInfo(quantize_info); ThrowBinaryException(ResourceLimitError,"MemoryAllocationFailed", image->filename); } status=ClassifyImageColors(cube_info,image,exception); if (status != MagickFalse) { if (cube_info->colors > cube_info->maximum_colors) ReduceImageColors(image,cube_info); status=SetImageColormap(image,cube_info,exception); } DestroyCubeInfo(cube_info); quantize_info=DestroyQuantizeInfo(quantize_info); if (status == MagickFalse) return(status); } else { char color[MagickPathExtent]; const char *p; /* Seed clusters from color list (e.g. red;green;blue). */ status=AcquireImageColormap(image,number_colors,exception); if (status == MagickFalse) return(status); for (n=0, p=colors; n < (ssize_t) image->colors; n++) { const char *q; for (q=p; *q != '\0'; q++) if (*q == ';') break; (void) CopyMagickString(color,p,(size_t) MagickMin(q-p+1, MagickPathExtent)); (void) QueryColorCompliance(color,AllCompliance,image->colormap+n, exception); if (*q == '\0') { n++; break; } p=q+1; } if (n < (ssize_t) image->colors) { RandomInfo *random_info; /* Seed clusters from random values. */ random_info=AcquireRandomInfo(); for ( ; n < (ssize_t) image->colors; n++) { (void) QueryColorCompliance("#000",AllCompliance,image->colormap+n, exception); image->colormap[n].red=RandomColorComponent(random_info); image->colormap[n].green=RandomColorComponent(random_info); image->colormap[n].blue=RandomColorComponent(random_info); if (image->alpha_trait != UndefinedPixelTrait) image->colormap[n].alpha=RandomColorComponent(random_info); if (image->colorspace == CMYKColorspace) image->colormap[n].black=RandomColorComponent(random_info); } random_info=DestroyRandomInfo(random_info); } } /* Iterative refinement. */ kmeans_pixels=AcquireKmeansThreadSet(number_colors); if (kmeans_pixels == (KmeansInfo **) NULL) ThrowBinaryException(ResourceLimitError,"MemoryAllocationFailed", image->filename); previous_tolerance=0.0; verbose=IsStringTrue(GetImageArtifact(image,"debug")); number_threads=(size_t) GetMagickResourceLimit(ThreadResource); image_view=AcquireAuthenticCacheView(image,exception); for (n=0; n < (ssize_t) max_iterations; n++) { double distortion; ssize_t j, y; for (j=0; j < (ssize_t) number_threads; j++) (void) memset(kmeans_pixels[j],0,image->colors*sizeof(*kmeans_pixels[j])); #if defined(MAGICKCORE_OPENMP_SUPPORT) #pragma omp parallel for schedule(dynamic) shared(status) \ magick_number_threads(image,image,image->rows,1) #endif for (y=0; y < (ssize_t) image->rows; y++) { const int id = GetOpenMPThreadId(); Quantum *magick_restrict q; ssize_t x; if (status == MagickFalse) continue; q=GetCacheViewAuthenticPixels(image_view,0,y,image->columns,1,exception); if (q == (Quantum *) NULL) { status=MagickFalse; continue; } for (x=0; x < (ssize_t) image->columns; x++) { double min_distance; ssize_t i, k; /* Assign each pixel whose mean has the least squared color distance. */ k=0; min_distance=KmeansMetric(image,q,image->colormap+0); for (i=1; i < (ssize_t) image->colors; i++) { double distance; if (min_distance <= MagickEpsilon) break; distance=KmeansMetric(image,q,image->colormap+i); if (distance < min_distance) { min_distance=distance; k=i; } } kmeans_pixels[id][k].red+=QuantumScale*GetPixelRed(image,q); kmeans_pixels[id][k].green+=QuantumScale*GetPixelGreen(image,q); kmeans_pixels[id][k].blue+=QuantumScale*GetPixelBlue(image,q); if (image->alpha_trait != UndefinedPixelTrait) kmeans_pixels[id][k].alpha+=QuantumScale*GetPixelAlpha(image,q); if (image->colorspace == CMYKColorspace) kmeans_pixels[id][k].black+=QuantumScale*GetPixelBlack(image,q); kmeans_pixels[id][k].count++; kmeans_pixels[id][k].distortion+=min_distance; SetPixelIndex(image,(Quantum) k,q); q+=GetPixelChannels(image); } if (SyncCacheViewAuthenticPixels(image_view,exception) == MagickFalse) status=MagickFalse; } if (status == MagickFalse) break; /* Reduce sums to [0] entry. */ for (j=1; j < (ssize_t) number_threads; j++) { ssize_t k; for (k=0; k < (ssize_t) image->colors; k++) { kmeans_pixels[0][k].red+=kmeans_pixels[j][k].red; kmeans_pixels[0][k].green+=kmeans_pixels[j][k].green; kmeans_pixels[0][k].blue+=kmeans_pixels[j][k].blue; if (image->alpha_trait != UndefinedPixelTrait) kmeans_pixels[0][k].alpha+=kmeans_pixels[j][k].alpha; if (image->colorspace == CMYKColorspace) kmeans_pixels[0][k].black+=kmeans_pixels[j][k].black; kmeans_pixels[0][k].count+=kmeans_pixels[j][k].count; kmeans_pixels[0][k].distortion+=kmeans_pixels[j][k].distortion; } } /* Calculate the new means (centroids) of the pixels in the new clusters. */ distortion=0.0; for (j=0; j < (ssize_t) image->colors; j++) { double gamma; gamma=PerceptibleReciprocal((double) kmeans_pixels[0][j].count); image->colormap[j].red=gamma*QuantumRange*kmeans_pixels[0][j].red; image->colormap[j].green=gamma*QuantumRange*kmeans_pixels[0][j].green; image->colormap[j].blue=gamma*QuantumRange*kmeans_pixels[0][j].blue; if (image->alpha_trait != UndefinedPixelTrait) image->colormap[j].alpha=gamma*QuantumRange*kmeans_pixels[0][j].alpha; if (image->colorspace == CMYKColorspace) image->colormap[j].black=gamma*QuantumRange*kmeans_pixels[0][j].black; distortion+=kmeans_pixels[0][j].distortion; } if (verbose != MagickFalse) (void) FormatLocaleFile(stderr,"distortion[%.20g]: %*g %*g\n",(double) n, GetMagickPrecision(),distortion,GetMagickPrecision(), fabs(distortion-previous_tolerance)); if (fabs(distortion-previous_tolerance) <= tolerance) break; previous_tolerance=distortion; if (image->progress_monitor != (MagickProgressMonitor) NULL) { MagickBooleanType proceed; proceed=SetImageProgress(image,KmeansImageTag,(MagickOffsetType) n, max_iterations); if (proceed == MagickFalse) status=MagickFalse; } } image_view=DestroyCacheView(image_view); kmeans_pixels=DestroyKmeansThreadSet(kmeans_pixels); if (image->progress_monitor != (MagickProgressMonitor) NULL) (void) SetImageProgress(image,KmeansImageTag,(MagickOffsetType) max_iterations-1,max_iterations); if (status == MagickFalse) return(status); return(SyncImage(image,exception)); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % P o s t e r i z e I m a g e % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % PosterizeImage() reduces the image to a limited number of colors for a % "poster" effect. % % The format of the PosterizeImage method is: % % MagickBooleanType PosterizeImage(Image *image,const size_t levels, % const DitherMethod dither_method,ExceptionInfo *exception) % % A description of each parameter follows: % % o image: Specifies a pointer to an Image structure. % % o levels: Number of color levels allowed in each channel. Very low values % (2, 3, or 4) have the most visible effect. % % o dither_method: choose from UndefinedDitherMethod, NoDitherMethod, % RiemersmaDitherMethod, FloydSteinbergDitherMethod. % % o exception: return any errors or warnings in this structure. % */ static inline double MagickRound(double x) { /* Round the fraction to nearest integer. */ if ((x-floor(x)) < (ceil(x)-x)) return(floor(x)); return(ceil(x)); } MagickExport MagickBooleanType PosterizeImage(Image *image,const size_t levels, const DitherMethod dither_method,ExceptionInfo *exception) { #define PosterizeImageTag "Posterize/Image" #define PosterizePixel(pixel) ClampToQuantum((MagickRealType) QuantumRange*( \ MagickRound(QuantumScale*pixel*(levels-1)))/MagickMax((ssize_t) levels-1,1)) CacheView *image_view; MagickBooleanType status; MagickOffsetType progress; QuantizeInfo *quantize_info; ssize_t i; ssize_t y; assert(image != (Image *) NULL); assert(image->signature == MagickCoreSignature); if (image->debug != MagickFalse) (void) LogMagickEvent(TraceEvent,GetMagickModule(),"%s",image->filename); assert(exception != (ExceptionInfo *) NULL); assert(exception->signature == MagickCoreSignature); if (image->storage_class == PseudoClass) #if defined(MAGICKCORE_OPENMP_SUPPORT) #pragma omp parallel for schedule(static) shared(progress,status) \ magick_number_threads(image,image,image->colors,1) #endif for (i=0; i < (ssize_t) image->colors; i++) { /* Posterize colormap. */ if ((GetPixelRedTraits(image) & UpdatePixelTrait) != 0) image->colormap[i].red=(double) PosterizePixel(image->colormap[i].red); if ((GetPixelGreenTraits(image) & UpdatePixelTrait) != 0) image->colormap[i].green=(double) PosterizePixel(image->colormap[i].green); if ((GetPixelBlueTraits(image) & UpdatePixelTrait) != 0) image->colormap[i].blue=(double) PosterizePixel(image->colormap[i].blue); if ((GetPixelAlphaTraits(image) & UpdatePixelTrait) != 0) image->colormap[i].alpha=(double) PosterizePixel(image->colormap[i].alpha); } /* Posterize image. */ status=MagickTrue; progress=0; image_view=AcquireAuthenticCacheView(image,exception); #if defined(MAGICKCORE_OPENMP_SUPPORT) #pragma omp parallel for schedule(static) shared(progress,status) \ magick_number_threads(image,image,image->rows,1) #endif for (y=0; y < (ssize_t) image->rows; y++) { Quantum *magick_restrict q; ssize_t x; if (status == MagickFalse) continue; q=GetCacheViewAuthenticPixels(image_view,0,y,image->columns,1,exception); if (q == (Quantum *) NULL) { status=MagickFalse; continue; } for (x=0; x < (ssize_t) image->columns; x++) { if ((GetPixelRedTraits(image) & UpdatePixelTrait) != 0) SetPixelRed(image,PosterizePixel(GetPixelRed(image,q)),q); if ((GetPixelGreenTraits(image) & UpdatePixelTrait) != 0) SetPixelGreen(image,PosterizePixel(GetPixelGreen(image,q)),q); if ((GetPixelBlueTraits(image) & UpdatePixelTrait) != 0) SetPixelBlue(image,PosterizePixel(GetPixelBlue(image,q)),q); if (((GetPixelBlackTraits(image) & UpdatePixelTrait) != 0) && (image->colorspace == CMYKColorspace)) SetPixelBlack(image,PosterizePixel(GetPixelBlack(image,q)),q); if (((GetPixelAlphaTraits(image) & UpdatePixelTrait) != 0) && (image->alpha_trait != UndefinedPixelTrait)) SetPixelAlpha(image,PosterizePixel(GetPixelAlpha(image,q)),q); q+=GetPixelChannels(image); } if (SyncCacheViewAuthenticPixels(image_view,exception) == MagickFalse) status=MagickFalse; if (image->progress_monitor != (MagickProgressMonitor) NULL) { MagickBooleanType proceed; #if defined(MAGICKCORE_OPENMP_SUPPORT) #pragma omp atomic #endif progress++; proceed=SetImageProgress(image,PosterizeImageTag,progress,image->rows); if (proceed == MagickFalse) status=MagickFalse; } } image_view=DestroyCacheView(image_view); quantize_info=AcquireQuantizeInfo((ImageInfo *) NULL); quantize_info->number_colors=(size_t) MagickMin((ssize_t) levels*levels* levels,MaxColormapSize+1); quantize_info->dither_method=dither_method; quantize_info->tree_depth=MaxTreeDepth; status=QuantizeImage(quantize_info,image,exception); quantize_info=DestroyQuantizeInfo(quantize_info); return(status); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % + P r u n e C h i l d % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % PruneChild() deletes the given node and merges its statistics into its % parent. % % The format of the PruneSubtree method is: % % PruneChild(CubeInfo *cube_info,const NodeInfo *node_info) % % A description of each parameter follows. % % o cube_info: A pointer to the Cube structure. % % o node_info: pointer to node in color cube tree that is to be pruned. % */ static void PruneChild(CubeInfo *cube_info,const NodeInfo *node_info) { NodeInfo *parent; size_t number_children; ssize_t i; /* Traverse any children. */ number_children=cube_info->associate_alpha == MagickFalse ? 8UL : 16UL; for (i=0; i < (ssize_t) number_children; i++) if (node_info->child[i] != (NodeInfo *) NULL) PruneChild(cube_info,node_info->child[i]); if (cube_info->nodes > cube_info->maximum_colors) { /* Merge color statistics into parent. */ parent=node_info->parent; parent->number_unique+=node_info->number_unique; parent->total_color.red+=node_info->total_color.red; parent->total_color.green+=node_info->total_color.green; parent->total_color.blue+=node_info->total_color.blue; parent->total_color.alpha+=node_info->total_color.alpha; parent->child[node_info->id]=(NodeInfo *) NULL; cube_info->nodes--; } } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % + P r u n e L e v e l % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % PruneLevel() deletes all nodes at the bottom level of the color tree merging % their color statistics into their parent node. % % The format of the PruneLevel method is: % % PruneLevel(CubeInfo *cube_info,const NodeInfo *node_info) % % A description of each parameter follows. % % o cube_info: A pointer to the Cube structure. % % o node_info: pointer to node in color cube tree that is to be pruned. % */ static void PruneLevel(CubeInfo *cube_info,const NodeInfo *node_info) { size_t number_children; ssize_t i; /* Traverse any children. */ number_children=cube_info->associate_alpha == MagickFalse ? 8UL : 16UL; for (i=0; i < (ssize_t) number_children; i++) if (node_info->child[i] != (NodeInfo *) NULL) PruneLevel(cube_info,node_info->child[i]); if (node_info->level == cube_info->depth) PruneChild(cube_info,node_info); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % + P r u n e T o C u b e D e p t h % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % PruneToCubeDepth() deletes any nodes at a depth greater than % cube_info->depth while merging their color statistics into their parent % node. % % The format of the PruneToCubeDepth method is: % % PruneToCubeDepth(CubeInfo *cube_info,const NodeInfo *node_info) % % A description of each parameter follows. % % o cube_info: A pointer to the Cube structure. % % o node_info: pointer to node in color cube tree that is to be pruned. % */ static void PruneToCubeDepth(CubeInfo *cube_info,const NodeInfo *node_info) { size_t number_children; ssize_t i; /* Traverse any children. */ number_children=cube_info->associate_alpha == MagickFalse ? 8UL : 16UL; for (i=0; i < (ssize_t) number_children; i++) if (node_info->child[i] != (NodeInfo *) NULL) PruneToCubeDepth(cube_info,node_info->child[i]); if (node_info->level > cube_info->depth) PruneChild(cube_info,node_info); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % Q u a n t i z e I m a g e % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % QuantizeImage() analyzes the colors within a reference image and chooses a % fixed number of colors to represent the image. The goal of the algorithm % is to minimize the color difference between the input and output image while % minimizing the processing time. % % The format of the QuantizeImage method is: % % MagickBooleanType QuantizeImage(const QuantizeInfo *quantize_info, % Image *image,ExceptionInfo *exception) % % A description of each parameter follows: % % o quantize_info: Specifies a pointer to an QuantizeInfo structure. % % o image: the image. % % o exception: return any errors or warnings in this structure. % */ MagickExport MagickBooleanType QuantizeImage(const QuantizeInfo *quantize_info, Image *image,ExceptionInfo *exception) { CubeInfo *cube_info; ImageType type; MagickBooleanType status; size_t depth, maximum_colors; assert(quantize_info != (const QuantizeInfo *) NULL); assert(quantize_info->signature == MagickCoreSignature); assert(image != (Image *) NULL); assert(image->signature == MagickCoreSignature); if (image->debug != MagickFalse) (void) LogMagickEvent(TraceEvent,GetMagickModule(),"%s",image->filename); assert(exception != (ExceptionInfo *) NULL); assert(exception->signature == MagickCoreSignature); maximum_colors=quantize_info->number_colors; if (maximum_colors == 0) maximum_colors=MaxColormapSize; if (maximum_colors > MaxColormapSize) maximum_colors=MaxColormapSize; type=IdentifyImageGray(image,exception); if (IsGrayImageType(type) != MagickFalse) (void) SetGrayscaleImage(image,exception); depth=quantize_info->tree_depth; if (depth == 0) { size_t colors; /* Depth of color tree is: Log4(colormap size)+2. */ colors=maximum_colors; for (depth=1; colors != 0; depth++) colors>>=2; if ((quantize_info->dither_method != NoDitherMethod) && (depth > 2)) depth--; if ((image->alpha_trait != UndefinedPixelTrait) && (depth > 5)) depth--; if (IsGrayImageType(type) != MagickFalse) depth=MaxTreeDepth; } /* Initialize color cube. */ cube_info=GetCubeInfo(quantize_info,depth,maximum_colors); if (cube_info == (CubeInfo *) NULL) ThrowBinaryException(ResourceLimitError,"MemoryAllocationFailed", image->filename); status=ClassifyImageColors(cube_info,image,exception); if (status != MagickFalse) { /* Reduce the number of colors in the image. */ if (cube_info->colors > cube_info->maximum_colors) ReduceImageColors(image,cube_info); status=AssignImageColors(image,cube_info,exception); } DestroyCubeInfo(cube_info); return(status); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % Q u a n t i z e I m a g e s % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % QuantizeImages() analyzes the colors within a set of reference images and % chooses a fixed number of colors to represent the set. The goal of the % algorithm is to minimize the color difference between the input and output % images while minimizing the processing time. % % The format of the QuantizeImages method is: % % MagickBooleanType QuantizeImages(const QuantizeInfo *quantize_info, % Image *images,ExceptionInfo *exception) % % A description of each parameter follows: % % o quantize_info: Specifies a pointer to an QuantizeInfo structure. % % o images: Specifies a pointer to a list of Image structures. % % o exception: return any errors or warnings in this structure. % */ MagickExport MagickBooleanType QuantizeImages(const QuantizeInfo *quantize_info, Image *images,ExceptionInfo *exception) { CubeInfo *cube_info; Image *image; MagickBooleanType proceed, status; MagickProgressMonitor progress_monitor; size_t depth, maximum_colors, number_images; ssize_t i; assert(quantize_info != (const QuantizeInfo *) NULL); assert(quantize_info->signature == MagickCoreSignature); assert(images != (Image *) NULL); assert(images->signature == MagickCoreSignature); if (images->debug != MagickFalse) (void) LogMagickEvent(TraceEvent,GetMagickModule(),"%s",images->filename); assert(exception != (ExceptionInfo *) NULL); assert(exception->signature == MagickCoreSignature); if (GetNextImageInList(images) == (Image *) NULL) { /* Handle a single image with QuantizeImage. */ status=QuantizeImage(quantize_info,images,exception); return(status); } status=MagickFalse; maximum_colors=quantize_info->number_colors; if (maximum_colors == 0) maximum_colors=MaxColormapSize; if (maximum_colors > MaxColormapSize) maximum_colors=MaxColormapSize; depth=quantize_info->tree_depth; if (depth == 0) { size_t colors; /* Depth of color tree is: Log4(colormap size)+2. */ colors=maximum_colors; for (depth=1; colors != 0; depth++) colors>>=2; if (quantize_info->dither_method != NoDitherMethod) depth--; } /* Initialize color cube. */ cube_info=GetCubeInfo(quantize_info,depth,maximum_colors); if (cube_info == (CubeInfo *) NULL) { (void) ThrowMagickException(exception,GetMagickModule(), ResourceLimitError,"MemoryAllocationFailed","`%s'",images->filename); return(MagickFalse); } number_images=GetImageListLength(images); image=images; for (i=0; image != (Image *) NULL; i++) { progress_monitor=SetImageProgressMonitor(image,(MagickProgressMonitor) NULL, image->client_data); status=ClassifyImageColors(cube_info,image,exception); if (status == MagickFalse) break; (void) SetImageProgressMonitor(image,progress_monitor,image->client_data); proceed=SetImageProgress(image,AssignImageTag,(MagickOffsetType) i, number_images); if (proceed == MagickFalse) break; image=GetNextImageInList(image); } if (status != MagickFalse) { /* Reduce the number of colors in an image sequence. */ ReduceImageColors(images,cube_info); image=images; for (i=0; image != (Image *) NULL; i++) { progress_monitor=SetImageProgressMonitor(image,(MagickProgressMonitor) NULL,image->client_data); status=AssignImageColors(image,cube_info,exception); if (status == MagickFalse) break; (void) SetImageProgressMonitor(image,progress_monitor, image->client_data); proceed=SetImageProgress(image,AssignImageTag,(MagickOffsetType) i, number_images); if (proceed == MagickFalse) break; image=GetNextImageInList(image); } } DestroyCubeInfo(cube_info); return(status); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % + Q u a n t i z e E r r o r F l a t t e n % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % QuantizeErrorFlatten() traverses the color cube and flattens the quantization % error into a sorted 1D array. This accelerates the color reduction process. % % Contributed by Yoya. % % The format of the QuantizeErrorFlatten method is: % % size_t QuantizeErrorFlatten(const CubeInfo *cube_info, % const NodeInfo *node_info,const ssize_t offset, % double *quantize_error) % % A description of each parameter follows. % % o cube_info: A pointer to the Cube structure. % % o node_info: pointer to node in color cube tree that is current pointer. % % o offset: quantize error offset. % % o quantize_error: the quantization error vector. % */ static size_t QuantizeErrorFlatten(const CubeInfo *cube_info, const NodeInfo *node_info,const ssize_t offset,double *quantize_error) { size_t n, number_children; ssize_t i; if (offset >= (ssize_t) cube_info->nodes) return(0); quantize_error[offset]=node_info->quantize_error; n=1; number_children=cube_info->associate_alpha == MagickFalse ? 8UL : 16UL; for (i=0; i < (ssize_t) number_children ; i++) if (node_info->child[i] != (NodeInfo *) NULL) n+=QuantizeErrorFlatten(cube_info,node_info->child[i],offset+n, quantize_error); return(n); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % + R e d u c e % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % Reduce() traverses the color cube tree and prunes any node whose % quantization error falls below a particular threshold. % % The format of the Reduce method is: % % Reduce(CubeInfo *cube_info,const NodeInfo *node_info) % % A description of each parameter follows. % % o cube_info: A pointer to the Cube structure. % % o node_info: pointer to node in color cube tree that is to be pruned. % */ static void Reduce(CubeInfo *cube_info,const NodeInfo *node_info) { size_t number_children; ssize_t i; /* Traverse any children. */ number_children=cube_info->associate_alpha == MagickFalse ? 8UL : 16UL; for (i=0; i < (ssize_t) number_children; i++) if (node_info->child[i] != (NodeInfo *) NULL) Reduce(cube_info,node_info->child[i]); if (node_info->quantize_error <= cube_info->pruning_threshold) PruneChild(cube_info,node_info); else { /* Find minimum pruning threshold. */ if (node_info->number_unique > 0) cube_info->colors++; if (node_info->quantize_error < cube_info->next_threshold) cube_info->next_threshold=node_info->quantize_error; } } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % + R e d u c e I m a g e C o l o r s % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % ReduceImageColors() repeatedly prunes the tree until the number of nodes % with n2 > 0 is less than or equal to the maximum number of colors allowed % in the output image. On any given iteration over the tree, it selects % those nodes whose E value is minimal for pruning and merges their % color statistics upward. It uses a pruning threshold, Ep, to govern % node selection as follows: % % Ep = 0 % while number of nodes with (n2 > 0) > required maximum number of colors % prune all nodes such that E <= Ep % Set Ep to minimum E in remaining nodes % % This has the effect of minimizing any quantization error when merging % two nodes together. % % When a node to be pruned has offspring, the pruning procedure invokes % itself recursively in order to prune the tree from the leaves upward. % n2, Sr, Sg, and Sb in a node being pruned are always added to the % corresponding data in that node's parent. This retains the pruned % node's color characteristics for later averaging. % % For each node, n2 pixels exist for which that node represents the % smallest volume in RGB space containing those pixel's colors. When n2 % > 0 the node will uniquely define a color in the output image. At the % beginning of reduction, n2 = 0 for all nodes except a the leaves of % the tree which represent colors present in the input image. % % The other pixel count, n1, indicates the total number of colors % within the cubic volume which the node represents. This includes n1 - % n2 pixels whose colors should be defined by nodes at a lower level in % the tree. % % The format of the ReduceImageColors method is: % % ReduceImageColors(const Image *image,CubeInfo *cube_info) % % A description of each parameter follows. % % o image: the image. % % o cube_info: A pointer to the Cube structure. % */ static int QuantizeErrorCompare(const void *error_p,const void *error_q) { double *p, *q; p=(double *) error_p; q=(double *) error_q; if (*p > *q) return(1); if (fabs(*q-*p) <= MagickEpsilon) return(0); return(-1); } static void ReduceImageColors(const Image *image,CubeInfo *cube_info) { #define ReduceImageTag "Reduce/Image" MagickBooleanType proceed; MagickOffsetType offset; size_t span; cube_info->next_threshold=0.0; if (cube_info->colors > cube_info->maximum_colors) { double *quantize_error; /* Enable rapid reduction of the number of unique colors. */ quantize_error=(double *) AcquireQuantumMemory(cube_info->nodes, sizeof(*quantize_error)); if (quantize_error != (double *) NULL) { (void) QuantizeErrorFlatten(cube_info,cube_info->root,0, quantize_error); qsort(quantize_error,cube_info->nodes,sizeof(double), QuantizeErrorCompare); if (cube_info->nodes > (110*(cube_info->maximum_colors+1)/100)) cube_info->next_threshold=quantize_error[cube_info->nodes-110* (cube_info->maximum_colors+1)/100]; quantize_error=(double *) RelinquishMagickMemory(quantize_error); } } for (span=cube_info->colors; cube_info->colors > cube_info->maximum_colors; ) { cube_info->pruning_threshold=cube_info->next_threshold; cube_info->next_threshold=cube_info->root->quantize_error-1; cube_info->colors=0; Reduce(cube_info,cube_info->root); offset=(MagickOffsetType) span-cube_info->colors; proceed=SetImageProgress(image,ReduceImageTag,offset,span- cube_info->maximum_colors+1); if (proceed == MagickFalse) break; } } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % R e m a p I m a g e % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % RemapImage() replaces the colors of an image with the closest of the colors % from the reference image. % % The format of the RemapImage method is: % % MagickBooleanType RemapImage(const QuantizeInfo *quantize_info, % Image *image,const Image *remap_image,ExceptionInfo *exception) % % A description of each parameter follows: % % o quantize_info: Specifies a pointer to an QuantizeInfo structure. % % o image: the image. % % o remap_image: the reference image. % % o exception: return any errors or warnings in this structure. % */ MagickExport MagickBooleanType RemapImage(const QuantizeInfo *quantize_info, Image *image,const Image *remap_image,ExceptionInfo *exception) { CubeInfo *cube_info; MagickBooleanType status; /* Initialize color cube. */ assert(image != (Image *) NULL); assert(image->signature == MagickCoreSignature); if (image->debug != MagickFalse) (void) LogMagickEvent(TraceEvent,GetMagickModule(),"%s",image->filename); assert(remap_image != (Image *) NULL); assert(remap_image->signature == MagickCoreSignature); assert(exception != (ExceptionInfo *) NULL); assert(exception->signature == MagickCoreSignature); cube_info=GetCubeInfo(quantize_info,MaxTreeDepth, quantize_info->number_colors); if (cube_info == (CubeInfo *) NULL) ThrowBinaryException(ResourceLimitError,"MemoryAllocationFailed", image->filename); status=ClassifyImageColors(cube_info,remap_image,exception); if (status != MagickFalse) { /* Classify image colors from the reference image. */ cube_info->quantize_info->number_colors=cube_info->colors; status=AssignImageColors(image,cube_info,exception); } DestroyCubeInfo(cube_info); return(status); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % R e m a p I m a g e s % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % RemapImages() replaces the colors of a sequence of images with the % closest color from a reference image. % % The format of the RemapImage method is: % % MagickBooleanType RemapImages(const QuantizeInfo *quantize_info, % Image *images,Image *remap_image,ExceptionInfo *exception) % % A description of each parameter follows: % % o quantize_info: Specifies a pointer to an QuantizeInfo structure. % % o images: the image sequence. % % o remap_image: the reference image. % % o exception: return any errors or warnings in this structure. % */ MagickExport MagickBooleanType RemapImages(const QuantizeInfo *quantize_info, Image *images,const Image *remap_image,ExceptionInfo *exception) { CubeInfo *cube_info; Image *image; MagickBooleanType status; assert(images != (Image *) NULL); assert(images->signature == MagickCoreSignature); if (images->debug != MagickFalse) (void) LogMagickEvent(TraceEvent,GetMagickModule(),"%s",images->filename); assert(exception != (ExceptionInfo *) NULL); assert(exception->signature == MagickCoreSignature); image=images; if (remap_image == (Image *) NULL) { /* Create a global colormap for an image sequence. */ status=QuantizeImages(quantize_info,images,exception); return(status); } /* Classify image colors from the reference image. */ cube_info=GetCubeInfo(quantize_info,MaxTreeDepth, quantize_info->number_colors); if (cube_info == (CubeInfo *) NULL) ThrowBinaryException(ResourceLimitError,"MemoryAllocationFailed", image->filename); status=ClassifyImageColors(cube_info,remap_image,exception); if (status != MagickFalse) { /* Classify image colors from the reference image. */ cube_info->quantize_info->number_colors=cube_info->colors; image=images; for ( ; image != (Image *) NULL; image=GetNextImageInList(image)) { status=AssignImageColors(image,cube_info,exception); if (status == MagickFalse) break; } } DestroyCubeInfo(cube_info); return(status); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % S e t G r a y s c a l e I m a g e % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % SetGrayscaleImage() converts an image to a PseudoClass grayscale image. % % The format of the SetGrayscaleImage method is: % % MagickBooleanType SetGrayscaleImage(Image *image, % ExceptionInfo *exception) % % A description of each parameter follows: % % o image: The image. % % o exception: return any errors or warnings in this structure. % */ #if defined(__cplusplus) || defined(c_plusplus) extern "C" { #endif static int IntensityCompare(const void *x,const void *y) { double intensity; PixelInfo *color_1, *color_2; color_1=(PixelInfo *) x; color_2=(PixelInfo *) y; intensity=GetPixelInfoIntensity((const Image *) NULL,color_1)- GetPixelInfoIntensity((const Image *) NULL,color_2); if (intensity < (double) INT_MIN) intensity=(double) INT_MIN; if (intensity > (double) INT_MAX) intensity=(double) INT_MAX; return((int) intensity); } #if defined(__cplusplus) || defined(c_plusplus) } #endif static MagickBooleanType SetGrayscaleImage(Image *image, ExceptionInfo *exception) { CacheView *image_view; MagickBooleanType status; PixelInfo *colormap; size_t extent; ssize_t *colormap_index, i, j, y; assert(image != (Image *) NULL); assert(image->signature == MagickCoreSignature); if (image->type != GrayscaleType) (void) TransformImageColorspace(image,GRAYColorspace,exception); extent=MagickMax(image->colors+1,MagickMax(MaxColormapSize,MaxMap+1)); colormap_index=(ssize_t *) AcquireQuantumMemory(extent, sizeof(*colormap_index)); if (colormap_index == (ssize_t *) NULL) ThrowBinaryException(ResourceLimitError,"MemoryAllocationFailed", image->filename); if (image->storage_class != PseudoClass) { (void) memset(colormap_index,(-1),extent*sizeof(*colormap_index)); if (AcquireImageColormap(image,MaxColormapSize,exception) == MagickFalse) { colormap_index=(ssize_t *) RelinquishMagickMemory(colormap_index); ThrowBinaryException(ResourceLimitError,"MemoryAllocationFailed", image->filename); } image->colors=0; status=MagickTrue; image_view=AcquireAuthenticCacheView(image,exception); #if defined(MAGICKCORE_OPENMP_SUPPORT) #pragma omp parallel for schedule(static) shared(status) \ magick_number_threads(image,image,image->rows,1) #endif for (y=0; y < (ssize_t) image->rows; y++) { Quantum *magick_restrict q; ssize_t x; if (status == MagickFalse) continue; q=GetCacheViewAuthenticPixels(image_view,0,y,image->columns,1, exception); if (q == (Quantum *) NULL) { status=MagickFalse; continue; } for (x=0; x < (ssize_t) image->columns; x++) { size_t intensity; intensity=ScaleQuantumToMap(GetPixelRed(image,q)); if (colormap_index[intensity] < 0) { #if defined(MAGICKCORE_OPENMP_SUPPORT) #pragma omp critical (MagickCore_SetGrayscaleImage) #endif if (colormap_index[intensity] < 0) { colormap_index[intensity]=(ssize_t) image->colors; image->colormap[image->colors].red=(double) GetPixelRed(image,q); image->colormap[image->colors].green=(double) GetPixelGreen(image,q); image->colormap[image->colors].blue=(double) GetPixelBlue(image,q); image->colors++; } } SetPixelIndex(image,(Quantum) colormap_index[intensity],q); q+=GetPixelChannels(image); } if (SyncCacheViewAuthenticPixels(image_view,exception) == MagickFalse) status=MagickFalse; } image_view=DestroyCacheView(image_view); } (void) memset(colormap_index,0,extent*sizeof(*colormap_index)); for (i=0; i < (ssize_t) image->colors; i++) image->colormap[i].alpha=(double) i; qsort((void *) image->colormap,image->colors,sizeof(PixelInfo), IntensityCompare); colormap=(PixelInfo *) AcquireQuantumMemory(image->colors,sizeof(*colormap)); if (colormap == (PixelInfo *) NULL) { colormap_index=(ssize_t *) RelinquishMagickMemory(colormap_index); ThrowBinaryException(ResourceLimitError,"MemoryAllocationFailed", image->filename); } j=0; colormap[j]=image->colormap[0]; for (i=0; i < (ssize_t) image->colors; i++) { if (IsPixelInfoEquivalent(&colormap[j],&image->colormap[i]) == MagickFalse) { j++; colormap[j]=image->colormap[i]; } colormap_index[(ssize_t) image->colormap[i].alpha]=j; } image->colors=(size_t) (j+1); image->colormap=(PixelInfo *) RelinquishMagickMemory(image->colormap); image->colormap=colormap; status=MagickTrue; image_view=AcquireAuthenticCacheView(image,exception); #if defined(MAGICKCORE_OPENMP_SUPPORT) #pragma omp parallel for schedule(static) shared(status) \ magick_number_threads(image,image,image->rows,1) #endif for (y=0; y < (ssize_t) image->rows; y++) { Quantum *magick_restrict q; ssize_t x; if (status == MagickFalse) continue; q=GetCacheViewAuthenticPixels(image_view,0,y,image->columns,1,exception); if (q == (Quantum *) NULL) { status=MagickFalse; continue; } for (x=0; x < (ssize_t) image->columns; x++) { SetPixelIndex(image,(Quantum) colormap_index[ScaleQuantumToMap( GetPixelIndex(image,q))],q); q+=GetPixelChannels(image); } if (SyncCacheViewAuthenticPixels(image_view,exception) == MagickFalse) status=MagickFalse; } image_view=DestroyCacheView(image_view); colormap_index=(ssize_t *) RelinquishMagickMemory(colormap_index); image->type=GrayscaleType; if (SetImageMonochrome(image,exception) != MagickFalse) image->type=BilevelType; return(status); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % + S e t I m a g e C o l o r m a p % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % SetImageColormap() traverses the color cube tree and sets the colormap of % the image. A colormap entry is any node in the color cube tree where the % of unique colors is not zero. % % The format of the SetImageColormap method is: % % MagickBooleanType SetImageColormap(Image *image,CubeInfo *cube_info, % ExceptionInfo *node_info) % % A description of each parameter follows. % % o image: the image. % % o cube_info: A pointer to the Cube structure. % % o exception: return any errors or warnings in this structure. % */ MagickBooleanType SetImageColormap(Image *image,CubeInfo *cube_info, ExceptionInfo *exception) { size_t number_colors; number_colors=MagickMax(cube_info->maximum_colors,cube_info->colors); if (AcquireImageColormap(image,number_colors,exception) == MagickFalse) ThrowBinaryException(ResourceLimitError,"MemoryAllocationFailed", image->filename); image->colors=0; DefineImageColormap(image,cube_info,cube_info->root); if (image->colors != number_colors) { image->colormap=(PixelInfo *) ResizeQuantumMemory(image->colormap, image->colors+1,sizeof(*image->colormap)); if (image->colormap == (PixelInfo *) NULL) ThrowBinaryException(ResourceLimitError,"MemoryAllocationFailed", image->filename); } return(MagickTrue); }

GB_bitmap_assign_M_row_template.c

//------------------------------------------------------------------------------ // GB_bitmap_assign_M_row_template: traverse M for GB_ROW_ASSIGN //------------------------------------------------------------------------------ // SuiteSparse:GraphBLAS, Timothy A. Davis, (c) 2017-2021, All Rights Reserved. // SPDX-License-Identifier: Apache-2.0 //------------------------------------------------------------------------------ // M is a 1-by-(C->vdim) hypersparse or sparse matrix, not a vector, for // GrB_Row_assign (if C is CSC) or GrB_Col_assign (if C is CSR). // C is bitmap/full. M is sparse/hyper, and can be jumbled. { const int64_t *restrict kfirst_Mslice = M_ek_slicing ; const int64_t *restrict klast_Mslice = M_ek_slicing + M_ntasks ; const int64_t *restrict pstart_Mslice = M_ek_slicing + M_ntasks * 2 ; ASSERT (mvlen == 1) ; int64_t iC = I [0] ; int tid ; #pragma omp parallel for num_threads(M_nthreads) schedule(dynamic,1) \ reduction(+:cnvals) for (tid = 0 ; tid < M_ntasks ; tid++) { int64_t kfirst = kfirst_Mslice [tid] ; int64_t klast = klast_Mslice [tid] ; int64_t task_cnvals = 0 ; //---------------------------------------------------------------------- // traverse over M (0,kfirst:klast) //---------------------------------------------------------------------- for (int64_t k = kfirst ; k <= klast ; k++) { //------------------------------------------------------------------ // find the part of M(0,k) for this task //------------------------------------------------------------------ int64_t jM = GBH (Mh, k) ; int64_t pM_start, pM_end ; GB_get_pA (&pM_start, &pM_end, tid, k, kfirst, klast, pstart_Mslice, Mp, mvlen) ; //------------------------------------------------------------------ // traverse over M(0,jM), the kth vector of M //------------------------------------------------------------------ // for row_assign: M is a single row, iC = I [0] // It has either 0 or 1 entry. int64_t pM = pM_start ; if (pM < pM_end) { bool mij = GB_mcast (Mx, pM, msize) ; if (mij) { int64_t jC = jM ; int64_t pC = iC + jC * cvlen ; GB_MASK_WORK (pC) ; } } } cnvals += task_cnvals ; } }

gather.c

#include "../../shared.h" #include "hale.h" #include <float.h> #include <math.h> #include <stdio.h> // Gathers all of the subcell quantities on the mesh void gather_subcell_mass_and_energy( const int ncells, const int nnodes, double* cell_centroids_x, double* cell_centroids_y, double* cell_centroids_z, int* cells_to_nodes_offsets, const double* nodes_x, const double* nodes_y, const double* nodes_z, const double* cell_volume, double* energy, double* density, double* velocity_x, double* velocity_y, double* velocity_z, double* ke_mass, double* cell_mass, double* subcell_mass, double* subcell_volume, double* subcell_ie_mass, double* subcell_ke_mass, double* subcell_centroids_x, double* subcell_centroids_y, double* subcell_centroids_z, int* faces_to_cells0, int* faces_to_cells1, int* cells_to_faces_offsets, int* cells_to_faces, int* cells_to_nodes, int* nodes_to_cells_offsets, int* nodes_to_cells, double* initial_mass, double* initial_ie_mass, double* initial_ke_mass); // Gathers the momentum into the subcells void gather_subcell_momentum( const int nnodes, const double* nodal_volumes, const double* nodal_mass, int* nodes_to_cells, const double* nodes_x, const double* nodes_y, const double* nodes_z, double* velocity_x, double* velocity_y, double* velocity_z, double* subcell_volume, double* cell_centroids_x, double* cell_centroids_y, double* cell_centroids_z, double* subcell_momentum_x, double* subcell_momentum_y, double* subcell_momentum_z, double* subcell_centroids_x, double* subcell_centroids_y, double* subcell_centroids_z, int* nodes_to_cells_offsets, int* cells_to_nodes_offsets, int* cells_to_nodes, int* nodes_to_nodes_offsets, int* nodes_to_nodes, vec_t* initial_momentum); // gathers all of the subcell quantities on the mesh void gather_subcell_quantities(UnstructuredMesh* umesh, HaleData* hale_data, vec_t* initial_momentum, double* initial_mass, double* initial_ie_mass, double* initial_ke_mass) { /* * GATHERING STAGE OF THE REMAP */ // Calculates the cell volume, subcell volume and the subcell centroids calc_volumes_centroids( umesh->ncells, umesh->nnodes, hale_data->nnodes_by_subcell, umesh->cells_to_nodes_offsets, umesh->cells_to_nodes, hale_data->subcells_to_faces_offsets, hale_data->subcells_to_faces, umesh->faces_to_nodes, umesh->faces_to_nodes_offsets, umesh->faces_cclockwise_cell, umesh->nodes_x0, umesh->nodes_y0, umesh->nodes_z0, hale_data->subcell_centroids_x, hale_data->subcell_centroids_y, hale_data->subcell_centroids_z, hale_data->subcell_volume, hale_data->cell_volume, hale_data->nodal_volumes, umesh->nodes_to_cells_offsets, umesh->nodes_to_cells); // Gathers all of the subcell quantities on the mesh gather_subcell_mass_and_energy( umesh->ncells, umesh->nnodes, umesh->cell_centroids_x, umesh->cell_centroids_y, umesh->cell_centroids_z, umesh->cells_to_nodes_offsets, umesh->nodes_x0, umesh->nodes_y0, umesh->nodes_z0, hale_data->cell_volume, hale_data->energy0, hale_data->density0, hale_data->velocity_x0, hale_data->velocity_y0, hale_data->velocity_z0, hale_data->ke_mass, hale_data->cell_mass, hale_data->subcell_mass, hale_data->subcell_volume, hale_data->subcell_ie_mass, hale_data->subcell_ke_mass, hale_data->subcell_centroids_x, hale_data->subcell_centroids_y, hale_data->subcell_centroids_z, umesh->faces_to_cells0, umesh->faces_to_cells1, umesh->cells_to_faces_offsets, umesh->cells_to_faces, umesh->cells_to_nodes, umesh->nodes_to_cells_offsets, umesh->nodes_to_cells, initial_mass, initial_ie_mass, initial_ke_mass); // Gathers the momentum the subcells gather_subcell_momentum( umesh->nnodes, hale_data->nodal_volumes, hale_data->nodal_mass, umesh->nodes_to_cells, umesh->nodes_x0, umesh->nodes_y0, umesh->nodes_z0, hale_data->velocity_x0, hale_data->velocity_y0, hale_data->velocity_z0, hale_data->subcell_volume, umesh->cell_centroids_x, umesh->cell_centroids_y, umesh->cell_centroids_z, hale_data->subcell_momentum_x, hale_data->subcell_momentum_y, hale_data->subcell_momentum_z, hale_data->subcell_centroids_x, hale_data->subcell_centroids_y, hale_data->subcell_centroids_z, umesh->nodes_to_cells_offsets, umesh->cells_to_nodes_offsets, umesh->cells_to_nodes, umesh->nodes_to_nodes_offsets, umesh->nodes_to_nodes, initial_momentum); } // Gathers all of the subcell quantities on the mesh void gather_subcell_mass_and_energy( const int ncells, const int nnodes, double* cell_centroids_x, double* cell_centroids_y, double* cell_centroids_z, int* cells_to_nodes_offsets, const double* nodes_x, const double* nodes_y, const double* nodes_z, const double* cell_volume, double* energy, double* density, double* velocity_x, double* velocity_y, double* velocity_z, double* ke_mass, double* cell_mass, double* subcell_mass, double* subcell_volume, double* subcell_ie_mass, double* subcell_ke_mass, double* subcell_centroids_x, double* subcell_centroids_y, double* subcell_centroids_z, int* faces_to_cells0, int* faces_to_cells1, int* cells_to_faces_offsets, int* cells_to_faces, int* cells_to_nodes, int* nodes_to_cells_offsets, int* nodes_to_cells, double* initial_mass, double* initial_ie_mass, double* initial_ke_mass) { double total_mass = 0.0; double total_ie_mass = 0.0; double total_ke_mass = 0.0; // We first have to determine the cell centered kinetic energy #pragma omp parallel for reduction(+ : total_ke_mass) for (int cc = 0; cc < ncells; ++cc) { const int cell_to_nodes_off = cells_to_nodes_offsets[(cc)]; const int nnodes_by_cell = cells_to_nodes_offsets[(cc + 1)] - cell_to_nodes_off; ke_mass[(cc)] = 0.0; // Subcells are ordered with the nodes on a face for (int nn = 0; nn < nnodes_by_cell; ++nn) { const int node_index = cells_to_nodes[(cell_to_nodes_off + nn)]; const int subcell_index = cell_to_nodes_off + nn; ke_mass[(cc)] += subcell_mass[(subcell_index)] * 0.5 * (velocity_x[(node_index)] * velocity_x[(node_index)] + velocity_y[(node_index)] * velocity_y[(node_index)] + velocity_z[(node_index)] * velocity_z[(node_index)]); } total_ke_mass += ke_mass[(cc)]; } double total_ie_in_subcells = 0.0; double total_ke_in_subcells = 0.0; // Calculate the sub-cell internal and kinetic energies #pragma omp parallel for reduction(+ : total_mass, total_ie_mass, \ total_ie_in_subcells, total_ke_in_subcells) for (int cc = 0; cc < ncells; ++cc) { // Calculating the volume dist necessary for the least squares // regression const int cell_to_faces_off = cells_to_faces_offsets[(cc)]; const int nfaces_by_cell = cells_to_faces_offsets[(cc + 1)] - cell_to_faces_off; const int cell_to_nodes_off = cells_to_nodes_offsets[(cc)]; const int nnodes_by_cell = cells_to_nodes_offsets[(cc + 1)] - cell_to_nodes_off; const double cell_ie = density[(cc)] * energy[(cc)]; const double cell_ke = ke_mass[(cc)] / cell_volume[(cc)]; vec_t cell_c = {0.0, 0.0, 0.0}; calc_centroid(nnodes_by_cell, nodes_x, nodes_y, nodes_z, cells_to_nodes, cell_to_nodes_off, &cell_c); vec_t ie_rhs = {0.0, 0.0, 0.0}; vec_t ke_rhs = {0.0, 0.0, 0.0}; vec_t coeff[3] = {{0.0, 0.0, 0.0}}; total_mass += cell_mass[(cc)]; total_ie_mass += cell_mass[(cc)] * energy[(cc)]; // Determine the weighted volume dist for neighbouring cells double gmax_ie = -DBL_MAX; double gmin_ie = DBL_MAX; double gmax_ke = -DBL_MAX; double gmin_ke = DBL_MAX; for (int ff = 0; ff < nfaces_by_cell; ++ff) { const int face_index = cells_to_faces[(cell_to_faces_off + ff)]; const int neighbour_index = (faces_to_cells0[(face_index)] == cc) ? faces_to_cells1[(face_index)] : faces_to_cells0[(face_index)]; // Check if boundary face if (neighbour_index == -1) { continue; } vec_t dist = {cell_centroids_x[(neighbour_index)] - cell_c.x, cell_centroids_y[(neighbour_index)] - cell_c.y, cell_centroids_z[(neighbour_index)] - cell_c.z}; // Store the neighbouring cell's contribution to the coefficients double neighbour_vol = cell_volume[(neighbour_index)]; coeff[0].x += 2.0 * (dist.x * dist.x) / (neighbour_vol * neighbour_vol); coeff[0].y += 2.0 * (dist.x * dist.y) / (neighbour_vol * neighbour_vol); coeff[0].z += 2.0 * (dist.x * dist.z) / (neighbour_vol * neighbour_vol); coeff[1].x += 2.0 * (dist.y * dist.x) / (neighbour_vol * neighbour_vol); coeff[1].y += 2.0 * (dist.y * dist.y) / (neighbour_vol * neighbour_vol); coeff[1].z += 2.0 * (dist.y * dist.z) / (neighbour_vol * neighbour_vol); coeff[2].x += 2.0 * (dist.z * dist.x) / (neighbour_vol * neighbour_vol); coeff[2].y += 2.0 * (dist.z * dist.y) / (neighbour_vol * neighbour_vol); coeff[2].z += 2.0 * (dist.z * dist.z) / (neighbour_vol * neighbour_vol); const double neighbour_ie = density[(neighbour_index)] * energy[(neighbour_index)]; const double neighbour_ke = ke_mass[(neighbour_index)] / neighbour_vol; gmax_ie = max(gmax_ie, neighbour_ie); gmin_ie = min(gmin_ie, neighbour_ie); gmax_ke = max(gmax_ke, neighbour_ke); gmin_ke = min(gmin_ke, neighbour_ke); // Prepare the RHS, which includes energy differential const double die = (neighbour_ie - cell_ie); const double dke = (neighbour_ke - cell_ke); ie_rhs.x += 2.0 * (dist.x * die) / neighbour_vol; ie_rhs.y += 2.0 * (dist.y * die) / neighbour_vol; ie_rhs.z += 2.0 * (dist.z * die) / neighbour_vol; ke_rhs.x += 2.0 * (dist.x * dke) / neighbour_vol; ke_rhs.y += 2.0 * (dist.y * dke) / neighbour_vol; ke_rhs.z += 2.0 * (dist.z * dke) / neighbour_vol; } // Determine the inverse of the coefficient matrix vec_t inv[3]; calc_3x3_inverse(&coeff, &inv); // Solve for the internal and kinetic energy gradients vec_t grad_ie = { inv[0].x * ie_rhs.x + inv[0].y * ie_rhs.y + inv[0].z * ie_rhs.z, inv[1].x * ie_rhs.x + inv[1].y * ie_rhs.y + inv[1].z * ie_rhs.z, inv[2].x * ie_rhs.x + inv[2].y * ie_rhs.y + inv[2].z * ie_rhs.z}; vec_t grad_ke = { inv[0].x * ke_rhs.x + inv[0].y * ke_rhs.y + inv[0].z * ke_rhs.z, inv[1].x * ke_rhs.x + inv[1].y * ke_rhs.y + inv[1].z * ke_rhs.z, inv[2].x * ke_rhs.x + inv[2].y * ke_rhs.y + inv[2].z * ke_rhs.z}; // Calculate the limiter for the gradient double limiter = 1.0; for (int nn = 0; nn < nnodes_by_cell; ++nn) { const int node_index = cells_to_nodes[(cell_to_nodes_off + nn)]; limiter = min(limiter, calc_cell_limiter(cell_ie, gmax_ie, gmin_ie, &grad_ie, nodes_x[(node_index)], nodes_y[(node_index)], nodes_z[(node_index)], &cell_c)); } // This stops extrema from worsening as part of the gather. Is it // conservative? grad_ie.x *= limiter; grad_ie.y *= limiter; grad_ie.z *= limiter; // Calculate the limiter for the gradient limiter = 1.0; for (int nn = 0; nn < nnodes_by_cell; ++nn) { const int node_index = cells_to_nodes[(cell_to_nodes_off + nn)]; limiter = min(limiter, calc_cell_limiter(cell_ke, gmax_ke, gmin_ke, &grad_ke, nodes_x[(node_index)], nodes_y[(node_index)], nodes_z[(node_index)], &cell_c)); } // This stops extrema from worsening as part of the gather. Is it // conservative? grad_ie.x *= limiter; grad_ie.y *= limiter; grad_ie.z *= limiter; // Subcells are ordered with the nodes on a face for (int nn = 0; nn < nnodes_by_cell; ++nn) { const int subcell_index = cell_to_nodes_off + nn; // Calculate the center of mass distance const double dx = subcell_centroids_x[(subcell_index)] - cell_c.x; const double dy = subcell_centroids_y[(subcell_index)] - cell_c.y; const double dz = subcell_centroids_z[(subcell_index)] - cell_c.z; // Subcell internal and kinetic energy from linear function at cell subcell_ie_mass[(subcell_index)] = subcell_volume[(subcell_index)] * (cell_ie + grad_ie.x * dx + grad_ie.y * dy + grad_ie.z * dz); subcell_ke_mass[(subcell_index)] = subcell_volume[(subcell_index)] * (cell_ke + grad_ke.x * dx + grad_ke.y * dy + grad_ke.z * dz); total_ie_in_subcells += subcell_ie_mass[(subcell_index)]; total_ke_in_subcells += subcell_ke_mass[(subcell_index)]; if (subcell_ie_mass[(subcell_index)] < -EPS || subcell_ke_mass[(subcell_index)] < -EPS) { printf("Negative energy mass %d %.12f %.12f\n", subcell_index, subcell_ie_mass[(subcell_index)], subcell_ke_mass[(subcell_index)]); } } } *initial_mass = total_mass; *initial_ie_mass = total_ie_in_subcells; *initial_ke_mass = total_ke_in_subcells; printf("Total Energy in Cells %.12f\n", total_ie_mass + total_ke_mass); printf("Total Energy in Subcells %.12f\n", total_ie_in_subcells + total_ke_in_subcells); printf("Difference %.12f\n\n", (total_ie_mass + total_ke_mass) - (total_ie_in_subcells + total_ke_in_subcells)); } // Gathers the momentum into the subcells void gather_subcell_momentum( const int nnodes, const double* nodal_volumes, const double* nodal_mass, int* nodes_to_cells, const double* nodes_x, const double* nodes_y, const double* nodes_z, double* velocity_x, double* velocity_y, double* velocity_z, double* subcell_volume, double* cell_centroids_x, double* cell_centroids_y, double* cell_centroids_z, double* subcell_momentum_x, double* subcell_momentum_y, double* subcell_momentum_z, double* subcell_centroids_x, double* subcell_centroids_y, double* subcell_centroids_z, int* nodes_to_cells_offsets, int* cells_to_nodes_offsets, int* cells_to_nodes, int* nodes_to_nodes_offsets, int* nodes_to_nodes, vec_t* initial_momentum) { double initial_momentum_x = 0.0; double initial_momentum_y = 0.0; double initial_momentum_z = 0.0; double total_subcell_vx = 0.0; double total_subcell_vy = 0.0; double total_subcell_vz = 0.0; #pragma omp parallel for reduction(+ : initial_momentum_x, initial_momentum_y, \ initial_momentum_z, total_subcell_vx, \ total_subcell_vy, total_subcell_vz) for (int nn = 0; nn < nnodes; ++nn) { // Calculate the gradient for the nodal momentum vec_t rhsx = {0.0, 0.0, 0.0}; vec_t rhsy = {0.0, 0.0, 0.0}; vec_t rhsz = {0.0, 0.0, 0.0}; vec_t coeff[3] = {{0.0, 0.0, 0.0}}; vec_t gmin = {DBL_MAX, DBL_MAX, DBL_MAX}; vec_t gmax = {-DBL_MAX, -DBL_MAX, -DBL_MAX}; vec_t node = {nodes_x[(nn)], nodes_y[(nn)], nodes_z[(nn)]}; const double nodal_density = nodal_mass[(nn)] / nodal_volumes[(nn)]; vec_t node_mom_density = {nodal_density * velocity_x[(nn)], nodal_density * velocity_y[(nn)], nodal_density * velocity_z[(nn)]}; initial_momentum_x += nodal_mass[(nn)] * velocity_x[(nn)]; initial_momentum_y += nodal_mass[(nn)] * velocity_y[(nn)]; initial_momentum_z += nodal_mass[(nn)] * velocity_z[(nn)]; const int node_to_nodes_off = nodes_to_nodes_offsets[(nn)]; const int nnodes_by_node = nodes_to_nodes_offsets[(nn + 1)] - node_to_nodes_off; for (int nn2 = 0; nn2 < nnodes_by_node; ++nn2) { const int neighbour_index = nodes_to_nodes[(node_to_nodes_off + nn2)]; if (neighbour_index == -1) { continue; } // Calculate the center of mass distance vec_t i = {nodes_x[(neighbour_index)] - node.x, nodes_y[(neighbour_index)] - node.y, nodes_z[(neighbour_index)] - node.z}; // Store the neighbouring cell's contribution to the coefficients double neighbour_vol = nodal_volumes[(neighbour_index)]; coeff[0].x += 2.0 * (i.x * i.x) / (neighbour_vol * neighbour_vol); coeff[0].y += 2.0 * (i.x * i.y) / (neighbour_vol * neighbour_vol); coeff[0].z += 2.0 * (i.x * i.z) / (neighbour_vol * neighbour_vol); coeff[1].x += 2.0 * (i.y * i.x) / (neighbour_vol * neighbour_vol); coeff[1].y += 2.0 * (i.y * i.y) / (neighbour_vol * neighbour_vol); coeff[1].z += 2.0 * (i.y * i.z) / (neighbour_vol * neighbour_vol); coeff[2].x += 2.0 * (i.z * i.x) / (neighbour_vol * neighbour_vol); coeff[2].y += 2.0 * (i.z * i.y) / (neighbour_vol * neighbour_vol); coeff[2].z += 2.0 * (i.z * i.z) / (neighbour_vol * neighbour_vol); const double neighbour_nodal_density = nodal_mass[(neighbour_index)] / nodal_volumes[(neighbour_index)]; vec_t neighbour_mom_density = { neighbour_nodal_density * velocity_x[(neighbour_index)], neighbour_nodal_density * velocity_y[(neighbour_index)], neighbour_nodal_density * velocity_z[(neighbour_index)]}; gmax.x = max(gmax.x, neighbour_mom_density.x); gmin.x = min(gmin.x, neighbour_mom_density.x); gmax.y = max(gmax.y, neighbour_mom_density.y); gmin.y = min(gmin.y, neighbour_mom_density.y); gmax.z = max(gmax.z, neighbour_mom_density.z); gmin.z = min(gmin.z, neighbour_mom_density.z); vec_t dv = {(neighbour_mom_density.x - node_mom_density.x), (neighbour_mom_density.y - node_mom_density.y), (neighbour_mom_density.z - node_mom_density.z)}; rhsx.x += 2.0 * i.x * dv.x / neighbour_vol; rhsx.y += 2.0 * i.y * dv.x / neighbour_vol; rhsx.z += 2.0 * i.z * dv.x / neighbour_vol; rhsy.x += 2.0 * i.x * dv.y / neighbour_vol; rhsy.y += 2.0 * i.y * dv.y / neighbour_vol; rhsy.z += 2.0 * i.z * dv.y / neighbour_vol; rhsz.x += 2.0 * i.x * dv.z / neighbour_vol; rhsz.y += 2.0 * i.y * dv.z / neighbour_vol; rhsz.z += 2.0 * i.z * dv.z / neighbour_vol; } // Determine the inverse of the coefficient matrix vec_t inv[3]; calc_3x3_inverse(&coeff, &inv); // Solve for the velocity density gradients vec_t grad_vx = {inv[0].x * rhsx.x + inv[0].y * rhsx.y + inv[0].z * rhsx.z, inv[1].x * rhsx.x + inv[1].y * rhsx.y + inv[1].z * rhsx.z, inv[2].x * rhsx.x + inv[2].y * rhsx.y + inv[2].z * rhsx.z}; vec_t grad_vy = {inv[0].x * rhsy.x + inv[0].y * rhsy.y + inv[0].z * rhsy.z, inv[1].x * rhsy.x + inv[1].y * rhsy.y + inv[1].z * rhsy.z, inv[2].x * rhsy.x + inv[2].y * rhsy.y + inv[2].z * rhsy.z}; vec_t grad_vz = {inv[0].x * rhsz.x + inv[0].y * rhsz.y + inv[0].z * rhsz.z, inv[1].x * rhsz.x + inv[1].y * rhsz.y + inv[1].z * rhsz.z, inv[2].x * rhsz.x + inv[2].y * rhsz.y + inv[2].z * rhsz.z}; // Limit the gradients double vx_limiter = 1.0; double vy_limiter = 1.0; double vz_limiter = 1.0; const int node_to_cells_off = nodes_to_cells_offsets[(nn)]; const int ncells_by_node = nodes_to_cells_offsets[(nn + 1)] - node_to_cells_off; for (int cc = 0; cc < ncells_by_node; ++cc) { const int cell_index = nodes_to_cells[(node_to_cells_off + cc)]; vec_t cell_c = {cell_centroids_x[(cell_index)], cell_centroids_y[(cell_index)], cell_centroids_z[(cell_index)]}; vx_limiter = min(vx_limiter, calc_cell_limiter(node_mom_density.x, gmax.x, gmin.x, &grad_vx, cell_c.x, cell_c.y, cell_c.z, &node)); vy_limiter = min(vy_limiter, calc_cell_limiter(node_mom_density.y, gmax.y, gmin.y, &grad_vy, cell_c.x, cell_c.y, cell_c.z, &node)); vz_limiter = min(vz_limiter, calc_cell_limiter(node_mom_density.z, gmax.z, gmin.z, &grad_vz, cell_c.x, cell_c.y, cell_c.z, &node)); } // This stops extrema from worsening as part of the gather. Is it // conservative? grad_vx.x *= vx_limiter; grad_vx.y *= vx_limiter; grad_vx.z *= vx_limiter; grad_vy.x *= vy_limiter; grad_vy.y *= vy_limiter; grad_vy.z *= vy_limiter; grad_vz.x *= vz_limiter; grad_vz.y *= vz_limiter; grad_vz.z *= vz_limiter; for (int cc = 0; cc < ncells_by_node; ++cc) { const int cell_index = nodes_to_cells[(node_to_cells_off + cc)]; const int cell_to_nodes_off = cells_to_nodes_offsets[(cell_index)]; const int nnodes_by_cell = cells_to_nodes_offsets[(cell_index + 1)] - cell_to_nodes_off; // Determine the position of the node in the cell int nn2; for (nn2 = 0; nn2 < nnodes_by_cell; ++nn2) { if (cells_to_nodes[(cell_to_nodes_off + nn2)] == nn) { break; } } const int subcell_index = cell_to_nodes_off + nn2; const double vol = subcell_volume[(subcell_index)]; const double dx = subcell_centroids_x[(subcell_index)] - nodes_x[(nn)]; const double dy = subcell_centroids_y[(subcell_index)] - nodes_y[(nn)]; const double dz = subcell_centroids_z[(subcell_index)] - nodes_z[(nn)]; subcell_momentum_x[(subcell_index)] = vol * (node_mom_density.x + grad_vx.x * dx + grad_vx.y * dy + grad_vx.z * dz); subcell_momentum_y[(subcell_index)] = vol * (node_mom_density.y + grad_vy.x * dx + grad_vy.y * dy + grad_vy.z * dz); subcell_momentum_z[(subcell_index)] = vol * (node_mom_density.z + grad_vz.x * dx + grad_vz.y * dy + grad_vz.z * dz); total_subcell_vx += subcell_momentum_x[(subcell_index)]; total_subcell_vy += subcell_momentum_y[(subcell_index)]; total_subcell_vz += subcell_momentum_z[(subcell_index)]; } } initial_momentum->x = total_subcell_vx; initial_momentum->y = total_subcell_vy; initial_momentum->z = total_subcell_vz; printf("Total Momentum in Cells (%.12f,%.12f,%.12f)\n", initial_momentum_x, initial_momentum_y, initial_momentum_z); printf("Total Momentum in Subcells (%.12f,%.12f,%.12f)\n", total_subcell_vx, total_subcell_vy, total_subcell_vz); printf("Difference (%.12f,%.12f,%.12f)\n\n", initial_momentum_x - total_subcell_vx, initial_momentum_y - total_subcell_vy, initial_momentum_z - total_subcell_vz); }

totientRangeParallel.c

// TotientRangePar.c - Parallel Euler Totient Function (C Version) // compile: gcc -Wall -O2 -o TotientRangePar TotientRangePar.c // run: ./TotientRangePar lower_num upper_num num_threads(optional) // Author: Max Kirker Burton 2260452b 13/11/19 // This program calculates the sum of the totients between a lower and an // upper limit using C longs, and can be run with several Goroutines either set as an argument or // as an environment variable // It is based on earlier work by: // Phil Trinder, Nathan Charles, Hans-Wolfgang Loidl and Colin Runciman // The comments provide (executable) Haskell specifications of the functions #include <stdio.h> #include <omp.h> #include <sys/time.h> // hcf x 0 = x // hcf x y = hcf y (rem x y) long hcf(long x, long y) { long t; while (y != 0) { t = x % y; x = y; y = t; } return x; } // relprime x y = hcf x y == 1 int relprime(long x, long y) { return hcf(x, y) == 1; } // euler n = length (filter (relprime n) [1 .. n-1]) long euler(long n) { long length, i; length = 0; for (i = 1; i < n; i++) if (relprime(n, i)) length += 1; return length; } // sumTotient lower upper = sum (map euler [lower, lower+1 .. upper]) long sumTotient(long lower, long upper, int n_threads) { long sum = 0, i; #pragma omp parallel for schedule(guided) reduction(+: sum) num_threads(n_threads) for (i = lower; i <= upper; i++){ sum += euler(i); } return sum; } int main(int argc, char ** argv) { long lower, upper; int num_threads = omp_get_num_threads(); float msec; struct timeval start, stop; if (argc < 3) { printf("fewer than 2 arguments\n"); return 1; } sscanf(argv[1], "%ld", &lower); sscanf(argv[2], "%ld", &upper); if (argc == 4){ sscanf(argv[3], "%d", &num_threads); } gettimeofday(&start, NULL); printf("C: Sum of Totients between [%ld..%ld] is %ld\n", lower, upper, sumTotient(lower, upper, num_threads)); gettimeofday(&stop, NULL); if (stop.tv_usec < start.tv_usec) { stop.tv_usec += 1000000; stop.tv_sec--; } msec = 1000 * (stop.tv_sec - start.tv_sec) + (stop.tv_usec - start.tv_usec) / 1000; printf("%f\n", msec); // Rename to elapsed time: return 0; }

ragf2.c

/* Copyright 2014-2020 The PySCF Developers. All Rights Reserved. Licensed under the Apache License, Version 2.0 (the "License"); you may not use this file except in compliance with the License. You may obtain a copy of the License at http://www.apache.org/licenses/LICENSE-2.0 Unless required by applicable law or agreed to in writing, software distributed under the License is distributed on an "AS IS" BASIS, WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. See the License for the specific language governing permissions and limitations under the License. * * Author: Oliver J. Backhouse <olbackhouse@gmail.com> * Alejandro Santana-Bonilla <alejandro.santana_bonilla@kcl.ac.uk> * George H. Booth <george.booth@kcl.ac.uk> */ #include<stdlib.h> #include<assert.h> #include<math.h> //#include "omp.h" #include "config.h" #include "vhf/fblas.h" /* * b_x = alpha * a_x + beta * b_x */ void AGF2sum_inplace(double *a, double *b, int x, double alpha, double beta) { int i; for (i = 0; i < x; i++) { b[i] *= beta; b[i] += alpha * a[i]; } } /* * b_x = a_x * b_x */ void AGF2prod_inplace(double *a, double *b, int x) { int i; for (i = 0; i < x; i++) { b[i] *= a[i]; } } /* * c_x = a_x * b_x */ void AGF2prod_outplace(double *a, double *b, int x, double *c) { int i; for (i = 0; i < x; i++) { c[i] = a[i] * b[i]; } } /* * b_xz = a_xiz */ void AGF2slice_0i2(double *a, int x, int y, int z, int idx, double *b) { double *pa, *pb; int i, k; for (i = 0; i < x; i++) { pb = b + i*z; pa = a + i*y*z + idx*z; for (k = 0; k < z; k++) { pb[k] = pa[k]; } } } /* * b_xy = a_xyi */ void AGF2slice_01i(double *a, int x, int y, int z, int idx, double *b) { double *pa, *pb; int i, j; for (i = 0; i < x; i++) { pb = b + i*y; pa = a + i*y*z + idx; for (j = 0; j < y; j++) { pb[j] = pa[j*z]; } } } /* * d_xy = a + b_x - c_y */ void AGF2sum_inplace_ener(double a, double *b, double *c, int x, int y, double *d) { double *pd; int i, j; for (i = 0; i < x; i++) { pd = d + i*y; for (j = 0; j < y; j++) { pd[j] = a + b[i] - c[j]; } } } /* * b_xy = a_y * b_xy */ void AGF2prod_inplace_ener(double *a, double *b, int x, int y) { double *pb; int i; for (i = 0; i < x; i++) { pb = b + i*y; AGF2prod_inplace(a, pb, y); } } /* * c_xy = a_y * b_xy */ void AGF2prod_outplace_ener(double *a, double *b, int x, int y, double *c) { double *pb, *pc; int i; for (i = 0; i < x; i++) { pb = b + i*y; pc = c + i*y; AGF2prod_outplace(a, pb, y, pc); } } /* * exact ERI * vv_xy = (xi|ja) [2(yi|ja) - (yj|ia)] * vev_xy = (xi|ja) [2(yi|ja) - (yj|ia)] (ei + ej - ea) */ void AGF2ee_vv_vev_islice(double *xija, double *e_i, double *e_a, double os_factor, double ss_factor, int nmo, int nocc, int nvir, int istart, int iend, double *vv, double *vev) { const double D1 = 1; const char TRANS_T = 'T'; const char TRANS_N = 'N'; const int nja = nocc * nvir; const int nxi = nmo * nocc; const double fpos = os_factor + ss_factor; const double fneg = -1.0 * ss_factor; #pragma omp parallel { double *eja = calloc(nocc*nvir, sizeof(double)); double *xia = calloc(nmo*nocc*nvir, sizeof(double)); double *xja = calloc(nmo*nocc*nvir, sizeof(double)); double *vv_priv = calloc(nmo*nmo, sizeof(double)); double *vev_priv = calloc(nmo*nmo, sizeof(double)); int i; #pragma omp for for (i = istart; i < iend; i++) { // build xija AGF2slice_0i2(xija, nmo, nocc, nja, i, xja); // build xjia AGF2slice_0i2(xija, nxi, nocc, nvir, i, xia); // build eija = ei + ej - ea AGF2sum_inplace_ener(e_i[i], e_i, e_a, nocc, nvir, eja); // inplace xjia = 2 * xija - xjia AGF2sum_inplace(xja, xia, nmo*nja, fpos, fneg); // vv_xy += xija * (2 yija - yjia) dgemm_(&TRANS_T, &TRANS_N, &nmo, &nmo, &nja, &D1, xia, &nja, xja, &nja, &D1, vv_priv, &nmo); // inplace xija = eija * xija AGF2prod_inplace_ener(eja, xja, nmo, nja); // vev_xy += xija * eija * (2 yija - yjia) dgemm_(&TRANS_T, &TRANS_N, &nmo, &nmo, &nja, &D1, xia, &nja, xja, &nja, &D1, vev_priv, &nmo); } free(eja); free(xia); free(xja); #pragma omp critical for (i = 0; i < (nmo*nmo); i++) { vv[i] += vv_priv[i]; vev[i] += vev_priv[i]; } free(vv_priv); free(vev_priv); } } /* * density fitting * (xi|ja) = (xi|Q)(Q|ja) * vv_xy = (xi|ja) [2(yi|ja) - (yj|ia)] * vev_xy = (xi|ja) [2(yi|ja) - (yj|ia)] (ei + ej - ea) */ void AGF2df_vv_vev_islice(double *qxi, double *qja, double *e_i, double *e_a, double os_factor, double ss_factor, int nmo, int nocc, int nvir, int naux, int istart, int iend, double *vv, double *vev) { const double D0 = 0.0; const double D1 = 1.0; const char TRANS_T = 'T'; const char TRANS_N = 'N'; const int nja = nocc * nvir; const int nxi = nmo * nocc; const double fpos = os_factor + ss_factor; const double fneg = -1.0 * ss_factor; #pragma omp parallel { double *qa = calloc(naux*nvir, sizeof(double)); double *qx = calloc(naux*nmo, sizeof(double)); double *eja = calloc(nocc*nvir, sizeof(double)); double *xia = calloc(nmo*nocc*nvir, sizeof(double)); double *xja = calloc(nmo*nocc*nvir, sizeof(double)); double *vv_priv = calloc(nmo*nmo, sizeof(double)); double *vev_priv = calloc(nmo*nmo, sizeof(double)); int i; #pragma omp for for (i = istart; i < iend; i++) { // build qx AGF2slice_01i(qxi, naux, nmo, nocc, i, qx); // build qa AGF2slice_0i2(qja, naux, nocc, nvir, i, qa); // build xija = xq * qja dgemm_(&TRANS_N, &TRANS_T, &nja, &nmo, &naux, &D1, qja, &nja, qx, &nmo, &D0, xja, &nja); // build xjia = xiq * qa dgemm_(&TRANS_N, &TRANS_T, &nvir, &nxi, &naux, &D1, qa, &nvir, qxi, &nxi, &D0, xia, &nvir); //printf("%13.9f %13.9f\n", xja[10], xia[10]); fflush(stdout); // build eija = ei + ej - ea AGF2sum_inplace_ener(e_i[i], e_i, e_a, nocc, nvir, eja); // inplace xjia = 2 * xija - xjia AGF2sum_inplace(xja, xia, nmo*nja, fpos, fneg); // vv_xy += xija * (2 yija - yjia) dgemm_(&TRANS_T, &TRANS_N, &nmo, &nmo, &nja, &D1, xia, &nja, xja, &nja, &D1, vv_priv, &nmo); // inplace xija = eija * xija AGF2prod_inplace_ener(eja, xja, nmo, nja); // vev_xy += xija * eija * (2 yija - yjia) dgemm_(&TRANS_T, &TRANS_N, &nmo, &nmo, &nja, &D1, xia, &nja, xja, &nja, &D1, vev_priv, &nmo); } free(qa); free(qx); free(eja); free(xia); free(xja); #pragma omp critical for (i = 0; i < (nmo*nmo); i++) { vv[i] += vv_priv[i]; vev[i] += vev_priv[i]; } free(vv_priv); free(vev_priv); } } /* * Removes an index from DGEMM and into a for loop to reduce the * thread-private memory overhead, at the cost of serial speed */ void AGF2df_vv_vev_islice_lowmem(double *qxi, double *qja, double *e_i, double *e_a, double os_factor, double ss_factor, int nmo, int nocc, int nvir, int naux, int start, int end, double *vv, double *vev) { const double D0 = 0.0; const double D1 = 1.0; const char TRANS_T = 'T'; const char TRANS_N = 'N'; const int one = 1; const double fpos = os_factor + ss_factor; const double fneg = -1.0 * ss_factor; //#pragma omp parallel //{ // double *xj = calloc(nmo*nocc, sizeof(double)); // double *xi = calloc(nmo*nocc, sizeof(double)); // double *qx = calloc(naux*nmo, sizeof(double)); // double *qj = calloc(naux*nocc, sizeof(double)); // double *ej = calloc(nocc, sizeof(double)); // // double *vv_priv = calloc(nmo*nmo, sizeof(double)); // double *vev_priv = calloc(nmo*nmo, sizeof(double)); // // int i, a, ia; // //#pragma omp for // for (ia = start; ia < end; ia++) { // i = ia / nvir; // a = ia % nvir; // // // build qx // AGF2slice_01i(qxi, naux, nmo, nocc, i, qx); // // // build qj // AGF2slice_01i(qja, naux, nocc, nvir, a, qj); // // // build xj = xq * qj // dgemm_(&TRANS_N, &TRANS_T, &nocc, &nmo, &naux, &D1, qj, &nocc, qx, &nmo, &D0, xj, &nocc); // // // build xi = xiq * q is this slow without incx=1? // dgemv_(&TRANS_N, &nxi, &naux, &D1, qxi, &nxi, &(qja[i*nvir+a]), &nja, &D0, xi, &one); // // // build eija = ei + ej - ea // AGF2sum_inplace_ener(e_i[i], e_i, &(e_a[a]), nocc, one, ej); // // // inplace xi = 2 * xj - xi // AGF2sum_inplace(xi, xj, nxi, fpos, fneg); // // // vv_xy += xj * (2 * yj - yi) // dgemm_(&TRANS_T, &TRANS_N, &nmo, &nmo, &nocc, &D1, xi, &nocc, xj, &nocc, &D1, vv_priv, &nmo); // // // inplace xj = ej * xj // AGF2prod_inplace_ener(ej, xj, nmo, nocc); // // // vev_xy += xj * ej * (2 * yj - yi) // dgemm_(&TRANS_T, &TRANS_N, &nmo, &nmo, &nocc, &D1, xi, &nocc, xj, &nocc, &D1, vev_priv, &nmo); // } // // free(xj); // free(xi); // free(qx); // free(qj); // free(ej); #pragma omp parallel { double *qx_i = calloc(naux*nmo, sizeof(double)); double *qx_j = calloc(naux*nmo, sizeof(double)); double *qa_i = calloc(naux*nvir, sizeof(double)); double *qa_j = calloc(naux*nvir, sizeof(double)); double *xa_i = calloc(nmo*nvir, sizeof(double)); double *xa_j = calloc(nmo*nvir, sizeof(double)); double *ea = calloc(nvir, sizeof(double)); double *vv_priv = calloc(nmo*nmo, sizeof(double)); double *vev_priv = calloc(nmo*nmo, sizeof(double)); int i, j, ij; #pragma omp for for (ij = start; ij < end; ij++) { i = ij / nocc; j = ij % nocc; // build qx_i AGF2slice_01i(qxi, naux, nmo, nocc, i, qx_i); // build qx_j AGF2slice_01i(qxi, naux, nmo, nocc, j, qx_j); // build qa_i AGF2slice_0i2(qja, naux, nocc, nvir, i, qa_i); // build qa_j AGF2slice_0i2(qja, naux, nocc, nvir, j, qa_j); // build xija dgemm_(&TRANS_N, &TRANS_T, &nvir, &nmo, &naux, &D1, qa_i, &nvir, qx_j, &nmo, &D0, xa_i, &nvir); // build xjia dgemm_(&TRANS_N, &TRANS_T, &nvir, &nmo, &naux, &D1, qa_j, &nvir, qx_i, &nmo, &D0, xa_j, &nvir); // build eija = ei + ej - ea AGF2sum_inplace_ener(e_i[i], &(e_i[j]), e_a, one, nvir, ea); // inplace xjia = 2 * xija - xjia AGF2sum_inplace(xa_j, xa_i, nmo*nvir, fpos, fneg); // vv_xy += xija * (2 * yija - yjia) dgemm_(&TRANS_T, &TRANS_N, &nmo, &nmo, &nvir, &D1, xa_j, &nvir, xa_i, &nvir, &D1, vv_priv, &nmo); // inplace xija = eija * xija AGF2prod_inplace_ener(ea, xa_i, nmo, nvir); // vv_xy += xija * (2 * yija - yjia) dgemm_(&TRANS_T, &TRANS_N, &nmo, &nmo, &nvir, &D1, xa_j, &nvir, xa_i, &nvir, &D1, vev_priv, &nmo); } free(qx_i); free(qx_j); free(qa_i); free(qa_j); free(xa_i); free(xa_j); free(ea); #pragma omp critical for (i = 0; i < (nmo*nmo); i++) { vv[i] += vv_priv[i]; vev[i] += vev_priv[i]; } free(vv_priv); free(vev_priv); } }

strlib_akechi.h

#pragma once #ifndef AKECHI_LIB_9f8vy8hhdsh93 #define AKECHI_LIB_9f8vy8hhdsh93 #include <algorithm> #include <iostream> #include <thread> #include <string> #include <vector> #include <map> #include <mutex> #include <unordered_map> #include <set> #include <unordered_set> #include <stack> #include <sstream> #include <fstream> #include <memory> #include <iomanip> #include <functional> #include <experimental/filesystem> #include <array> #include <chrono> namespace akechi_akihide { namespace filesystem = std::experimental::filesystem; class dcout { private: bool ms_isd; public: template<typename tc> dcout& operator<<(tc cmd) { if (ms_isd) { std::cout << cmd << std::flush; } return *this; } void enable() { ms_isd = true; } void disable() { ms_isd = false; } }; extern dcout cout; class CRecTime { private: std::chrono::time_point<std::chrono::high_resolution_clock> t1; std::chrono::time_point<std::chrono::high_resolution_clock> t0; std::chrono::time_point<std::chrono::high_resolution_clock> tt; double mwidth; double vtotal; public: CRecTime() { mwidth = 1000 * 1000; t0 = std::chrono::high_resolution_clock::now(); t1 = std::chrono::high_resolution_clock::now(); vtotal = 0; }; void begin() { t1 = std::chrono::high_resolution_clock::now(); } void end() { tt = std::chrono::high_resolution_clock::now(); vtotal += std::chrono::duration_cast<std::chrono::microseconds>(tt - t1).count(); } double getdiff() { auto diff = tt - t1; double ta = std::chrono::duration_cast<std::chrono::microseconds>(diff).count(); return ta / mwidth; } double gettotal() { auto diff = tt - t0; double ta = std::chrono::duration_cast<std::chrono::microseconds>(diff).count(); return ta / mwidth; } double get_valid_total() { return vtotal / mwidth; } }; inline void parallel_for(int32_t nth, int32_t N, std::function<void(int32_t)> fth) { if (nth < 1) return; if (nth > N) nth = N; #pragma omp parallel for for (int32_t ith = 0; ith < nth; ith++) { int32_t ibegin = N *ith / nth; int32_t iend = N *(ith + 1) / nth; for (int32_t i = ibegin; i < iend; i++) { fth(i); } } } class fstreamE : public std::fstream { //this class is for writing in bigendian order. private: std::vector<char> m_vbuff; public: template<class Tc> void writeB(const Tc &data) { m_vbuff.resize(0); for (size_t i = 1; i <= sizeof(Tc); i++) { m_vbuff.push_back(((const char*)&data)[sizeof(Tc) - i]); } write(m_vbuff.data(), m_vbuff.size()); } template<class Tc> void readB(Tc &data) { m_vbuff.resize(sizeof(Tc)); read(m_vbuff.data(), m_vbuff.size()); for (size_t i = 1; i <= sizeof(Tc); i++) { ((char*)&data)[i - 1] = m_vbuff[sizeof(Tc) - i]; } } template<class Tc> void writeL(const Tc &data) { write((const char*)&data, sizeof(Tc)); } template<class Tc> void readL(Tc &data) { read((char*)&data, sizeof(Tc)); } }; std::string mGetModulePath(std::string path); std::vector<std::string> GetCmdLine(std::string scmd); std::vector<std::string> DirExtFileSplitter(std::string path);//split the path to directory,extention,and filename. corresoponding to both character of '\' and '/' for directory symbol. void strReplace(std::string& str, const std::string& from, const std::string& to); std::vector<std::string> split(const std::string &str, const std::string &delim); //Timer Class. this class enable to run rambda function with given interval [ms]. class CTimer { private: bool is; std::thread th; std::function<void(double)> m_f; double m_interval; public: CTimer(double interval, std::function<void(double)> f)//[s] { is = true; m_interval = interval*1000; m_f = f; th = std::thread([&]() { std::chrono::high_resolution_clock::time_point st = std::chrono::high_resolution_clock::now(); std::chrono::high_resolution_clock::time_point t1 = std::chrono::high_resolution_clock::now(); while (is) { std::this_thread::sleep_for(std::chrono::milliseconds(1)); std::chrono::high_resolution_clock::time_point t2 = std::chrono::high_resolution_clock::now(); double diff = std::chrono::duration_cast<std::chrono::milliseconds>(t2 - t1).count(); if (diff > m_interval) { t1 = t2; double t = std::chrono::duration_cast<std::chrono::milliseconds>(t2 - st).count(); m_f(t/1000); } } }); } ~CTimer() { is = false; if (th.joinable()) { th.join(); } } }; //-----UUID generation class which support 128bit comparesion operation. so this class can be used as key of std contaner. class myUUID { private: static bool m_isseq; static size_t ms_cSequentialID; static std::mutex ms_Mutex; public: static const int uuidlen = 16; static void setDefSeuquential(); static void setDefRandom(); static myUUID GetUUIDv4(); static myUUID GetUUIDSeq(); unsigned char* m_UUIDa() { return (unsigned char*)m_pi64.data(); }; unsigned int* m_pi32() { return (unsigned int*)m_pi64.data(); }; std::array<size_t, 2> m_pi64; static myUUID NULLID; myUUID() { m_pi64[0] = 0; m_pi64[1] = 0; } ~myUUID(); myUUID(const myUUID &obj); const myUUID& operator=(const myUUID& u1); std::string getuuidbyASCII(); std::string getuuidbyASCII_non0pack(); myUUID(std::string str); myUUID(const std::vector<char>& str); myUUID(const std::vector<unsigned char>& str); }; inline bool operator==(const myUUID &id1, const myUUID &id2) { return id1.m_pi64 == id2.m_pi64; } inline bool operator!=(const myUUID &id1, const myUUID &id2) { return id1.m_pi64 != id2.m_pi64; } inline bool operator<(const myUUID &id1, const myUUID &id2) { return id1.m_pi64 < id2.m_pi64; } inline bool operator>(const myUUID &id1, const myUUID &id2) { return id1.m_pi64 > id2.m_pi64; } inline bool operator <= (const myUUID &id1, const myUUID &id2) { return id2.m_pi64 <= id1.m_pi64; } inline bool operator>=(const myUUID &id1, const myUUID &id2) { return id2.m_pi64 >= id1.m_pi64; } class CMT { private: const unsigned int M = 397; const unsigned int MATRIX_A = 0x9908b0dfUL; /* constant vector a */ const unsigned int UPPER_MASK = 0x80000000UL; /* most significant w-r bits */ const unsigned int LOWER_MASK = 0x7fffffffUL; /* least significant r bits */ std::array<unsigned long, 624> mt; /* the array for the state vector */ int mti; /* initializes mt[N] with a seed */ public: CMT(unsigned long s = 91516) { mt[0] = s & 0xffffffffUL; for (mti = 1; mti < mt.size(); mti++) { mt[mti] = (1812433253UL * (mt[mti - 1] ^ (mt[mti - 1] >> 30)) + mti); /* See Knuth TAOCP Vol2. 3rd Ed. P.106 for multiplier. */ /* In the previous versions, MSBs of the seed affect */ /* only MSBs of the array mt[]. */ /* 2002/01/09 modified by Makoto Matsumoto */ mt[mti] &= 0xffffffffUL; /* for >32 bit machines */ } } unsigned long genrand_int32CPU(void) { unsigned long y; static unsigned long mag01[2] = { 0x0UL, MATRIX_A }; /* mag01[x] = x * MATRIX_A for x=0,1 */ if (mti >= mt.size()) { /* generate N words at one time */ int kk; for (kk = 0; kk < mt.size() - M; kk++) { y = (mt[kk] & UPPER_MASK) | (mt[kk + 1] & LOWER_MASK); mt[kk] = mt[kk + M] ^ (y >> 1) ^ mag01[y & 0x1UL]; } for (; kk < mt.size() - 1; kk++) { y = (mt[kk] & UPPER_MASK) | (mt[kk + 1] & LOWER_MASK); mt[kk] = mt[kk + (M - mt.size())] ^ (y >> 1) ^ mag01[y & 0x1UL]; } y = (mt[mt.size() - 1] & UPPER_MASK) | (mt[0] & LOWER_MASK); mt[mt.size() - 1] = mt[M - 1] ^ (y >> 1) ^ mag01[y & 0x1UL]; mti = 0; } y = mt[mti++]; /* Tempering */ y ^= (y >> 11); y ^= (y << 7) & 0x9d2c5680UL; y ^= (y << 15) & 0xefc60000UL; y ^= (y >> 18); return y; } }; template<class Tc> class CInsertOnly { private: Tc* m_v; public: Tc operator=(const Tc& ms) { *m_v = ms; } Tc operator=(Tc&& ms) { *m_v = std::move(ms); } CInsertOnly operator=(const CInsertOnly& ms) = delete; CInsertOnly& operator&() = delete; CInsertOnly(const CInsertOnly& t) = delete; CInsertOnly(CInsertOnly&& t) = delete; CInsertOnly(Tc& t) { m_v = &t; } operator Tc() { return *m_v; } }; class CValueS { public: private: class CValue { protected: public: virtual CValue* CreteCopy() = 0; CValue() { } virtual ~CValue() { } protected: }; class CAUUID final : public CValue { private: public: myUUID m_v; CValue* CreteCopy() override { CAUUID* pn = new CAUUID(); pn->m_v = m_v; return pn; } CAUUID() { } }; class CNumber final : public CValue { private: public: double m_v; CValue* CreteCopy() override { CNumber* pn = new CNumber(); pn->m_v = m_v; return pn; } CNumber() { m_v = 0; } }; class CBool final : public CValue { private: public: bool m_v; CValue* CreteCopy() override { CBool* pn = new CBool(); pn->m_v = m_v; return pn; } CBool() { m_v = false; } bool cbool() { return false; }; }; class CString final : public CValue { private: public: std::string m_v; CValue* CreteCopy() override { CString* pn = new CString(); pn->m_v = m_v; return pn; } CString() { } }; class CNUL final : public CValue { private: public: CValue* CreteCopy() override { CNUL* pn = new CNUL(); return pn; } }; class CEmpty final : public CValue { private: public: CValue* CreteCopy() override { CEmpty* pn = new CEmpty(); return pn; } }; class CObject final : public CValue { private: public: std::map<std::string, CValueS> m_v; CValue* CreteCopy() override { CObject* pn = new CObject(); pn->m_v = m_v; return pn; } }; class CArray final : public CValue { private: public: std::vector<CValueS> m_v; CValue* CreteCopy() override { CArray* pn = new CArray(); pn->m_v = m_v; return pn; } }; std::unique_ptr<CValue> m_p; void Empty_value() { CEmpty* ps = new CEmpty(); m_p.reset(ps); } bool is_empty() { auto& pr = *m_p.get(); return typeid(pr) == typeid(CEmpty); }; public: CValueS() { m_p.reset(new CNUL); } CValueS& operator=(const CValueS& ts) { m_p.reset(ts.m_p->CreteCopy()); return *this; } CValueS& operator=(CValueS&& ts) { m_p = std::move(ts.m_p); ts.m_p.reset(new CNUL); return *this; } CValueS(const CValueS& ts) { m_p.reset(ts.m_p->CreteCopy()); } CValueS(CValueS&& ts) { m_p = std::move(ts.m_p); ts.m_p.reset(new CNUL); } ~CValueS() { } std::string& string_value() { CString* ps; if (!is_string()) { ps = new CString(); m_p.reset(ps); } else { ps = (CString*)m_p.get(); } return ps->m_v; } double& number_value() { CNumber* ps; if (!is_number()) { ps = new CNumber(); m_p.reset(ps); } else { ps = (CNumber*)m_p.get(); } return ps->m_v; } myUUID& UUID_value() { CAUUID* ps; if (!is_uuid()) { ps = new CAUUID(); m_p.reset(ps); } else { ps = (CAUUID*)m_p.get(); } return ps->m_v; } bool& bool_value() { CBool* ps; if (!is_bool()) { ps = new CBool(); m_p.reset(ps); } else { ps = (CBool*)m_p.get(); } return ps->m_v; } void Nul_value() { CNUL* ps = new CNUL(); m_p.reset(ps); } std::map<std::string, CValueS>& object_items() { CObject* ps; if (!is_object()) { ps = new CObject(); m_p.reset(ps); } else { ps = (CObject*)m_p.get(); } return ps->m_v; } std::vector<CValueS>& array_items() { CArray* ps; if (!is_array()) { ps = new CArray(); m_p.reset(ps); } else { ps = (CArray*)m_p.get(); } return ps->m_v; } bool is_string() { auto& pr = *m_p.get(); return typeid(pr) == typeid(CString); }; bool is_number() { auto& pr = *m_p.get(); return typeid(pr) == typeid(CNumber); }; bool is_nul() { auto& pr = *m_p.get(); return typeid(pr) == typeid(CNUL); }; bool is_object() { auto& pr = *m_p.get(); return typeid(pr) == typeid(CObject); }; bool is_bool() { auto& pr = *m_p.get(); return typeid(pr) == typeid(CBool); }; bool is_array() { auto& pr = *m_p.get(); return typeid(pr) == typeid(CArray); }; bool is_uuid() { auto& pr = *m_p.get(); return typeid(pr) == typeid(CAUUID); }; void push_back(const CValueS& a) { CArray* ps; if (!is_array()) { ps = new CArray(); m_p.reset(ps); } else { ps = (CArray*)m_p.get(); } ps->m_v.push_back(a); } void push_back(CValueS&& a) { CArray* ps; if (!is_array()) { ps = new CArray(); m_p.reset(ps); } else { ps = (CArray*)m_p.get(); } ps->m_v.push_back(std::move(a)); } CValueS& push_back() { CArray* ps; if (!is_array()) { ps = new CArray(); m_p.reset(ps); } else { ps = (CArray*)m_p.get(); } ps->m_v.push_back(CValueS()); return ps->m_v.back(); } CValueS& operator [](const std::string& s) { CObject* ps; if (!is_object()) { ps = new CObject(); m_p.reset(ps); } else { ps = (CObject*)m_p.get(); } return ps->m_v[s]; } CValueS& operator [](size_t i) { CArray* ps; if (!is_array()) { ps = new CArray(); m_p.reset(ps); } else { ps = (CArray*)m_p.get(); } if (ps->m_v.size() <= i) { ps->m_v.resize(i + 1); } return ps->m_v[i]; } bool write_json(std::string& str, std::string& err); bool read_json(std::string str, std::string& err); void read_CSV_comma(std::string str); void read_CSV_semicolon(std::string str); bool read_json_file(std::string fname, std::string& err) { std::fstream fs; fs.open(fname, std::ios::in | std::ios::binary); if (!fs.is_open()) { err = "cannot open the file :" + fname; return false; } std::vector<char> dat(filesystem::file_size(fname)); fs.read(dat.data(), dat.size()); fs.close(); dat.push_back(0); return this->read_json(dat.data(), err); } bool read_CSV_file_comma(std::string fname, std::string& err) { std::fstream fs; fs.open(fname, std::ios::in | std::ios::binary); if (!fs.is_open()) { err = "cannot open the file :" + fname; return false; } std::vector<char> dat(filesystem::file_size(fname)); fs.read(dat.data(), dat.size()); fs.close(); dat.push_back(0); this->read_CSV_comma(dat.data()); return true; } bool read_CSV_file_semicolon(std::string fname, std::string& err) { std::fstream fs; fs.open(fname, std::ios::in | std::ios::binary); if (!fs.is_open()) { err = "cannot open the file :" + fname; return false; } std::vector<char> dat(filesystem::file_size(fname)); fs.read(dat.data(), dat.size()); fs.close(); dat.push_back(0); this->read_CSV_semicolon(dat.data()); return true; } bool write_json_file(std::string path, std::string& err) { std::fstream fs; std::string str; fs.open(path, std::ios::out | std::ios::binary); if (!fs.is_open()) { err = "cannot open the file :" + path; return false; } write_json(str, err); fs << str; return true; } }; class KATO { //this class can deal with csv formated time depedent result data. std::vector<std::pair<std::string, std::vector<akechi_akihide::CValueS>>> m_mapvalue; public: KATO(std::vector<std::string> vnames) { for (auto& it : vnames) { m_mapvalue.push_back(std::make_pair(it, std::vector<akechi_akihide::CValueS>())); } } void addNext(const std::function<akechi_akihide::CValueS(std::string)> &f) { for (auto& itv : m_mapvalue) { itv.second.push_back(std::move(f(itv.first))); } } void OutPut(std::string filepath) { if (m_mapvalue.begin() == m_mapvalue.end()) { return; } std::fstream fs; std::experimental::filesystem::path p2 = filepath; for (int i = 0; i < 100; i++) { std::experimental::filesystem::path p3; if (i == 0) { p3 = p2; } else { p3 = p2.parent_path() / std::experimental::filesystem::path(p2.stem().string() + std::to_string(i - 1) + p2.extension().string()); } fs.open(p3, std::ios::binary | std::ios::out); if (fs.is_open()) { std::cout << p3 << "\n"; break; } } for (auto& itv : m_mapvalue) { fs << "\"" << itv.first << "\","; } fs << "\r\n"; int64_t cs = m_mapvalue.begin()->second.size() ; for (int64_t c=0; c< cs; c++) { for (auto& itv : m_mapvalue) { fs << itv.second[c].number_value() << ","; } fs << "\r\n"; } } }; } #endif

op_openmp4_rt_support.c

// // header files // #include <math.h> #include <stdio.h> #include <stdlib.h> #include <string.h> #include <omp.h> #include <op_lib_c.h> #include <op_lib_core.h> #include <op_rt_support.h> // // routines to move arrays to/from GPU device // void op_mvHostToDevice(void **map, int size) { if (!OP_hybrid_gpu) return; char *temp = (char*)*map; #pragma omp target enter data map(to: temp[:size]) #pragma omp target update to(temp[:size]) //TODO test } void op_cpHostToDevice(void **data_d, void **data_h, int size) { if (!OP_hybrid_gpu) return; *data_d = (char*)op_malloc(size); memcpy(*data_d, *data_h, size); char *tmp = (char *)*data_d; //TODO jo igy? decl miatt kell az enter data elm. #pragma omp target enter data map(to: tmp[:size]) #pragma omp target update to(tmp[:size]) } op_plan *op_plan_get(char const *name, op_set set, int part_size, int nargs, op_arg *args, int ninds, int *inds) { return op_plan_get_stage(name, set, part_size, nargs, args, ninds, inds, OP_STAGE_ALL); } op_plan *op_plan_get_stage(char const *name, op_set set, int part_size, int nargs, op_arg *args, int ninds, int *inds, int staging) { return op_plan_get_stage_upload(name, set, part_size, nargs, args, ninds, inds, staging, 1); } op_plan *op_plan_get_stage_upload(char const *name, op_set set, int part_size, int nargs, op_arg *args, int ninds, int *inds, int staging, int upload) { op_plan *plan = op_plan_core(name, set, part_size, nargs, args, ninds, inds, staging); if (!OP_hybrid_gpu || !upload) return plan; int set_size = set->size; for (int i = 0; i < nargs; i++) { if (args[i].idx != -1 && args[i].acc != OP_READ) { set_size += set->exec_size; break; } } if (plan->count == 1) { int *offsets = (int *)malloc((plan->ninds_staged + 1) * sizeof(int)); offsets[0] = 0; for (int m = 0; m < plan->ninds_staged; m++) { int count = 0; for (int m2 = 0; m2 < nargs; m2++) if (plan->inds_staged[m2] == m) count++; offsets[m + 1] = offsets[m] + count; } op_mvHostToDevice((void **)&(plan->ind_map), offsets[plan->ninds_staged] * set_size * sizeof(int)); for (int m = 0; m < plan->ninds_staged; m++) { plan->ind_maps[m] = &plan->ind_map[set_size * offsets[m]]; } free(offsets); int counter = 0; for (int m = 0; m < nargs; m++) if (plan->loc_maps[m] != NULL) counter++; op_mvHostToDevice((void **)&(plan->loc_map), sizeof(short) * counter * set_size); counter = 0; for (int m = 0; m < nargs; m++) if (plan->loc_maps[m] != NULL) { plan->loc_maps[m] = &plan->loc_map[set_size * counter]; counter++; } op_mvHostToDevice((void **)&(plan->ind_sizes), sizeof(int) * plan->nblocks * plan->ninds_staged); op_mvHostToDevice((void **)&(plan->ind_offs), sizeof(int) * plan->nblocks * plan->ninds_staged); op_mvHostToDevice((void **)&(plan->nthrcol), sizeof(int) * plan->nblocks); op_mvHostToDevice((void **)&(plan->thrcol), sizeof(int) * set_size); op_mvHostToDevice((void **)&(plan->col_reord), sizeof(int) * set_size); op_mvHostToDevice((void **)&(plan->offset), sizeof(int) * plan->nblocks); plan->offset_d = plan->offset; op_mvHostToDevice((void **)&(plan->nelems), sizeof(int) * plan->nblocks); plan->nelems_d = plan->nelems; op_mvHostToDevice((void **)&(plan->blkmap), sizeof(int) * plan->nblocks); plan->blkmap_d = plan->blkmap; } return plan; } void op_cuda_exit() { if (!OP_hybrid_gpu) return; op_dat_entry *item; TAILQ_FOREACH(item, &OP_dat_list, entries) { #pragma omp target exit data map(from: (item->dat)->data_d) free((item->dat)->data_d); } /* for (int ip = 0; ip < OP_plan_index; ip++) { OP_plans[ip].ind_map = NULL; OP_plans[ip].loc_map = NULL; OP_plans[ip].ind_sizes = NULL; OP_plans[ip].ind_offs = NULL; OP_plans[ip].nthrcol = NULL; OP_plans[ip].thrcol = NULL; OP_plans[ip].col_reord = NULL; OP_plans[ip].offset = NULL; OP_plans[ip].nelems = NULL; OP_plans[ip].blkmap = NULL; } */ // cudaDeviceReset ( ); } // // routines to resize constant/reduct arrays, if necessary // void reallocConstArrays(int consts_bytes) { (void) consts_bytes; } void reallocReductArrays(int reduct_bytes) { (void) reduct_bytes; } // // routines to move constant/reduct arrays // void mvConstArraysToDevice(int consts_bytes) { (void) consts_bytes; } void mvReductArraysToDevice(int reduct_bytes) { (void) reduct_bytes; } void mvReductArraysToHost(int reduct_bytes) { (void) reduct_bytes; } // // routine to fetch data from GPU to CPU (with transposing SoA to AoS if needed) // void op_cuda_get_data(op_dat dat) { if (!OP_hybrid_gpu) return; if (dat->dirty_hd == 2) dat->dirty_hd = 0; else return; #pragma omp target update from(dat->data_d[:dat->size * dat->set->size]) // transpose data if (strstr(dat->type, ":soa") != NULL || (OP_auto_soa && dat->dim > 1)) { int element_size = dat->size / dat->dim; for (int i = 0; i < dat->dim; i++) { for (int j = 0; j < dat->set->size; j++) { for (int c = 0; c < element_size; c++) { dat->data[dat->size * j + element_size * i + c] = dat->data_d[element_size * i * dat->set->size + element_size * j + c]; } } } } else { memcpy(dat->data,dat->data_d,dat->size * dat->set->size); } } void deviceSync() { // cutilSafeCall(cudaDeviceSynchronize()); } #ifndef OPMPI void cutilDeviceInit(int argc, char **argv) { (void)argc; (void)argv; // copy one scalar to initialize OpenMP env. // Improvement: later we can set default device. int tmp=0; #pragma omp target enter data map(to:tmp) OP_hybrid_gpu = 1; } void op_upload_dat(op_dat dat) { if (!OP_hybrid_gpu) return; int set_size = dat->set->size; if (strstr(dat->type, ":soa") != NULL || (OP_auto_soa && dat->dim > 1)) { int element_size = dat->size / dat->dim; for (int i = 0; i < dat->dim; i++) { for (int j = 0; j < set_size; j++) { for (int c = 0; c < element_size; c++) { dat->data_d[element_size * i * set_size + element_size * j + c] = dat->data[dat->size * j + element_size * i + c]; } } } } else { memcpy(dat->data_d,dat->data,dat->size * dat->set->size); } #pragma omp target update to(dat->data_d[:set_size*dat->size]) } void op_download_dat(op_dat dat) { if (!OP_hybrid_gpu) return; #pragma omp target update from(dat->data_d[:dat->size * dat->set->size]) int set_size = dat->set->size; if (strstr(dat->type, ":soa") != NULL || (OP_auto_soa && dat->dim > 1)) { int element_size = dat->size / dat->dim; for (int i = 0; i < dat->dim; i++) { for (int j = 0; j < set_size; j++) { for (int c = 0; c < element_size; c++) { dat->data[dat->size * j + element_size * i + c] = dat->data_d[element_size * i * set_size + element_size * j + c]; } } } } else { memcpy(dat->data,dat->data_d,dat->size * dat->set->size); } } int op_mpi_halo_exchanges(op_set set, int nargs, op_arg *args) { //TODO itt a download + dirty allitas ekv egy getdata hivassal for (int n = 0; n < nargs; n++) if (args[n].opt && args[n].argtype == OP_ARG_DAT && args[n].dat->dirty_hd == 2) { op_download_dat(args[n].dat); args[n].dat->dirty_hd = 0; } return set->size; } void op_mpi_set_dirtybit(int nargs, op_arg *args) { for (int n = 0; n < nargs; n++) { if ((args[n].opt == 1) && (args[n].argtype == OP_ARG_DAT) && (args[n].acc == OP_INC || args[n].acc == OP_WRITE || args[n].acc == OP_RW)) { args[n].dat->dirty_hd = 1; } } } int op_mpi_halo_exchanges_cuda(op_set set, int nargs, op_arg *args) { for (int n = 0; n < nargs; n++) if (args[n].opt && args[n].argtype == OP_ARG_DAT && args[n].dat->dirty_hd == 1) { op_upload_dat(args[n].dat); args[n].dat->dirty_hd = 0; } return set->size; } void op_mpi_set_dirtybit_cuda(int nargs, op_arg *args) { for (int n = 0; n < nargs; n++) { if ((args[n].opt == 1) && (args[n].argtype == OP_ARG_DAT) && (args[n].acc == OP_INC || args[n].acc == OP_WRITE || args[n].acc == OP_RW)) { args[n].dat->dirty_hd = 2; } } } void op_mpi_wait_all(int nargs, op_arg *args) { (void)nargs; (void)args; } void op_mpi_wait_all_cuda(int nargs, op_arg *args) { (void)nargs; (void)args; } void op_mpi_reset_halos(int nargs, op_arg *args) { (void)nargs; (void)args; } void op_mpi_barrier() {} void *op_mpi_perf_time(const char *name, double time) { (void)name; (void)time; return (void *)name; } #ifdef COMM_PERF void op_mpi_perf_comms(void *k_i, int nargs, op_arg *args) { (void)k_i; (void)nargs; (void)args; } #endif void op_mpi_reduce_float(op_arg *args, float *data) { (void)args; (void)data; } void op_mpi_reduce_double(op_arg *args, double *data) { (void)args; (void)data; } void op_mpi_reduce_int(op_arg *args, int *data) { (void)args; (void)data; } void op_mpi_reduce_bool(op_arg *args, bool *data) { (void)args; (void)data; } void op_partition(const char *lib_name, const char *lib_routine, op_set prime_set, op_map prime_map, op_dat coords) { (void)lib_name; (void)lib_routine; (void)prime_set; (void)prime_map; (void)coords; } void op_partition_reverse() {} void op_compute_moment(double t, double *first, double *second) { *first = t; *second = t * t; } void op_compute_moment_across_times(double* times, int ntimes, bool ignore_zeros, double *first, double *second) { *first = 0.0; *second = 0.0f; int n = 0; for (int i=0; i<ntimes; i++) { if (ignore_zeros && (times[i] == 0.0f)) { continue; } *first += times[i]; *second += times[i] * times[i]; n++; } if (n != 0) { *first /= (double)n; *second /= (double)n; } } int op_is_root() { return 1; } #endif

dihedral.c

#include <stdio.h> #include <math.h> inline void crossProduct3(double a[], const double b[], const double c[]) { //Calculate the cross product between length-three vectors b and c, storing //the result in a (a)[0] = (b)[1] * (c)[2] - (c)[1] * (b)[2]; (a)[1] = (b)[2] * (c)[0] - (c)[2] * (b)[0]; (a)[2] = (b)[0] * (c)[1] - (c)[0] * (b)[1]; } inline double dotProduct3(const double b[], const double c[]) { //Calculate the dot product between length-three vectors b and c return b[0] * c[0] + b[1] * c[1] + b[2] * c[2]; } double dihedral(const double *x0, const double *x1, const double *x2, const double *x3) { //Calculate the signed dihedral angle between four points. //Result in radians //x0, x1, x2, x3 should be length three arrays int i; double b1[3], b2[3], b3[3], c1[3], c2[3]; double arg1, arg2, b2_norm; for (i = 0; i < 3; i++) { b1[i] = x1[i] - x0[i]; b2[i] = x2[i] - x1[i]; b3[i] = x3[i] - x2[i]; } crossProduct3(c1, b2, b3); crossProduct3(c2, b1, b2); arg1 = dotProduct3(b1, c1); b2_norm = sqrt(dotProduct3(b2, b2)); arg1 = arg1 * b2_norm; arg2 = dotProduct3(c2, c1); return atan2(arg1, arg2); } void dihedrals_from_traj(double *results, const double *xyzlist, const long *quartets, int traj_length, int num_atoms, int num_quartets) { // results is a 2D array (traj_length x num_quartets). xyzlist is a 3D // array (traj_length x num_atoms x 3). quartets is a 2D array (num_quartets // x 4) where each row is the four atomindices of the atoms to calculate the // dihedral angle between // results are storted in the results array int i,j,k; long e[4] = {0,0,0,0}; double *x[4] = {0,0,0,0}; double *result_ptr; #pragma omp parallel for default(none) shared(results, xyzlist, quartets, traj_length, num_atoms, num_quartets) private(j, k, e, x, result_ptr) for (i = 0; i < traj_length; i++) { for (j = 0; j < num_quartets; j++) { for (k = 0; k < 4; k++) { e[k] = quartets[4*j + k]; x[k] = xyzlist + i*num_atoms*3 + e[k]*3; } /*printf("i: %d -- j %d\n", i, j); printf("first %f", *(xyzlist + i * traj_length*3 + 4*3)); printf("e -- %d %d %d %d\n", e[0], e[1], e[2], e[3]); printf("x0: %f\n", *(x[0])); printf("x1: %f\n", *(x[1])); printf("x2: %f\n", *(x[2])); printf("Calculated %f\n", dihedral(x[0], x[1], x[2], x[3]));*/ result_ptr = results + i * num_quartets + j; *result_ptr = dihedral(x[0], x[1], x[2], x[3]); } } } /* Another version of the code that uses floats instead of doubles */ inline void crossProduct3_float(float a[], const float b[], const float c[]) { //Calculate the cross product between length-three vectors b and c, storing //the result in a (a)[0] = (b)[1] * (c)[2] - (c)[1] * (b)[2]; (a)[1] = (b)[2] * (c)[0] - (c)[2] * (b)[0]; (a)[2] = (b)[0] * (c)[1] - (c)[0] * (b)[1]; } inline double dotProduct3_float(const float b[], const float c[]) { //Calculate the dot product between length-three vectors b and c return b[0] * c[0] + b[1] * c[1] + b[2] * c[2]; } double dihedral_float(const float *x0, const float *x1, const float *x2, const float *x3) { //Calculate the signed dihedral angle between four points. //Result in radians //x0, x1, x2, x3 should be length three arrays int i; float b1[3], b2[3], b3[3], c1[3], c2[3]; float arg1, arg2, b2_norm; for (i = 0; i < 3; i++) { b1[i] = x1[i] - x0[i]; b2[i] = x2[i] - x1[i]; b3[i] = x3[i] - x2[i]; } crossProduct3_float(c1, b2, b3); crossProduct3_float(c2, b1, b2); arg1 = dotProduct3_float(b1, c1); b2_norm = sqrt(dotProduct3_float(b2, b2)); arg1 = arg1 * b2_norm; arg2 = dotProduct3_float(c2, c1); return atan2(arg1, arg2); } void dihedrals_from_traj_float(float *results, const float *xyzlist, const long *quartets, int traj_length, int num_atoms, int num_quartets) { // results is a 2D array (traj_length x num_quartets). xyzlist is a 3D // array (traj_length x num_atoms x 3). quartets is a 2D array (num_quartets // x 4) where each row is the four atomindices of the atoms to calculate the // dihedral angle between // results are storted in the results array int i,j,k; long e[4] = {0,0,0,0}; float *x[4] = {0,0,0,0}; float *result_ptr; #pragma omp parallel for default(none) shared(results, xyzlist, quartets, traj_length, num_atoms, num_quartets) private(j, k, e, x, result_ptr) for (i = 0; i < traj_length; i++) { for (j = 0; j < num_quartets; j++) { for (k = 0; k < 4; k++) { e[k] = quartets[4*j + k]; x[k] = xyzlist + i*num_atoms*3 + e[k]*3; } /*printf("i: %d -- j %d\n", i, j); printf("first %f", *(xyzlist + i * traj_length*3 + 4*3)); printf("e -- %d %d %d %d\n", e[0], e[1], e[2], e[3]); printf("x0: %f\n", *(x[0])); printf("x1: %f\n", *(x[1])); printf("x2: %f\n", *(x[2])); printf("Calculated %f\n", dihedral(x[0], x[1], x[2], x[3]));*/ result_ptr = results + i * num_quartets + j; *result_ptr = dihedral_float(x[0], x[1], x[2], x[3]); } } }

cvAdvDiff_bnd_omp.c

/* ----------------------------------------------------------------- * Programmer(s): Daniel Reynolds and Ting Yan @ SMU * Based on cvAdvDiff_bnd.c and parallelized with OpenMP * ----------------------------------------------------------------- * SUNDIALS Copyright Start * Copyright (c) 2002-2020, Lawrence Livermore National Security * and Southern Methodist University. * All rights reserved. * * See the top-level LICENSE and NOTICE files for details. * * SPDX-License-Identifier: BSD-3-Clause * SUNDIALS Copyright End * ----------------------------------------------------------------- * Example problem: * * The following is a simple example problem with a banded Jacobian, * solved using CVODE. * The problem is the semi-discrete form of the advection-diffusion * equation in 2-D: * du/dt = d^2 u / dx^2 + .5 du/dx + d^2 u / dy^2 * on the rectangle 0 <= x <= 2, 0 <= y <= 1, and the time * interval 0 <= t <= 1. Homogeneous Dirichlet boundary conditions * are posed, and the initial condition is * u(x,y,t=0) = x(2-x)y(1-y)exp(5xy). * The PDE is discretized on a uniform MX+2 by MY+2 grid with * central differencing, and with boundary values eliminated, * leaving an ODE system of size NEQ = MX*MY. * This program solves the problem with the BDF method, Newton * iteration with the SUNBAND linear solver, and a user-supplied * Jacobian routine. * It uses scalar relative and absolute tolerances. * Output is printed at t = .1, .2, ..., 1. * Run statistics (optional outputs) are printed at the end. * * Optionally, we can set the number of threads from environment * variable or command line. To check the current value for number * of threads from environment: * % echo $OMP_NUM_THREADS * * Execution: * * To use the default value or the number of threads from the * environment value, run without arguments: * % ./cvAdvDiff_bnd_omp * The environment variable can be over-ridden with a command line * argument specifying the number of threads to use, e.g: * % ./cvAdvDiff_bnd_omp 5 * ----------------------------------------------------------------- */ #include <stdio.h> #include <stdlib.h> #include <math.h> /* Header files with a description of contents */ #include <cvode/cvode.h> /* prototypes for CVODE fcts., consts. */ #include <nvector/nvector_openmp.h> /* serial N_Vector types, fcts., macros */ #include <sunmatrix/sunmatrix_band.h> /* access to band SUNMatrix */ #include <sunlinsol/sunlinsol_band.h> /* access to band SUNLinearSolver */ #include <sundials/sundials_types.h> /* definition of type realtype */ #ifdef _OPENMP #include <omp.h> #endif /* Problem Constants */ #define XMAX RCONST(2.0) /* domain boundaries */ #define YMAX RCONST(1.0) #define MX 10 /* mesh dimensions */ #define MY 5 #define NEQ MX*MY /* number of equations */ #define ATOL RCONST(1.0e-5) /* scalar absolute tolerance */ #define T0 RCONST(0.0) /* initial time */ #define T1 RCONST(0.1) /* first output time */ #define DTOUT RCONST(0.1) /* output time increment */ #define NOUT 10 /* number of output times */ #define ZERO RCONST(0.0) #define HALF RCONST(0.5) #define ONE RCONST(1.0) #define TWO RCONST(2.0) #define FIVE RCONST(5.0) /* User-defined vector access macro IJth */ /* IJth is defined in order to isolate the translation from the mathematical 2-dimensional structure of the dependent variable vector to the underlying 1-dimensional storage. IJth(vdata,i,j) references the element in the vdata array for u at mesh point (i,j), where 1 <= i <= MX, 1 <= j <= MY. The vdata array is obtained via the macro call vdata = NV_DATA_S(v), where v is an N_Vector. The variables are ordered by the y index j, then by the x index i. */ #define IJth(vdata,i,j) (vdata[(j-1) + (i-1)*MY]) /* Type : UserData (contains grid constants) */ typedef struct { realtype dx, dy, hdcoef, hacoef, vdcoef; int nthreads; } *UserData; /* Private Helper Functions */ static void SetIC(N_Vector u, UserData data); static void PrintHeader(realtype reltol, realtype abstol, realtype umax); static void PrintOutput(realtype t, realtype umax, long int nst); static void PrintFinalStats(void *cvode_mem); /* Private function to check function return values */ static int check_retval(void *returnvalue, const char *funcname, int opt); /* Functions Called by the Solver */ static int f(realtype t, N_Vector u, N_Vector udot, void *user_data); static int Jac(realtype t, N_Vector u, N_Vector fu, SUNMatrix J, void *user_data, N_Vector tmp1, N_Vector tmp2, N_Vector tmp3); /* *------------------------------- * Main Program *------------------------------- */ int main(int argc, char *argv[]) { realtype dx, dy, reltol, abstol, t, tout, umax; N_Vector u; UserData data; SUNMatrix A; SUNLinearSolver LS; void *cvode_mem; int iout, retval; long int nst; int num_threads; u = NULL; data = NULL; A = NULL; LS = NULL; cvode_mem = NULL; /* Set the number of threads to use */ num_threads = 1; /* default value */ #ifdef _OPENMP num_threads = omp_get_max_threads(); /* Overwrite with OMP_NUM_THREADS environment variable */ #endif if (argc > 1) /* overwrite with command line value, if supplied */ num_threads = (int) strtol(argv[1], NULL, 0); /* Create an OpenMP vector */ u = N_VNew_OpenMP(NEQ, num_threads); /* Allocate u vector */ if(check_retval((void*)u, "N_VNew_OpenMP", 0)) return(1); reltol = ZERO; /* Set the tolerances */ abstol = ATOL; data = (UserData) malloc(sizeof *data); /* Allocate data memory */ if(check_retval((void *)data, "malloc", 2)) return(1); dx = data->dx = XMAX/(MX+1); /* Set grid coefficients in data */ dy = data->dy = YMAX/(MY+1); data->hdcoef = ONE/(dx*dx); data->hacoef = HALF/(TWO*dx); data->vdcoef = ONE/(dy*dy); data->nthreads = num_threads; SetIC(u, data); /* Initialize u vector */ /* Call CVodeCreate to create the solver memory and specify the * Backward Differentiation Formula */ cvode_mem = CVodeCreate(CV_BDF); if(check_retval((void *)cvode_mem, "CVodeCreate", 0)) return(1); /* Call CVodeInit to initialize the integrator memory and specify the * user's right hand side function in u'=f(t,u), the inital time T0, and * the initial dependent variable vector u. */ retval = CVodeInit(cvode_mem, f, T0, u); if(check_retval(&retval, "CVodeInit", 1)) return(1); /* Call CVodeSStolerances to specify the scalar relative tolerance * and scalar absolute tolerance */ retval = CVodeSStolerances(cvode_mem, reltol, abstol); if (check_retval(&retval, "CVodeSStolerances", 1)) return(1); /* Set the pointer to user-defined data */ retval = CVodeSetUserData(cvode_mem, data); if(check_retval(&retval, "CVodeSetUserData", 1)) return(1); /* Create banded SUNMatrix for use in linear solves -- since this will be factored, set the storage bandwidth to be the sum of upper and lower bandwidths */ A = SUNBandMatrix(NEQ, MY, MY); if(check_retval((void *)A, "SUNBandMatrix", 0)) return(1); /* Create banded SUNLinearSolver object for use by CVode */ LS = SUNLinSol_Band(u, A); if(check_retval((void *)LS, "SUNLinSol_Band", 0)) return(1); /* Call CVodeSetLinearSolver to attach the matrix and linear solver to CVode */ retval = CVodeSetLinearSolver(cvode_mem, LS, A); if(check_retval(&retval, "CVodeSetLinearSolver", 1)) return(1); /* Set the user-supplied Jacobian routine Jac */ retval = CVodeSetJacFn(cvode_mem, Jac); if(check_retval(&retval, "CVodeSetJacFn", 1)) return(1); /* In loop over output points: call CVode, print results, test for errors */ umax = N_VMaxNorm(u); PrintHeader(reltol, abstol, umax); for(iout=1, tout=T1; iout <= NOUT; iout++, tout += DTOUT) { retval = CVode(cvode_mem, tout, u, &t, CV_NORMAL); if(check_retval(&retval, "CVode", 1)) break; umax = N_VMaxNorm(u); retval = CVodeGetNumSteps(cvode_mem, &nst); check_retval(&retval, "CVodeGetNumSteps", 1); PrintOutput(t, umax, nst); } PrintFinalStats(cvode_mem); /* Print some final statistics */ printf("num_threads = %i\n\n", num_threads); N_VDestroy(u); /* Free the u vector */ CVodeFree(&cvode_mem); /* Free the integrator memory */ SUNLinSolFree(LS); /* Free the linear solver memory */ SUNMatDestroy(A); /* Free the matrix memory */ free(data); /* Free the user data */ return(0); } /* *------------------------------- * Functions called by the solver *------------------------------- */ /* f routine. Compute f(t,u). */ static int f(realtype t, N_Vector u,N_Vector udot, void *user_data) { realtype uij, udn, uup, ult, urt, hordc, horac, verdc, hdiff, hadv, vdiff; realtype *udata, *dudata; sunindextype i, j; UserData data; i = j = 0; udata = NV_DATA_OMP(u); dudata = NV_DATA_OMP(udot); /* Extract needed constants from data */ data = (UserData) user_data; hordc = data->hdcoef; horac = data->hacoef; verdc = data->vdcoef; /* Loop over all grid points. */ #pragma omp parallel for default(shared) private(j, i, uij, udn, uup, ult, urt, hdiff, hadv, vdiff) num_threads(data->nthreads) for (j=1; j <= MY; j++) { for (i=1; i <= MX; i++) { /* Extract u at x_i, y_j and four neighboring points */ uij = IJth(udata, i, j); udn = (j == 1) ? ZERO : IJth(udata, i, j-1); uup = (j == MY) ? ZERO : IJth(udata, i, j+1); ult = (i == 1) ? ZERO : IJth(udata, i-1, j); urt = (i == MX) ? ZERO : IJth(udata, i+1, j); /* Set diffusion and advection terms and load into udot */ hdiff = hordc*(ult - TWO*uij + urt); hadv = horac*(urt - ult); vdiff = verdc*(uup - TWO*uij + udn); IJth(dudata, i, j) = hdiff + hadv + vdiff; } } return(0); } /* Jacobian routine. Compute J(t,u). */ static int Jac(realtype t, N_Vector u, N_Vector fu, SUNMatrix J, void *user_data, N_Vector tmp1, N_Vector tmp2, N_Vector tmp3) { sunindextype i, j, k; realtype *kthCol, hordc, horac, verdc; UserData data; /* The components of f = udot that depend on u(i,j) are f(i,j), f(i-1,j), f(i+1,j), f(i,j-1), f(i,j+1), with df(i,j)/du(i,j) = -2 (1/dx^2 + 1/dy^2) df(i-1,j)/du(i,j) = 1/dx^2 + .25/dx (if i > 1) df(i+1,j)/du(i,j) = 1/dx^2 - .25/dx (if i < MX) df(i,j-1)/du(i,j) = 1/dy^2 (if j > 1) df(i,j+1)/du(i,j) = 1/dy^2 (if j < MY) */ i = j = 0; data = (UserData) user_data; hordc = data->hdcoef; horac = data->hacoef; verdc = data->vdcoef; #pragma omp parallel for collapse(2) default(shared) private(i, j, k, kthCol) num_threads(data->nthreads) for (j=1; j <= MY; j++) { for (i=1; i <= MX; i++) { k = j-1 + (i-1)*MY; kthCol = SUNBandMatrix_Column(J,k); /* set the kth column of J */ SM_COLUMN_ELEMENT_B(kthCol,k,k) = -TWO*(verdc+hordc); if (i != 1) SM_COLUMN_ELEMENT_B(kthCol,k-MY,k) = hordc + horac; if (i != MX) SM_COLUMN_ELEMENT_B(kthCol,k+MY,k) = hordc - horac; if (j != 1) SM_COLUMN_ELEMENT_B(kthCol,k-1,k) = verdc; if (j != MY) SM_COLUMN_ELEMENT_B(kthCol,k+1,k) = verdc; } } return(0); } /* *------------------------------- * Private helper functions *------------------------------- */ /* Set initial conditions in u vector */ static void SetIC(N_Vector u, UserData data) { sunindextype i, j; realtype x, y, dx, dy; realtype *udata; i = j = 0; /* Extract needed constants from data */ dx = data->dx; dy = data->dy; /* Set pointer to data array in vector u. */ udata = NV_DATA_OMP(u); /* Load initial profile into u vector */ #pragma omp parallel for default(shared) private(j, i, y, x) for (j=1; j <= MY; j++) { y = j*dy; for (i=1; i <= MX; i++) { x = i*dx; IJth(udata,i,j) = x*(XMAX - x)*y*(YMAX - y)*exp(FIVE*x*y); } } } /* Print first lines of output (problem description) */ static void PrintHeader(realtype reltol, realtype abstol, realtype umax) { printf("\n2-D Advection-Diffusion Equation\n"); printf("Mesh dimensions = %d X %d\n", MX, MY); printf("Total system size = %d\n", NEQ); #if defined(SUNDIALS_EXTENDED_PRECISION) printf("Tolerance parameters: reltol = %Lg abstol = %Lg\n\n", reltol, abstol); printf("At t = %Lg max.norm(u) =%14.6Le \n", T0, umax); #elif defined(SUNDIALS_DOUBLE_PRECISION) printf("Tolerance parameters: reltol = %g abstol = %g\n\n", reltol, abstol); printf("At t = %g max.norm(u) =%14.6e \n", T0, umax); #else printf("Tolerance parameters: reltol = %g abstol = %g\n\n", reltol, abstol); printf("At t = %g max.norm(u) =%14.6e \n", T0, umax); #endif return; } /* Print current value */ static void PrintOutput(realtype t, realtype umax, long int nst) { #if defined(SUNDIALS_EXTENDED_PRECISION) printf("At t = %4.2Lf max.norm(u) =%14.6Le nst = %4ld\n", t, umax, nst); #elif defined(SUNDIALS_DOUBLE_PRECISION) printf("At t = %4.2f max.norm(u) =%14.6e nst = %4ld\n", t, umax, nst); #else printf("At t = %4.2f max.norm(u) =%14.6e nst = %4ld\n", t, umax, nst); #endif return; } /* Get and print some final statistics */ static void PrintFinalStats(void *cvode_mem) { int retval; long int nst, nfe, nsetups, netf, nni, ncfn, nje, nfeLS; retval = CVodeGetNumSteps(cvode_mem, &nst); check_retval(&retval, "CVodeGetNumSteps", 1); retval = CVodeGetNumRhsEvals(cvode_mem, &nfe); check_retval(&retval, "CVodeGetNumRhsEvals", 1); retval = CVodeGetNumLinSolvSetups(cvode_mem, &nsetups); check_retval(&retval, "CVodeGetNumLinSolvSetups", 1); retval = CVodeGetNumErrTestFails(cvode_mem, &netf); check_retval(&retval, "CVodeGetNumErrTestFails", 1); retval = CVodeGetNumNonlinSolvIters(cvode_mem, &nni); check_retval(&retval, "CVodeGetNumNonlinSolvIters", 1); retval = CVodeGetNumNonlinSolvConvFails(cvode_mem, &ncfn); check_retval(&retval, "CVodeGetNumNonlinSolvConvFails", 1); retval = CVodeGetNumJacEvals(cvode_mem, &nje); check_retval(&retval, "CVodeGetNumJacEvals", 1); retval = CVodeGetNumLinRhsEvals(cvode_mem, &nfeLS); check_retval(&retval, "CVodeGetNumLinRhsEvals", 1); printf("\nFinal Statistics:\n"); printf("nst = %-6ld nfe = %-6ld nsetups = %-6ld nfeLS = %-6ld nje = %ld\n", nst, nfe, nsetups, nfeLS, nje); printf("nni = %-6ld ncfn = %-6ld netf = %ld\n", nni, ncfn, netf); return; } /* Check function return value... opt == 0 means SUNDIALS function allocates memory so check if returned NULL pointer opt == 1 means SUNDIALS function returns an integer value so check if retval < 0 opt == 2 means function allocates memory so check if returned NULL pointer */ static int check_retval(void *returnvalue, const char *funcname, int opt) { int *retval; /* Check if SUNDIALS function returned NULL pointer - no memory allocated */ if (opt == 0 && returnvalue == NULL) { fprintf(stderr, "\nSUNDIALS_ERROR: %s() failed - returned NULL pointer\n\n", funcname); return(1); } /* Check if retval < 0 */ else if (opt == 1) { retval = (int *) returnvalue; if (*retval < 0) { fprintf(stderr, "\nSUNDIALS_ERROR: %s() failed with retval = %d\n\n", funcname, *retval); return(1); }} /* Check if function returned NULL pointer - no memory allocated */ else if (opt == 2 && returnvalue == NULL) { fprintf(stderr, "\nMEMORY_ERROR: %s() failed - returned NULL pointer\n\n", funcname); return(1); } return(0); }

common.h

#ifndef LIGHTGBM_UTILS_COMMON_FUN_H_ #define LIGHTGBM_UTILS_COMMON_FUN_H_ #include <LightGBM/utils/log.h> #include <LightGBM/utils/openmp_wrapper.h> #include <cstdio> #include <string> #include <vector> #include <sstream> #include <cstdint> #include <algorithm> #include <cmath> #include <functional> #include <memory> #include <iterator> #include <type_traits> #include <iomanip> namespace LightGBM { namespace Common { inline char tolower(char in) { if (in <= 'Z' && in >= 'A') return in - ('Z' - 'z'); return in; } inline static std::string Trim(std::string str) { if (str.empty()) { return str; } str.erase(str.find_last_not_of(" \f\n\r\t\v") + 1); str.erase(0, str.find_first_not_of(" \f\n\r\t\v")); return str; } inline static std::string RemoveQuotationSymbol(std::string str) { if (str.empty()) { return str; } str.erase(str.find_last_not_of("'\"") + 1); str.erase(0, str.find_first_not_of("'\"")); return str; } inline static bool StartsWith(const std::string& str, const std::string prefix) { if (str.substr(0, prefix.size()) == prefix) { return true; } else { return false; } } inline static std::vector<std::string> Split(const char* c_str, char delimiter) { std::vector<std::string> ret; std::string str(c_str); size_t i = 0; size_t pos = 0; while (pos < str.length()) { if (str[pos] == delimiter) { if (i < pos) { ret.push_back(str.substr(i, pos - i)); } ++pos; i = pos; } else { ++pos; } } if (i < pos) { ret.push_back(str.substr(i)); } return ret; } inline static std::vector<std::string> SplitLines(const char* c_str) { std::vector<std::string> ret; std::string str(c_str); size_t i = 0; size_t pos = 0; while (pos < str.length()) { if (str[pos] == '\n' || str[pos] == '\r') { if (i < pos) { ret.push_back(str.substr(i, pos - i)); } // skip the line endings while (str[pos] == '\n' || str[pos] == '\r') ++pos; // new begin i = pos; } else { ++pos; } } if (i < pos) { ret.push_back(str.substr(i)); } return ret; } inline static std::vector<std::string> Split(const char* c_str, const char* delimiters) { std::vector<std::string> ret; std::string str(c_str); size_t i = 0; size_t pos = 0; while (pos < str.length()) { bool met_delimiters = false; for (int j = 0; delimiters[j] != '\0'; ++j) { if (str[pos] == delimiters[j]) { met_delimiters = true; break; } } if (met_delimiters) { if (i < pos) { ret.push_back(str.substr(i, pos - i)); } ++pos; i = pos; } else { ++pos; } } if (i < pos) { ret.push_back(str.substr(i)); } return ret; } inline static std::string FindFromLines(const std::vector<std::string>& lines, const char* key_word) { for (auto& line : lines) { size_t find_pos = line.find(key_word); if (find_pos != std::string::npos) { return line; } } return ""; } inline static const char* Atoi(const char* p, int* out) { int sign, value; while (*p == ' ') { ++p; } sign = 1; if (*p == '-') { sign = -1; ++p; } else if (*p == '+') { ++p; } for (value = 0; *p >= '0' && *p <= '9'; ++p) { value = value * 10 + (*p - '0'); } *out = sign * value; while (*p == ' ') { ++p; } return p; } inline static const char* Atof(const char* p, double* out) { int frac; double sign, value, scale; *out = NAN; // Skip leading white space, if any. while (*p == ' ') { ++p; } // Get sign, if any. sign = 1.0; if (*p == '-') { sign = -1.0; ++p; } else if (*p == '+') { ++p; } // is a number if ((*p >= '0' && *p <= '9') || *p == '.' || *p == 'e' || *p == 'E') { // Get digits before decimal point or exponent, if any. for (value = 0.0; *p >= '0' && *p <= '9'; ++p) { value = value * 10.0 + (*p - '0'); } // Get digits after decimal point, if any. if (*p == '.') { double pow10 = 10.0; ++p; while (*p >= '0' && *p <= '9') { value += (*p - '0') / pow10; pow10 *= 10.0; ++p; } } // Handle exponent, if any. frac = 0; scale = 1.0; if ((*p == 'e') || (*p == 'E')) { uint32_t expon; // Get sign of exponent, if any. ++p; if (*p == '-') { frac = 1; ++p; } else if (*p == '+') { ++p; } // Get digits of exponent, if any. for (expon = 0; *p >= '0' && *p <= '9'; ++p) { expon = expon * 10 + (*p - '0'); } if (expon > 308) expon = 308; // Calculate scaling factor. while (expon >= 50) { scale *= 1E50; expon -= 50; } while (expon >= 8) { scale *= 1E8; expon -= 8; } while (expon > 0) { scale *= 10.0; expon -= 1; } } // Return signed and scaled floating point result. *out = sign * (frac ? (value / scale) : (value * scale)); } else { size_t cnt = 0; while (*(p + cnt) != '\0' && *(p + cnt) != ' ' && *(p + cnt) != '\t' && *(p + cnt) != ',' && *(p + cnt) != '\n' && *(p + cnt) != '\r' && *(p + cnt) != ':') { ++cnt; } if (cnt > 0) { std::string tmp_str(p, cnt); std::transform(tmp_str.begin(), tmp_str.end(), tmp_str.begin(), Common::tolower); if (tmp_str == std::string("na") || tmp_str == std::string("nan")) { *out = NAN; } else if (tmp_str == std::string("inf") || tmp_str == std::string("infinity")) { *out = sign * 1e308; } else { Log::Fatal("Unknown token %s in data file", tmp_str.c_str()); } p += cnt; } } while (*p == ' ') { ++p; } return p; } inline bool AtoiAndCheck(const char* p, int* out) { const char* after = Atoi(p, out); if (*after != '\0') { return false; } return true; } inline bool AtofAndCheck(const char* p, double* out) { const char* after = Atof(p, out); if (*after != '\0') { return false; } return true; } inline static const char* SkipSpaceAndTab(const char* p) { while (*p == ' ' || *p == '\t') { ++p; } return p; } inline static const char* SkipReturn(const char* p) { while (*p == '\n' || *p == '\r' || *p == ' ') { ++p; } return p; } template<typename T, typename T2> inline static std::vector<T2> ArrayCast(const std::vector<T>& arr) { std::vector<T2> ret; for (size_t i = 0; i < arr.size(); ++i) { ret.push_back(static_cast<T2>(arr[i])); } return ret; } template<typename T> inline static std::string ArrayToString(const std::vector<T>& arr, char delimiter) { if (arr.empty()) { return std::string(""); } std::stringstream str_buf; str_buf << std::setprecision(std::numeric_limits<double>::digits10 + 2); str_buf << arr[0]; for (size_t i = 1; i < arr.size(); ++i) { str_buf << delimiter; str_buf << arr[i]; } return str_buf.str(); } template<typename T> inline static std::string ArrayToString(const std::vector<T>& arr, size_t n, char delimiter) { if (arr.empty() || n == 0) { return std::string(""); } std::stringstream str_buf; str_buf << std::setprecision(std::numeric_limits<double>::digits10 + 2); str_buf << arr[0]; for (size_t i = 1; i < std::min(n, arr.size()); ++i) { str_buf << delimiter; str_buf << arr[i]; } return str_buf.str(); } template<typename T, bool is_float> struct __StringToTHelper { T operator()(const std::string& str) const { return static_cast<T>(std::stoll(str)); } }; template<typename T> struct __StringToTHelper<T, true> { T operator()(const std::string& str) const { return static_cast<T>(std::stod(str)); } }; template<typename T> inline static std::vector<T> StringToArray(const std::string& str, char delimiter, size_t n) { if (n == 0) { return std::vector<T>(); } std::vector<std::string> strs = Split(str.c_str(), delimiter); if (strs.size() != n) { Log::Fatal("StringToArray error, size doesn't match."); } std::vector<T> ret(n); __StringToTHelper<T, std::is_floating_point<T>::value> helper; for (size_t i = 0; i < n; ++i) { ret[i] = helper(strs[i]); } return ret; } template<typename T> inline static std::vector<T> StringToArray(const std::string& str, char delimiter) { std::vector<std::string> strs = Split(str.c_str(), delimiter); std::vector<T> ret; ret.reserve(strs.size()); __StringToTHelper<T, std::is_floating_point<T>::value> helper; for (const auto& s : strs) { ret.push_back(helper(s)); } return ret; } template<typename T> inline static std::string Join(const std::vector<T>& strs, const char* delimiter) { if (strs.empty()) { return std::string(""); } std::stringstream str_buf; str_buf << std::setprecision(std::numeric_limits<double>::digits10 + 2); str_buf << strs[0]; for (size_t i = 1; i < strs.size(); ++i) { str_buf << delimiter; str_buf << strs[i]; } return str_buf.str(); } template<typename T> inline static std::string Join(const std::vector<T>& strs, size_t start, size_t end, const char* delimiter) { if (end - start <= 0) { return std::string(""); } start = std::min(start, static_cast<size_t>(strs.size()) - 1); end = std::min(end, static_cast<size_t>(strs.size())); std::stringstream str_buf; str_buf << std::setprecision(std::numeric_limits<double>::digits10 + 2); str_buf << strs[start]; for (size_t i = start + 1; i < end; ++i) { str_buf << delimiter; str_buf << strs[i]; } return str_buf.str(); } static inline int64_t Pow2RoundUp(int64_t x) { int64_t t = 1; for (int i = 0; i < 64; ++i) { if (t >= x) { return t; } t <<= 1; } return 0; } /*! * \brief Do inplace softmax transformaton on p_rec * \param p_rec The input/output vector of the values. */ inline void Softmax(std::vector<double>* p_rec) { std::vector<double> &rec = *p_rec; double wmax = rec[0]; for (size_t i = 1; i < rec.size(); ++i) { wmax = std::max(rec[i], wmax); } double wsum = 0.0f; for (size_t i = 0; i < rec.size(); ++i) { rec[i] = std::exp(rec[i] - wmax); wsum += rec[i]; } for (size_t i = 0; i < rec.size(); ++i) { rec[i] /= static_cast<double>(wsum); } } inline void Softmax(const double* input, double* output, int len) { double wmax = input[0]; for (int i = 1; i < len; ++i) { wmax = std::max(input[i], wmax); } double wsum = 0.0f; for (int i = 0; i < len; ++i) { output[i] = std::exp(input[i] - wmax); wsum += output[i]; } for (int i = 0; i < len; ++i) { output[i] /= static_cast<double>(wsum); } } template<typename T> std::vector<const T*> ConstPtrInVectorWrapper(const std::vector<std::unique_ptr<T>>& input) { std::vector<const T*> ret; for (size_t i = 0; i < input.size(); ++i) { ret.push_back(input.at(i).get()); } return ret; } template<typename T1, typename T2> inline void SortForPair(std::vector<T1>& keys, std::vector<T2>& values, size_t start, bool is_reverse = false) { std::vector<std::pair<T1, T2>> arr; for (size_t i = start; i < keys.size(); ++i) { arr.emplace_back(keys[i], values[i]); } if (!is_reverse) { std::sort(arr.begin(), arr.end(), [](const std::pair<T1, T2>& a, const std::pair<T1, T2>& b) { return a.first < b.first; }); } else { std::sort(arr.begin(), arr.end(), [](const std::pair<T1, T2>& a, const std::pair<T1, T2>& b) { return a.first > b.first; }); } for (size_t i = start; i < arr.size(); ++i) { keys[i] = arr[i].first; values[i] = arr[i].second; } } /* * approximate hessians of absolute loss with Gaussian function * cf. https://en.wikipedia.org/wiki/Gaussian_function * * y is a prediction. * t means true target. * g means gradient. * eta is a parameter to control the width of Gaussian function. * w means weights. */ inline static double ApproximateHessianWithGaussian(const double y, const double t, const double g, const double eta, const double w=1.0f) { const double diff = y - t; const double pi = 4.0 * std::atan(1.0); const double x = std::fabs(diff); const double a = 2.0 * std::fabs(g) * w; // difference of two first derivatives, (zero to inf) and (zero to -inf). const double b = 0.0; const double c = std::max((std::fabs(y) + std::fabs(t)) * eta, 1.0e-10); return w * std::exp(-(x - b) * (x - b) / (2.0 * c * c)) * a / (c * std::sqrt(2 * pi)); } template <typename T> inline static std::vector<T*> Vector2Ptr(std::vector<std::vector<T>>& data) { std::vector<T*> ptr(data.size()); for (size_t i = 0; i < data.size(); ++i) { ptr[i] = data[i].data(); } return ptr; } template <typename T> inline static std::vector<int> VectorSize(const std::vector<std::vector<T>>& data) { std::vector<int> ret(data.size()); for (size_t i = 0; i < data.size(); ++i) { ret[i] = static_cast<int>(data[i].size()); } return ret; } inline static double AvoidInf(double x) { if (x >= 1e300) { return 1e300; } else if(x <= -1e300) { return -1e300; } else { return x; } } template<class _Iter> inline static typename std::iterator_traits<_Iter>::value_type* IteratorValType(_Iter) { return (0); } template<class _RanIt, class _Pr, class _VTRanIt> inline static void ParallelSort(_RanIt _First, _RanIt _Last, _Pr _Pred, _VTRanIt*) { size_t len = _Last - _First; const size_t kMinInnerLen = 1024; int num_threads = 1; #pragma omp parallel #pragma omp master { num_threads = omp_get_num_threads(); } if (len <= kMinInnerLen || num_threads <= 1) { std::sort(_First, _Last, _Pred); return; } size_t inner_size = (len + num_threads - 1) / num_threads; inner_size = std::max(inner_size, kMinInnerLen); num_threads = static_cast<int>((len + inner_size - 1) / inner_size); #pragma omp parallel for schedule(static,1) for (int i = 0; i < num_threads; ++i) { size_t left = inner_size*i; size_t right = left + inner_size; right = std::min(right, len); if (right > left) { std::sort(_First + left, _First + right, _Pred); } } // Buffer for merge. std::vector<_VTRanIt> temp_buf(len); _RanIt buf = temp_buf.begin(); size_t s = inner_size; // Recursive merge while (s < len) { int loop_size = static_cast<int>((len + s * 2 - 1) / (s * 2)); #pragma omp parallel for schedule(static,1) for (int i = 0; i < loop_size; ++i) { size_t left = i * 2 * s; size_t mid = left + s; size_t right = mid + s; right = std::min(len, right); if (mid >= right) { continue; } std::copy(_First + left, _First + mid, buf + left); std::merge(buf + left, buf + mid, _First + mid, _First + right, _First + left, _Pred); } s *= 2; } } template<class _RanIt, class _Pr> inline static void ParallelSort(_RanIt _First, _RanIt _Last, _Pr _Pred) { return ParallelSort(_First, _Last, _Pred, IteratorValType(_First)); } // Check that all y[] are in interval [ymin, ymax] (end points included); throws error if not template <typename T> inline void CheckElementsIntervalClosed(const T *y, T ymin, T ymax, int ny, const char *callername) { for (int i = 0; i < ny; ++i) { if (y[i] < ymin || y[i] > ymax) { std::ostringstream os; os << "[%s]: does not tolerate element [#%i = " << y[i] << "] outside [" << ymin << ", " << ymax << "]"; Log::Fatal(os.str().c_str(), callername, i); } } } // One-pass scan over array w with nw elements: find min, max and sum of elements; // this is useful for checking weight requirements. template <typename T1, typename T2> inline void ObtainMinMaxSum(const T1 *w, int nw, T1 *mi, T1 *ma, T2 *su) { T1 minw = w[0]; T1 maxw = w[0]; T2 sumw = static_cast<T2>(w[0]); for (int i = 1; i < nw; ++i) { sumw += w[i]; if (w[i] < minw) minw = w[i]; if (w[i] > maxw) maxw = w[i]; } if (mi != nullptr) *mi = minw; if (ma != nullptr) *ma = maxw; if (su != nullptr) *su = sumw; } template<class T> inline std::vector<uint32_t> ConstructBitset(const T* vals, int n) { std::vector<uint32_t> ret; for (int i = 0; i < n; ++i) { int i1 = vals[i] / 32; int i2 = vals[i] % 32; if (static_cast<int>(ret.size()) < i1 + 1) { ret.resize(i1 + 1, 0); } ret[i1] |= (1 << i2); } return ret; } template<class T> inline bool FindInBitset(const uint32_t* bits, int n, T pos) { int i1 = pos / 32; if (i1 >= n) { return false; } int i2 = pos % 32; return (bits[i1] >> i2) & 1; } } // namespace Common } // namespace LightGBM #endif // LightGBM_UTILS_COMMON_FUN_H_

rose_example1_OpenMP.c

#include <omp.h> #include <stdio.h> #include <sys/time.h> #define N 30000 int main() { int i; int j; double x[30002UL][30002UL]; double y[30002UL][30002UL]; double sum; double tmp; //for timing the code section struct timeval start; struct timeval end; float delta; for (i = 0; i <= 30000 + 1; i++) { for (j = 0; j <= 30000 + 1; j++) { x[i][j] = (((double )((i + j) % 3)) - 0.9999); } } printf("\nMemory allocation done successfully\n"); //start timer and calculation gettimeofday(&start,0); #pragma omp parallel default(none) shared(sum,x,y) private(j,i,tmp) { #pragma omp for reduction ( + :sum) for (j = 1; j < 30000 + 1; j++) { for (i = 1; i < 30000 + 1; i++) { tmp = (0.2 * ((((x[i][j] + x[i - 1][j]) + x[i + 1][j]) + x[i][j - 1]) + x[i][j + 1])); y[i][j] = tmp; sum = (sum + tmp); } } } //stop timer and calculation gettimeofday(&end,0); delta = (((((end.tv_sec - start.tv_sec) * 1000000u) + end.tv_usec) - start.tv_usec) / 1.e6); printf("\nThe total sum is: %lf\n",sum); //print time to completion printf("run time = %fs\n",delta); return 0; }

3d7pt.lbpar.c

#include <omp.h> #include <math.h> #define ceild(n,d) ceil(((double)(n))/((double)(d))) #define floord(n,d) floor(((double)(n))/((double)(d))) #define max(x,y) ((x) > (y)? (x) : (y)) #define min(x,y) ((x) < (y)? (x) : (y)) /* * Order-1, 3D 7 point stencil * Adapted from PLUTO and Pochoir test bench * * Tareq Malas */ #include <stdio.h> #include <stdlib.h> #include <sys/time.h> #ifdef LIKWID_PERFMON #include <likwid.h> #endif #include "print_utils.h" #define TESTS 2 #define MAX(a,b) ((a) > (b) ? a : b) #define MIN(a,b) ((a) < (b) ? a : b) /* Subtract the `struct timeval' values X and Y, * storing the result in RESULT. * * Return 1 if the difference is negative, otherwise 0. */ int timeval_subtract(struct timeval *result, struct timeval *x, struct timeval *y) { /* Perform the carry for the later subtraction by updating y. */ if (x->tv_usec < y->tv_usec) { int nsec = (y->tv_usec - x->tv_usec) / 1000000 + 1; y->tv_usec -= 1000000 * nsec; y->tv_sec += nsec; } if (x->tv_usec - y->tv_usec > 1000000) { int nsec = (x->tv_usec - y->tv_usec) / 1000000; y->tv_usec += 1000000 * nsec; y->tv_sec -= nsec; } /* Compute the time remaining to wait. * tv_usec is certainly positive. */ result->tv_sec = x->tv_sec - y->tv_sec; result->tv_usec = x->tv_usec - y->tv_usec; /* Return 1 if result is negative. */ return x->tv_sec < y->tv_sec; } int main(int argc, char *argv[]) { int t, i, j, k, test; int Nx, Ny, Nz, Nt; if (argc > 3) { Nx = atoi(argv[1])+2; Ny = atoi(argv[2])+2; Nz = atoi(argv[3])+2; } if (argc > 4) Nt = atoi(argv[4]); double ****A = (double ****) malloc(sizeof(double***)*2); A[0] = (double ***) malloc(sizeof(double**)*Nz); A[1] = (double ***) malloc(sizeof(double**)*Nz); for(i=0; i<Nz; i++){ A[0][i] = (double**) malloc(sizeof(double*)*Ny); A[1][i] = (double**) malloc(sizeof(double*)*Ny); for(j=0;j<Ny;j++){ A[0][i][j] = (double*) malloc(sizeof(double)*Nx); A[1][i][j] = (double*) malloc(sizeof(double)*Nx); } } // tile size information, including extra element to decide the list length int *tile_size = (int*) malloc(sizeof(int)); tile_size[0] = -1; // The list is modified here before source-to-source transformations tile_size = (int*) realloc((void *)tile_size, sizeof(int)*5); tile_size[0] = 16; tile_size[1] = 16; tile_size[2] = 4; tile_size[3] = 256; tile_size[4] = -1; // for timekeeping int ts_return = -1; struct timeval start, end, result; double tdiff = 0.0, min_tdiff=1.e100; const int BASE = 1024; const double alpha = 0.0876; const double beta = 0.0765; // initialize variables // srand(42); for (i = 1; i < Nz; i++) { for (j = 1; j < Ny; j++) { for (k = 1; k < Nx; k++) { A[0][i][j][k] = 1.0 * (rand() % BASE); } } } #ifdef LIKWID_PERFMON LIKWID_MARKER_INIT; #pragma omp parallel { LIKWID_MARKER_THREADINIT; #pragma omp barrier LIKWID_MARKER_START("calc"); } #endif int num_threads = 1; #if defined(_OPENMP) num_threads = omp_get_max_threads(); #endif for(test=0; test<TESTS; test++){ gettimeofday(&start, 0); // serial execution - Addition: 6 && Multiplication: 2 /* Copyright (C) 1991-2014 Free Software Foundation, Inc. This file is part of the GNU C Library. The GNU C Library is free software; you can redistribute it and/or modify it under the terms of the GNU Lesser General Public License as published by the Free Software Foundation; either version 2.1 of the License, or (at your option) any later version. The GNU C Library is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU Lesser General Public License for more details. You should have received a copy of the GNU Lesser General Public License along with the GNU C Library; if not, see <http://www.gnu.org/licenses/>. */ /* This header is separate from features.h so that the compiler can include it implicitly at the start of every compilation. It must not itself include <features.h> or any other header that includes <features.h> because the implicit include comes before any feature test macros that may be defined in a source file before it first explicitly includes a system header. GCC knows the name of this header in order to preinclude it. */ /* glibc's intent is to support the IEC 559 math functionality, real and complex. If the GCC (4.9 and later) predefined macros specifying compiler intent are available, use them to determine whether the overall intent is to support these features; otherwise, presume an older compiler has intent to support these features and define these macros by default. */ /* wchar_t uses ISO/IEC 10646 (2nd ed., published 2011-03-15) / Unicode 6.0. */ /* We do not support C11 <threads.h>. */ int t1, t2, t3, t4, t5, t6, t7, t8; int lb, ub, lbp, ubp, lb2, ub2; register int lbv, ubv; /* Start of CLooG code */ if ((Nt >= 2) && (Nx >= 3) && (Ny >= 3) && (Nz >= 3)) { for (t1=-1;t1<=floord(Nt-2,8);t1++) { lbp=max(ceild(t1,2),ceild(16*t1-Nt+3,16)); ubp=min(floord(Nt+Nz-4,16),floord(8*t1+Nz+5,16)); #pragma omp parallel for private(lbv,ubv,t3,t4,t5,t6,t7,t8) for (t2=lbp;t2<=ubp;t2++) { for (t3=max(max(0,ceild(16*t2-Nz,4)),2*t1);t3<=min(min(min(floord(Nt+Ny-4,4),floord(8*t1+Ny+13,4)),floord(16*t2+Ny+12,4)),floord(16*t1-16*t2+Nz+Ny+11,4));t3++) { for (t4=max(max(max(0,ceild(t1-31,32)),ceild(16*t2-Nz-252,256)),ceild(4*t3-Ny-252,256));t4<=min(min(min(min(floord(4*t3+Nx,256),floord(Nt+Nx-4,256)),floord(8*t1+Nx+13,256)),floord(16*t2+Nx+12,256)),floord(16*t1-16*t2+Nz+Nx+11,256));t4++) { for (t5=max(max(max(max(max(0,8*t1),16*t1-16*t2+1),16*t2-Nz+2),4*t3-Ny+2),256*t4-Nx+2);t5<=min(min(min(min(min(Nt-2,8*t1+15),16*t2+14),4*t3+2),256*t4+254),16*t1-16*t2+Nz+13);t5++) { for (t6=max(max(16*t2,t5+1),-16*t1+16*t2+2*t5-15);t6<=min(min(16*t2+15,-16*t1+16*t2+2*t5),t5+Nz-2);t6++) { for (t7=max(4*t3,t5+1);t7<=min(4*t3+3,t5+Ny-2);t7++) { lbv=max(256*t4,t5+1); ubv=min(256*t4+255,t5+Nx-2); #pragma ivdep #pragma vector always for (t8=lbv;t8<=ubv;t8++) { A[( t5 + 1) % 2][ (-t5+t6)][ (-t5+t7)][ (-t5+t8)] = ((alpha * A[ t5 % 2][ (-t5+t6)][ (-t5+t7)][ (-t5+t8)]) + (beta * (((((A[ t5 % 2][ (-t5+t6) - 1][ (-t5+t7)][ (-t5+t8)] + A[ t5 % 2][ (-t5+t6)][ (-t5+t7) - 1][ (-t5+t8)]) + A[ t5 % 2][ (-t5+t6)][ (-t5+t7)][ (-t5+t8) - 1]) + A[ t5 % 2][ (-t5+t6) + 1][ (-t5+t7)][ (-t5+t8)]) + A[ t5 % 2][ (-t5+t6)][ (-t5+t7) + 1][ (-t5+t8)]) + A[ t5 % 2][ (-t5+t6)][ (-t5+t7)][ (-t5+t8) + 1])));; } } } } } } } } } /* End of CLooG code */ gettimeofday(&end, 0); ts_return = timeval_subtract(&result, &end, &start); tdiff = (double) (result.tv_sec + result.tv_usec * 1.0e-6); min_tdiff = min(min_tdiff, tdiff); printf("Rank 0 TEST# %d time: %f\n", test, tdiff); } PRINT_RESULTS(1, "constant") #ifdef LIKWID_PERFMON #pragma omp parallel { LIKWID_MARKER_STOP("calc"); } LIKWID_MARKER_CLOSE; #endif // Free allocated arrays (Causing performance degradation /* for(i=0; i<Nz; i++){ for(j=0;j<Ny;j++){ free(A[0][i][j]); free(A[1][i][j]); } free(A[0][i]); free(A[1][i]); } free(A[0]); free(A[1]); */ return 0; }

CFD_assembler_ExtForces.c

/* This file is part of redbKIT. * Copyright (c) 2016, Ecole Polytechnique Federale de Lausanne (EPFL) * Author: Federico Negri <federico.negri@epfl.ch> */ #include "mex.h" #include <stdio.h> #include <math.h> #include "blas.h" #include <string.h> #ifdef _OPENMP #include <omp.h> #else #warning "OpenMP not enabled. Compile with mex CFD_assembler_ExtForces.c CFLAGS="\$CFLAGS -fopenmp" LDFLAGS="\$LDFLAGS -fopenmp"" #endif void mexFunction(int nlhs, mxArray* plhs[], int nrhs, const mxArray* prhs[]) { /* Check for proper number of arguments. */ if(nrhs!=6) { mexErrMsgTxt("6 inputs are required."); } else if(nlhs>2) { mexErrMsgTxt("Too many output arguments."); } double* f = mxGetPr(prhs[0]); int noe = mxGetN(prhs[1]); int numRowsElements = mxGetM(prhs[1]); double* elements = mxGetPr(prhs[1]); double* nln_ptr = mxGetPr(prhs[2]); int nln = (int)(nln_ptr[0]); plhs[0] = mxCreateDoubleMatrix(nln*noe,1, mxREAL); plhs[1] = mxCreateDoubleMatrix(nln*noe,1, mxREAL); double* myRrows = mxGetPr(plhs[0]); double* myRcoef = mxGetPr(plhs[1]); int k,l; int q; int NumQuadPoints = mxGetN(prhs[3]); double* w = mxGetPr(prhs[3]); double* detjac = mxGetPr(prhs[4]); double* phi = mxGetPr(prhs[5]); /* Assembly: loop over the elements */ int ie; int a; #pragma omp parallel for shared(detjac,elements,myRrows,myRcoef) private(ie,a,q) firstprivate(phi,w,numRowsElements,nln) for (ie = 0; ie < noe; ie = ie + 1 ) { int ii = 0; /* loop over test functions --> a */ for (a = 0; a < nln; a = a + 1 ) { double floc = 0; for (q = 0; q < NumQuadPoints; q = q + 1 ) { floc = floc + ( phi[a+q*nln] * f[ie+q*noe] ) * w[q]; } myRrows[ie*nln+ii] = elements[a+ie*numRowsElements]; myRcoef[ie*nln+ii] = floc*detjac[ie]; ii = ii + 1; } } }

nstream-memcpy-target.c

/// /// Copyright (c) 2019, Intel Corporation /// Copyright (c) 2021, NVIDIA /// /// Redistribution and use in source and binary forms, with or without /// modification, are permitted provided that the following conditions /// are met: /// /// * Redistributions of source code must retain the above copyright /// notice, this list of conditions and the following disclaimer. /// * Redistributions in binary form must reproduce the above /// copyright notice, this list of conditions and the following /// disclaimer in the documentation and/or other materials provided /// with the distribution. /// * Neither the name of Intel Corporation nor the names of its /// contributors may be used to endorse or promote products /// derived from this software without specific prior written /// permission. /// /// THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS /// "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT /// LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS /// FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE /// COPYRIGHT OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, /// INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, /// BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; /// LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER /// CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT /// LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN /// ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE /// POSSIBILITY OF SUCH DAMAGE. ////////////////////////////////////////////////////////////////////// /// /// NAME: nstream /// /// PURPOSE: To compute memory bandwidth when adding a vector of a given /// number of double precision values to the scalar multiple of /// another vector of the same length, and storing the result in /// a third vector. /// /// USAGE: The program takes as input the number /// of iterations to loop over the triad vectors and /// the length of the vectors. /// /// <progname> <# iterations> <vector length> /// /// The output consists of diagnostics to make sure the /// algorithm worked, and of timing statistics. /// /// NOTES: Bandwidth is determined as the number of words read, plus the /// number of words written, times the size of the words, divided /// by the execution time. For a vector length of N, the total /// number of words read and written is 4*N*sizeof(double). /// /// /// HISTORY: This code is loosely based on the Stream benchmark by John /// McCalpin, but does not follow all the Stream rules. Hence, /// reported results should not be associated with Stream in /// external publications /// /// Converted to C++11 by Jeff Hammond, November 2017. /// Converted to C11 by Jeff Hammond, February 2019. /// ////////////////////////////////////////////////////////////////////// #include "prk_util.h" #include "prk_openmp.h" OMP_REQUIRES(unified_address) int main(int argc, char * argv[]) { printf("Parallel Research Kernels version %d\n", PRKVERSION ); printf("C11/OpenMP TARGET STREAM triad: A = B + scalar * C\n"); ////////////////////////////////////////////////////////////////////// /// Read and test input parameters ////////////////////////////////////////////////////////////////////// if (argc < 3) { printf("Usage: <# iterations> <vector length>\n"); return 1; } int iterations = atoi(argv[1]); if (iterations < 1) { printf("ERROR: iterations must be >= 1\n"); return 1; } // length of a the vector size_t length = atol(argv[2]); if (length <= 0) { printf("ERROR: Vector length must be greater than 0\n"); return 1; } int device = (argc > 3) ? atol(argv[3]) : omp_get_default_device(); if ( (device < 0 || omp_get_num_devices() <= device ) && (device != omp_get_default_device()) ) { printf("ERROR: device number %d is not valid.\n", device); return 1; } printf("Number of iterations = %d\n", iterations); printf("Vector length = %zu\n", length); printf("OpenMP Device = %d\n", device); ////////////////////////////////////////////////////////////////////// // Allocate space and perform the computation ////////////////////////////////////////////////////////////////////// double nstream_time = 0.0; int host = omp_get_initial_device(); size_t bytes = length*sizeof(double); double * restrict h_A = omp_target_alloc(bytes, host); double * restrict h_B = omp_target_alloc(bytes, host); double * restrict h_C = omp_target_alloc(bytes, host); double scalar = 3.0; #pragma omp parallel for simd schedule(static) for (size_t i=0; i<length; i++) { h_A[i] = 0.0; h_B[i] = 2.0; h_C[i] = 2.0; } double * restrict d_A = omp_target_alloc(bytes, device); double * restrict d_B = omp_target_alloc(bytes, device); double * restrict d_C = omp_target_alloc(bytes, device); int rc = 0; rc = omp_target_memcpy(d_A, h_A, bytes, 0, 0, device, host); if (rc) { printf("ERROR: omp_target_memcpy(A) returned %d\n", rc); abort(); } rc = omp_target_memcpy(d_B, h_B, bytes, 0, 0, device, host); if (rc) { printf("ERROR: omp_target_memcpy(B) returned %d\n", rc); abort(); } rc = omp_target_memcpy(d_C, h_C, bytes, 0, 0, device, host); if (rc) { printf("ERROR: omp_target_memcpy(C) returned %d\n", rc); abort(); } omp_target_free(h_C, host); omp_target_free(h_B, host); { for (int iter = 0; iter<=iterations; iter++) { if (iter==1) nstream_time = omp_get_wtime(); OMP_TARGET( teams distribute parallel for simd schedule(static) device(device) is_device_ptr(d_A,d_B,d_C) ) for (size_t i=0; i<length; i++) { d_A[i] += d_B[i] + scalar * d_C[i]; } } nstream_time = omp_get_wtime() - nstream_time; } rc = omp_target_memcpy(h_A, d_A, bytes, 0, 0, host, device); if (rc) { printf("ERROR: omp_target_memcpy(A) returned %d\n", rc); abort(); } omp_target_free(d_C, device); omp_target_free(d_B, device); omp_target_free(d_A, device); ////////////////////////////////////////////////////////////////////// /// Analyze and output results ////////////////////////////////////////////////////////////////////// double ar = 0.0; double br = 2.0; double cr = 2.0; for (int i=0; i<=iterations; i++) { ar += br + scalar * cr; } ar *= length; double asum = 0.0; #pragma omp parallel for reduction(+:asum) for (size_t i=0; i<length; i++) { asum += fabs(h_A[i]); } omp_target_free(h_A, host); double epsilon=1.e-8; if (fabs(ar-asum)/asum > epsilon) { printf("Failed Validation on output array\n" " Expected checksum: %lf\n" " Observed checksum: %lf\n" "ERROR: solution did not validate\n", ar, asum); return 1; } else { printf("Solution validates\n"); double avgtime = nstream_time/iterations; double nbytes = 4.0 * length * sizeof(double); printf("Rate (MB/s): %lf Avg time (s): %lf\n", 1.e-6*nbytes/avgtime, avgtime); } return 0; }

cpu_bound.c

/* * Copyright (c) 2009, 2010, 2011, ETH Zurich. * All rights reserved. * * This file is distributed under the terms in the attached LICENSE file. * If you do not find this file, copies can be found by writing to: * ETH Zurich D-INFK, Universitaetstrasse 6, CH-8092 Zurich. Attn: Systems Group. */ #include <stdlib.h> #include <stdio.h> #include <time.h> #include <assert.h> #include <stdint.h> #include <omp.h> #include <arch/x86/barrelfish_kpi/asm_inlines_arch.h> #define WORK_PERIOD 5000000000UL #define STACK_SIZE (64 * 1024) int main(int argc, char *argv[]) { uint64_t now, start; volatile uint64_t workcnt, workload = 0; int64_t workmax = 1000; int64_t i; if(argc == 1) { printf("calibrating...\n"); do { workload = 0; workmax *= 2; start = rdtsc(); for(i = 0; i < workmax; i++) { workload++; } now = rdtsc(); } while(now - start < WORK_PERIOD); // Compute so the max number of CPUs would calc for WORK_PERIOD workmax *= omp_get_num_procs(); printf("workmax = %ld\n", workmax); return 0; } else { workmax = atol(argv[1]); } int nthreads = omp_get_max_threads(); if(argc == 3) { nthreads = atoi(argv[2]); bomp_bomp_init(nthreads); omp_set_num_threads(nthreads); } printf("threads %d, workmax %ld, CPUs %d\n", nthreads, workmax, omp_get_num_procs()); start = rdtsc(); // Do some work #pragma omp parallel for private(workcnt) for(i = 0; i < workmax; i++) { workcnt++; } now = rdtsc(); printf("%s: threads %d, compute time %lu ticks\n", argv[0], nthreads, now - start); for(;;); return 0; }

Sema.h

//===--- Sema.h - Semantic Analysis & AST Building --------------*- C++ -*-===// // // Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions. // See https://llvm.org/LICENSE.txt for license information. // SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception // //===----------------------------------------------------------------------===// // // This file defines the Sema class, which performs semantic analysis and // builds ASTs. // //===----------------------------------------------------------------------===// #ifndef LLVM_CLANG_SEMA_SEMA_H #define LLVM_CLANG_SEMA_SEMA_H #include "clang/AST/ASTConcept.h" #include "clang/AST/ASTFwd.h" #include "clang/AST/Attr.h" #include "clang/AST/Availability.h" #include "clang/AST/ComparisonCategories.h" #include "clang/AST/DeclTemplate.h" #include "clang/AST/DeclarationName.h" #include "clang/AST/Expr.h" #include "clang/AST/ExprCXX.h" #include "clang/AST/ExprConcepts.h" #include "clang/AST/ExprObjC.h" #include "clang/AST/ExprOpenMP.h" #include "clang/AST/ExternalASTSource.h" #include "clang/AST/LocInfoType.h" #include "clang/AST/MangleNumberingContext.h" #include "clang/AST/NSAPI.h" #include "clang/AST/PrettyPrinter.h" #include "clang/AST/StmtCXX.h" #include "clang/AST/StmtOpenMP.h" #include "clang/AST/TypeLoc.h" #include "clang/AST/TypeOrdering.h" #include "clang/Basic/BitmaskEnum.h" #include "clang/Basic/Builtins.h" #include "clang/Basic/DarwinSDKInfo.h" #include "clang/Basic/DiagnosticSema.h" #include "clang/Basic/ExpressionTraits.h" #include "clang/Basic/Module.h" #include "clang/Basic/OpenCLOptions.h" #include "clang/Basic/OpenMPKinds.h" #include "clang/Basic/PragmaKinds.h" #include "clang/Basic/Specifiers.h" #include "clang/Basic/TemplateKinds.h" #include "clang/Basic/TypeTraits.h" #include "clang/Sema/AnalysisBasedWarnings.h" #include "clang/Sema/CleanupInfo.h" #include "clang/Sema/DeclSpec.h" #include "clang/Sema/ExternalSemaSource.h" #include "clang/Sema/IdentifierResolver.h" #include "clang/Sema/ObjCMethodList.h" #include "clang/Sema/Ownership.h" #include "clang/Sema/Scope.h" #include "clang/Sema/SemaConcept.h" #include "clang/Sema/TypoCorrection.h" #include "clang/Sema/Weak.h" #include "llvm/ADT/ArrayRef.h" #include "llvm/ADT/Optional.h" #include "llvm/ADT/SetVector.h" #include "llvm/ADT/SmallBitVector.h" #include "llvm/ADT/SmallPtrSet.h" #include "llvm/ADT/SmallSet.h" #include "llvm/ADT/SmallVector.h" #include "llvm/ADT/TinyPtrVector.h" #include "llvm/Frontend/OpenMP/OMPConstants.h" #include <deque> #include <memory> #include <string> #include <tuple> #include <vector> namespace llvm { class APSInt; template <typename ValueT> struct DenseMapInfo; template <typename ValueT, typename ValueInfoT> class DenseSet; class SmallBitVector; struct InlineAsmIdentifierInfo; } namespace clang { class ADLResult; class ASTConsumer; class ASTContext; class ASTMutationListener; class ASTReader; class ASTWriter; class ArrayType; class ParsedAttr; class BindingDecl; class BlockDecl; class CapturedDecl; class CXXBasePath; class CXXBasePaths; class CXXBindTemporaryExpr; typedef SmallVector<CXXBaseSpecifier*, 4> CXXCastPath; class CXXConstructorDecl; class CXXConversionDecl; class CXXDeleteExpr; class CXXDestructorDecl; class CXXFieldCollector; class CXXMemberCallExpr; class CXXMethodDecl; class CXXScopeSpec; class CXXTemporary; class CXXTryStmt; class CallExpr; class ClassTemplateDecl; class ClassTemplatePartialSpecializationDecl; class ClassTemplateSpecializationDecl; class VarTemplatePartialSpecializationDecl; class CodeCompleteConsumer; class CodeCompletionAllocator; class CodeCompletionTUInfo; class CodeCompletionResult; class CoroutineBodyStmt; class Decl; class DeclAccessPair; class DeclContext; class DeclRefExpr; class DeclaratorDecl; class DeducedTemplateArgument; class DependentDiagnostic; class DesignatedInitExpr; class Designation; class EnableIfAttr; class EnumConstantDecl; class Expr; class ExtVectorType; class FormatAttr; class FriendDecl; class FunctionDecl; class FunctionProtoType; class FunctionTemplateDecl; class ImplicitConversionSequence; typedef MutableArrayRef<ImplicitConversionSequence> ConversionSequenceList; class InitListExpr; class InitializationKind; class InitializationSequence; class InitializedEntity; class IntegerLiteral; class LabelStmt; class LambdaExpr; class LangOptions; class LocalInstantiationScope; class LookupResult; class MacroInfo; typedef ArrayRef<std::pair<IdentifierInfo *, SourceLocation>> ModuleIdPath; class ModuleLoader; class MultiLevelTemplateArgumentList; class NamedDecl; class ObjCCategoryDecl; class ObjCCategoryImplDecl; class ObjCCompatibleAliasDecl; class ObjCContainerDecl; class ObjCImplDecl; class ObjCImplementationDecl; class ObjCInterfaceDecl; class ObjCIvarDecl; template <class T> class ObjCList; class ObjCMessageExpr; class ObjCMethodDecl; class ObjCPropertyDecl; class ObjCProtocolDecl; class OMPThreadPrivateDecl; class OMPRequiresDecl; class OMPDeclareReductionDecl; class OMPDeclareSimdDecl; class OMPClause; struct OMPVarListLocTy; struct OverloadCandidate; enum class OverloadCandidateParamOrder : char; enum OverloadCandidateRewriteKind : unsigned; class OverloadCandidateSet; class OverloadExpr; class ParenListExpr; class ParmVarDecl; class Preprocessor; class PseudoDestructorTypeStorage; class PseudoObjectExpr; class QualType; class StandardConversionSequence; class Stmt; class StringLiteral; class SwitchStmt; class TemplateArgument; class TemplateArgumentList; class TemplateArgumentLoc; class TemplateDecl; class TemplateInstantiationCallback; class TemplateParameterList; class TemplatePartialOrderingContext; class TemplateTemplateParmDecl; class Token; class TypeAliasDecl; class TypedefDecl; class TypedefNameDecl; class TypeLoc; class TypoCorrectionConsumer; class UnqualifiedId; class UnresolvedLookupExpr; class UnresolvedMemberExpr; class UnresolvedSetImpl; class UnresolvedSetIterator; class UsingDecl; class UsingShadowDecl; class ValueDecl; class VarDecl; class VarTemplateSpecializationDecl; class VisibilityAttr; class VisibleDeclConsumer; class IndirectFieldDecl; struct DeductionFailureInfo; class TemplateSpecCandidateSet; namespace sema { class AccessedEntity; class BlockScopeInfo; class Capture; class CapturedRegionScopeInfo; class CapturingScopeInfo; class CompoundScopeInfo; class DelayedDiagnostic; class DelayedDiagnosticPool; class FunctionScopeInfo; class LambdaScopeInfo; class PossiblyUnreachableDiag; class SemaPPCallbacks; class TemplateDeductionInfo; } namespace threadSafety { class BeforeSet; void threadSafetyCleanup(BeforeSet* Cache); } // FIXME: No way to easily map from TemplateTypeParmTypes to // TemplateTypeParmDecls, so we have this horrible PointerUnion. typedef std::pair<llvm::PointerUnion<const TemplateTypeParmType*, NamedDecl*>, SourceLocation> UnexpandedParameterPack; /// Describes whether we've seen any nullability information for the given /// file. struct FileNullability { /// The first pointer declarator (of any pointer kind) in the file that does /// not have a corresponding nullability annotation. SourceLocation PointerLoc; /// The end location for the first pointer declarator in the file. Used for /// placing fix-its. SourceLocation PointerEndLoc; /// Which kind of pointer declarator we saw. uint8_t PointerKind; /// Whether we saw any type nullability annotations in the given file. bool SawTypeNullability = false; }; /// A mapping from file IDs to a record of whether we've seen nullability /// information in that file. class FileNullabilityMap { /// A mapping from file IDs to the nullability information for each file ID. llvm::DenseMap<FileID, FileNullability> Map; /// A single-element cache based on the file ID. struct { FileID File; FileNullability Nullability; } Cache; public: FileNullability &operator[](FileID file) { // Check the single-element cache. if (file == Cache.File) return Cache.Nullability; // It's not in the single-element cache; flush the cache if we have one. if (!Cache.File.isInvalid()) { Map[Cache.File] = Cache.Nullability; } // Pull this entry into the cache. Cache.File = file; Cache.Nullability = Map[file]; return Cache.Nullability; } }; // TODO SYCL Integration header approach relies on an assumption that kernel // lambda objects created by the host compiler and any of the device compilers // will be identical wrt to field types, order and offsets. Some verification // mechanism should be developed to enforce that. // TODO FIXME SYCL Support for SYCL in FE should be refactored: // - kernel identification and generation should be made a separate pass over // AST. RecursiveASTVisitor + VisitFunctionTemplateDecl + // FunctionTemplateDecl::getSpecializations() mechanism could be used for that. // - All SYCL stuff on Sema level should be encapsulated into a single Sema // field // - Move SYCL stuff into a separate header // Represents contents of a SYCL integration header file produced by a SYCL // device compiler and used by SYCL host compiler (via forced inclusion into // compiled SYCL source): // - SYCL kernel names // - SYCL kernel parameters and offsets of corresponding actual arguments class SYCLIntegrationHeader { public: // Kind of kernel's parameters as captured by the compiler in the // kernel lambda or function object enum kernel_param_kind_t { kind_first, kind_accessor = kind_first, kind_std_layout, kind_sampler, kind_pointer, kind_specialization_constants_buffer, kind_stream, kind_last = kind_stream }; public: SYCLIntegrationHeader(Sema &S); /// Emits contents of the header into given stream. void emit(raw_ostream &Out); /// Emits contents of the header into a file with given name. /// Returns true/false on success/failure. bool emit(StringRef MainSrc); /// Signals that subsequent parameter descriptor additions will go to /// the kernel with given name. Starts new kernel invocation descriptor. void startKernel(const FunctionDecl *SyclKernel, QualType KernelNameType, SourceLocation Loc, bool IsESIMD, bool IsUnnamedKernel); /// Adds a kernel parameter descriptor to current kernel invocation /// descriptor. void addParamDesc(kernel_param_kind_t Kind, int Info, unsigned Offset); /// Signals that addition of parameter descriptors to current kernel /// invocation descriptor has finished. void endKernel(); /// Registers a specialization constant to emit info for it into the header. void addSpecConstant(StringRef IDName, QualType IDType); /// Update the names of a kernel description based on its SyclKernel. void updateKernelNames(const FunctionDecl *SyclKernel, StringRef Name, StringRef StableName) { auto Itr = llvm::find_if(KernelDescs, [SyclKernel](const KernelDesc &KD) { return KD.SyclKernel == SyclKernel; }); assert(Itr != KernelDescs.end() && "Unknown kernel description"); Itr->updateKernelNames(Name, StableName); } /// Note which free functions (this_id, this_item, etc) are called within the /// kernel void setCallsThisId(bool B); void setCallsThisItem(bool B); void setCallsThisNDItem(bool B); void setCallsThisGroup(bool B); private: // Kernel actual parameter descriptor. struct KernelParamDesc { // Represents a parameter kind. kernel_param_kind_t Kind = kind_last; // If Kind is kind_scalar or kind_struct, then // denotes parameter size in bytes (includes padding for structs) // If Kind is kind_accessor // denotes access target; possible access targets are defined in // access/access.hpp int Info = 0; // Offset of the captured parameter value in the lambda or function object. unsigned Offset = 0; KernelParamDesc() = default; }; // there are four free functions the kernel may call (this_id, this_item, // this_nd_item, this_group) struct KernelCallsSYCLFreeFunction { bool CallsThisId = false; bool CallsThisItem = false; bool CallsThisNDItem = false; bool CallsThisGroup = false; }; // Kernel invocation descriptor struct KernelDesc { /// sycl_kernel function associated with this kernel. const FunctionDecl *SyclKernel; /// Kernel name. std::string Name; /// Kernel name type. QualType NameType; /// Kernel name with stable lambda name mangling std::string StableName; SourceLocation KernelLocation; /// Whether this kernel is an ESIMD one. bool IsESIMDKernel; /// Descriptor of kernel actual parameters. SmallVector<KernelParamDesc, 8> Params; // Whether kernel calls any of the SYCL free functions (this_item(), // this_id(), etc) KernelCallsSYCLFreeFunction FreeFunctionCalls; // If we are in unnamed kernel/lambda mode AND this is one that the user // hasn't provided an explicit name for. bool IsUnnamedKernel; KernelDesc(const FunctionDecl *SyclKernel, QualType NameType, SourceLocation KernelLoc, bool IsESIMD, bool IsUnnamedKernel) : SyclKernel(SyclKernel), NameType(NameType), KernelLocation(KernelLoc), IsESIMDKernel(IsESIMD), IsUnnamedKernel(IsUnnamedKernel) {} void updateKernelNames(StringRef Name, StringRef StableName) { this->Name = Name.str(); this->StableName = StableName.str(); } }; /// Returns the latest invocation descriptor started by /// SYCLIntegrationHeader::startKernel KernelDesc *getCurKernelDesc() { return KernelDescs.size() > 0 ? &KernelDescs[KernelDescs.size() - 1] : nullptr; } private: /// Keeps invocation descriptors for each kernel invocation started by /// SYCLIntegrationHeader::startKernel SmallVector<KernelDesc, 4> KernelDescs; using SpecConstID = std::pair<QualType, std::string>; /// Keeps specialization constants met in the translation unit. Maps spec /// constant's ID type to generated unique name. Duplicates are removed at /// integration header emission time. llvm::SmallVector<SpecConstID, 4> SpecConsts; Sema &S; }; class SYCLIntegrationFooter { public: SYCLIntegrationFooter(Sema &S) : S(S) {} bool emit(StringRef MainSrc); void addVarDecl(const VarDecl *VD); private: bool emit(raw_ostream &O); Sema &S; llvm::SmallVector<const VarDecl *> SpecConstants; void emitSpecIDName(raw_ostream &O, const VarDecl *VD); }; /// Tracks expected type during expression parsing, for use in code completion. /// The type is tied to a particular token, all functions that update or consume /// the type take a start location of the token they are looking at as a /// parameter. This avoids updating the type on hot paths in the parser. class PreferredTypeBuilder { public: PreferredTypeBuilder(bool Enabled) : Enabled(Enabled) {} void enterCondition(Sema &S, SourceLocation Tok); void enterReturn(Sema &S, SourceLocation Tok); void enterVariableInit(SourceLocation Tok, Decl *D); /// Handles e.g. BaseType{ .D = Tok... void enterDesignatedInitializer(SourceLocation Tok, QualType BaseType, const Designation &D); /// Computing a type for the function argument may require running /// overloading, so we postpone its computation until it is actually needed. /// /// Clients should be very careful when using this funciton, as it stores a /// function_ref, clients should make sure all calls to get() with the same /// location happen while function_ref is alive. /// /// The callback should also emit signature help as a side-effect, but only /// if the completion point has been reached. void enterFunctionArgument(SourceLocation Tok, llvm::function_ref<QualType()> ComputeType); void enterParenExpr(SourceLocation Tok, SourceLocation LParLoc); void enterUnary(Sema &S, SourceLocation Tok, tok::TokenKind OpKind, SourceLocation OpLoc); void enterBinary(Sema &S, SourceLocation Tok, Expr *LHS, tok::TokenKind Op); void enterMemAccess(Sema &S, SourceLocation Tok, Expr *Base); void enterSubscript(Sema &S, SourceLocation Tok, Expr *LHS); /// Handles all type casts, including C-style cast, C++ casts, etc. void enterTypeCast(SourceLocation Tok, QualType CastType); /// Get the expected type associated with this location, if any. /// /// If the location is a function argument, determining the expected type /// involves considering all function overloads and the arguments so far. /// In this case, signature help for these function overloads will be reported /// as a side-effect (only if the completion point has been reached). QualType get(SourceLocation Tok) const { if (!Enabled || Tok != ExpectedLoc) return QualType(); if (!Type.isNull()) return Type; if (ComputeType) return ComputeType(); return QualType(); } private: bool Enabled; /// Start position of a token for which we store expected type. SourceLocation ExpectedLoc; /// Expected type for a token starting at ExpectedLoc. QualType Type; /// A function to compute expected type at ExpectedLoc. It is only considered /// if Type is null. llvm::function_ref<QualType()> ComputeType; }; /// Sema - This implements semantic analysis and AST building for C. class Sema final { Sema(const Sema &) = delete; void operator=(const Sema &) = delete; ///Source of additional semantic information. ExternalSemaSource *ExternalSource; ///Whether Sema has generated a multiplexer and has to delete it. bool isMultiplexExternalSource; static bool mightHaveNonExternalLinkage(const DeclaratorDecl *FD); bool isVisibleSlow(const NamedDecl *D); /// Determine whether two declarations should be linked together, given that /// the old declaration might not be visible and the new declaration might /// not have external linkage. bool shouldLinkPossiblyHiddenDecl(const NamedDecl *Old, const NamedDecl *New) { if (isVisible(Old)) return true; // See comment in below overload for why it's safe to compute the linkage // of the new declaration here. if (New->isExternallyDeclarable()) { assert(Old->isExternallyDeclarable() && "should not have found a non-externally-declarable previous decl"); return true; } return false; } bool shouldLinkPossiblyHiddenDecl(LookupResult &Old, const NamedDecl *New); void setupImplicitSpecialMemberType(CXXMethodDecl *SpecialMem, QualType ResultTy, ArrayRef<QualType> Args); public: /// The maximum alignment, same as in llvm::Value. We duplicate them here /// because that allows us not to duplicate the constants in clang code, /// which we must to since we can't directly use the llvm constants. /// The value is verified against llvm here: lib/CodeGen/CGDecl.cpp /// /// This is the greatest alignment value supported by load, store, and alloca /// instructions, and global values. static const unsigned MaxAlignmentExponent = 32; static const uint64_t MaximumAlignment = 1ull << MaxAlignmentExponent; typedef OpaquePtr<DeclGroupRef> DeclGroupPtrTy; typedef OpaquePtr<TemplateName> TemplateTy; typedef OpaquePtr<QualType> TypeTy; OpenCLOptions OpenCLFeatures; FPOptions CurFPFeatures; const LangOptions &LangOpts; Preprocessor &PP; ASTContext &Context; ASTConsumer &Consumer; DiagnosticsEngine &Diags; SourceManager &SourceMgr; /// Flag indicating whether or not to collect detailed statistics. bool CollectStats; /// Code-completion consumer. CodeCompleteConsumer *CodeCompleter; /// CurContext - This is the current declaration context of parsing. DeclContext *CurContext; /// Generally null except when we temporarily switch decl contexts, /// like in \see ActOnObjCTemporaryExitContainerContext. DeclContext *OriginalLexicalContext; /// VAListTagName - The declaration name corresponding to __va_list_tag. /// This is used as part of a hack to omit that class from ADL results. DeclarationName VAListTagName; bool MSStructPragmaOn; // True when \#pragma ms_struct on /// Controls member pointer representation format under the MS ABI. LangOptions::PragmaMSPointersToMembersKind MSPointerToMemberRepresentationMethod; /// Stack of active SEH __finally scopes. Can be empty. SmallVector<Scope*, 2> CurrentSEHFinally; /// Source location for newly created implicit MSInheritanceAttrs SourceLocation ImplicitMSInheritanceAttrLoc; /// Holds TypoExprs that are created from `createDelayedTypo`. This is used by /// `TransformTypos` in order to keep track of any TypoExprs that are created /// recursively during typo correction and wipe them away if the correction /// fails. llvm::SmallVector<TypoExpr *, 2> TypoExprs; /// pragma clang section kind enum PragmaClangSectionKind { PCSK_Invalid = 0, PCSK_BSS = 1, PCSK_Data = 2, PCSK_Rodata = 3, PCSK_Text = 4, PCSK_Relro = 5 }; enum PragmaClangSectionAction { PCSA_Set = 0, PCSA_Clear = 1 }; struct PragmaClangSection { std::string SectionName; bool Valid = false; SourceLocation PragmaLocation; }; PragmaClangSection PragmaClangBSSSection; PragmaClangSection PragmaClangDataSection; PragmaClangSection PragmaClangRodataSection; PragmaClangSection PragmaClangRelroSection; PragmaClangSection PragmaClangTextSection; enum PragmaMsStackAction { PSK_Reset = 0x0, // #pragma () PSK_Set = 0x1, // #pragma (value) PSK_Push = 0x2, // #pragma (push[, id]) PSK_Pop = 0x4, // #pragma (pop[, id]) PSK_Show = 0x8, // #pragma (show) -- only for "pack"! PSK_Push_Set = PSK_Push | PSK_Set, // #pragma (push[, id], value) PSK_Pop_Set = PSK_Pop | PSK_Set, // #pragma (pop[, id], value) }; // #pragma pack and align. class AlignPackInfo { public: // `Native` represents default align mode, which may vary based on the // platform. enum Mode : unsigned char { Native, Natural, Packed, Mac68k }; // #pragma pack info constructor AlignPackInfo(AlignPackInfo::Mode M, unsigned Num, bool IsXL) : PackAttr(true), AlignMode(M), PackNumber(Num), XLStack(IsXL) { assert(Num == PackNumber && "The pack number has been truncated."); } // #pragma align info constructor AlignPackInfo(AlignPackInfo::Mode M, bool IsXL) : PackAttr(false), AlignMode(M), PackNumber(M == Packed ? 1 : UninitPackVal), XLStack(IsXL) {} explicit AlignPackInfo(bool IsXL) : AlignPackInfo(Native, IsXL) {} AlignPackInfo() : AlignPackInfo(Native, false) {} // When a AlignPackInfo itself cannot be used, this returns an 32-bit // integer encoding for it. This should only be passed to // AlignPackInfo::getFromRawEncoding, it should not be inspected directly. static uint32_t getRawEncoding(const AlignPackInfo &Info) { std::uint32_t Encoding{}; if (Info.IsXLStack()) Encoding |= IsXLMask; Encoding |= static_cast<uint32_t>(Info.getAlignMode()) << 1; if (Info.IsPackAttr()) Encoding |= PackAttrMask; Encoding |= static_cast<uint32_t>(Info.getPackNumber()) << 4; return Encoding; } static AlignPackInfo getFromRawEncoding(unsigned Encoding) { bool IsXL = static_cast<bool>(Encoding & IsXLMask); AlignPackInfo::Mode M = static_cast<AlignPackInfo::Mode>((Encoding & AlignModeMask) >> 1); int PackNumber = (Encoding & PackNumMask) >> 4; if (Encoding & PackAttrMask) return AlignPackInfo(M, PackNumber, IsXL); return AlignPackInfo(M, IsXL); } bool IsPackAttr() const { return PackAttr; } bool IsAlignAttr() const { return !PackAttr; } Mode getAlignMode() const { return AlignMode; } unsigned getPackNumber() const { return PackNumber; } bool IsPackSet() const { // #pragma align, #pragma pack(), and #pragma pack(0) do not set the pack // attriute on a decl. return PackNumber != UninitPackVal && PackNumber != 0; } bool IsXLStack() const { return XLStack; } bool operator==(const AlignPackInfo &Info) const { return std::tie(AlignMode, PackNumber, PackAttr, XLStack) == std::tie(Info.AlignMode, Info.PackNumber, Info.PackAttr, Info.XLStack); } bool operator!=(const AlignPackInfo &Info) const { return !(*this == Info); } private: /// \brief True if this is a pragma pack attribute, /// not a pragma align attribute. bool PackAttr; /// \brief The alignment mode that is in effect. Mode AlignMode; /// \brief The pack number of the stack. unsigned char PackNumber; /// \brief True if it is a XL #pragma align/pack stack. bool XLStack; /// \brief Uninitialized pack value. static constexpr unsigned char UninitPackVal = -1; // Masks to encode and decode an AlignPackInfo. static constexpr uint32_t IsXLMask{0x0000'0001}; static constexpr uint32_t AlignModeMask{0x0000'0006}; static constexpr uint32_t PackAttrMask{0x00000'0008}; static constexpr uint32_t PackNumMask{0x0000'01F0}; }; template<typename ValueType> struct PragmaStack { struct Slot { llvm::StringRef StackSlotLabel; ValueType Value; SourceLocation PragmaLocation; SourceLocation PragmaPushLocation; Slot(llvm::StringRef StackSlotLabel, ValueType Value, SourceLocation PragmaLocation, SourceLocation PragmaPushLocation) : StackSlotLabel(StackSlotLabel), Value(Value), PragmaLocation(PragmaLocation), PragmaPushLocation(PragmaPushLocation) {} }; void Act(SourceLocation PragmaLocation, PragmaMsStackAction Action, llvm::StringRef StackSlotLabel, ValueType Value) { if (Action == PSK_Reset) { CurrentValue = DefaultValue; CurrentPragmaLocation = PragmaLocation; return; } if (Action & PSK_Push) Stack.emplace_back(StackSlotLabel, CurrentValue, CurrentPragmaLocation, PragmaLocation); else if (Action & PSK_Pop) { if (!StackSlotLabel.empty()) { // If we've got a label, try to find it and jump there. auto I = llvm::find_if(llvm::reverse(Stack), [&](const Slot &x) { return x.StackSlotLabel == StackSlotLabel; }); // If we found the label so pop from there. if (I != Stack.rend()) { CurrentValue = I->Value; CurrentPragmaLocation = I->PragmaLocation; Stack.erase(std::prev(I.base()), Stack.end()); } } else if (!Stack.empty()) { // We do not have a label, just pop the last entry. CurrentValue = Stack.back().Value; CurrentPragmaLocation = Stack.back().PragmaLocation; Stack.pop_back(); } } if (Action & PSK_Set) { CurrentValue = Value; CurrentPragmaLocation = PragmaLocation; } } // MSVC seems to add artificial slots to #pragma stacks on entering a C++ // method body to restore the stacks on exit, so it works like this: // // struct S { // #pragma <name>(push, InternalPragmaSlot, <current_pragma_value>) // void Method {} // #pragma <name>(pop, InternalPragmaSlot) // }; // // It works even with #pragma vtordisp, although MSVC doesn't support // #pragma vtordisp(push [, id], n) // syntax. // // Push / pop a named sentinel slot. void SentinelAction(PragmaMsStackAction Action, StringRef Label) { assert((Action == PSK_Push || Action == PSK_Pop) && "Can only push / pop #pragma stack sentinels!"); Act(CurrentPragmaLocation, Action, Label, CurrentValue); } // Constructors. explicit PragmaStack(const ValueType &Default) : DefaultValue(Default), CurrentValue(Default) {} bool hasValue() const { return CurrentValue != DefaultValue; } SmallVector<Slot, 2> Stack; ValueType DefaultValue; // Value used for PSK_Reset action. ValueType CurrentValue; SourceLocation CurrentPragmaLocation; }; // FIXME: We should serialize / deserialize these if they occur in a PCH (but // we shouldn't do so if they're in a module). /// Whether to insert vtordisps prior to virtual bases in the Microsoft /// C++ ABI. Possible values are 0, 1, and 2, which mean: /// /// 0: Suppress all vtordisps /// 1: Insert vtordisps in the presence of vbase overrides and non-trivial /// structors /// 2: Always insert vtordisps to support RTTI on partially constructed /// objects PragmaStack<MSVtorDispMode> VtorDispStack; PragmaStack<AlignPackInfo> AlignPackStack; // The current #pragma align/pack values and locations at each #include. struct AlignPackIncludeState { AlignPackInfo CurrentValue; SourceLocation CurrentPragmaLocation; bool HasNonDefaultValue, ShouldWarnOnInclude; }; SmallVector<AlignPackIncludeState, 8> AlignPackIncludeStack; // Segment #pragmas. PragmaStack<StringLiteral *> DataSegStack; PragmaStack<StringLiteral *> BSSSegStack; PragmaStack<StringLiteral *> ConstSegStack; PragmaStack<StringLiteral *> CodeSegStack; // This stack tracks the current state of Sema.CurFPFeatures. PragmaStack<FPOptionsOverride> FpPragmaStack; FPOptionsOverride CurFPFeatureOverrides() { FPOptionsOverride result; if (!FpPragmaStack.hasValue()) { result = FPOptionsOverride(); } else { result = FpPragmaStack.CurrentValue; } return result; } // RAII object to push / pop sentinel slots for all MS #pragma stacks. // Actions should be performed only if we enter / exit a C++ method body. class PragmaStackSentinelRAII { public: PragmaStackSentinelRAII(Sema &S, StringRef SlotLabel, bool ShouldAct); ~PragmaStackSentinelRAII(); private: Sema &S; StringRef SlotLabel; bool ShouldAct; }; /// A mapping that describes the nullability we've seen in each header file. FileNullabilityMap NullabilityMap; /// Last section used with #pragma init_seg. StringLiteral *CurInitSeg; SourceLocation CurInitSegLoc; /// VisContext - Manages the stack for \#pragma GCC visibility. void *VisContext; // Really a "PragmaVisStack*" /// This an attribute introduced by \#pragma clang attribute. struct PragmaAttributeEntry { SourceLocation Loc; ParsedAttr *Attribute; SmallVector<attr::SubjectMatchRule, 4> MatchRules; bool IsUsed; }; /// A push'd group of PragmaAttributeEntries. struct PragmaAttributeGroup { /// The location of the push attribute. SourceLocation Loc; /// The namespace of this push group. const IdentifierInfo *Namespace; SmallVector<PragmaAttributeEntry, 2> Entries; }; SmallVector<PragmaAttributeGroup, 2> PragmaAttributeStack; /// The declaration that is currently receiving an attribute from the /// #pragma attribute stack. const Decl *PragmaAttributeCurrentTargetDecl; /// This represents the last location of a "#pragma clang optimize off" /// directive if such a directive has not been closed by an "on" yet. If /// optimizations are currently "on", this is set to an invalid location. SourceLocation OptimizeOffPragmaLocation; /// Flag indicating if Sema is building a recovery call expression. /// /// This flag is used to avoid building recovery call expressions /// if Sema is already doing so, which would cause infinite recursions. bool IsBuildingRecoveryCallExpr; /// Used to control the generation of ExprWithCleanups. CleanupInfo Cleanup; /// ExprCleanupObjects - This is the stack of objects requiring /// cleanup that are created by the current full expression. SmallVector<ExprWithCleanups::CleanupObject, 8> ExprCleanupObjects; /// Store a set of either DeclRefExprs or MemberExprs that contain a reference /// to a variable (constant) that may or may not be odr-used in this Expr, and /// we won't know until all lvalue-to-rvalue and discarded value conversions /// have been applied to all subexpressions of the enclosing full expression. /// This is cleared at the end of each full expression. using MaybeODRUseExprSet = llvm::SetVector<Expr *, SmallVector<Expr *, 4>, llvm::SmallPtrSet<Expr *, 4>>; MaybeODRUseExprSet MaybeODRUseExprs; std::unique_ptr<sema::FunctionScopeInfo> CachedFunctionScope; /// Stack containing information about each of the nested /// function, block, and method scopes that are currently active. SmallVector<sema::FunctionScopeInfo *, 4> FunctionScopes; /// The index of the first FunctionScope that corresponds to the current /// context. unsigned FunctionScopesStart = 0; ArrayRef<sema::FunctionScopeInfo*> getFunctionScopes() const { return llvm::makeArrayRef(FunctionScopes.begin() + FunctionScopesStart, FunctionScopes.end()); } /// Stack containing information needed when in C++2a an 'auto' is encountered /// in a function declaration parameter type specifier in order to invent a /// corresponding template parameter in the enclosing abbreviated function /// template. This information is also present in LambdaScopeInfo, stored in /// the FunctionScopes stack. SmallVector<InventedTemplateParameterInfo, 4> InventedParameterInfos; /// The index of the first InventedParameterInfo that refers to the current /// context. unsigned InventedParameterInfosStart = 0; ArrayRef<InventedTemplateParameterInfo> getInventedParameterInfos() const { return llvm::makeArrayRef(InventedParameterInfos.begin() + InventedParameterInfosStart, InventedParameterInfos.end()); } typedef LazyVector<TypedefNameDecl *, ExternalSemaSource, &ExternalSemaSource::ReadExtVectorDecls, 2, 2> ExtVectorDeclsType; /// ExtVectorDecls - This is a list all the extended vector types. This allows /// us to associate a raw vector type with one of the ext_vector type names. /// This is only necessary for issuing pretty diagnostics. ExtVectorDeclsType ExtVectorDecls; /// FieldCollector - Collects CXXFieldDecls during parsing of C++ classes. std::unique_ptr<CXXFieldCollector> FieldCollector; typedef llvm::SmallSetVector<NamedDecl *, 16> NamedDeclSetType; /// Set containing all declared private fields that are not used. NamedDeclSetType UnusedPrivateFields; /// Set containing all typedefs that are likely unused. llvm::SmallSetVector<const TypedefNameDecl *, 4> UnusedLocalTypedefNameCandidates; /// Delete-expressions to be analyzed at the end of translation unit /// /// This list contains class members, and locations of delete-expressions /// that could not be proven as to whether they mismatch with new-expression /// used in initializer of the field. typedef std::pair<SourceLocation, bool> DeleteExprLoc; typedef llvm::SmallVector<DeleteExprLoc, 4> DeleteLocs; llvm::MapVector<FieldDecl *, DeleteLocs> DeleteExprs; typedef llvm::SmallPtrSet<const CXXRecordDecl*, 8> RecordDeclSetTy; /// PureVirtualClassDiagSet - a set of class declarations which we have /// emitted a list of pure virtual functions. Used to prevent emitting the /// same list more than once. std::unique_ptr<RecordDeclSetTy> PureVirtualClassDiagSet; /// ParsingInitForAutoVars - a set of declarations with auto types for which /// we are currently parsing the initializer. llvm::SmallPtrSet<const Decl*, 4> ParsingInitForAutoVars; /// Look for a locally scoped extern "C" declaration by the given name. NamedDecl *findLocallyScopedExternCDecl(DeclarationName Name); typedef LazyVector<VarDecl *, ExternalSemaSource, &ExternalSemaSource::ReadTentativeDefinitions, 2, 2> TentativeDefinitionsType; /// All the tentative definitions encountered in the TU. TentativeDefinitionsType TentativeDefinitions; /// All the external declarations encoutered and used in the TU. SmallVector<VarDecl *, 4> ExternalDeclarations; typedef LazyVector<const DeclaratorDecl *, ExternalSemaSource, &ExternalSemaSource::ReadUnusedFileScopedDecls, 2, 2> UnusedFileScopedDeclsType; /// The set of file scoped decls seen so far that have not been used /// and must warn if not used. Only contains the first declaration. UnusedFileScopedDeclsType UnusedFileScopedDecls; typedef LazyVector<CXXConstructorDecl *, ExternalSemaSource, &ExternalSemaSource::ReadDelegatingConstructors, 2, 2> DelegatingCtorDeclsType; /// All the delegating constructors seen so far in the file, used for /// cycle detection at the end of the TU. DelegatingCtorDeclsType DelegatingCtorDecls; /// All the overriding functions seen during a class definition /// that had their exception spec checks delayed, plus the overridden /// function. SmallVector<std::pair<const CXXMethodDecl*, const CXXMethodDecl*>, 2> DelayedOverridingExceptionSpecChecks; /// All the function redeclarations seen during a class definition that had /// their exception spec checks delayed, plus the prior declaration they /// should be checked against. Except during error recovery, the new decl /// should always be a friend declaration, as that's the only valid way to /// redeclare a special member before its class is complete. SmallVector<std::pair<FunctionDecl*, FunctionDecl*>, 2> DelayedEquivalentExceptionSpecChecks; typedef llvm::MapVector<const FunctionDecl *, std::unique_ptr<LateParsedTemplate>> LateParsedTemplateMapT; LateParsedTemplateMapT LateParsedTemplateMap; /// Callback to the parser to parse templated functions when needed. typedef void LateTemplateParserCB(void *P, LateParsedTemplate &LPT); typedef void LateTemplateParserCleanupCB(void *P); LateTemplateParserCB *LateTemplateParser; LateTemplateParserCleanupCB *LateTemplateParserCleanup; void *OpaqueParser; void SetLateTemplateParser(LateTemplateParserCB *LTP, LateTemplateParserCleanupCB *LTPCleanup, void *P) { LateTemplateParser = LTP; LateTemplateParserCleanup = LTPCleanup; OpaqueParser = P; } class DelayedDiagnostics; class DelayedDiagnosticsState { sema::DelayedDiagnosticPool *SavedPool; friend class Sema::DelayedDiagnostics; }; typedef DelayedDiagnosticsState ParsingDeclState; typedef DelayedDiagnosticsState ProcessingContextState; /// A class which encapsulates the logic for delaying diagnostics /// during parsing and other processing. class DelayedDiagnostics { /// The current pool of diagnostics into which delayed /// diagnostics should go. sema::DelayedDiagnosticPool *CurPool; public: DelayedDiagnostics() : CurPool(nullptr) {} /// Adds a delayed diagnostic. void add(const sema::DelayedDiagnostic &diag); // in DelayedDiagnostic.h /// Determines whether diagnostics should be delayed. bool shouldDelayDiagnostics() { return CurPool != nullptr; } /// Returns the current delayed-diagnostics pool. sema::DelayedDiagnosticPool *getCurrentPool() const { return CurPool; } /// Enter a new scope. Access and deprecation diagnostics will be /// collected in this pool. DelayedDiagnosticsState push(sema::DelayedDiagnosticPool &pool) { DelayedDiagnosticsState state; state.SavedPool = CurPool; CurPool = &pool; return state; } /// Leave a delayed-diagnostic state that was previously pushed. /// Do not emit any of the diagnostics. This is performed as part /// of the bookkeeping of popping a pool "properly". void popWithoutEmitting(DelayedDiagnosticsState state) { CurPool = state.SavedPool; } /// Enter a new scope where access and deprecation diagnostics are /// not delayed. DelayedDiagnosticsState pushUndelayed() { DelayedDiagnosticsState state; state.SavedPool = CurPool; CurPool = nullptr; return state; } /// Undo a previous pushUndelayed(). void popUndelayed(DelayedDiagnosticsState state) { assert(CurPool == nullptr); CurPool = state.SavedPool; } } DelayedDiagnostics; /// A RAII object to temporarily push a declaration context. class ContextRAII { private: Sema &S; DeclContext *SavedContext; ProcessingContextState SavedContextState; QualType SavedCXXThisTypeOverride; unsigned SavedFunctionScopesStart; unsigned SavedInventedParameterInfosStart; public: ContextRAII(Sema &S, DeclContext *ContextToPush, bool NewThisContext = true) : S(S), SavedContext(S.CurContext), SavedContextState(S.DelayedDiagnostics.pushUndelayed()), SavedCXXThisTypeOverride(S.CXXThisTypeOverride), SavedFunctionScopesStart(S.FunctionScopesStart), SavedInventedParameterInfosStart(S.InventedParameterInfosStart) { assert(ContextToPush && "pushing null context"); S.CurContext = ContextToPush; if (NewThisContext) S.CXXThisTypeOverride = QualType(); // Any saved FunctionScopes do not refer to this context. S.FunctionScopesStart = S.FunctionScopes.size(); S.InventedParameterInfosStart = S.InventedParameterInfos.size(); } void pop() { if (!SavedContext) return; S.CurContext = SavedContext; S.DelayedDiagnostics.popUndelayed(SavedContextState); S.CXXThisTypeOverride = SavedCXXThisTypeOverride; S.FunctionScopesStart = SavedFunctionScopesStart; S.InventedParameterInfosStart = SavedInventedParameterInfosStart; SavedContext = nullptr; } ~ContextRAII() { pop(); } }; /// Whether the AST is currently being rebuilt to correct immediate /// invocations. Immediate invocation candidates and references to consteval /// functions aren't tracked when this is set. bool RebuildingImmediateInvocation = false; /// Used to change context to isConstantEvaluated without pushing a heavy /// ExpressionEvaluationContextRecord object. bool isConstantEvaluatedOverride; bool isConstantEvaluated() { return ExprEvalContexts.back().isConstantEvaluated() || isConstantEvaluatedOverride; } /// RAII object to handle the state changes required to synthesize /// a function body. class SynthesizedFunctionScope { Sema &S; Sema::ContextRAII SavedContext; bool PushedCodeSynthesisContext = false; public: SynthesizedFunctionScope(Sema &S, DeclContext *DC) : S(S), SavedContext(S, DC) { S.PushFunctionScope(); S.PushExpressionEvaluationContext( Sema::ExpressionEvaluationContext::PotentiallyEvaluated); if (auto *FD = dyn_cast<FunctionDecl>(DC)) FD->setWillHaveBody(true); else assert(isa<ObjCMethodDecl>(DC)); } void addContextNote(SourceLocation UseLoc) { assert(!PushedCodeSynthesisContext); Sema::CodeSynthesisContext Ctx; Ctx.Kind = Sema::CodeSynthesisContext::DefiningSynthesizedFunction; Ctx.PointOfInstantiation = UseLoc; Ctx.Entity = cast<Decl>(S.CurContext); S.pushCodeSynthesisContext(Ctx); PushedCodeSynthesisContext = true; } ~SynthesizedFunctionScope() { if (PushedCodeSynthesisContext) S.popCodeSynthesisContext(); if (auto *FD = dyn_cast<FunctionDecl>(S.CurContext)) FD->setWillHaveBody(false); S.PopExpressionEvaluationContext(); S.PopFunctionScopeInfo(); } }; /// WeakUndeclaredIdentifiers - Identifiers contained in /// \#pragma weak before declared. rare. may alias another /// identifier, declared or undeclared llvm::MapVector<IdentifierInfo *, WeakInfo> WeakUndeclaredIdentifiers; /// ExtnameUndeclaredIdentifiers - Identifiers contained in /// \#pragma redefine_extname before declared. Used in Solaris system headers /// to define functions that occur in multiple standards to call the version /// in the currently selected standard. llvm::DenseMap<IdentifierInfo*,AsmLabelAttr*> ExtnameUndeclaredIdentifiers; /// Load weak undeclared identifiers from the external source. void LoadExternalWeakUndeclaredIdentifiers(); /// WeakTopLevelDecl - Translation-unit scoped declarations generated by /// \#pragma weak during processing of other Decls. /// I couldn't figure out a clean way to generate these in-line, so /// we store them here and handle separately -- which is a hack. /// It would be best to refactor this. SmallVector<Decl*,2> WeakTopLevelDecl; IdentifierResolver IdResolver; /// Translation Unit Scope - useful to Objective-C actions that need /// to lookup file scope declarations in the "ordinary" C decl namespace. /// For example, user-defined classes, built-in "id" type, etc. Scope *TUScope; /// The C++ "std" namespace, where the standard library resides. LazyDeclPtr StdNamespace; /// The C++ "std::bad_alloc" class, which is defined by the C++ /// standard library. LazyDeclPtr StdBadAlloc; /// The C++ "std::align_val_t" enum class, which is defined by the C++ /// standard library. LazyDeclPtr StdAlignValT; /// The C++ "std::experimental" namespace, where the experimental parts /// of the standard library resides. NamespaceDecl *StdExperimentalNamespaceCache; /// The C++ "std::initializer_list" template, which is defined in /// \<initializer_list>. ClassTemplateDecl *StdInitializerList; /// The C++ "std::coroutine_traits" template, which is defined in /// \<coroutine_traits> ClassTemplateDecl *StdCoroutineTraitsCache; /// The C++ "type_info" declaration, which is defined in \<typeinfo>. RecordDecl *CXXTypeInfoDecl; /// The MSVC "_GUID" struct, which is defined in MSVC header files. RecordDecl *MSVCGuidDecl; /// Caches identifiers/selectors for NSFoundation APIs. std::unique_ptr<NSAPI> NSAPIObj; /// The declaration of the Objective-C NSNumber class. ObjCInterfaceDecl *NSNumberDecl; /// The declaration of the Objective-C NSValue class. ObjCInterfaceDecl *NSValueDecl; /// Pointer to NSNumber type (NSNumber *). QualType NSNumberPointer; /// Pointer to NSValue type (NSValue *). QualType NSValuePointer; /// The Objective-C NSNumber methods used to create NSNumber literals. ObjCMethodDecl *NSNumberLiteralMethods[NSAPI::NumNSNumberLiteralMethods]; /// The declaration of the Objective-C NSString class. ObjCInterfaceDecl *NSStringDecl; /// Pointer to NSString type (NSString *). QualType NSStringPointer; /// The declaration of the stringWithUTF8String: method. ObjCMethodDecl *StringWithUTF8StringMethod; /// The declaration of the valueWithBytes:objCType: method. ObjCMethodDecl *ValueWithBytesObjCTypeMethod; /// The declaration of the Objective-C NSArray class. ObjCInterfaceDecl *NSArrayDecl; /// The declaration of the arrayWithObjects:count: method. ObjCMethodDecl *ArrayWithObjectsMethod; /// The declaration of the Objective-C NSDictionary class. ObjCInterfaceDecl *NSDictionaryDecl; /// The declaration of the dictionaryWithObjects:forKeys:count: method. ObjCMethodDecl *DictionaryWithObjectsMethod; /// id<NSCopying> type. QualType QIDNSCopying; /// will hold 'respondsToSelector:' Selector RespondsToSelectorSel; /// A flag to remember whether the implicit forms of operator new and delete /// have been declared. bool GlobalNewDeleteDeclared; /// Describes how the expressions currently being parsed are /// evaluated at run-time, if at all. enum class ExpressionEvaluationContext { /// The current expression and its subexpressions occur within an /// unevaluated operand (C++11 [expr]p7), such as the subexpression of /// \c sizeof, where the type of the expression may be significant but /// no code will be generated to evaluate the value of the expression at /// run time. Unevaluated, /// The current expression occurs within a braced-init-list within /// an unevaluated operand. This is mostly like a regular unevaluated /// context, except that we still instantiate constexpr functions that are /// referenced here so that we can perform narrowing checks correctly. UnevaluatedList, /// The current expression occurs within a discarded statement. /// This behaves largely similarly to an unevaluated operand in preventing /// definitions from being required, but not in other ways. DiscardedStatement, /// The current expression occurs within an unevaluated /// operand that unconditionally permits abstract references to /// fields, such as a SIZE operator in MS-style inline assembly. UnevaluatedAbstract, /// The current context is "potentially evaluated" in C++11 terms, /// but the expression is evaluated at compile-time (like the values of /// cases in a switch statement). ConstantEvaluated, /// In addition of being constant evaluated, the current expression /// occurs in an immediate function context - either a consteval function /// or a consteval if function. ImmediateFunctionContext, /// The current expression is potentially evaluated at run time, /// which means that code may be generated to evaluate the value of the /// expression at run time. PotentiallyEvaluated, /// The current expression is potentially evaluated, but any /// declarations referenced inside that expression are only used if /// in fact the current expression is used. /// /// This value is used when parsing default function arguments, for which /// we would like to provide diagnostics (e.g., passing non-POD arguments /// through varargs) but do not want to mark declarations as "referenced" /// until the default argument is used. PotentiallyEvaluatedIfUsed }; using ImmediateInvocationCandidate = llvm::PointerIntPair<ConstantExpr *, 1>; /// Data structure used to record current or nested /// expression evaluation contexts. struct ExpressionEvaluationContextRecord { /// The expression evaluation context. ExpressionEvaluationContext Context; /// Whether the enclosing context needed a cleanup. CleanupInfo ParentCleanup; /// The number of active cleanup objects when we entered /// this expression evaluation context. unsigned NumCleanupObjects; /// The number of typos encountered during this expression evaluation /// context (i.e. the number of TypoExprs created). unsigned NumTypos; MaybeODRUseExprSet SavedMaybeODRUseExprs; /// The lambdas that are present within this context, if it /// is indeed an unevaluated context. SmallVector<LambdaExpr *, 2> Lambdas; /// The declaration that provides context for lambda expressions /// and block literals if the normal declaration context does not /// suffice, e.g., in a default function argument. Decl *ManglingContextDecl; /// If we are processing a decltype type, a set of call expressions /// for which we have deferred checking the completeness of the return type. SmallVector<CallExpr *, 8> DelayedDecltypeCalls; /// If we are processing a decltype type, a set of temporary binding /// expressions for which we have deferred checking the destructor. SmallVector<CXXBindTemporaryExpr *, 8> DelayedDecltypeBinds; llvm::SmallPtrSet<const Expr *, 8> PossibleDerefs; /// Expressions appearing as the LHS of a volatile assignment in this /// context. We produce a warning for these when popping the context if /// they are not discarded-value expressions nor unevaluated operands. SmallVector<Expr*, 2> VolatileAssignmentLHSs; /// Set of candidates for starting an immediate invocation. llvm::SmallVector<ImmediateInvocationCandidate, 4> ImmediateInvocationCandidates; /// Set of DeclRefExprs referencing a consteval function when used in a /// context not already known to be immediately invoked. llvm::SmallPtrSet<DeclRefExpr *, 4> ReferenceToConsteval; /// \brief Describes whether we are in an expression constext which we have /// to handle differently. enum ExpressionKind { EK_Decltype, EK_TemplateArgument, EK_Other } ExprContext; ExpressionEvaluationContextRecord(ExpressionEvaluationContext Context, unsigned NumCleanupObjects, CleanupInfo ParentCleanup, Decl *ManglingContextDecl, ExpressionKind ExprContext) : Context(Context), ParentCleanup(ParentCleanup), NumCleanupObjects(NumCleanupObjects), NumTypos(0), ManglingContextDecl(ManglingContextDecl), ExprContext(ExprContext) {} bool isUnevaluated() const { return Context == ExpressionEvaluationContext::Unevaluated || Context == ExpressionEvaluationContext::UnevaluatedAbstract || Context == ExpressionEvaluationContext::UnevaluatedList; } bool isConstantEvaluated() const { return Context == ExpressionEvaluationContext::ConstantEvaluated || Context == ExpressionEvaluationContext::ImmediateFunctionContext; } bool isImmediateFunctionContext() const { return Context == ExpressionEvaluationContext::ImmediateFunctionContext; } }; /// A stack of expression evaluation contexts. SmallVector<ExpressionEvaluationContextRecord, 8> ExprEvalContexts; /// Emit a warning for all pending noderef expressions that we recorded. void WarnOnPendingNoDerefs(ExpressionEvaluationContextRecord &Rec); /// Compute the mangling number context for a lambda expression or /// block literal. Also return the extra mangling decl if any. /// /// \param DC - The DeclContext containing the lambda expression or /// block literal. std::tuple<MangleNumberingContext *, Decl *> getCurrentMangleNumberContext(const DeclContext *DC); /// SpecialMemberOverloadResult - The overloading result for a special member /// function. /// /// This is basically a wrapper around PointerIntPair. The lowest bits of the /// integer are used to determine whether overload resolution succeeded. class SpecialMemberOverloadResult { public: enum Kind { NoMemberOrDeleted, Ambiguous, Success }; private: llvm::PointerIntPair<CXXMethodDecl*, 2> Pair; public: SpecialMemberOverloadResult() : Pair() {} SpecialMemberOverloadResult(CXXMethodDecl *MD) : Pair(MD, MD->isDeleted() ? NoMemberOrDeleted : Success) {} CXXMethodDecl *getMethod() const { return Pair.getPointer(); } void setMethod(CXXMethodDecl *MD) { Pair.setPointer(MD); } Kind getKind() const { return static_cast<Kind>(Pair.getInt()); } void setKind(Kind K) { Pair.setInt(K); } }; class SpecialMemberOverloadResultEntry : public llvm::FastFoldingSetNode, public SpecialMemberOverloadResult { public: SpecialMemberOverloadResultEntry(const llvm::FoldingSetNodeID &ID) : FastFoldingSetNode(ID) {} }; /// A cache of special member function overload resolution results /// for C++ records. llvm::FoldingSet<SpecialMemberOverloadResultEntry> SpecialMemberCache; /// A cache of the flags available in enumerations with the flag_bits /// attribute. mutable llvm::DenseMap<const EnumDecl*, llvm::APInt> FlagBitsCache; /// The kind of translation unit we are processing. /// /// When we're processing a complete translation unit, Sema will perform /// end-of-translation-unit semantic tasks (such as creating /// initializers for tentative definitions in C) once parsing has /// completed. Modules and precompiled headers perform different kinds of /// checks. const TranslationUnitKind TUKind; llvm::BumpPtrAllocator BumpAlloc; /// The number of SFINAE diagnostics that have been trapped. unsigned NumSFINAEErrors; typedef llvm::DenseMap<ParmVarDecl *, llvm::TinyPtrVector<ParmVarDecl *>> UnparsedDefaultArgInstantiationsMap; /// A mapping from parameters with unparsed default arguments to the /// set of instantiations of each parameter. /// /// This mapping is a temporary data structure used when parsing /// nested class templates or nested classes of class templates, /// where we might end up instantiating an inner class before the /// default arguments of its methods have been parsed. UnparsedDefaultArgInstantiationsMap UnparsedDefaultArgInstantiations; // Contains the locations of the beginning of unparsed default // argument locations. llvm::DenseMap<ParmVarDecl *, SourceLocation> UnparsedDefaultArgLocs; /// UndefinedInternals - all the used, undefined objects which require a /// definition in this translation unit. llvm::MapVector<NamedDecl *, SourceLocation> UndefinedButUsed; /// Determine if VD, which must be a variable or function, is an external /// symbol that nonetheless can't be referenced from outside this translation /// unit because its type has no linkage and it's not extern "C". bool isExternalWithNoLinkageType(ValueDecl *VD); /// Obtain a sorted list of functions that are undefined but ODR-used. void getUndefinedButUsed( SmallVectorImpl<std::pair<NamedDecl *, SourceLocation> > &Undefined); /// Retrieves list of suspicious delete-expressions that will be checked at /// the end of translation unit. const llvm::MapVector<FieldDecl *, DeleteLocs> & getMismatchingDeleteExpressions() const; class GlobalMethodPool { public: using Lists = std::pair<ObjCMethodList, ObjCMethodList>; using iterator = llvm::DenseMap<Selector, Lists>::iterator; iterator begin() { return Methods.begin(); } iterator end() { return Methods.end(); } iterator find(Selector Sel) { return Methods.find(Sel); } std::pair<iterator, bool> insert(std::pair<Selector, Lists> &&Val) { return Methods.insert(Val); } int count(Selector Sel) const { return Methods.count(Sel); } bool empty() const { return Methods.empty(); } private: llvm::DenseMap<Selector, Lists> Methods; }; /// Method Pool - allows efficient lookup when typechecking messages to "id". /// We need to maintain a list, since selectors can have differing signatures /// across classes. In Cocoa, this happens to be extremely uncommon (only 1% /// of selectors are "overloaded"). /// At the head of the list it is recorded whether there were 0, 1, or >= 2 /// methods inside categories with a particular selector. GlobalMethodPool MethodPool; /// Method selectors used in a \@selector expression. Used for implementation /// of -Wselector. llvm::MapVector<Selector, SourceLocation> ReferencedSelectors; /// List of SourceLocations where 'self' is implicitly retained inside a /// block. llvm::SmallVector<std::pair<SourceLocation, const BlockDecl *>, 1> ImplicitlyRetainedSelfLocs; /// Kinds of C++ special members. enum CXXSpecialMember { CXXDefaultConstructor, CXXCopyConstructor, CXXMoveConstructor, CXXCopyAssignment, CXXMoveAssignment, CXXDestructor, CXXInvalid }; typedef llvm::PointerIntPair<CXXRecordDecl *, 3, CXXSpecialMember> SpecialMemberDecl; /// The C++ special members which we are currently in the process of /// declaring. If this process recursively triggers the declaration of the /// same special member, we should act as if it is not yet declared. llvm::SmallPtrSet<SpecialMemberDecl, 4> SpecialMembersBeingDeclared; /// Kinds of defaulted comparison operator functions. enum class DefaultedComparisonKind : unsigned char { /// This is not a defaultable comparison operator. None, /// This is an operator== that should be implemented as a series of /// subobject comparisons. Equal, /// This is an operator<=> that should be implemented as a series of /// subobject comparisons. ThreeWay, /// This is an operator!= that should be implemented as a rewrite in terms /// of a == comparison. NotEqual, /// This is an <, <=, >, or >= that should be implemented as a rewrite in /// terms of a <=> comparison. Relational, }; /// The function definitions which were renamed as part of typo-correction /// to match their respective declarations. We want to keep track of them /// to ensure that we don't emit a "redefinition" error if we encounter a /// correctly named definition after the renamed definition. llvm::SmallPtrSet<const NamedDecl *, 4> TypoCorrectedFunctionDefinitions; /// Stack of types that correspond to the parameter entities that are /// currently being copy-initialized. Can be empty. llvm::SmallVector<QualType, 4> CurrentParameterCopyTypes; void ReadMethodPool(Selector Sel); void updateOutOfDateSelector(Selector Sel); /// Private Helper predicate to check for 'self'. bool isSelfExpr(Expr *RExpr); bool isSelfExpr(Expr *RExpr, const ObjCMethodDecl *Method); /// Cause the active diagnostic on the DiagosticsEngine to be /// emitted. This is closely coupled to the SemaDiagnosticBuilder class and /// should not be used elsewhere. void EmitCurrentDiagnostic(unsigned DiagID); /// Records and restores the CurFPFeatures state on entry/exit of compound /// statements. class FPFeaturesStateRAII { public: FPFeaturesStateRAII(Sema &S) : S(S), OldFPFeaturesState(S.CurFPFeatures) { OldOverrides = S.FpPragmaStack.CurrentValue; } ~FPFeaturesStateRAII() { S.CurFPFeatures = OldFPFeaturesState; S.FpPragmaStack.CurrentValue = OldOverrides; } FPOptionsOverride getOverrides() { return OldOverrides; } private: Sema& S; FPOptions OldFPFeaturesState; FPOptionsOverride OldOverrides; }; void addImplicitTypedef(StringRef Name, QualType T); bool WarnedStackExhausted = false; /// Increment when we find a reference; decrement when we find an ignored /// assignment. Ultimately the value is 0 if every reference is an ignored /// assignment. llvm::DenseMap<const VarDecl *, int> RefsMinusAssignments; Optional<std::unique_ptr<DarwinSDKInfo>> CachedDarwinSDKInfo; public: Sema(Preprocessor &pp, ASTContext &ctxt, ASTConsumer &consumer, TranslationUnitKind TUKind = TU_Complete, CodeCompleteConsumer *CompletionConsumer = nullptr); ~Sema(); /// Perform initialization that occurs after the parser has been /// initialized but before it parses anything. void Initialize(); /// This virtual key function only exists to limit the emission of debug info /// describing the Sema class. GCC and Clang only emit debug info for a class /// with a vtable when the vtable is emitted. Sema is final and not /// polymorphic, but the debug info size savings are so significant that it is /// worth adding a vtable just to take advantage of this optimization. virtual void anchor(); const LangOptions &getLangOpts() const { return LangOpts; } OpenCLOptions &getOpenCLOptions() { return OpenCLFeatures; } FPOptions &getCurFPFeatures() { return CurFPFeatures; } DiagnosticsEngine &getDiagnostics() const { return Diags; } SourceManager &getSourceManager() const { return SourceMgr; } Preprocessor &getPreprocessor() const { return PP; } ASTContext &getASTContext() const { return Context; } ASTConsumer &getASTConsumer() const { return Consumer; } ASTMutationListener *getASTMutationListener() const; ExternalSemaSource* getExternalSource() const { return ExternalSource; } DarwinSDKInfo *getDarwinSDKInfoForAvailabilityChecking(SourceLocation Loc, StringRef Platform); ///Registers an external source. If an external source already exists, /// creates a multiplex external source and appends to it. /// ///\param[in] E - A non-null external sema source. /// void addExternalSource(ExternalSemaSource *E); void PrintStats() const; /// Warn that the stack is nearly exhausted. void warnStackExhausted(SourceLocation Loc); /// Run some code with "sufficient" stack space. (Currently, at least 256K is /// guaranteed). Produces a warning if we're low on stack space and allocates /// more in that case. Use this in code that may recurse deeply (for example, /// in template instantiation) to avoid stack overflow. void runWithSufficientStackSpace(SourceLocation Loc, llvm::function_ref<void()> Fn); /// Helper class that creates diagnostics with optional /// template instantiation stacks. /// /// This class provides a wrapper around the basic DiagnosticBuilder /// class that emits diagnostics. ImmediateDiagBuilder is /// responsible for emitting the diagnostic (as DiagnosticBuilder /// does) and, if the diagnostic comes from inside a template /// instantiation, printing the template instantiation stack as /// well. class ImmediateDiagBuilder : public DiagnosticBuilder { Sema &SemaRef; unsigned DiagID; public: ImmediateDiagBuilder(DiagnosticBuilder &DB, Sema &SemaRef, unsigned DiagID) : DiagnosticBuilder(DB), SemaRef(SemaRef), DiagID(DiagID) {} ImmediateDiagBuilder(DiagnosticBuilder &&DB, Sema &SemaRef, unsigned DiagID) : DiagnosticBuilder(DB), SemaRef(SemaRef), DiagID(DiagID) {} // This is a cunning lie. DiagnosticBuilder actually performs move // construction in its copy constructor (but due to varied uses, it's not // possible to conveniently express this as actual move construction). So // the default copy ctor here is fine, because the base class disables the // source anyway, so the user-defined ~ImmediateDiagBuilder is a safe no-op // in that case anwyay. ImmediateDiagBuilder(const ImmediateDiagBuilder &) = default; ~ImmediateDiagBuilder() { // If we aren't active, there is nothing to do. if (!isActive()) return; // Otherwise, we need to emit the diagnostic. First clear the diagnostic // builder itself so it won't emit the diagnostic in its own destructor. // // This seems wasteful, in that as written the DiagnosticBuilder dtor will // do its own needless checks to see if the diagnostic needs to be // emitted. However, because we take care to ensure that the builder // objects never escape, a sufficiently smart compiler will be able to // eliminate that code. Clear(); // Dispatch to Sema to emit the diagnostic. SemaRef.EmitCurrentDiagnostic(DiagID); } /// Teach operator<< to produce an object of the correct type. template <typename T> friend const ImmediateDiagBuilder & operator<<(const ImmediateDiagBuilder &Diag, const T &Value) { const DiagnosticBuilder &BaseDiag = Diag; BaseDiag << Value; return Diag; } // It is necessary to limit this to rvalue reference to avoid calling this // function with a bitfield lvalue argument since non-const reference to // bitfield is not allowed. template <typename T, typename = typename std::enable_if< !std::is_lvalue_reference<T>::value>::type> const ImmediateDiagBuilder &operator<<(T &&V) const { const DiagnosticBuilder &BaseDiag = *this; BaseDiag << std::move(V); return *this; } }; /// Bitmask to contain the list of reasons a single diagnostic should be /// emitted, based on its language. This permits multiple offload systems /// to coexist in the same translation unit. enum class DeviceDiagnosticReason { /// Diagnostic doesn't apply to anything. Included for completeness, but /// should make this a no-op. None = 0, /// OpenMP specific diagnostic. OmpDevice = 1 << 0, OmpHost = 1 << 1, OmpAll = OmpDevice | OmpHost, /// CUDA specific diagnostics. CudaDevice = 1 << 2, CudaHost = 1 << 3, CudaAll = CudaDevice | CudaHost, /// SYCL specific diagnostic. Sycl = 1 << 4, /// ESIMD specific diagnostic. Esimd = 1 << 5, /// A flag representing 'all'. This can be used to avoid the check /// all-together and make this behave as it did before the /// DiagnosticReason was added (that is, unconditionally emit). /// Note: This needs to be updated if any flags above are added. All = OmpAll | CudaAll | Sycl | Esimd, LLVM_MARK_AS_BITMASK_ENUM(/*LargestValue=*/All) }; private: // A collection of a pair of undefined functions and their callers known // to be reachable from a routine on the device (kernel or device function). typedef std::pair<const FunctionDecl *, const FunctionDecl *> CallPair; llvm::SmallVector<CallPair> UndefinedReachableFromSyclDevice; public: // Helper routine to add a pair of Callee-Caller pair of FunctionDecl * // to UndefinedReachableFromSyclDevice. void addFDToReachableFromSyclDevice(const FunctionDecl *Callee, const FunctionDecl *Caller) { UndefinedReachableFromSyclDevice.push_back(std::make_pair(Callee, Caller)); } // Helper routine to check if a pair of Callee-Caller FunctionDecl * // is in UndefinedReachableFromSyclDevice. bool isFDReachableFromSyclDevice(const FunctionDecl *Callee, const FunctionDecl *Caller) { return llvm::any_of(UndefinedReachableFromSyclDevice, [Callee, Caller](const CallPair &P) { return P.first == Callee && P.second == Caller; }); } /// A generic diagnostic builder for errors which may or may not be deferred. /// /// In CUDA, there exist constructs (e.g. variable-length arrays, try/catch) /// which are not allowed to appear inside __device__ functions and are /// allowed to appear in __host__ __device__ functions only if the host+device /// function is never codegen'ed. /// /// To handle this, we use the notion of "deferred diagnostics", where we /// attach a diagnostic to a FunctionDecl that's emitted iff it's codegen'ed. /// /// This class lets you emit either a regular diagnostic, a deferred /// diagnostic, or no diagnostic at all, according to an argument you pass to /// its constructor, thus simplifying the process of creating these "maybe /// deferred" diagnostics. class SemaDiagnosticBuilder { public: enum Kind { /// Emit no diagnostics. K_Nop, /// Emit the diagnostic immediately (i.e., behave like Sema::Diag()). K_Immediate, /// Emit the diagnostic immediately, and, if it's a warning or error, also /// emit a call stack showing how this function can be reached by an a /// priori known-emitted function. K_ImmediateWithCallStack, /// Create a deferred diagnostic, which is emitted only if the function /// it's attached to is codegen'ed. Also emit a call stack as with /// K_ImmediateWithCallStack. K_Deferred }; SemaDiagnosticBuilder(Kind K, SourceLocation Loc, unsigned DiagID, FunctionDecl *Fn, Sema &S, DeviceDiagnosticReason R); SemaDiagnosticBuilder(SemaDiagnosticBuilder &&D); SemaDiagnosticBuilder(const SemaDiagnosticBuilder &) = default; ~SemaDiagnosticBuilder(); bool isImmediate() const { return ImmediateDiag.hasValue(); } /// Convertible to bool: True if we immediately emitted an error, false if /// we didn't emit an error or we created a deferred error. /// /// Example usage: /// /// if (SemaDiagnosticBuilder(...) << foo << bar) /// return ExprError(); /// /// But see CUDADiagIfDeviceCode() and CUDADiagIfHostCode() -- you probably /// want to use these instead of creating a SemaDiagnosticBuilder yourself. operator bool() const { return isImmediate(); } template <typename T> friend const SemaDiagnosticBuilder & operator<<(const SemaDiagnosticBuilder &Diag, const T &Value) { if (Diag.ImmediateDiag.hasValue()) *Diag.ImmediateDiag << Value; else if (Diag.PartialDiagId.hasValue()) Diag.S.DeviceDeferredDiags[Diag.Fn][*Diag.PartialDiagId] .getDiag() .second << Value; return Diag; } // It is necessary to limit this to rvalue reference to avoid calling this // function with a bitfield lvalue argument since non-const reference to // bitfield is not allowed. template <typename T, typename = typename std::enable_if< !std::is_lvalue_reference<T>::value>::type> const SemaDiagnosticBuilder &operator<<(T &&V) const { if (ImmediateDiag.hasValue()) *ImmediateDiag << std::move(V); else if (PartialDiagId.hasValue()) S.DeviceDeferredDiags[Fn][*PartialDiagId].getDiag().second << std::move(V); return *this; } friend const SemaDiagnosticBuilder & operator<<(const SemaDiagnosticBuilder &Diag, const PartialDiagnostic &PD) { if (Diag.ImmediateDiag.hasValue()) PD.Emit(*Diag.ImmediateDiag); else if (Diag.PartialDiagId.hasValue()) Diag.S.DeviceDeferredDiags[Diag.Fn][*Diag.PartialDiagId] .getDiag() .second = PD; return Diag; } void AddFixItHint(const FixItHint &Hint) const { if (ImmediateDiag.hasValue()) ImmediateDiag->AddFixItHint(Hint); else if (PartialDiagId.hasValue()) S.DeviceDeferredDiags[Fn][*PartialDiagId].getDiag().second.AddFixItHint( Hint); } friend ExprResult ExprError(const SemaDiagnosticBuilder &) { return ExprError(); } friend StmtResult StmtError(const SemaDiagnosticBuilder &) { return StmtError(); } operator ExprResult() const { return ExprError(); } operator StmtResult() const { return StmtError(); } operator TypeResult() const { return TypeError(); } operator DeclResult() const { return DeclResult(true); } operator MemInitResult() const { return MemInitResult(true); } private: Sema &S; SourceLocation Loc; unsigned DiagID; FunctionDecl *Fn; bool ShowCallStack; // Invariant: At most one of these Optionals has a value. // FIXME: Switch these to a Variant once that exists. llvm::Optional<ImmediateDiagBuilder> ImmediateDiag; llvm::Optional<unsigned> PartialDiagId; }; /// Is the last error level diagnostic immediate. This is used to determined /// whether the next info diagnostic should be immediate. bool IsLastErrorImmediate = true; /// Emit a diagnostic. SemaDiagnosticBuilder Diag(SourceLocation Loc, unsigned DiagID, bool DeferHint = false); /// Emit a partial diagnostic. SemaDiagnosticBuilder Diag(SourceLocation Loc, const PartialDiagnostic &PD, bool DeferHint = false); /// Build a partial diagnostic. PartialDiagnostic PDiag(unsigned DiagID = 0); // in SemaInternal.h /// Whether deferrable diagnostics should be deferred. bool DeferDiags = false; /// RAII class to control scope of DeferDiags. class DeferDiagsRAII { Sema &S; bool SavedDeferDiags = false; public: DeferDiagsRAII(Sema &S, bool DeferDiags) : S(S), SavedDeferDiags(S.DeferDiags) { S.DeferDiags = DeferDiags; } ~DeferDiagsRAII() { S.DeferDiags = SavedDeferDiags; } }; /// Whether uncompilable error has occurred. This includes error happens /// in deferred diagnostics. bool hasUncompilableErrorOccurred() const; bool findMacroSpelling(SourceLocation &loc, StringRef name); /// Get a string to suggest for zero-initialization of a type. std::string getFixItZeroInitializerForType(QualType T, SourceLocation Loc) const; std::string getFixItZeroLiteralForType(QualType T, SourceLocation Loc) const; /// Calls \c Lexer::getLocForEndOfToken() SourceLocation getLocForEndOfToken(SourceLocation Loc, unsigned Offset = 0); /// Retrieve the module loader associated with the preprocessor. ModuleLoader &getModuleLoader() const; /// Invent a new identifier for parameters of abbreviated templates. IdentifierInfo * InventAbbreviatedTemplateParameterTypeName(IdentifierInfo *ParamName, unsigned Index); void emitAndClearUnusedLocalTypedefWarnings(); private: /// Function or variable declarations to be checked for whether the deferred /// diagnostics should be emitted. llvm::SmallSetVector<Decl *, 4> DeclsToCheckForDeferredDiags; public: // Emit all deferred diagnostics. void emitDeferredDiags(); enum TUFragmentKind { /// The global module fragment, between 'module;' and a module-declaration. Global, /// A normal translation unit fragment. For a non-module unit, this is the /// entire translation unit. Otherwise, it runs from the module-declaration /// to the private-module-fragment (if any) or the end of the TU (if not). Normal, /// The private module fragment, between 'module :private;' and the end of /// the translation unit. Private }; void ActOnStartOfTranslationUnit(); void ActOnEndOfTranslationUnit(); void ActOnEndOfTranslationUnitFragment(TUFragmentKind Kind); void CheckDelegatingCtorCycles(); Scope *getScopeForContext(DeclContext *Ctx); void PushFunctionScope(); void PushBlockScope(Scope *BlockScope, BlockDecl *Block); sema::LambdaScopeInfo *PushLambdaScope(); /// This is used to inform Sema what the current TemplateParameterDepth /// is during Parsing. Currently it is used to pass on the depth /// when parsing generic lambda 'auto' parameters. void RecordParsingTemplateParameterDepth(unsigned Depth); void PushCapturedRegionScope(Scope *RegionScope, CapturedDecl *CD, RecordDecl *RD, CapturedRegionKind K, unsigned OpenMPCaptureLevel = 0); /// Custom deleter to allow FunctionScopeInfos to be kept alive for a short /// time after they've been popped. class PoppedFunctionScopeDeleter { Sema *Self; public: explicit PoppedFunctionScopeDeleter(Sema *Self) : Self(Self) {} void operator()(sema::FunctionScopeInfo *Scope) const; }; using PoppedFunctionScopePtr = std::unique_ptr<sema::FunctionScopeInfo, PoppedFunctionScopeDeleter>; PoppedFunctionScopePtr PopFunctionScopeInfo(const sema::AnalysisBasedWarnings::Policy *WP = nullptr, const Decl *D = nullptr, QualType BlockType = QualType()); sema::FunctionScopeInfo *getCurFunction() const { return FunctionScopes.empty() ? nullptr : FunctionScopes.back(); } sema::FunctionScopeInfo *getEnclosingFunction() const; void setFunctionHasBranchIntoScope(); void setFunctionHasBranchProtectedScope(); void setFunctionHasIndirectGoto(); void setFunctionHasMustTail(); void PushCompoundScope(bool IsStmtExpr); void PopCompoundScope(); sema::CompoundScopeInfo &getCurCompoundScope() const; bool hasAnyUnrecoverableErrorsInThisFunction() const; /// Retrieve the current block, if any. sema::BlockScopeInfo *getCurBlock(); /// Get the innermost lambda enclosing the current location, if any. This /// looks through intervening non-lambda scopes such as local functions and /// blocks. sema::LambdaScopeInfo *getEnclosingLambda() const; /// Retrieve the current lambda scope info, if any. /// \param IgnoreNonLambdaCapturingScope true if should find the top-most /// lambda scope info ignoring all inner capturing scopes that are not /// lambda scopes. sema::LambdaScopeInfo * getCurLambda(bool IgnoreNonLambdaCapturingScope = false); /// Retrieve the current generic lambda info, if any. sema::LambdaScopeInfo *getCurGenericLambda(); /// Retrieve the current captured region, if any. sema::CapturedRegionScopeInfo *getCurCapturedRegion(); /// Retrieve the current function, if any, that should be analyzed for /// potential availability violations. sema::FunctionScopeInfo *getCurFunctionAvailabilityContext(); /// WeakTopLevelDeclDecls - access to \#pragma weak-generated Decls SmallVectorImpl<Decl *> &WeakTopLevelDecls() { return WeakTopLevelDecl; } /// Called before parsing a function declarator belonging to a function /// declaration. void ActOnStartFunctionDeclarationDeclarator(Declarator &D, unsigned TemplateParameterDepth); /// Called after parsing a function declarator belonging to a function /// declaration. void ActOnFinishFunctionDeclarationDeclarator(Declarator &D); void ActOnComment(SourceRange Comment); //===--------------------------------------------------------------------===// // Type Analysis / Processing: SemaType.cpp. // QualType BuildQualifiedType(QualType T, SourceLocation Loc, Qualifiers Qs, const DeclSpec *DS = nullptr); QualType BuildQualifiedType(QualType T, SourceLocation Loc, unsigned CVRA, const DeclSpec *DS = nullptr); QualType BuildPointerType(QualType T, SourceLocation Loc, DeclarationName Entity); QualType BuildReferenceType(QualType T, bool LValueRef, SourceLocation Loc, DeclarationName Entity); QualType BuildArrayType(QualType T, ArrayType::ArraySizeModifier ASM, Expr *ArraySize, unsigned Quals, SourceRange Brackets, DeclarationName Entity); QualType BuildVectorType(QualType T, Expr *VecSize, SourceLocation AttrLoc); QualType BuildExtVectorType(QualType T, Expr *ArraySize, SourceLocation AttrLoc); QualType BuildMatrixType(QualType T, Expr *NumRows, Expr *NumColumns, SourceLocation AttrLoc); QualType BuildAddressSpaceAttr(QualType &T, LangAS ASIdx, Expr *AddrSpace, SourceLocation AttrLoc); /// Same as above, but constructs the AddressSpace index if not provided. QualType BuildAddressSpaceAttr(QualType &T, Expr *AddrSpace, SourceLocation AttrLoc); SYCLIntelFPGAIVDepAttr * BuildSYCLIntelFPGAIVDepAttr(const AttributeCommonInfo &CI, Expr *Expr1, Expr *Expr2); LoopUnrollHintAttr *BuildLoopUnrollHintAttr(const AttributeCommonInfo &A, Expr *E); OpenCLUnrollHintAttr * BuildOpenCLLoopUnrollHintAttr(const AttributeCommonInfo &A, Expr *E); SYCLIntelFPGALoopCountAttr * BuildSYCLIntelFPGALoopCountAttr(const AttributeCommonInfo &CI, Expr *E); SYCLIntelFPGAInitiationIntervalAttr * BuildSYCLIntelFPGAInitiationIntervalAttr(const AttributeCommonInfo &CI, Expr *E); SYCLIntelFPGAMaxConcurrencyAttr * BuildSYCLIntelFPGAMaxConcurrencyAttr(const AttributeCommonInfo &CI, Expr *E); SYCLIntelFPGAMaxInterleavingAttr * BuildSYCLIntelFPGAMaxInterleavingAttr(const AttributeCommonInfo &CI, Expr *E); SYCLIntelFPGASpeculatedIterationsAttr * BuildSYCLIntelFPGASpeculatedIterationsAttr(const AttributeCommonInfo &CI, Expr *E); SYCLIntelFPGALoopCoalesceAttr * BuildSYCLIntelFPGALoopCoalesceAttr(const AttributeCommonInfo &CI, Expr *E); bool CheckQualifiedFunctionForTypeId(QualType T, SourceLocation Loc); bool CheckFunctionReturnType(QualType T, SourceLocation Loc); /// Build a function type. /// /// This routine checks the function type according to C++ rules and /// under the assumption that the result type and parameter types have /// just been instantiated from a template. It therefore duplicates /// some of the behavior of GetTypeForDeclarator, but in a much /// simpler form that is only suitable for this narrow use case. /// /// \param T The return type of the function. /// /// \param ParamTypes The parameter types of the function. This array /// will be modified to account for adjustments to the types of the /// function parameters. /// /// \param Loc The location of the entity whose type involves this /// function type or, if there is no such entity, the location of the /// type that will have function type. /// /// \param Entity The name of the entity that involves the function /// type, if known. /// /// \param EPI Extra information about the function type. Usually this will /// be taken from an existing function with the same prototype. /// /// \returns A suitable function type, if there are no errors. The /// unqualified type will always be a FunctionProtoType. /// Otherwise, returns a NULL type. QualType BuildFunctionType(QualType T, MutableArrayRef<QualType> ParamTypes, SourceLocation Loc, DeclarationName Entity, const FunctionProtoType::ExtProtoInfo &EPI); QualType BuildMemberPointerType(QualType T, QualType Class, SourceLocation Loc, DeclarationName Entity); QualType BuildBlockPointerType(QualType T, SourceLocation Loc, DeclarationName Entity); QualType BuildParenType(QualType T); QualType BuildAtomicType(QualType T, SourceLocation Loc); QualType BuildReadPipeType(QualType T, SourceLocation Loc); QualType BuildWritePipeType(QualType T, SourceLocation Loc); QualType BuildExtIntType(bool IsUnsigned, Expr *BitWidth, SourceLocation Loc); TypeSourceInfo *GetTypeForDeclarator(Declarator &D, Scope *S); TypeSourceInfo *GetTypeForDeclaratorCast(Declarator &D, QualType FromTy); /// Package the given type and TSI into a ParsedType. ParsedType CreateParsedType(QualType T, TypeSourceInfo *TInfo); DeclarationNameInfo GetNameForDeclarator(Declarator &D); DeclarationNameInfo GetNameFromUnqualifiedId(const UnqualifiedId &Name); static QualType GetTypeFromParser(ParsedType Ty, TypeSourceInfo **TInfo = nullptr); CanThrowResult canThrow(const Stmt *E); /// Determine whether the callee of a particular function call can throw. /// E, D and Loc are all optional. static CanThrowResult canCalleeThrow(Sema &S, const Expr *E, const Decl *D, SourceLocation Loc = SourceLocation()); const FunctionProtoType *ResolveExceptionSpec(SourceLocation Loc, const FunctionProtoType *FPT); void UpdateExceptionSpec(FunctionDecl *FD, const FunctionProtoType::ExceptionSpecInfo &ESI); bool CheckSpecifiedExceptionType(QualType &T, SourceRange Range); bool CheckDistantExceptionSpec(QualType T); bool CheckEquivalentExceptionSpec(FunctionDecl *Old, FunctionDecl *New); bool CheckEquivalentExceptionSpec( const FunctionProtoType *Old, SourceLocation OldLoc, const FunctionProtoType *New, SourceLocation NewLoc); bool CheckEquivalentExceptionSpec( const PartialDiagnostic &DiagID, const PartialDiagnostic & NoteID, const FunctionProtoType *Old, SourceLocation OldLoc, const FunctionProtoType *New, SourceLocation NewLoc); bool handlerCanCatch(QualType HandlerType, QualType ExceptionType); bool CheckExceptionSpecSubset(const PartialDiagnostic &DiagID, const PartialDiagnostic &NestedDiagID, const PartialDiagnostic &NoteID, const PartialDiagnostic &NoThrowDiagID, const FunctionProtoType *Superset, SourceLocation SuperLoc, const FunctionProtoType *Subset, SourceLocation SubLoc); bool CheckParamExceptionSpec(const PartialDiagnostic &NestedDiagID, const PartialDiagnostic &NoteID, const FunctionProtoType *Target, SourceLocation TargetLoc, const FunctionProtoType *Source, SourceLocation SourceLoc); TypeResult ActOnTypeName(Scope *S, Declarator &D); /// The parser has parsed the context-sensitive type 'instancetype' /// in an Objective-C message declaration. Return the appropriate type. ParsedType ActOnObjCInstanceType(SourceLocation Loc); /// Abstract class used to diagnose incomplete types. struct TypeDiagnoser { TypeDiagnoser() {} virtual void diagnose(Sema &S, SourceLocation Loc, QualType T) = 0; virtual ~TypeDiagnoser() {} }; static int getPrintable(int I) { return I; } static unsigned getPrintable(unsigned I) { return I; } static bool getPrintable(bool B) { return B; } static const char * getPrintable(const char *S) { return S; } static StringRef getPrintable(StringRef S) { return S; } static const std::string &getPrintable(const std::string &S) { return S; } static const IdentifierInfo *getPrintable(const IdentifierInfo *II) { return II; } static DeclarationName getPrintable(DeclarationName N) { return N; } static QualType getPrintable(QualType T) { return T; } static SourceRange getPrintable(SourceRange R) { return R; } static SourceRange getPrintable(SourceLocation L) { return L; } static SourceRange getPrintable(const Expr *E) { return E->getSourceRange(); } static SourceRange getPrintable(TypeLoc TL) { return TL.getSourceRange();} template <typename... Ts> class BoundTypeDiagnoser : public TypeDiagnoser { protected: unsigned DiagID; std::tuple<const Ts &...> Args; template <std::size_t... Is> void emit(const SemaDiagnosticBuilder &DB, std::index_sequence<Is...>) const { // Apply all tuple elements to the builder in order. bool Dummy[] = {false, (DB << getPrintable(std::get<Is>(Args)))...}; (void)Dummy; } public: BoundTypeDiagnoser(unsigned DiagID, const Ts &...Args) : TypeDiagnoser(), DiagID(DiagID), Args(Args...) { assert(DiagID != 0 && "no diagnostic for type diagnoser"); } void diagnose(Sema &S, SourceLocation Loc, QualType T) override { const SemaDiagnosticBuilder &DB = S.Diag(Loc, DiagID); emit(DB, std::index_sequence_for<Ts...>()); DB << T; } }; /// Do a check to make sure \p Name looks like a legal argument for the /// swift_name attribute applied to decl \p D. Raise a diagnostic if the name /// is invalid for the given declaration. /// /// \p AL is used to provide caret diagnostics in case of a malformed name. /// /// \returns true if the name is a valid swift name for \p D, false otherwise. bool DiagnoseSwiftName(Decl *D, StringRef Name, SourceLocation Loc, const ParsedAttr &AL, bool IsAsync); /// A derivative of BoundTypeDiagnoser for which the diagnostic's type /// parameter is preceded by a 0/1 enum that is 1 if the type is sizeless. /// For example, a diagnostic with no other parameters would generally have /// the form "...%select{incomplete|sizeless}0 type %1...". template <typename... Ts> class SizelessTypeDiagnoser : public BoundTypeDiagnoser<Ts...> { public: SizelessTypeDiagnoser(unsigned DiagID, const Ts &... Args) : BoundTypeDiagnoser<Ts...>(DiagID, Args...) {} void diagnose(Sema &S, SourceLocation Loc, QualType T) override { const SemaDiagnosticBuilder &DB = S.Diag(Loc, this->DiagID); this->emit(DB, std::index_sequence_for<Ts...>()); DB << T->isSizelessType() << T; } }; enum class CompleteTypeKind { /// Apply the normal rules for complete types. In particular, /// treat all sizeless types as incomplete. Normal, /// Relax the normal rules for complete types so that they include /// sizeless built-in types. AcceptSizeless, // FIXME: Eventually we should flip the default to Normal and opt in // to AcceptSizeless rather than opt out of it. Default = AcceptSizeless }; private: /// Methods for marking which expressions involve dereferencing a pointer /// marked with the 'noderef' attribute. Expressions are checked bottom up as /// they are parsed, meaning that a noderef pointer may not be accessed. For /// example, in `&*p` where `p` is a noderef pointer, we will first parse the /// `*p`, but need to check that `address of` is called on it. This requires /// keeping a container of all pending expressions and checking if the address /// of them are eventually taken. void CheckSubscriptAccessOfNoDeref(const ArraySubscriptExpr *E); void CheckAddressOfNoDeref(const Expr *E); void CheckMemberAccessOfNoDeref(const MemberExpr *E); bool RequireCompleteTypeImpl(SourceLocation Loc, QualType T, CompleteTypeKind Kind, TypeDiagnoser *Diagnoser); struct ModuleScope { SourceLocation BeginLoc; clang::Module *Module = nullptr; bool ModuleInterface = false; bool ImplicitGlobalModuleFragment = false; VisibleModuleSet OuterVisibleModules; }; /// The modules we're currently parsing. llvm::SmallVector<ModuleScope, 16> ModuleScopes; /// Namespace definitions that we will export when they finish. llvm::SmallPtrSet<const NamespaceDecl*, 8> DeferredExportedNamespaces; /// Get the module whose scope we are currently within. Module *getCurrentModule() const { return ModuleScopes.empty() ? nullptr : ModuleScopes.back().Module; } VisibleModuleSet VisibleModules; public: /// Get the module owning an entity. Module *getOwningModule(const Decl *Entity) { return Entity->getOwningModule(); } /// Make a merged definition of an existing hidden definition \p ND /// visible at the specified location. void makeMergedDefinitionVisible(NamedDecl *ND); bool isModuleVisible(const Module *M, bool ModulePrivate = false); // When loading a non-modular PCH files, this is used to restore module // visibility. void makeModuleVisible(Module *Mod, SourceLocation ImportLoc) { VisibleModules.setVisible(Mod, ImportLoc); } /// Determine whether a declaration is visible to name lookup. bool isVisible(const NamedDecl *D) { return D->isUnconditionallyVisible() || isVisibleSlow(D); } /// Determine whether any declaration of an entity is visible. bool hasVisibleDeclaration(const NamedDecl *D, llvm::SmallVectorImpl<Module *> *Modules = nullptr) { return isVisible(D) || hasVisibleDeclarationSlow(D, Modules); } bool hasVisibleDeclarationSlow(const NamedDecl *D, llvm::SmallVectorImpl<Module *> *Modules); bool hasVisibleMergedDefinition(NamedDecl *Def); bool hasMergedDefinitionInCurrentModule(NamedDecl *Def); /// Determine if \p D and \p Suggested have a structurally compatible /// layout as described in C11 6.2.7/1. bool hasStructuralCompatLayout(Decl *D, Decl *Suggested); /// Determine if \p D has a visible definition. If not, suggest a declaration /// that should be made visible to expose the definition. bool hasVisibleDefinition(NamedDecl *D, NamedDecl **Suggested, bool OnlyNeedComplete = false); bool hasVisibleDefinition(const NamedDecl *D) { NamedDecl *Hidden; return hasVisibleDefinition(const_cast<NamedDecl*>(D), &Hidden); } /// Determine if the template parameter \p D has a visible default argument. bool hasVisibleDefaultArgument(const NamedDecl *D, llvm::SmallVectorImpl<Module *> *Modules = nullptr); /// Determine if there is a visible declaration of \p D that is an explicit /// specialization declaration for a specialization of a template. (For a /// member specialization, use hasVisibleMemberSpecialization.) bool hasVisibleExplicitSpecialization( const NamedDecl *D, llvm::SmallVectorImpl<Module *> *Modules = nullptr); /// Determine if there is a visible declaration of \p D that is a member /// specialization declaration (as opposed to an instantiated declaration). bool hasVisibleMemberSpecialization( const NamedDecl *D, llvm::SmallVectorImpl<Module *> *Modules = nullptr); /// Determine if \p A and \p B are equivalent internal linkage declarations /// from different modules, and thus an ambiguity error can be downgraded to /// an extension warning. bool isEquivalentInternalLinkageDeclaration(const NamedDecl *A, const NamedDecl *B); void diagnoseEquivalentInternalLinkageDeclarations( SourceLocation Loc, const NamedDecl *D, ArrayRef<const NamedDecl *> Equiv); bool isUsualDeallocationFunction(const CXXMethodDecl *FD); bool isCompleteType(SourceLocation Loc, QualType T, CompleteTypeKind Kind = CompleteTypeKind::Default) { return !RequireCompleteTypeImpl(Loc, T, Kind, nullptr); } bool RequireCompleteType(SourceLocation Loc, QualType T, CompleteTypeKind Kind, TypeDiagnoser &Diagnoser); bool RequireCompleteType(SourceLocation Loc, QualType T, CompleteTypeKind Kind, unsigned DiagID); bool RequireCompleteType(SourceLocation Loc, QualType T, TypeDiagnoser &Diagnoser) { return RequireCompleteType(Loc, T, CompleteTypeKind::Default, Diagnoser); } bool RequireCompleteType(SourceLocation Loc, QualType T, unsigned DiagID) { return RequireCompleteType(Loc, T, CompleteTypeKind::Default, DiagID); } template <typename... Ts> bool RequireCompleteType(SourceLocation Loc, QualType T, unsigned DiagID, const Ts &...Args) { BoundTypeDiagnoser<Ts...> Diagnoser(DiagID, Args...); return RequireCompleteType(Loc, T, Diagnoser); } template <typename... Ts> bool RequireCompleteSizedType(SourceLocation Loc, QualType T, unsigned DiagID, const Ts &... Args) { SizelessTypeDiagnoser<Ts...> Diagnoser(DiagID, Args...); return RequireCompleteType(Loc, T, CompleteTypeKind::Normal, Diagnoser); } /// Get the type of expression E, triggering instantiation to complete the /// type if necessary -- that is, if the expression refers to a templated /// static data member of incomplete array type. /// /// May still return an incomplete type if instantiation was not possible or /// if the type is incomplete for a different reason. Use /// RequireCompleteExprType instead if a diagnostic is expected for an /// incomplete expression type. QualType getCompletedType(Expr *E); void completeExprArrayBound(Expr *E); bool RequireCompleteExprType(Expr *E, CompleteTypeKind Kind, TypeDiagnoser &Diagnoser); bool RequireCompleteExprType(Expr *E, unsigned DiagID); template <typename... Ts> bool RequireCompleteExprType(Expr *E, unsigned DiagID, const Ts &...Args) { BoundTypeDiagnoser<Ts...> Diagnoser(DiagID, Args...); return RequireCompleteExprType(E, CompleteTypeKind::Default, Diagnoser); } template <typename... Ts> bool RequireCompleteSizedExprType(Expr *E, unsigned DiagID, const Ts &... Args) { SizelessTypeDiagnoser<Ts...> Diagnoser(DiagID, Args...); return RequireCompleteExprType(E, CompleteTypeKind::Normal, Diagnoser); } bool RequireLiteralType(SourceLocation Loc, QualType T, TypeDiagnoser &Diagnoser); bool RequireLiteralType(SourceLocation Loc, QualType T, unsigned DiagID); template <typename... Ts> bool RequireLiteralType(SourceLocation Loc, QualType T, unsigned DiagID, const Ts &...Args) { BoundTypeDiagnoser<Ts...> Diagnoser(DiagID, Args...); return RequireLiteralType(Loc, T, Diagnoser); } QualType getElaboratedType(ElaboratedTypeKeyword Keyword, const CXXScopeSpec &SS, QualType T, TagDecl *OwnedTagDecl = nullptr); QualType BuildTypeofExprType(Expr *E, SourceLocation Loc); /// If AsUnevaluated is false, E is treated as though it were an evaluated /// context, such as when building a type for decltype(auto). QualType BuildDecltypeType(Expr *E, SourceLocation Loc, bool AsUnevaluated = true); QualType BuildUnaryTransformType(QualType BaseType, UnaryTransformType::UTTKind UKind, SourceLocation Loc); //===--------------------------------------------------------------------===// // Symbol table / Decl tracking callbacks: SemaDecl.cpp. // struct SkipBodyInfo { SkipBodyInfo() : ShouldSkip(false), CheckSameAsPrevious(false), Previous(nullptr), New(nullptr) {} bool ShouldSkip; bool CheckSameAsPrevious; NamedDecl *Previous; NamedDecl *New; }; DeclGroupPtrTy ConvertDeclToDeclGroup(Decl *Ptr, Decl *OwnedType = nullptr); void DiagnoseUseOfUnimplementedSelectors(); bool isSimpleTypeSpecifier(tok::TokenKind Kind) const; ParsedType getTypeName(const IdentifierInfo &II, SourceLocation NameLoc, Scope *S, CXXScopeSpec *SS = nullptr, bool isClassName = false, bool HasTrailingDot = false, ParsedType ObjectType = nullptr, bool IsCtorOrDtorName = false, bool WantNontrivialTypeSourceInfo = false, bool IsClassTemplateDeductionContext = true, IdentifierInfo **CorrectedII = nullptr); TypeSpecifierType isTagName(IdentifierInfo &II, Scope *S); bool isMicrosoftMissingTypename(const CXXScopeSpec *SS, Scope *S); void DiagnoseUnknownTypeName(IdentifierInfo *&II, SourceLocation IILoc, Scope *S, CXXScopeSpec *SS, ParsedType &SuggestedType, bool IsTemplateName = false); /// Attempt to behave like MSVC in situations where lookup of an unqualified /// type name has failed in a dependent context. In these situations, we /// automatically form a DependentTypeName that will retry lookup in a related /// scope during instantiation. ParsedType ActOnMSVCUnknownTypeName(const IdentifierInfo &II, SourceLocation NameLoc, bool IsTemplateTypeArg); /// Describes the result of the name lookup and resolution performed /// by \c ClassifyName(). enum NameClassificationKind { /// This name is not a type or template in this context, but might be /// something else. NC_Unknown, /// Classification failed; an error has been produced. NC_Error, /// The name has been typo-corrected to a keyword. NC_Keyword, /// The name was classified as a type. NC_Type, /// The name was classified as a specific non-type, non-template /// declaration. ActOnNameClassifiedAsNonType should be called to /// convert the declaration to an expression. NC_NonType, /// The name was classified as an ADL-only function name. /// ActOnNameClassifiedAsUndeclaredNonType should be called to convert the /// result to an expression. NC_UndeclaredNonType, /// The name denotes a member of a dependent type that could not be /// resolved. ActOnNameClassifiedAsDependentNonType should be called to /// convert the result to an expression. NC_DependentNonType, /// The name was classified as an overload set, and an expression /// representing that overload set has been formed. /// ActOnNameClassifiedAsOverloadSet should be called to form a suitable /// expression referencing the overload set. NC_OverloadSet, /// The name was classified as a template whose specializations are types. NC_TypeTemplate, /// The name was classified as a variable template name. NC_VarTemplate, /// The name was classified as a function template name. NC_FunctionTemplate, /// The name was classified as an ADL-only function template name. NC_UndeclaredTemplate, /// The name was classified as a concept name. NC_Concept, }; class NameClassification { NameClassificationKind Kind; union { ExprResult Expr; NamedDecl *NonTypeDecl; TemplateName Template; ParsedType Type; }; explicit NameClassification(NameClassificationKind Kind) : Kind(Kind) {} public: NameClassification(ParsedType Type) : Kind(NC_Type), Type(Type) {} NameClassification(const IdentifierInfo *Keyword) : Kind(NC_Keyword) {} static NameClassification Error() { return NameClassification(NC_Error); } static NameClassification Unknown() { return NameClassification(NC_Unknown); } static NameClassification OverloadSet(ExprResult E) { NameClassification Result(NC_OverloadSet); Result.Expr = E; return Result; } static NameClassification NonType(NamedDecl *D) { NameClassification Result(NC_NonType); Result.NonTypeDecl = D; return Result; } static NameClassification UndeclaredNonType() { return NameClassification(NC_UndeclaredNonType); } static NameClassification DependentNonType() { return NameClassification(NC_DependentNonType); } static NameClassification TypeTemplate(TemplateName Name) { NameClassification Result(NC_TypeTemplate); Result.Template = Name; return Result; } static NameClassification VarTemplate(TemplateName Name) { NameClassification Result(NC_VarTemplate); Result.Template = Name; return Result; } static NameClassification FunctionTemplate(TemplateName Name) { NameClassification Result(NC_FunctionTemplate); Result.Template = Name; return Result; } static NameClassification Concept(TemplateName Name) { NameClassification Result(NC_Concept); Result.Template = Name; return Result; } static NameClassification UndeclaredTemplate(TemplateName Name) { NameClassification Result(NC_UndeclaredTemplate); Result.Template = Name; return Result; } NameClassificationKind getKind() const { return Kind; } ExprResult getExpression() const { assert(Kind == NC_OverloadSet); return Expr; } ParsedType getType() const { assert(Kind == NC_Type); return Type; } NamedDecl *getNonTypeDecl() const { assert(Kind == NC_NonType); return NonTypeDecl; } TemplateName getTemplateName() const { assert(Kind == NC_TypeTemplate || Kind == NC_FunctionTemplate || Kind == NC_VarTemplate || Kind == NC_Concept || Kind == NC_UndeclaredTemplate); return Template; } TemplateNameKind getTemplateNameKind() const { switch (Kind) { case NC_TypeTemplate: return TNK_Type_template; case NC_FunctionTemplate: return TNK_Function_template; case NC_VarTemplate: return TNK_Var_template; case NC_Concept: return TNK_Concept_template; case NC_UndeclaredTemplate: return TNK_Undeclared_template; default: llvm_unreachable("unsupported name classification."); } } }; /// Perform name lookup on the given name, classifying it based on /// the results of name lookup and the following token. /// /// This routine is used by the parser to resolve identifiers and help direct /// parsing. When the identifier cannot be found, this routine will attempt /// to correct the typo and classify based on the resulting name. /// /// \param S The scope in which we're performing name lookup. /// /// \param SS The nested-name-specifier that precedes the name. /// /// \param Name The identifier. If typo correction finds an alternative name, /// this pointer parameter will be updated accordingly. /// /// \param NameLoc The location of the identifier. /// /// \param NextToken The token following the identifier. Used to help /// disambiguate the name. /// /// \param CCC The correction callback, if typo correction is desired. NameClassification ClassifyName(Scope *S, CXXScopeSpec &SS, IdentifierInfo *&Name, SourceLocation NameLoc, const Token &NextToken, CorrectionCandidateCallback *CCC = nullptr); /// Act on the result of classifying a name as an undeclared (ADL-only) /// non-type declaration. ExprResult ActOnNameClassifiedAsUndeclaredNonType(IdentifierInfo *Name, SourceLocation NameLoc); /// Act on the result of classifying a name as an undeclared member of a /// dependent base class. ExprResult ActOnNameClassifiedAsDependentNonType(const CXXScopeSpec &SS, IdentifierInfo *Name, SourceLocation NameLoc, bool IsAddressOfOperand); /// Act on the result of classifying a name as a specific non-type /// declaration. ExprResult ActOnNameClassifiedAsNonType(Scope *S, const CXXScopeSpec &SS, NamedDecl *Found, SourceLocation NameLoc, const Token &NextToken); /// Act on the result of classifying a name as an overload set. ExprResult ActOnNameClassifiedAsOverloadSet(Scope *S, Expr *OverloadSet); /// Describes the detailed kind of a template name. Used in diagnostics. enum class TemplateNameKindForDiagnostics { ClassTemplate, FunctionTemplate, VarTemplate, AliasTemplate, TemplateTemplateParam, Concept, DependentTemplate }; TemplateNameKindForDiagnostics getTemplateNameKindForDiagnostics(TemplateName Name); /// Determine whether it's plausible that E was intended to be a /// template-name. bool mightBeIntendedToBeTemplateName(ExprResult E, bool &Dependent) { if (!getLangOpts().CPlusPlus || E.isInvalid()) return false; Dependent = false; if (auto *DRE = dyn_cast<DeclRefExpr>(E.get())) return !DRE->hasExplicitTemplateArgs(); if (auto *ME = dyn_cast<MemberExpr>(E.get())) return !ME->hasExplicitTemplateArgs(); Dependent = true; if (auto *DSDRE = dyn_cast<DependentScopeDeclRefExpr>(E.get())) return !DSDRE->hasExplicitTemplateArgs(); if (auto *DSME = dyn_cast<CXXDependentScopeMemberExpr>(E.get())) return !DSME->hasExplicitTemplateArgs(); // Any additional cases recognized here should also be handled by // diagnoseExprIntendedAsTemplateName. return false; } void diagnoseExprIntendedAsTemplateName(Scope *S, ExprResult TemplateName, SourceLocation Less, SourceLocation Greater); void warnOnReservedIdentifier(const NamedDecl *D); Decl *ActOnDeclarator(Scope *S, Declarator &D); NamedDecl *HandleDeclarator(Scope *S, Declarator &D, MultiTemplateParamsArg TemplateParameterLists); bool tryToFixVariablyModifiedVarType(TypeSourceInfo *&TInfo, QualType &T, SourceLocation Loc, unsigned FailedFoldDiagID); void RegisterLocallyScopedExternCDecl(NamedDecl *ND, Scope *S); bool DiagnoseClassNameShadow(DeclContext *DC, DeclarationNameInfo Info); bool diagnoseQualifiedDeclaration(CXXScopeSpec &SS, DeclContext *DC, DeclarationName Name, SourceLocation Loc, bool IsTemplateId); void diagnoseIgnoredQualifiers(unsigned DiagID, unsigned Quals, SourceLocation FallbackLoc, SourceLocation ConstQualLoc = SourceLocation(), SourceLocation VolatileQualLoc = SourceLocation(), SourceLocation RestrictQualLoc = SourceLocation(), SourceLocation AtomicQualLoc = SourceLocation(), SourceLocation UnalignedQualLoc = SourceLocation()); static bool adjustContextForLocalExternDecl(DeclContext *&DC); void DiagnoseFunctionSpecifiers(const DeclSpec &DS); NamedDecl *getShadowedDeclaration(const TypedefNameDecl *D, const LookupResult &R); NamedDecl *getShadowedDeclaration(const VarDecl *D, const LookupResult &R); NamedDecl *getShadowedDeclaration(const BindingDecl *D, const LookupResult &R); void CheckShadow(NamedDecl *D, NamedDecl *ShadowedDecl, const LookupResult &R); void CheckShadow(Scope *S, VarDecl *D); /// Warn if 'E', which is an expression that is about to be modified, refers /// to a shadowing declaration. void CheckShadowingDeclModification(Expr *E, SourceLocation Loc); void DiagnoseShadowingLambdaDecls(const sema::LambdaScopeInfo *LSI); private: /// Map of current shadowing declarations to shadowed declarations. Warn if /// it looks like the user is trying to modify the shadowing declaration. llvm::DenseMap<const NamedDecl *, const NamedDecl *> ShadowingDecls; public: void CheckCastAlign(Expr *Op, QualType T, SourceRange TRange); void handleTagNumbering(const TagDecl *Tag, Scope *TagScope); void setTagNameForLinkagePurposes(TagDecl *TagFromDeclSpec, TypedefNameDecl *NewTD); void CheckTypedefForVariablyModifiedType(Scope *S, TypedefNameDecl *D); NamedDecl* ActOnTypedefDeclarator(Scope* S, Declarator& D, DeclContext* DC, TypeSourceInfo *TInfo, LookupResult &Previous); NamedDecl* ActOnTypedefNameDecl(Scope* S, DeclContext* DC, TypedefNameDecl *D, LookupResult &Previous, bool &Redeclaration); NamedDecl *ActOnVariableDeclarator(Scope *S, Declarator &D, DeclContext *DC, TypeSourceInfo *TInfo, LookupResult &Previous, MultiTemplateParamsArg TemplateParamLists, bool &AddToScope, ArrayRef<BindingDecl *> Bindings = None); NamedDecl * ActOnDecompositionDeclarator(Scope *S, Declarator &D, MultiTemplateParamsArg TemplateParamLists); // Returns true if the variable declaration is a redeclaration bool CheckVariableDeclaration(VarDecl *NewVD, LookupResult &Previous); void CheckVariableDeclarationType(VarDecl *NewVD); bool DeduceVariableDeclarationType(VarDecl *VDecl, bool DirectInit, Expr *Init); void CheckCompleteVariableDeclaration(VarDecl *VD); void CheckCompleteDecompositionDeclaration(DecompositionDecl *DD); void MaybeSuggestAddingStaticToDecl(const FunctionDecl *D); NamedDecl* ActOnFunctionDeclarator(Scope* S, Declarator& D, DeclContext* DC, TypeSourceInfo *TInfo, LookupResult &Previous, MultiTemplateParamsArg TemplateParamLists, bool &AddToScope); bool AddOverriddenMethods(CXXRecordDecl *DC, CXXMethodDecl *MD); enum class CheckConstexprKind { /// Diagnose issues that are non-constant or that are extensions. Diagnose, /// Identify whether this function satisfies the formal rules for constexpr /// functions in the current lanugage mode (with no extensions). CheckValid }; bool CheckConstexprFunctionDefinition(const FunctionDecl *FD, CheckConstexprKind Kind); void DiagnoseHiddenVirtualMethods(CXXMethodDecl *MD); void FindHiddenVirtualMethods(CXXMethodDecl *MD, SmallVectorImpl<CXXMethodDecl*> &OverloadedMethods); void NoteHiddenVirtualMethods(CXXMethodDecl *MD, SmallVectorImpl<CXXMethodDecl*> &OverloadedMethods); // Returns true if the function declaration is a redeclaration bool CheckFunctionDeclaration(Scope *S, FunctionDecl *NewFD, LookupResult &Previous, bool IsMemberSpecialization); bool shouldLinkDependentDeclWithPrevious(Decl *D, Decl *OldDecl); bool canFullyTypeCheckRedeclaration(ValueDecl *NewD, ValueDecl *OldD, QualType NewT, QualType OldT); void CheckMain(FunctionDecl *FD, const DeclSpec &D); void CheckMSVCRTEntryPoint(FunctionDecl *FD); Attr *getImplicitCodeSegOrSectionAttrForFunction(const FunctionDecl *FD, bool IsDefinition); void CheckFunctionOrTemplateParamDeclarator(Scope *S, Declarator &D); Decl *ActOnParamDeclarator(Scope *S, Declarator &D); ParmVarDecl *BuildParmVarDeclForTypedef(DeclContext *DC, SourceLocation Loc, QualType T); ParmVarDecl *CheckParameter(DeclContext *DC, SourceLocation StartLoc, SourceLocation NameLoc, IdentifierInfo *Name, QualType T, TypeSourceInfo *TSInfo, StorageClass SC); void ActOnParamDefaultArgument(Decl *param, SourceLocation EqualLoc, Expr *defarg); void ActOnParamUnparsedDefaultArgument(Decl *param, SourceLocation EqualLoc, SourceLocation ArgLoc); void ActOnParamDefaultArgumentError(Decl *param, SourceLocation EqualLoc); ExprResult ConvertParamDefaultArgument(ParmVarDecl *Param, Expr *DefaultArg, SourceLocation EqualLoc); void SetParamDefaultArgument(ParmVarDecl *Param, Expr *DefaultArg, SourceLocation EqualLoc); // Contexts where using non-trivial C union types can be disallowed. This is // passed to err_non_trivial_c_union_in_invalid_context. enum NonTrivialCUnionContext { // Function parameter. NTCUC_FunctionParam, // Function return. NTCUC_FunctionReturn, // Default-initialized object. NTCUC_DefaultInitializedObject, // Variable with automatic storage duration. NTCUC_AutoVar, // Initializer expression that might copy from another object. NTCUC_CopyInit, // Assignment. NTCUC_Assignment, // Compound literal. NTCUC_CompoundLiteral, // Block capture. NTCUC_BlockCapture, // lvalue-to-rvalue conversion of volatile type. NTCUC_LValueToRValueVolatile, }; /// Emit diagnostics if the initializer or any of its explicit or /// implicitly-generated subexpressions require copying or /// default-initializing a type that is or contains a C union type that is /// non-trivial to copy or default-initialize. void checkNonTrivialCUnionInInitializer(const Expr *Init, SourceLocation Loc); // These flags are passed to checkNonTrivialCUnion. enum NonTrivialCUnionKind { NTCUK_Init = 0x1, NTCUK_Destruct = 0x2, NTCUK_Copy = 0x4, }; /// Emit diagnostics if a non-trivial C union type or a struct that contains /// a non-trivial C union is used in an invalid context. void checkNonTrivialCUnion(QualType QT, SourceLocation Loc, NonTrivialCUnionContext UseContext, unsigned NonTrivialKind); void AddInitializerToDecl(Decl *dcl, Expr *init, bool DirectInit); void ActOnUninitializedDecl(Decl *dcl); void ActOnInitializerError(Decl *Dcl); void ActOnPureSpecifier(Decl *D, SourceLocation PureSpecLoc); void ActOnCXXForRangeDecl(Decl *D); StmtResult ActOnCXXForRangeIdentifier(Scope *S, SourceLocation IdentLoc, IdentifierInfo *Ident, ParsedAttributes &Attrs, SourceLocation AttrEnd); void SetDeclDeleted(Decl *dcl, SourceLocation DelLoc); void SetDeclDefaulted(Decl *dcl, SourceLocation DefaultLoc); void CheckStaticLocalForDllExport(VarDecl *VD); void FinalizeDeclaration(Decl *D); DeclGroupPtrTy FinalizeDeclaratorGroup(Scope *S, const DeclSpec &DS, ArrayRef<Decl *> Group); DeclGroupPtrTy BuildDeclaratorGroup(MutableArrayRef<Decl *> Group); /// Should be called on all declarations that might have attached /// documentation comments. void ActOnDocumentableDecl(Decl *D); void ActOnDocumentableDecls(ArrayRef<Decl *> Group); void ActOnFinishKNRParamDeclarations(Scope *S, Declarator &D, SourceLocation LocAfterDecls); void CheckForFunctionRedefinition( FunctionDecl *FD, const FunctionDecl *EffectiveDefinition = nullptr, SkipBodyInfo *SkipBody = nullptr); Decl *ActOnStartOfFunctionDef(Scope *S, Declarator &D, MultiTemplateParamsArg TemplateParamLists, SkipBodyInfo *SkipBody = nullptr); Decl *ActOnStartOfFunctionDef(Scope *S, Decl *D, SkipBodyInfo *SkipBody = nullptr); void ActOnStartTrailingRequiresClause(Scope *S, Declarator &D); ExprResult ActOnFinishTrailingRequiresClause(ExprResult ConstraintExpr); ExprResult ActOnRequiresClause(ExprResult ConstraintExpr); void ActOnStartOfObjCMethodDef(Scope *S, Decl *D); bool isObjCMethodDecl(Decl *D) { return D && isa<ObjCMethodDecl>(D); } /// Determine whether we can delay parsing the body of a function or /// function template until it is used, assuming we don't care about emitting /// code for that function. /// /// This will be \c false if we may need the body of the function in the /// middle of parsing an expression (where it's impractical to switch to /// parsing a different function), for instance, if it's constexpr in C++11 /// or has an 'auto' return type in C++14. These cases are essentially bugs. bool canDelayFunctionBody(const Declarator &D); /// Determine whether we can skip parsing the body of a function /// definition, assuming we don't care about analyzing its body or emitting /// code for that function. /// /// This will be \c false only if we may need the body of the function in /// order to parse the rest of the program (for instance, if it is /// \c constexpr in C++11 or has an 'auto' return type in C++14). bool canSkipFunctionBody(Decl *D); void computeNRVO(Stmt *Body, sema::FunctionScopeInfo *Scope); Decl *ActOnFinishFunctionBody(Decl *Decl, Stmt *Body); Decl *ActOnFinishFunctionBody(Decl *Decl, Stmt *Body, bool IsInstantiation); Decl *ActOnSkippedFunctionBody(Decl *Decl); void ActOnFinishInlineFunctionDef(FunctionDecl *D); /// ActOnFinishDelayedAttribute - Invoked when we have finished parsing an /// attribute for which parsing is delayed. void ActOnFinishDelayedAttribute(Scope *S, Decl *D, ParsedAttributes &Attrs); /// Diagnose any unused parameters in the given sequence of /// ParmVarDecl pointers. void DiagnoseUnusedParameters(ArrayRef<ParmVarDecl *> Parameters); /// Diagnose whether the size of parameters or return value of a /// function or obj-c method definition is pass-by-value and larger than a /// specified threshold. void DiagnoseSizeOfParametersAndReturnValue(ArrayRef<ParmVarDecl *> Parameters, QualType ReturnTy, NamedDecl *D); void DiagnoseInvalidJumps(Stmt *Body); Decl *ActOnFileScopeAsmDecl(Expr *expr, SourceLocation AsmLoc, SourceLocation RParenLoc); /// Handle a C++11 empty-declaration and attribute-declaration. Decl *ActOnEmptyDeclaration(Scope *S, const ParsedAttributesView &AttrList, SourceLocation SemiLoc); enum class ModuleDeclKind { Interface, ///< 'export module X;' Implementation, ///< 'module X;' }; /// The parser has processed a module-declaration that begins the definition /// of a module interface or implementation. DeclGroupPtrTy ActOnModuleDecl(SourceLocation StartLoc, SourceLocation ModuleLoc, ModuleDeclKind MDK, ModuleIdPath Path, bool IsFirstDecl); /// The parser has processed a global-module-fragment declaration that begins /// the definition of the global module fragment of the current module unit. /// \param ModuleLoc The location of the 'module' keyword. DeclGroupPtrTy ActOnGlobalModuleFragmentDecl(SourceLocation ModuleLoc); /// The parser has processed a private-module-fragment declaration that begins /// the definition of the private module fragment of the current module unit. /// \param ModuleLoc The location of the 'module' keyword. /// \param PrivateLoc The location of the 'private' keyword. DeclGroupPtrTy ActOnPrivateModuleFragmentDecl(SourceLocation ModuleLoc, SourceLocation PrivateLoc); /// The parser has processed a module import declaration. /// /// \param StartLoc The location of the first token in the declaration. This /// could be the location of an '@', 'export', or 'import'. /// \param ExportLoc The location of the 'export' keyword, if any. /// \param ImportLoc The location of the 'import' keyword. /// \param Path The module access path. DeclResult ActOnModuleImport(SourceLocation StartLoc, SourceLocation ExportLoc, SourceLocation ImportLoc, ModuleIdPath Path); DeclResult ActOnModuleImport(SourceLocation StartLoc, SourceLocation ExportLoc, SourceLocation ImportLoc, Module *M, ModuleIdPath Path = {}); /// The parser has processed a module import translated from a /// #include or similar preprocessing directive. void ActOnModuleInclude(SourceLocation DirectiveLoc, Module *Mod); void BuildModuleInclude(SourceLocation DirectiveLoc, Module *Mod); /// The parsed has entered a submodule. void ActOnModuleBegin(SourceLocation DirectiveLoc, Module *Mod); /// The parser has left a submodule. void ActOnModuleEnd(SourceLocation DirectiveLoc, Module *Mod); /// Create an implicit import of the given module at the given /// source location, for error recovery, if possible. /// /// This routine is typically used when an entity found by name lookup /// is actually hidden within a module that we know about but the user /// has forgotten to import. void createImplicitModuleImportForErrorRecovery(SourceLocation Loc, Module *Mod); /// Kinds of missing import. Note, the values of these enumerators correspond /// to %select values in diagnostics. enum class MissingImportKind { Declaration, Definition, DefaultArgument, ExplicitSpecialization, PartialSpecialization }; /// Diagnose that the specified declaration needs to be visible but /// isn't, and suggest a module import that would resolve the problem. void diagnoseMissingImport(SourceLocation Loc, NamedDecl *Decl, MissingImportKind MIK, bool Recover = true); void diagnoseMissingImport(SourceLocation Loc, NamedDecl *Decl, SourceLocation DeclLoc, ArrayRef<Module *> Modules, MissingImportKind MIK, bool Recover); Decl *ActOnStartExportDecl(Scope *S, SourceLocation ExportLoc, SourceLocation LBraceLoc); Decl *ActOnFinishExportDecl(Scope *S, Decl *ExportDecl, SourceLocation RBraceLoc); /// We've found a use of a templated declaration that would trigger an /// implicit instantiation. Check that any relevant explicit specializations /// and partial specializations are visible, and diagnose if not. void checkSpecializationVisibility(SourceLocation Loc, NamedDecl *Spec); /// Retrieve a suitable printing policy for diagnostics. PrintingPolicy getPrintingPolicy() const { return getPrintingPolicy(Context, PP); } /// Retrieve a suitable printing policy for diagnostics. static PrintingPolicy getPrintingPolicy(const ASTContext &Ctx, const Preprocessor &PP); /// Scope actions. void ActOnPopScope(SourceLocation Loc, Scope *S); void ActOnTranslationUnitScope(Scope *S); Decl *ParsedFreeStandingDeclSpec(Scope *S, AccessSpecifier AS, DeclSpec &DS, RecordDecl *&AnonRecord); Decl *ParsedFreeStandingDeclSpec(Scope *S, AccessSpecifier AS, DeclSpec &DS, MultiTemplateParamsArg TemplateParams, bool IsExplicitInstantiation, RecordDecl *&AnonRecord); Decl *BuildAnonymousStructOrUnion(Scope *S, DeclSpec &DS, AccessSpecifier AS, RecordDecl *Record, const PrintingPolicy &Policy); Decl *BuildMicrosoftCAnonymousStruct(Scope *S, DeclSpec &DS, RecordDecl *Record); /// Common ways to introduce type names without a tag for use in diagnostics. /// Keep in sync with err_tag_reference_non_tag. enum NonTagKind { NTK_NonStruct, NTK_NonClass, NTK_NonUnion, NTK_NonEnum, NTK_Typedef, NTK_TypeAlias, NTK_Template, NTK_TypeAliasTemplate, NTK_TemplateTemplateArgument, }; /// Given a non-tag type declaration, returns an enum useful for indicating /// what kind of non-tag type this is. NonTagKind getNonTagTypeDeclKind(const Decl *D, TagTypeKind TTK); bool isAcceptableTagRedeclaration(const TagDecl *Previous, TagTypeKind NewTag, bool isDefinition, SourceLocation NewTagLoc, const IdentifierInfo *Name); enum TagUseKind { TUK_Reference, // Reference to a tag: 'struct foo *X;' TUK_Declaration, // Fwd decl of a tag: 'struct foo;' TUK_Definition, // Definition of a tag: 'struct foo { int X; } Y;' TUK_Friend // Friend declaration: 'friend struct foo;' }; Decl *ActOnTag(Scope *S, unsigned TagSpec, TagUseKind TUK, SourceLocation KWLoc, CXXScopeSpec &SS, IdentifierInfo *Name, SourceLocation NameLoc, const ParsedAttributesView &Attr, AccessSpecifier AS, SourceLocation ModulePrivateLoc, MultiTemplateParamsArg TemplateParameterLists, bool &OwnedDecl, bool &IsDependent, SourceLocation ScopedEnumKWLoc, bool ScopedEnumUsesClassTag, TypeResult UnderlyingType, bool IsTypeSpecifier, bool IsTemplateParamOrArg, SkipBodyInfo *SkipBody = nullptr); Decl *ActOnTemplatedFriendTag(Scope *S, SourceLocation FriendLoc, unsigned TagSpec, SourceLocation TagLoc, CXXScopeSpec &SS, IdentifierInfo *Name, SourceLocation NameLoc, const ParsedAttributesView &Attr, MultiTemplateParamsArg TempParamLists); TypeResult ActOnDependentTag(Scope *S, unsigned TagSpec, TagUseKind TUK, const CXXScopeSpec &SS, IdentifierInfo *Name, SourceLocation TagLoc, SourceLocation NameLoc); void ActOnDefs(Scope *S, Decl *TagD, SourceLocation DeclStart, IdentifierInfo *ClassName, SmallVectorImpl<Decl *> &Decls); Decl *ActOnField(Scope *S, Decl *TagD, SourceLocation DeclStart, Declarator &D, Expr *BitfieldWidth); FieldDecl *HandleField(Scope *S, RecordDecl *TagD, SourceLocation DeclStart, Declarator &D, Expr *BitfieldWidth, InClassInitStyle InitStyle, AccessSpecifier AS); MSPropertyDecl *HandleMSProperty(Scope *S, RecordDecl *TagD, SourceLocation DeclStart, Declarator &D, Expr *BitfieldWidth, InClassInitStyle InitStyle, AccessSpecifier AS, const ParsedAttr &MSPropertyAttr); FieldDecl *CheckFieldDecl(DeclarationName Name, QualType T, TypeSourceInfo *TInfo, RecordDecl *Record, SourceLocation Loc, bool Mutable, Expr *BitfieldWidth, InClassInitStyle InitStyle, SourceLocation TSSL, AccessSpecifier AS, NamedDecl *PrevDecl, Declarator *D = nullptr); bool CheckNontrivialField(FieldDecl *FD); void DiagnoseNontrivial(const CXXRecordDecl *Record, CXXSpecialMember CSM); enum TrivialABIHandling { /// The triviality of a method unaffected by "trivial_abi". TAH_IgnoreTrivialABI, /// The triviality of a method affected by "trivial_abi". TAH_ConsiderTrivialABI }; bool SpecialMemberIsTrivial(CXXMethodDecl *MD, CXXSpecialMember CSM, TrivialABIHandling TAH = TAH_IgnoreTrivialABI, bool Diagnose = false); /// For a defaulted function, the kind of defaulted function that it is. class DefaultedFunctionKind { CXXSpecialMember SpecialMember : 8; DefaultedComparisonKind Comparison : 8; public: DefaultedFunctionKind() : SpecialMember(CXXInvalid), Comparison(DefaultedComparisonKind::None) { } DefaultedFunctionKind(CXXSpecialMember CSM) : SpecialMember(CSM), Comparison(DefaultedComparisonKind::None) {} DefaultedFunctionKind(DefaultedComparisonKind Comp) : SpecialMember(CXXInvalid), Comparison(Comp) {} bool isSpecialMember() const { return SpecialMember != CXXInvalid; } bool isComparison() const { return Comparison != DefaultedComparisonKind::None; } explicit operator bool() const { return isSpecialMember() || isComparison(); } CXXSpecialMember asSpecialMember() const { return SpecialMember; } DefaultedComparisonKind asComparison() const { return Comparison; } /// Get the index of this function kind for use in diagnostics. unsigned getDiagnosticIndex() const { static_assert(CXXInvalid > CXXDestructor, "invalid should have highest index"); static_assert((unsigned)DefaultedComparisonKind::None == 0, "none should be equal to zero"); return SpecialMember + (unsigned)Comparison; } }; DefaultedFunctionKind getDefaultedFunctionKind(const FunctionDecl *FD); CXXSpecialMember getSpecialMember(const CXXMethodDecl *MD) { return getDefaultedFunctionKind(MD).asSpecialMember(); } DefaultedComparisonKind getDefaultedComparisonKind(const FunctionDecl *FD) { return getDefaultedFunctionKind(FD).asComparison(); } void ActOnLastBitfield(SourceLocation DeclStart, SmallVectorImpl<Decl *> &AllIvarDecls); Decl *ActOnIvar(Scope *S, SourceLocation DeclStart, Declarator &D, Expr *BitfieldWidth, tok::ObjCKeywordKind visibility); // This is used for both record definitions and ObjC interface declarations. void ActOnFields(Scope *S, SourceLocation RecLoc, Decl *TagDecl, ArrayRef<Decl *> Fields, SourceLocation LBrac, SourceLocation RBrac, const ParsedAttributesView &AttrList); /// ActOnTagStartDefinition - Invoked when we have entered the /// scope of a tag's definition (e.g., for an enumeration, class, /// struct, or union). void ActOnTagStartDefinition(Scope *S, Decl *TagDecl); /// Perform ODR-like check for C/ObjC when merging tag types from modules. /// Differently from C++, actually parse the body and reject / error out /// in case of a structural mismatch. bool ActOnDuplicateDefinition(DeclSpec &DS, Decl *Prev, SkipBodyInfo &SkipBody); typedef void *SkippedDefinitionContext; /// Invoked when we enter a tag definition that we're skipping. SkippedDefinitionContext ActOnTagStartSkippedDefinition(Scope *S, Decl *TD); Decl *ActOnObjCContainerStartDefinition(Decl *IDecl); /// ActOnStartCXXMemberDeclarations - Invoked when we have parsed a /// C++ record definition's base-specifiers clause and are starting its /// member declarations. void ActOnStartCXXMemberDeclarations(Scope *S, Decl *TagDecl, SourceLocation FinalLoc, bool IsFinalSpelledSealed, bool IsAbstract, SourceLocation LBraceLoc); /// ActOnTagFinishDefinition - Invoked once we have finished parsing /// the definition of a tag (enumeration, class, struct, or union). void ActOnTagFinishDefinition(Scope *S, Decl *TagDecl, SourceRange BraceRange); void ActOnTagFinishSkippedDefinition(SkippedDefinitionContext Context); void ActOnObjCContainerFinishDefinition(); /// Invoked when we must temporarily exit the objective-c container /// scope for parsing/looking-up C constructs. /// /// Must be followed by a call to \see ActOnObjCReenterContainerContext void ActOnObjCTemporaryExitContainerContext(DeclContext *DC); void ActOnObjCReenterContainerContext(DeclContext *DC); /// ActOnTagDefinitionError - Invoked when there was an unrecoverable /// error parsing the definition of a tag. void ActOnTagDefinitionError(Scope *S, Decl *TagDecl); EnumConstantDecl *CheckEnumConstant(EnumDecl *Enum, EnumConstantDecl *LastEnumConst, SourceLocation IdLoc, IdentifierInfo *Id, Expr *val); bool CheckEnumUnderlyingType(TypeSourceInfo *TI); bool CheckEnumRedeclaration(SourceLocation EnumLoc, bool IsScoped, QualType EnumUnderlyingTy, bool IsFixed, const EnumDecl *Prev); /// Determine whether the body of an anonymous enumeration should be skipped. /// \param II The name of the first enumerator. SkipBodyInfo shouldSkipAnonEnumBody(Scope *S, IdentifierInfo *II, SourceLocation IILoc); Decl *ActOnEnumConstant(Scope *S, Decl *EnumDecl, Decl *LastEnumConstant, SourceLocation IdLoc, IdentifierInfo *Id, const ParsedAttributesView &Attrs, SourceLocation EqualLoc, Expr *Val); void ActOnEnumBody(SourceLocation EnumLoc, SourceRange BraceRange, Decl *EnumDecl, ArrayRef<Decl *> Elements, Scope *S, const ParsedAttributesView &Attr); /// Set the current declaration context until it gets popped. void PushDeclContext(Scope *S, DeclContext *DC); void PopDeclContext(); /// EnterDeclaratorContext - Used when we must lookup names in the context /// of a declarator's nested name specifier. void EnterDeclaratorContext(Scope *S, DeclContext *DC); void ExitDeclaratorContext(Scope *S); /// Enter a template parameter scope, after it's been associated with a particular /// DeclContext. Causes lookup within the scope to chain through enclosing contexts /// in the correct order. void EnterTemplatedContext(Scope *S, DeclContext *DC); /// Push the parameters of D, which must be a function, into scope. void ActOnReenterFunctionContext(Scope* S, Decl* D); void ActOnExitFunctionContext(); DeclContext *getFunctionLevelDeclContext(); /// getCurFunctionDecl - If inside of a function body, this returns a pointer /// to the function decl for the function being parsed. If we're currently /// in a 'block', this returns the containing context. FunctionDecl *getCurFunctionDecl(); /// getCurMethodDecl - If inside of a method body, this returns a pointer to /// the method decl for the method being parsed. If we're currently /// in a 'block', this returns the containing context. ObjCMethodDecl *getCurMethodDecl(); /// getCurFunctionOrMethodDecl - Return the Decl for the current ObjC method /// or C function we're in, otherwise return null. If we're currently /// in a 'block', this returns the containing context. NamedDecl *getCurFunctionOrMethodDecl(); /// Add this decl to the scope shadowed decl chains. void PushOnScopeChains(NamedDecl *D, Scope *S, bool AddToContext = true); /// isDeclInScope - If 'Ctx' is a function/method, isDeclInScope returns true /// if 'D' is in Scope 'S', otherwise 'S' is ignored and isDeclInScope returns /// true if 'D' belongs to the given declaration context. /// /// \param AllowInlineNamespace If \c true, allow the declaration to be in the /// enclosing namespace set of the context, rather than contained /// directly within it. bool isDeclInScope(NamedDecl *D, DeclContext *Ctx, Scope *S = nullptr, bool AllowInlineNamespace = false); /// Finds the scope corresponding to the given decl context, if it /// happens to be an enclosing scope. Otherwise return NULL. static Scope *getScopeForDeclContext(Scope *S, DeclContext *DC); /// Subroutines of ActOnDeclarator(). TypedefDecl *ParseTypedefDecl(Scope *S, Declarator &D, QualType T, TypeSourceInfo *TInfo); bool isIncompatibleTypedef(TypeDecl *Old, TypedefNameDecl *New); /// Describes the kind of merge to perform for availability /// attributes (including "deprecated", "unavailable", and "availability"). enum AvailabilityMergeKind { /// Don't merge availability attributes at all. AMK_None, /// Merge availability attributes for a redeclaration, which requires /// an exact match. AMK_Redeclaration, /// Merge availability attributes for an override, which requires /// an exact match or a weakening of constraints. AMK_Override, /// Merge availability attributes for an implementation of /// a protocol requirement. AMK_ProtocolImplementation, /// Merge availability attributes for an implementation of /// an optional protocol requirement. AMK_OptionalProtocolImplementation }; /// Describes the kind of priority given to an availability attribute. /// /// The sum of priorities deteremines the final priority of the attribute. /// The final priority determines how the attribute will be merged. /// An attribute with a lower priority will always remove higher priority /// attributes for the specified platform when it is being applied. An /// attribute with a higher priority will not be applied if the declaration /// already has an availability attribute with a lower priority for the /// specified platform. The final prirority values are not expected to match /// the values in this enumeration, but instead should be treated as a plain /// integer value. This enumeration just names the priority weights that are /// used to calculate that final vaue. enum AvailabilityPriority : int { /// The availability attribute was specified explicitly next to the /// declaration. AP_Explicit = 0, /// The availability attribute was applied using '#pragma clang attribute'. AP_PragmaClangAttribute = 1, /// The availability attribute for a specific platform was inferred from /// an availability attribute for another platform. AP_InferredFromOtherPlatform = 2 }; /// Attribute merging methods. Return true if a new attribute was added. AvailabilityAttr * mergeAvailabilityAttr(NamedDecl *D, const AttributeCommonInfo &CI, IdentifierInfo *Platform, bool Implicit, VersionTuple Introduced, VersionTuple Deprecated, VersionTuple Obsoleted, bool IsUnavailable, StringRef Message, bool IsStrict, StringRef Replacement, AvailabilityMergeKind AMK, int Priority); TypeVisibilityAttr * mergeTypeVisibilityAttr(Decl *D, const AttributeCommonInfo &CI, TypeVisibilityAttr::VisibilityType Vis); VisibilityAttr *mergeVisibilityAttr(Decl *D, const AttributeCommonInfo &CI, VisibilityAttr::VisibilityType Vis); UuidAttr *mergeUuidAttr(Decl *D, const AttributeCommonInfo &CI, StringRef UuidAsWritten, MSGuidDecl *GuidDecl); DLLImportAttr *mergeDLLImportAttr(Decl *D, const AttributeCommonInfo &CI); DLLExportAttr *mergeDLLExportAttr(Decl *D, const AttributeCommonInfo &CI); MSInheritanceAttr *mergeMSInheritanceAttr(Decl *D, const AttributeCommonInfo &CI, bool BestCase, MSInheritanceModel Model); ErrorAttr *mergeErrorAttr(Decl *D, const AttributeCommonInfo &CI, StringRef NewUserDiagnostic); FormatAttr *mergeFormatAttr(Decl *D, const AttributeCommonInfo &CI, IdentifierInfo *Format, int FormatIdx, int FirstArg); SectionAttr *mergeSectionAttr(Decl *D, const AttributeCommonInfo &CI, StringRef Name); CodeSegAttr *mergeCodeSegAttr(Decl *D, const AttributeCommonInfo &CI, StringRef Name); AlwaysInlineAttr *mergeAlwaysInlineAttr(Decl *D, const AttributeCommonInfo &CI, const IdentifierInfo *Ident); MinSizeAttr *mergeMinSizeAttr(Decl *D, const AttributeCommonInfo &CI); SwiftNameAttr *mergeSwiftNameAttr(Decl *D, const SwiftNameAttr &SNA, StringRef Name); OptimizeNoneAttr *mergeOptimizeNoneAttr(Decl *D, const AttributeCommonInfo &CI); InternalLinkageAttr *mergeInternalLinkageAttr(Decl *D, const ParsedAttr &AL); InternalLinkageAttr *mergeInternalLinkageAttr(Decl *D, const InternalLinkageAttr &AL); WebAssemblyImportNameAttr *mergeImportNameAttr( Decl *D, const WebAssemblyImportNameAttr &AL); WebAssemblyImportModuleAttr *mergeImportModuleAttr( Decl *D, const WebAssemblyImportModuleAttr &AL); EnforceTCBAttr *mergeEnforceTCBAttr(Decl *D, const EnforceTCBAttr &AL); EnforceTCBLeafAttr *mergeEnforceTCBLeafAttr(Decl *D, const EnforceTCBLeafAttr &AL); BTFDeclTagAttr *mergeBTFDeclTagAttr(Decl *D, const BTFDeclTagAttr &AL); void mergeDeclAttributes(NamedDecl *New, Decl *Old, AvailabilityMergeKind AMK = AMK_Redeclaration); void MergeTypedefNameDecl(Scope *S, TypedefNameDecl *New, LookupResult &OldDecls); bool MergeFunctionDecl(FunctionDecl *New, NamedDecl *&Old, Scope *S, bool MergeTypeWithOld); bool MergeCompatibleFunctionDecls(FunctionDecl *New, FunctionDecl *Old, Scope *S, bool MergeTypeWithOld); void mergeObjCMethodDecls(ObjCMethodDecl *New, ObjCMethodDecl *Old); void MergeVarDecl(VarDecl *New, LookupResult &Previous); void MergeVarDeclTypes(VarDecl *New, VarDecl *Old, bool MergeTypeWithOld); void MergeVarDeclExceptionSpecs(VarDecl *New, VarDecl *Old); bool checkVarDeclRedefinition(VarDecl *OldDefn, VarDecl *NewDefn); void notePreviousDefinition(const NamedDecl *Old, SourceLocation New); bool MergeCXXFunctionDecl(FunctionDecl *New, FunctionDecl *Old, Scope *S); // AssignmentAction - This is used by all the assignment diagnostic functions // to represent what is actually causing the operation enum AssignmentAction { AA_Assigning, AA_Passing, AA_Returning, AA_Converting, AA_Initializing, AA_Sending, AA_Casting, AA_Passing_CFAudited }; /// C++ Overloading. enum OverloadKind { /// This is a legitimate overload: the existing declarations are /// functions or function templates with different signatures. Ovl_Overload, /// This is not an overload because the signature exactly matches /// an existing declaration. Ovl_Match, /// This is not an overload because the lookup results contain a /// non-function. Ovl_NonFunction }; OverloadKind CheckOverload(Scope *S, FunctionDecl *New, const LookupResult &OldDecls, NamedDecl *&OldDecl, bool IsForUsingDecl); bool IsOverload(FunctionDecl *New, FunctionDecl *Old, bool IsForUsingDecl, bool ConsiderCudaAttrs = true, bool ConsiderRequiresClauses = true); enum class AllowedExplicit { /// Allow no explicit functions to be used. None, /// Allow explicit conversion functions but not explicit constructors. Conversions, /// Allow both explicit conversion functions and explicit constructors. All }; ImplicitConversionSequence TryImplicitConversion(Expr *From, QualType ToType, bool SuppressUserConversions, AllowedExplicit AllowExplicit, bool InOverloadResolution, bool CStyle, bool AllowObjCWritebackConversion); bool IsIntegralPromotion(Expr *From, QualType FromType, QualType ToType); bool IsFloatingPointPromotion(QualType FromType, QualType ToType); bool IsComplexPromotion(QualType FromType, QualType ToType); bool IsPointerConversion(Expr *From, QualType FromType, QualType ToType, bool InOverloadResolution, QualType& ConvertedType, bool &IncompatibleObjC); bool isObjCPointerConversion(QualType FromType, QualType ToType, QualType& ConvertedType, bool &IncompatibleObjC); bool isObjCWritebackConversion(QualType FromType, QualType ToType, QualType &ConvertedType); bool IsBlockPointerConversion(QualType FromType, QualType ToType, QualType& ConvertedType); bool FunctionParamTypesAreEqual(const FunctionProtoType *OldType, const FunctionProtoType *NewType, unsigned *ArgPos = nullptr); void HandleFunctionTypeMismatch(PartialDiagnostic &PDiag, QualType FromType, QualType ToType); void maybeExtendBlockObject(ExprResult &E); CastKind PrepareCastToObjCObjectPointer(ExprResult &E); bool CheckPointerConversion(Expr *From, QualType ToType, CastKind &Kind, CXXCastPath& BasePath, bool IgnoreBaseAccess, bool Diagnose = true); bool IsMemberPointerConversion(Expr *From, QualType FromType, QualType ToType, bool InOverloadResolution, QualType &ConvertedType); bool CheckMemberPointerConversion(Expr *From, QualType ToType, CastKind &Kind, CXXCastPath &BasePath, bool IgnoreBaseAccess); bool IsQualificationConversion(QualType FromType, QualType ToType, bool CStyle, bool &ObjCLifetimeConversion); bool IsFunctionConversion(QualType FromType, QualType ToType, QualType &ResultTy); bool DiagnoseMultipleUserDefinedConversion(Expr *From, QualType ToType); bool isSameOrCompatibleFunctionType(CanQualType Param, CanQualType Arg); bool CanPerformAggregateInitializationForOverloadResolution( const InitializedEntity &Entity, InitListExpr *From); bool IsStringInit(Expr *Init, const ArrayType *AT); bool CanPerformCopyInitialization(const InitializedEntity &Entity, ExprResult Init); ExprResult PerformCopyInitialization(const InitializedEntity &Entity, SourceLocation EqualLoc, ExprResult Init, bool TopLevelOfInitList = false, bool AllowExplicit = false); ExprResult PerformObjectArgumentInitialization(Expr *From, NestedNameSpecifier *Qualifier, NamedDecl *FoundDecl, CXXMethodDecl *Method); /// Check that the lifetime of the initializer (and its subobjects) is /// sufficient for initializing the entity, and perform lifetime extension /// (when permitted) if not. void checkInitializerLifetime(const InitializedEntity &Entity, Expr *Init); ExprResult PerformContextuallyConvertToBool(Expr *From); ExprResult PerformContextuallyConvertToObjCPointer(Expr *From); /// Contexts in which a converted constant expression is required. enum CCEKind { CCEK_CaseValue, ///< Expression in a case label. CCEK_Enumerator, ///< Enumerator value with fixed underlying type. CCEK_TemplateArg, ///< Value of a non-type template parameter. CCEK_ArrayBound, ///< Array bound in array declarator or new-expression. CCEK_ExplicitBool, ///< Condition in an explicit(bool) specifier. CCEK_Noexcept ///< Condition in a noexcept(bool) specifier. }; ExprResult CheckConvertedConstantExpression(Expr *From, QualType T, llvm::APSInt &Value, CCEKind CCE); ExprResult CheckConvertedConstantExpression(Expr *From, QualType T, APValue &Value, CCEKind CCE, NamedDecl *Dest = nullptr); /// Abstract base class used to perform a contextual implicit /// conversion from an expression to any type passing a filter. class ContextualImplicitConverter { public: bool Suppress; bool SuppressConversion; ContextualImplicitConverter(bool Suppress = false, bool SuppressConversion = false) : Suppress(Suppress), SuppressConversion(SuppressConversion) {} /// Determine whether the specified type is a valid destination type /// for this conversion. virtual bool match(QualType T) = 0; /// Emits a diagnostic complaining that the expression does not have /// integral or enumeration type. virtual SemaDiagnosticBuilder diagnoseNoMatch(Sema &S, SourceLocation Loc, QualType T) = 0; /// Emits a diagnostic when the expression has incomplete class type. virtual SemaDiagnosticBuilder diagnoseIncomplete(Sema &S, SourceLocation Loc, QualType T) = 0; /// Emits a diagnostic when the only matching conversion function /// is explicit. virtual SemaDiagnosticBuilder diagnoseExplicitConv( Sema &S, SourceLocation Loc, QualType T, QualType ConvTy) = 0; /// Emits a note for the explicit conversion function. virtual SemaDiagnosticBuilder noteExplicitConv(Sema &S, CXXConversionDecl *Conv, QualType ConvTy) = 0; /// Emits a diagnostic when there are multiple possible conversion /// functions. virtual SemaDiagnosticBuilder diagnoseAmbiguous(Sema &S, SourceLocation Loc, QualType T) = 0; /// Emits a note for one of the candidate conversions. virtual SemaDiagnosticBuilder noteAmbiguous(Sema &S, CXXConversionDecl *Conv, QualType ConvTy) = 0; /// Emits a diagnostic when we picked a conversion function /// (for cases when we are not allowed to pick a conversion function). virtual SemaDiagnosticBuilder diagnoseConversion( Sema &S, SourceLocation Loc, QualType T, QualType ConvTy) = 0; virtual ~ContextualImplicitConverter() {} }; class ICEConvertDiagnoser : public ContextualImplicitConverter { bool AllowScopedEnumerations; public: ICEConvertDiagnoser(bool AllowScopedEnumerations, bool Suppress, bool SuppressConversion) : ContextualImplicitConverter(Suppress, SuppressConversion), AllowScopedEnumerations(AllowScopedEnumerations) {} /// Match an integral or (possibly scoped) enumeration type. bool match(QualType T) override; SemaDiagnosticBuilder diagnoseNoMatch(Sema &S, SourceLocation Loc, QualType T) override { return diagnoseNotInt(S, Loc, T); } /// Emits a diagnostic complaining that the expression does not have /// integral or enumeration type. virtual SemaDiagnosticBuilder diagnoseNotInt(Sema &S, SourceLocation Loc, QualType T) = 0; }; /// Perform a contextual implicit conversion. ExprResult PerformContextualImplicitConversion( SourceLocation Loc, Expr *FromE, ContextualImplicitConverter &Converter); enum ObjCSubscriptKind { OS_Array, OS_Dictionary, OS_Error }; ObjCSubscriptKind CheckSubscriptingKind(Expr *FromE); // Note that LK_String is intentionally after the other literals, as // this is used for diagnostics logic. enum ObjCLiteralKind { LK_Array, LK_Dictionary, LK_Numeric, LK_Boxed, LK_String, LK_Block, LK_None }; ObjCLiteralKind CheckLiteralKind(Expr *FromE); ExprResult PerformObjectMemberConversion(Expr *From, NestedNameSpecifier *Qualifier, NamedDecl *FoundDecl, NamedDecl *Member); // Members have to be NamespaceDecl* or TranslationUnitDecl*. // TODO: make this is a typesafe union. typedef llvm::SmallSetVector<DeclContext *, 16> AssociatedNamespaceSet; typedef llvm::SmallSetVector<CXXRecordDecl *, 16> AssociatedClassSet; using ADLCallKind = CallExpr::ADLCallKind; void AddOverloadCandidate(FunctionDecl *Function, DeclAccessPair FoundDecl, ArrayRef<Expr *> Args, OverloadCandidateSet &CandidateSet, bool SuppressUserConversions = false, bool PartialOverloading = false, bool AllowExplicit = true, bool AllowExplicitConversion = false, ADLCallKind IsADLCandidate = ADLCallKind::NotADL, ConversionSequenceList EarlyConversions = None, OverloadCandidateParamOrder PO = {}); void AddFunctionCandidates(const UnresolvedSetImpl &Functions, ArrayRef<Expr *> Args, OverloadCandidateSet &CandidateSet, TemplateArgumentListInfo *ExplicitTemplateArgs = nullptr, bool SuppressUserConversions = false, bool PartialOverloading = false, bool FirstArgumentIsBase = false); void AddMethodCandidate(DeclAccessPair FoundDecl, QualType ObjectType, Expr::Classification ObjectClassification, ArrayRef<Expr *> Args, OverloadCandidateSet& CandidateSet, bool SuppressUserConversion = false, OverloadCandidateParamOrder PO = {}); void AddMethodCandidate(CXXMethodDecl *Method, DeclAccessPair FoundDecl, CXXRecordDecl *ActingContext, QualType ObjectType, Expr::Classification ObjectClassification, ArrayRef<Expr *> Args, OverloadCandidateSet& CandidateSet, bool SuppressUserConversions = false, bool PartialOverloading = false, ConversionSequenceList EarlyConversions = None, OverloadCandidateParamOrder PO = {}); void AddMethodTemplateCandidate(FunctionTemplateDecl *MethodTmpl, DeclAccessPair FoundDecl, CXXRecordDecl *ActingContext, TemplateArgumentListInfo *ExplicitTemplateArgs, QualType ObjectType, Expr::Classification ObjectClassification, ArrayRef<Expr *> Args, OverloadCandidateSet& CandidateSet, bool SuppressUserConversions = false, bool PartialOverloading = false, OverloadCandidateParamOrder PO = {}); void AddTemplateOverloadCandidate( FunctionTemplateDecl *FunctionTemplate, DeclAccessPair FoundDecl, TemplateArgumentListInfo *ExplicitTemplateArgs, ArrayRef<Expr *> Args, OverloadCandidateSet &CandidateSet, bool SuppressUserConversions = false, bool PartialOverloading = false, bool AllowExplicit = true, ADLCallKind IsADLCandidate = ADLCallKind::NotADL, OverloadCandidateParamOrder PO = {}); bool CheckNonDependentConversions( FunctionTemplateDecl *FunctionTemplate, ArrayRef<QualType> ParamTypes, ArrayRef<Expr *> Args, OverloadCandidateSet &CandidateSet, ConversionSequenceList &Conversions, bool SuppressUserConversions, CXXRecordDecl *ActingContext = nullptr, QualType ObjectType = QualType(), Expr::Classification ObjectClassification = {}, OverloadCandidateParamOrder PO = {}); void AddConversionCandidate( CXXConversionDecl *Conversion, DeclAccessPair FoundDecl, CXXRecordDecl *ActingContext, Expr *From, QualType ToType, OverloadCandidateSet &CandidateSet, bool AllowObjCConversionOnExplicit, bool AllowExplicit, bool AllowResultConversion = true); void AddTemplateConversionCandidate( FunctionTemplateDecl *FunctionTemplate, DeclAccessPair FoundDecl, CXXRecordDecl *ActingContext, Expr *From, QualType ToType, OverloadCandidateSet &CandidateSet, bool AllowObjCConversionOnExplicit, bool AllowExplicit, bool AllowResultConversion = true); void AddSurrogateCandidate(CXXConversionDecl *Conversion, DeclAccessPair FoundDecl, CXXRecordDecl *ActingContext, const FunctionProtoType *Proto, Expr *Object, ArrayRef<Expr *> Args, OverloadCandidateSet& CandidateSet); void AddNonMemberOperatorCandidates( const UnresolvedSetImpl &Functions, ArrayRef<Expr *> Args, OverloadCandidateSet &CandidateSet, TemplateArgumentListInfo *ExplicitTemplateArgs = nullptr); void AddMemberOperatorCandidates(OverloadedOperatorKind Op, SourceLocation OpLoc, ArrayRef<Expr *> Args, OverloadCandidateSet &CandidateSet, OverloadCandidateParamOrder PO = {}); void AddBuiltinCandidate(QualType *ParamTys, ArrayRef<Expr *> Args, OverloadCandidateSet& CandidateSet, bool IsAssignmentOperator = false, unsigned NumContextualBoolArguments = 0); void AddBuiltinOperatorCandidates(OverloadedOperatorKind Op, SourceLocation OpLoc, ArrayRef<Expr *> Args, OverloadCandidateSet& CandidateSet); void AddArgumentDependentLookupCandidates(DeclarationName Name, SourceLocation Loc, ArrayRef<Expr *> Args, TemplateArgumentListInfo *ExplicitTemplateArgs, OverloadCandidateSet& CandidateSet, bool PartialOverloading = false); // Emit as a 'note' the specific overload candidate void NoteOverloadCandidate( NamedDecl *Found, FunctionDecl *Fn, OverloadCandidateRewriteKind RewriteKind = OverloadCandidateRewriteKind(), QualType DestType = QualType(), bool TakingAddress = false); // Emit as a series of 'note's all template and non-templates identified by // the expression Expr void NoteAllOverloadCandidates(Expr *E, QualType DestType = QualType(), bool TakingAddress = false); /// Check the enable_if expressions on the given function. Returns the first /// failing attribute, or NULL if they were all successful. EnableIfAttr *CheckEnableIf(FunctionDecl *Function, SourceLocation CallLoc, ArrayRef<Expr *> Args, bool MissingImplicitThis = false); /// Find the failed Boolean condition within a given Boolean /// constant expression, and describe it with a string. std::pair<Expr *, std::string> findFailedBooleanCondition(Expr *Cond); /// Emit diagnostics for the diagnose_if attributes on Function, ignoring any /// non-ArgDependent DiagnoseIfAttrs. /// /// Argument-dependent diagnose_if attributes should be checked each time a /// function is used as a direct callee of a function call. /// /// Returns true if any errors were emitted. bool diagnoseArgDependentDiagnoseIfAttrs(const FunctionDecl *Function, const Expr *ThisArg, ArrayRef<const Expr *> Args, SourceLocation Loc); /// Emit diagnostics for the diagnose_if attributes on Function, ignoring any /// ArgDependent DiagnoseIfAttrs. /// /// Argument-independent diagnose_if attributes should be checked on every use /// of a function. /// /// Returns true if any errors were emitted. bool diagnoseArgIndependentDiagnoseIfAttrs(const NamedDecl *ND, SourceLocation Loc); /// Returns whether the given function's address can be taken or not, /// optionally emitting a diagnostic if the address can't be taken. /// /// Returns false if taking the address of the function is illegal. bool checkAddressOfFunctionIsAvailable(const FunctionDecl *Function, bool Complain = false, SourceLocation Loc = SourceLocation()); // [PossiblyAFunctionType] --> [Return] // NonFunctionType --> NonFunctionType // R (A) --> R(A) // R (*)(A) --> R (A) // R (&)(A) --> R (A) // R (S::*)(A) --> R (A) QualType ExtractUnqualifiedFunctionType(QualType PossiblyAFunctionType); FunctionDecl * ResolveAddressOfOverloadedFunction(Expr *AddressOfExpr, QualType TargetType, bool Complain, DeclAccessPair &Found, bool *pHadMultipleCandidates = nullptr); FunctionDecl * resolveAddressOfSingleOverloadCandidate(Expr *E, DeclAccessPair &FoundResult); bool resolveAndFixAddressOfSingleOverloadCandidate( ExprResult &SrcExpr, bool DoFunctionPointerConversion = false); FunctionDecl * ResolveSingleFunctionTemplateSpecialization(OverloadExpr *ovl, bool Complain = false, DeclAccessPair *Found = nullptr); bool ResolveAndFixSingleFunctionTemplateSpecialization( ExprResult &SrcExpr, bool DoFunctionPointerConverion = false, bool Complain = false, SourceRange OpRangeForComplaining = SourceRange(), QualType DestTypeForComplaining = QualType(), unsigned DiagIDForComplaining = 0); Expr *FixOverloadedFunctionReference(Expr *E, DeclAccessPair FoundDecl, FunctionDecl *Fn); ExprResult FixOverloadedFunctionReference(ExprResult, DeclAccessPair FoundDecl, FunctionDecl *Fn); void AddOverloadedCallCandidates(UnresolvedLookupExpr *ULE, ArrayRef<Expr *> Args, OverloadCandidateSet &CandidateSet, bool PartialOverloading = false); void AddOverloadedCallCandidates( LookupResult &R, TemplateArgumentListInfo *ExplicitTemplateArgs, ArrayRef<Expr *> Args, OverloadCandidateSet &CandidateSet); // An enum used to represent the different possible results of building a // range-based for loop. enum ForRangeStatus { FRS_Success, FRS_NoViableFunction, FRS_DiagnosticIssued }; ForRangeStatus BuildForRangeBeginEndCall(SourceLocation Loc, SourceLocation RangeLoc, const DeclarationNameInfo &NameInfo, LookupResult &MemberLookup, OverloadCandidateSet *CandidateSet, Expr *Range, ExprResult *CallExpr); ExprResult BuildOverloadedCallExpr(Scope *S, Expr *Fn, UnresolvedLookupExpr *ULE, SourceLocation LParenLoc, MultiExprArg Args, SourceLocation RParenLoc, Expr *ExecConfig, bool AllowTypoCorrection=true, bool CalleesAddressIsTaken=false); bool buildOverloadedCallSet(Scope *S, Expr *Fn, UnresolvedLookupExpr *ULE, MultiExprArg Args, SourceLocation RParenLoc, OverloadCandidateSet *CandidateSet, ExprResult *Result); ExprResult CreateUnresolvedLookupExpr(CXXRecordDecl *NamingClass, NestedNameSpecifierLoc NNSLoc, DeclarationNameInfo DNI, const UnresolvedSetImpl &Fns, bool PerformADL = true); ExprResult CreateOverloadedUnaryOp(SourceLocation OpLoc, UnaryOperatorKind Opc, const UnresolvedSetImpl &Fns, Expr *input, bool RequiresADL = true); void LookupOverloadedBinOp(OverloadCandidateSet &CandidateSet, OverloadedOperatorKind Op, const UnresolvedSetImpl &Fns, ArrayRef<Expr *> Args, bool RequiresADL = true); ExprResult CreateOverloadedBinOp(SourceLocation OpLoc, BinaryOperatorKind Opc, const UnresolvedSetImpl &Fns, Expr *LHS, Expr *RHS, bool RequiresADL = true, bool AllowRewrittenCandidates = true, FunctionDecl *DefaultedFn = nullptr); ExprResult BuildSynthesizedThreeWayComparison(SourceLocation OpLoc, const UnresolvedSetImpl &Fns, Expr *LHS, Expr *RHS, FunctionDecl *DefaultedFn); ExprResult CreateOverloadedArraySubscriptExpr(SourceLocation LLoc, SourceLocation RLoc, Expr *Base,Expr *Idx); ExprResult BuildCallToMemberFunction(Scope *S, Expr *MemExpr, SourceLocation LParenLoc, MultiExprArg Args, SourceLocation RParenLoc, Expr *ExecConfig = nullptr, bool IsExecConfig = false, bool AllowRecovery = false); ExprResult BuildCallToObjectOfClassType(Scope *S, Expr *Object, SourceLocation LParenLoc, MultiExprArg Args, SourceLocation RParenLoc); ExprResult BuildOverloadedArrowExpr(Scope *S, Expr *Base, SourceLocation OpLoc, bool *NoArrowOperatorFound = nullptr); /// CheckCallReturnType - Checks that a call expression's return type is /// complete. Returns true on failure. The location passed in is the location /// that best represents the call. bool CheckCallReturnType(QualType ReturnType, SourceLocation Loc, CallExpr *CE, FunctionDecl *FD); /// Helpers for dealing with blocks and functions. bool CheckParmsForFunctionDef(ArrayRef<ParmVarDecl *> Parameters, bool CheckParameterNames); void CheckCXXDefaultArguments(FunctionDecl *FD); void CheckExtraCXXDefaultArguments(Declarator &D); Scope *getNonFieldDeclScope(Scope *S); /// \name Name lookup /// /// These routines provide name lookup that is used during semantic /// analysis to resolve the various kinds of names (identifiers, /// overloaded operator names, constructor names, etc.) into zero or /// more declarations within a particular scope. The major entry /// points are LookupName, which performs unqualified name lookup, /// and LookupQualifiedName, which performs qualified name lookup. /// /// All name lookup is performed based on some specific criteria, /// which specify what names will be visible to name lookup and how /// far name lookup should work. These criteria are important both /// for capturing language semantics (certain lookups will ignore /// certain names, for example) and for performance, since name /// lookup is often a bottleneck in the compilation of C++. Name /// lookup criteria is specified via the LookupCriteria enumeration. /// /// The results of name lookup can vary based on the kind of name /// lookup performed, the current language, and the translation /// unit. In C, for example, name lookup will either return nothing /// (no entity found) or a single declaration. In C++, name lookup /// can additionally refer to a set of overloaded functions or /// result in an ambiguity. All of the possible results of name /// lookup are captured by the LookupResult class, which provides /// the ability to distinguish among them. //@{ /// Describes the kind of name lookup to perform. enum LookupNameKind { /// Ordinary name lookup, which finds ordinary names (functions, /// variables, typedefs, etc.) in C and most kinds of names /// (functions, variables, members, types, etc.) in C++. LookupOrdinaryName = 0, /// Tag name lookup, which finds the names of enums, classes, /// structs, and unions. LookupTagName, /// Label name lookup. LookupLabel, /// Member name lookup, which finds the names of /// class/struct/union members. LookupMemberName, /// Look up of an operator name (e.g., operator+) for use with /// operator overloading. This lookup is similar to ordinary name /// lookup, but will ignore any declarations that are class members. LookupOperatorName, /// Look up a name following ~ in a destructor name. This is an ordinary /// lookup, but prefers tags to typedefs. LookupDestructorName, /// Look up of a name that precedes the '::' scope resolution /// operator in C++. This lookup completely ignores operator, object, /// function, and enumerator names (C++ [basic.lookup.qual]p1). LookupNestedNameSpecifierName, /// Look up a namespace name within a C++ using directive or /// namespace alias definition, ignoring non-namespace names (C++ /// [basic.lookup.udir]p1). LookupNamespaceName, /// Look up all declarations in a scope with the given name, /// including resolved using declarations. This is appropriate /// for checking redeclarations for a using declaration. LookupUsingDeclName, /// Look up an ordinary name that is going to be redeclared as a /// name with linkage. This lookup ignores any declarations that /// are outside of the current scope unless they have linkage. See /// C99 6.2.2p4-5 and C++ [basic.link]p6. LookupRedeclarationWithLinkage, /// Look up a friend of a local class. This lookup does not look /// outside the innermost non-class scope. See C++11 [class.friend]p11. LookupLocalFriendName, /// Look up the name of an Objective-C protocol. LookupObjCProtocolName, /// Look up implicit 'self' parameter of an objective-c method. LookupObjCImplicitSelfParam, /// Look up the name of an OpenMP user-defined reduction operation. LookupOMPReductionName, /// Look up the name of an OpenMP user-defined mapper. LookupOMPMapperName, /// Look up any declaration with any name. LookupAnyName }; /// Specifies whether (or how) name lookup is being performed for a /// redeclaration (vs. a reference). enum RedeclarationKind { /// The lookup is a reference to this name that is not for the /// purpose of redeclaring the name. NotForRedeclaration = 0, /// The lookup results will be used for redeclaration of a name, /// if an entity by that name already exists and is visible. ForVisibleRedeclaration, /// The lookup results will be used for redeclaration of a name /// with external linkage; non-visible lookup results with external linkage /// may also be found. ForExternalRedeclaration }; RedeclarationKind forRedeclarationInCurContext() { // A declaration with an owning module for linkage can never link against // anything that is not visible. We don't need to check linkage here; if // the context has internal linkage, redeclaration lookup won't find things // from other TUs, and we can't safely compute linkage yet in general. if (cast<Decl>(CurContext) ->getOwningModuleForLinkage(/*IgnoreLinkage*/true)) return ForVisibleRedeclaration; return ForExternalRedeclaration; } /// The possible outcomes of name lookup for a literal operator. enum LiteralOperatorLookupResult { /// The lookup resulted in an error. LOLR_Error, /// The lookup found no match but no diagnostic was issued. LOLR_ErrorNoDiagnostic, /// The lookup found a single 'cooked' literal operator, which /// expects a normal literal to be built and passed to it. LOLR_Cooked, /// The lookup found a single 'raw' literal operator, which expects /// a string literal containing the spelling of the literal token. LOLR_Raw, /// The lookup found an overload set of literal operator templates, /// which expect the characters of the spelling of the literal token to be /// passed as a non-type template argument pack. LOLR_Template, /// The lookup found an overload set of literal operator templates, /// which expect the character type and characters of the spelling of the /// string literal token to be passed as template arguments. LOLR_StringTemplatePack, }; SpecialMemberOverloadResult LookupSpecialMember(CXXRecordDecl *D, CXXSpecialMember SM, bool ConstArg, bool VolatileArg, bool RValueThis, bool ConstThis, bool VolatileThis); typedef std::function<void(const TypoCorrection &)> TypoDiagnosticGenerator; typedef std::function<ExprResult(Sema &, TypoExpr *, TypoCorrection)> TypoRecoveryCallback; private: bool CppLookupName(LookupResult &R, Scope *S); struct TypoExprState { std::unique_ptr<TypoCorrectionConsumer> Consumer; TypoDiagnosticGenerator DiagHandler; TypoRecoveryCallback RecoveryHandler; TypoExprState(); TypoExprState(TypoExprState &&other) noexcept; TypoExprState &operator=(TypoExprState &&other) noexcept; }; /// The set of unhandled TypoExprs and their associated state. llvm::MapVector<TypoExpr *, TypoExprState> DelayedTypos; /// Creates a new TypoExpr AST node. TypoExpr *createDelayedTypo(std::unique_ptr<TypoCorrectionConsumer> TCC, TypoDiagnosticGenerator TDG, TypoRecoveryCallback TRC, SourceLocation TypoLoc); // The set of known/encountered (unique, canonicalized) NamespaceDecls. // // The boolean value will be true to indicate that the namespace was loaded // from an AST/PCH file, or false otherwise. llvm::MapVector<NamespaceDecl*, bool> KnownNamespaces; /// Whether we have already loaded known namespaces from an extenal /// source. bool LoadedExternalKnownNamespaces; /// Helper for CorrectTypo and CorrectTypoDelayed used to create and /// populate a new TypoCorrectionConsumer. Returns nullptr if typo correction /// should be skipped entirely. std::unique_ptr<TypoCorrectionConsumer> makeTypoCorrectionConsumer(const DeclarationNameInfo &Typo, Sema::LookupNameKind LookupKind, Scope *S, CXXScopeSpec *SS, CorrectionCandidateCallback &CCC, DeclContext *MemberContext, bool EnteringContext, const ObjCObjectPointerType *OPT, bool ErrorRecovery); public: const TypoExprState &getTypoExprState(TypoExpr *TE) const; /// Clears the state of the given TypoExpr. void clearDelayedTypo(TypoExpr *TE); /// Look up a name, looking for a single declaration. Return /// null if the results were absent, ambiguous, or overloaded. /// /// It is preferable to use the elaborated form and explicitly handle /// ambiguity and overloaded. NamedDecl *LookupSingleName(Scope *S, DeclarationName Name, SourceLocation Loc, LookupNameKind NameKind, RedeclarationKind Redecl = NotForRedeclaration); bool LookupBuiltin(LookupResult &R); void LookupNecessaryTypesForBuiltin(Scope *S, unsigned ID); bool LookupName(LookupResult &R, Scope *S, bool AllowBuiltinCreation = false); bool LookupQualifiedName(LookupResult &R, DeclContext *LookupCtx, bool InUnqualifiedLookup = false); bool LookupQualifiedName(LookupResult &R, DeclContext *LookupCtx, CXXScopeSpec &SS); bool LookupParsedName(LookupResult &R, Scope *S, CXXScopeSpec *SS, bool AllowBuiltinCreation = false, bool EnteringContext = false); ObjCProtocolDecl *LookupProtocol(IdentifierInfo *II, SourceLocation IdLoc, RedeclarationKind Redecl = NotForRedeclaration); bool LookupInSuper(LookupResult &R, CXXRecordDecl *Class); void LookupOverloadedOperatorName(OverloadedOperatorKind Op, Scope *S, UnresolvedSetImpl &Functions); LabelDecl *LookupOrCreateLabel(IdentifierInfo *II, SourceLocation IdentLoc, SourceLocation GnuLabelLoc = SourceLocation()); DeclContextLookupResult LookupConstructors(CXXRecordDecl *Class); CXXConstructorDecl *LookupDefaultConstructor(CXXRecordDecl *Class); CXXConstructorDecl *LookupCopyingConstructor(CXXRecordDecl *Class, unsigned Quals); CXXMethodDecl *LookupCopyingAssignment(CXXRecordDecl *Class, unsigned Quals, bool RValueThis, unsigned ThisQuals); CXXConstructorDecl *LookupMovingConstructor(CXXRecordDecl *Class, unsigned Quals); CXXMethodDecl *LookupMovingAssignment(CXXRecordDecl *Class, unsigned Quals, bool RValueThis, unsigned ThisQuals); CXXDestructorDecl *LookupDestructor(CXXRecordDecl *Class); bool checkLiteralOperatorId(const CXXScopeSpec &SS, const UnqualifiedId &Id, bool IsUDSuffix); LiteralOperatorLookupResult LookupLiteralOperator(Scope *S, LookupResult &R, ArrayRef<QualType> ArgTys, bool AllowRaw, bool AllowTemplate, bool AllowStringTemplate, bool DiagnoseMissing, StringLiteral *StringLit = nullptr); bool isKnownName(StringRef name); /// Status of the function emission on the CUDA/HIP/OpenMP host/device attrs. enum class FunctionEmissionStatus { Emitted, CUDADiscarded, // Discarded due to CUDA/HIP hostness OMPDiscarded, // Discarded due to OpenMP hostness TemplateDiscarded, // Discarded due to uninstantiated templates Unknown, }; FunctionEmissionStatus getEmissionStatus(FunctionDecl *Decl, bool Final = false); DeviceDiagnosticReason getEmissionReason(const FunctionDecl *Decl); // Whether the callee should be ignored in CUDA/HIP/OpenMP host/device check. bool shouldIgnoreInHostDeviceCheck(FunctionDecl *Callee); void ArgumentDependentLookup(DeclarationName Name, SourceLocation Loc, ArrayRef<Expr *> Args, ADLResult &Functions); void LookupVisibleDecls(Scope *S, LookupNameKind Kind, VisibleDeclConsumer &Consumer, bool IncludeGlobalScope = true, bool LoadExternal = true); void LookupVisibleDecls(DeclContext *Ctx, LookupNameKind Kind, VisibleDeclConsumer &Consumer, bool IncludeGlobalScope = true, bool IncludeDependentBases = false, bool LoadExternal = true); enum CorrectTypoKind { CTK_NonError, // CorrectTypo used in a non error recovery situation. CTK_ErrorRecovery // CorrectTypo used in normal error recovery. }; TypoCorrection CorrectTypo(const DeclarationNameInfo &Typo, Sema::LookupNameKind LookupKind, Scope *S, CXXScopeSpec *SS, CorrectionCandidateCallback &CCC, CorrectTypoKind Mode, DeclContext *MemberContext = nullptr, bool EnteringContext = false, const ObjCObjectPointerType *OPT = nullptr, bool RecordFailure = true); TypoExpr *CorrectTypoDelayed(const DeclarationNameInfo &Typo, Sema::LookupNameKind LookupKind, Scope *S, CXXScopeSpec *SS, CorrectionCandidateCallback &CCC, TypoDiagnosticGenerator TDG, TypoRecoveryCallback TRC, CorrectTypoKind Mode, DeclContext *MemberContext = nullptr, bool EnteringContext = false, const ObjCObjectPointerType *OPT = nullptr); /// Process any TypoExprs in the given Expr and its children, /// generating diagnostics as appropriate and returning a new Expr if there /// were typos that were all successfully corrected and ExprError if one or /// more typos could not be corrected. /// /// \param E The Expr to check for TypoExprs. /// /// \param InitDecl A VarDecl to avoid because the Expr being corrected is its /// initializer. /// /// \param RecoverUncorrectedTypos If true, when typo correction fails, it /// will rebuild the given Expr with all TypoExprs degraded to RecoveryExprs. /// /// \param Filter A function applied to a newly rebuilt Expr to determine if /// it is an acceptable/usable result from a single combination of typo /// corrections. As long as the filter returns ExprError, different /// combinations of corrections will be tried until all are exhausted. ExprResult CorrectDelayedTyposInExpr( Expr *E, VarDecl *InitDecl = nullptr, bool RecoverUncorrectedTypos = false, llvm::function_ref<ExprResult(Expr *)> Filter = [](Expr *E) -> ExprResult { return E; }); ExprResult CorrectDelayedTyposInExpr( ExprResult ER, VarDecl *InitDecl = nullptr, bool RecoverUncorrectedTypos = false, llvm::function_ref<ExprResult(Expr *)> Filter = [](Expr *E) -> ExprResult { return E; }) { return ER.isInvalid() ? ER : CorrectDelayedTyposInExpr(ER.get(), InitDecl, RecoverUncorrectedTypos, Filter); } void diagnoseTypo(const TypoCorrection &Correction, const PartialDiagnostic &TypoDiag, bool ErrorRecovery = true); void diagnoseTypo(const TypoCorrection &Correction, const PartialDiagnostic &TypoDiag, const PartialDiagnostic &PrevNote, bool ErrorRecovery = true); void MarkTypoCorrectedFunctionDefinition(const NamedDecl *F); void FindAssociatedClassesAndNamespaces(SourceLocation InstantiationLoc, ArrayRef<Expr *> Args, AssociatedNamespaceSet &AssociatedNamespaces, AssociatedClassSet &AssociatedClasses); void FilterLookupForScope(LookupResult &R, DeclContext *Ctx, Scope *S, bool ConsiderLinkage, bool AllowInlineNamespace); bool CheckRedeclarationModuleOwnership(NamedDecl *New, NamedDecl *Old); void DiagnoseAmbiguousLookup(LookupResult &Result); //@} /// Attempts to produce a RecoveryExpr after some AST node cannot be created. ExprResult CreateRecoveryExpr(SourceLocation Begin, SourceLocation End, ArrayRef<Expr *> SubExprs, QualType T = QualType()); ObjCInterfaceDecl *getObjCInterfaceDecl(IdentifierInfo *&Id, SourceLocation IdLoc, bool TypoCorrection = false); FunctionDecl *CreateBuiltin(IdentifierInfo *II, QualType Type, unsigned ID, SourceLocation Loc); NamedDecl *LazilyCreateBuiltin(IdentifierInfo *II, unsigned ID, Scope *S, bool ForRedeclaration, SourceLocation Loc); NamedDecl *ImplicitlyDefineFunction(SourceLocation Loc, IdentifierInfo &II, Scope *S); void AddKnownFunctionAttributesForReplaceableGlobalAllocationFunction( FunctionDecl *FD); void AddKnownFunctionAttributes(FunctionDecl *FD); // More parsing and symbol table subroutines. void ProcessPragmaWeak(Scope *S, Decl *D); // Decl attributes - this routine is the top level dispatcher. void ProcessDeclAttributes(Scope *S, Decl *D, const Declarator &PD); // Helper for delayed processing of attributes. void ProcessDeclAttributeDelayed(Decl *D, const ParsedAttributesView &AttrList); void ProcessDeclAttributeList(Scope *S, Decl *D, const ParsedAttributesView &AL, bool IncludeCXX11Attributes = true); bool ProcessAccessDeclAttributeList(AccessSpecDecl *ASDecl, const ParsedAttributesView &AttrList); void checkUnusedDeclAttributes(Declarator &D); /// Handles semantic checking for features that are common to all attributes, /// such as checking whether a parameter was properly specified, or the /// correct number of arguments were passed, etc. Returns true if the /// attribute has been diagnosed. bool checkCommonAttributeFeatures(const Decl *D, const ParsedAttr &A); bool checkCommonAttributeFeatures(const Stmt *S, const ParsedAttr &A); /// Determine if type T is a valid subject for a nonnull and similar /// attributes. By default, we look through references (the behavior used by /// nonnull), but if the second parameter is true, then we treat a reference /// type as valid. bool isValidPointerAttrType(QualType T, bool RefOkay = false); bool CheckRegparmAttr(const ParsedAttr &attr, unsigned &value); bool CheckCallingConvAttr(const ParsedAttr &attr, CallingConv &CC, const FunctionDecl *FD = nullptr); bool CheckAttrTarget(const ParsedAttr &CurrAttr); bool CheckAttrNoArgs(const ParsedAttr &CurrAttr); bool checkStringLiteralArgumentAttr(const ParsedAttr &Attr, unsigned ArgNum, StringRef &Str, SourceLocation *ArgLocation = nullptr); llvm::Error isValidSectionSpecifier(StringRef Str); bool checkSectionName(SourceLocation LiteralLoc, StringRef Str); bool checkTargetAttr(SourceLocation LiteralLoc, StringRef Str); bool checkMSInheritanceAttrOnDefinition( CXXRecordDecl *RD, SourceRange Range, bool BestCase, MSInheritanceModel SemanticSpelling); void CheckAlignasUnderalignment(Decl *D); /// Adjust the calling convention of a method to be the ABI default if it /// wasn't specified explicitly. This handles method types formed from /// function type typedefs and typename template arguments. void adjustMemberFunctionCC(QualType &T, bool IsStatic, bool IsCtorOrDtor, SourceLocation Loc); // Check if there is an explicit attribute, but only look through parens. // The intent is to look for an attribute on the current declarator, but not // one that came from a typedef. bool hasExplicitCallingConv(QualType T); /// Get the outermost AttributedType node that sets a calling convention. /// Valid types should not have multiple attributes with different CCs. const AttributedType *getCallingConvAttributedType(QualType T) const; /// Process the attributes before creating an attributed statement. Returns /// the semantic attributes that have been processed. void ProcessStmtAttributes(Stmt *Stmt, const ParsedAttributesWithRange &InAttrs, SmallVectorImpl<const Attr *> &OutAttrs); void WarnConflictingTypedMethods(ObjCMethodDecl *Method, ObjCMethodDecl *MethodDecl, bool IsProtocolMethodDecl); void CheckConflictingOverridingMethod(ObjCMethodDecl *Method, ObjCMethodDecl *Overridden, bool IsProtocolMethodDecl); /// WarnExactTypedMethods - This routine issues a warning if method /// implementation declaration matches exactly that of its declaration. void WarnExactTypedMethods(ObjCMethodDecl *Method, ObjCMethodDecl *MethodDecl, bool IsProtocolMethodDecl); typedef llvm::SmallPtrSet<Selector, 8> SelectorSet; /// CheckImplementationIvars - This routine checks if the instance variables /// listed in the implelementation match those listed in the interface. void CheckImplementationIvars(ObjCImplementationDecl *ImpDecl, ObjCIvarDecl **Fields, unsigned nIvars, SourceLocation Loc); /// ImplMethodsVsClassMethods - This is main routine to warn if any method /// remains unimplemented in the class or category \@implementation. void ImplMethodsVsClassMethods(Scope *S, ObjCImplDecl* IMPDecl, ObjCContainerDecl* IDecl, bool IncompleteImpl = false); /// DiagnoseUnimplementedProperties - This routine warns on those properties /// which must be implemented by this implementation. void DiagnoseUnimplementedProperties(Scope *S, ObjCImplDecl* IMPDecl, ObjCContainerDecl *CDecl, bool SynthesizeProperties); /// Diagnose any null-resettable synthesized setters. void diagnoseNullResettableSynthesizedSetters(const ObjCImplDecl *impDecl); /// DefaultSynthesizeProperties - This routine default synthesizes all /// properties which must be synthesized in the class's \@implementation. void DefaultSynthesizeProperties(Scope *S, ObjCImplDecl *IMPDecl, ObjCInterfaceDecl *IDecl, SourceLocation AtEnd); void DefaultSynthesizeProperties(Scope *S, Decl *D, SourceLocation AtEnd); /// IvarBacksCurrentMethodAccessor - This routine returns 'true' if 'IV' is /// an ivar synthesized for 'Method' and 'Method' is a property accessor /// declared in class 'IFace'. bool IvarBacksCurrentMethodAccessor(ObjCInterfaceDecl *IFace, ObjCMethodDecl *Method, ObjCIvarDecl *IV); /// DiagnoseUnusedBackingIvarInAccessor - Issue an 'unused' warning if ivar which /// backs the property is not used in the property's accessor. void DiagnoseUnusedBackingIvarInAccessor(Scope *S, const ObjCImplementationDecl *ImplD); /// GetIvarBackingPropertyAccessor - If method is a property setter/getter and /// it property has a backing ivar, returns this ivar; otherwise, returns NULL. /// It also returns ivar's property on success. ObjCIvarDecl *GetIvarBackingPropertyAccessor(const ObjCMethodDecl *Method, const ObjCPropertyDecl *&PDecl) const; /// Called by ActOnProperty to handle \@property declarations in /// class extensions. ObjCPropertyDecl *HandlePropertyInClassExtension(Scope *S, SourceLocation AtLoc, SourceLocation LParenLoc, FieldDeclarator &FD, Selector GetterSel, SourceLocation GetterNameLoc, Selector SetterSel, SourceLocation SetterNameLoc, const bool isReadWrite, unsigned &Attributes, const unsigned AttributesAsWritten, QualType T, TypeSourceInfo *TSI, tok::ObjCKeywordKind MethodImplKind); /// Called by ActOnProperty and HandlePropertyInClassExtension to /// handle creating the ObjcPropertyDecl for a category or \@interface. ObjCPropertyDecl *CreatePropertyDecl(Scope *S, ObjCContainerDecl *CDecl, SourceLocation AtLoc, SourceLocation LParenLoc, FieldDeclarator &FD, Selector GetterSel, SourceLocation GetterNameLoc, Selector SetterSel, SourceLocation SetterNameLoc, const bool isReadWrite, const unsigned Attributes, const unsigned AttributesAsWritten, QualType T, TypeSourceInfo *TSI, tok::ObjCKeywordKind MethodImplKind, DeclContext *lexicalDC = nullptr); /// AtomicPropertySetterGetterRules - This routine enforces the rule (via /// warning) when atomic property has one but not the other user-declared /// setter or getter. void AtomicPropertySetterGetterRules(ObjCImplDecl* IMPDecl, ObjCInterfaceDecl* IDecl); void DiagnoseOwningPropertyGetterSynthesis(const ObjCImplementationDecl *D); void DiagnoseMissingDesignatedInitOverrides( const ObjCImplementationDecl *ImplD, const ObjCInterfaceDecl *IFD); void DiagnoseDuplicateIvars(ObjCInterfaceDecl *ID, ObjCInterfaceDecl *SID); enum MethodMatchStrategy { MMS_loose, MMS_strict }; /// MatchTwoMethodDeclarations - Checks if two methods' type match and returns /// true, or false, accordingly. bool MatchTwoMethodDeclarations(const ObjCMethodDecl *Method, const ObjCMethodDecl *PrevMethod, MethodMatchStrategy strategy = MMS_strict); /// MatchAllMethodDeclarations - Check methods declaraed in interface or /// or protocol against those declared in their implementations. void MatchAllMethodDeclarations(const SelectorSet &InsMap, const SelectorSet &ClsMap, SelectorSet &InsMapSeen, SelectorSet &ClsMapSeen, ObjCImplDecl* IMPDecl, ObjCContainerDecl* IDecl, bool &IncompleteImpl, bool ImmediateClass, bool WarnCategoryMethodImpl=false); /// CheckCategoryVsClassMethodMatches - Checks that methods implemented in /// category matches with those implemented in its primary class and /// warns each time an exact match is found. void CheckCategoryVsClassMethodMatches(ObjCCategoryImplDecl *CatIMP); /// Add the given method to the list of globally-known methods. void addMethodToGlobalList(ObjCMethodList *List, ObjCMethodDecl *Method); /// Returns default addr space for method qualifiers. LangAS getDefaultCXXMethodAddrSpace() const; private: /// AddMethodToGlobalPool - Add an instance or factory method to the global /// pool. See descriptoin of AddInstanceMethodToGlobalPool. void AddMethodToGlobalPool(ObjCMethodDecl *Method, bool impl, bool instance); /// LookupMethodInGlobalPool - Returns the instance or factory method and /// optionally warns if there are multiple signatures. ObjCMethodDecl *LookupMethodInGlobalPool(Selector Sel, SourceRange R, bool receiverIdOrClass, bool instance); public: /// - Returns instance or factory methods in global method pool for /// given selector. It checks the desired kind first, if none is found, and /// parameter checkTheOther is set, it then checks the other kind. If no such /// method or only one method is found, function returns false; otherwise, it /// returns true. bool CollectMultipleMethodsInGlobalPool(Selector Sel, SmallVectorImpl<ObjCMethodDecl*>& Methods, bool InstanceFirst, bool CheckTheOther, const ObjCObjectType *TypeBound = nullptr); bool AreMultipleMethodsInGlobalPool(Selector Sel, ObjCMethodDecl *BestMethod, SourceRange R, bool receiverIdOrClass, SmallVectorImpl<ObjCMethodDecl*>& Methods); void DiagnoseMultipleMethodInGlobalPool(SmallVectorImpl<ObjCMethodDecl*> &Methods, Selector Sel, SourceRange R, bool receiverIdOrClass); private: /// - Returns a selector which best matches given argument list or /// nullptr if none could be found ObjCMethodDecl *SelectBestMethod(Selector Sel, MultiExprArg Args, bool IsInstance, SmallVectorImpl<ObjCMethodDecl*>& Methods); /// Record the typo correction failure and return an empty correction. TypoCorrection FailedCorrection(IdentifierInfo *Typo, SourceLocation TypoLoc, bool RecordFailure = true) { if (RecordFailure) TypoCorrectionFailures[Typo].insert(TypoLoc); return TypoCorrection(); } public: /// AddInstanceMethodToGlobalPool - All instance methods in a translation /// unit are added to a global pool. This allows us to efficiently associate /// a selector with a method declaraation for purposes of typechecking /// messages sent to "id" (where the class of the object is unknown). void AddInstanceMethodToGlobalPool(ObjCMethodDecl *Method, bool impl=false) { AddMethodToGlobalPool(Method, impl, /*instance*/true); } /// AddFactoryMethodToGlobalPool - Same as above, but for factory methods. void AddFactoryMethodToGlobalPool(ObjCMethodDecl *Method, bool impl=false) { AddMethodToGlobalPool(Method, impl, /*instance*/false); } /// AddAnyMethodToGlobalPool - Add any method, instance or factory to global /// pool. void AddAnyMethodToGlobalPool(Decl *D); /// LookupInstanceMethodInGlobalPool - Returns the method and warns if /// there are multiple signatures. ObjCMethodDecl *LookupInstanceMethodInGlobalPool(Selector Sel, SourceRange R, bool receiverIdOrClass=false) { return LookupMethodInGlobalPool(Sel, R, receiverIdOrClass, /*instance*/true); } /// LookupFactoryMethodInGlobalPool - Returns the method and warns if /// there are multiple signatures. ObjCMethodDecl *LookupFactoryMethodInGlobalPool(Selector Sel, SourceRange R, bool receiverIdOrClass=false) { return LookupMethodInGlobalPool(Sel, R, receiverIdOrClass, /*instance*/false); } const ObjCMethodDecl *SelectorsForTypoCorrection(Selector Sel, QualType ObjectType=QualType()); /// LookupImplementedMethodInGlobalPool - Returns the method which has an /// implementation. ObjCMethodDecl *LookupImplementedMethodInGlobalPool(Selector Sel); /// CollectIvarsToConstructOrDestruct - Collect those ivars which require /// initialization. void CollectIvarsToConstructOrDestruct(ObjCInterfaceDecl *OI, SmallVectorImpl<ObjCIvarDecl*> &Ivars); //===--------------------------------------------------------------------===// // Statement Parsing Callbacks: SemaStmt.cpp. public: class FullExprArg { public: FullExprArg() : E(nullptr) { } FullExprArg(Sema &actions) : E(nullptr) { } ExprResult release() { return E; } Expr *get() const { return E; } Expr *operator->() { return E; } private: // FIXME: No need to make the entire Sema class a friend when it's just // Sema::MakeFullExpr that needs access to the constructor below. friend class Sema; explicit FullExprArg(Expr *expr) : E(expr) {} Expr *E; }; FullExprArg MakeFullExpr(Expr *Arg) { return MakeFullExpr(Arg, Arg ? Arg->getExprLoc() : SourceLocation()); } FullExprArg MakeFullExpr(Expr *Arg, SourceLocation CC) { return FullExprArg( ActOnFinishFullExpr(Arg, CC, /*DiscardedValue*/ false).get()); } FullExprArg MakeFullDiscardedValueExpr(Expr *Arg) { ExprResult FE = ActOnFinishFullExpr(Arg, Arg ? Arg->getExprLoc() : SourceLocation(), /*DiscardedValue*/ true); return FullExprArg(FE.get()); } StmtResult ActOnExprStmt(ExprResult Arg, bool DiscardedValue = true); StmtResult ActOnExprStmtError(); StmtResult ActOnNullStmt(SourceLocation SemiLoc, bool HasLeadingEmptyMacro = false); void ActOnStartOfCompoundStmt(bool IsStmtExpr); void ActOnAfterCompoundStatementLeadingPragmas(); void ActOnFinishOfCompoundStmt(); StmtResult ActOnCompoundStmt(SourceLocation L, SourceLocation R, ArrayRef<Stmt *> Elts, bool isStmtExpr); /// A RAII object to enter scope of a compound statement. class CompoundScopeRAII { public: CompoundScopeRAII(Sema &S, bool IsStmtExpr = false) : S(S) { S.ActOnStartOfCompoundStmt(IsStmtExpr); } ~CompoundScopeRAII() { S.ActOnFinishOfCompoundStmt(); } private: Sema &S; }; /// An RAII helper that pops function a function scope on exit. struct FunctionScopeRAII { Sema &S; bool Active; FunctionScopeRAII(Sema &S) : S(S), Active(true) {} ~FunctionScopeRAII() { if (Active) S.PopFunctionScopeInfo(); } void disable() { Active = false; } }; StmtResult ActOnDeclStmt(DeclGroupPtrTy Decl, SourceLocation StartLoc, SourceLocation EndLoc); void ActOnForEachDeclStmt(DeclGroupPtrTy Decl); StmtResult ActOnForEachLValueExpr(Expr *E); ExprResult ActOnCaseExpr(SourceLocation CaseLoc, ExprResult Val); StmtResult ActOnCaseStmt(SourceLocation CaseLoc, ExprResult LHS, SourceLocation DotDotDotLoc, ExprResult RHS, SourceLocation ColonLoc); void ActOnCaseStmtBody(Stmt *CaseStmt, Stmt *SubStmt); StmtResult ActOnDefaultStmt(SourceLocation DefaultLoc, SourceLocation ColonLoc, Stmt *SubStmt, Scope *CurScope); StmtResult ActOnLabelStmt(SourceLocation IdentLoc, LabelDecl *TheDecl, SourceLocation ColonLoc, Stmt *SubStmt); StmtResult BuildAttributedStmt(SourceLocation AttrsLoc, ArrayRef<const Attr *> Attrs, Stmt *SubStmt); StmtResult ActOnAttributedStmt(const ParsedAttributesWithRange &AttrList, Stmt *SubStmt); bool CheckRebuiltAttributedStmtAttributes(ArrayRef<const Attr *> Attrs); class ConditionResult; StmtResult ActOnIfStmt(SourceLocation IfLoc, IfStatementKind StatementKind, SourceLocation LParenLoc, Stmt *InitStmt, ConditionResult Cond, SourceLocation RParenLoc, Stmt *ThenVal, SourceLocation ElseLoc, Stmt *ElseVal); StmtResult BuildIfStmt(SourceLocation IfLoc, IfStatementKind StatementKind, SourceLocation LParenLoc, Stmt *InitStmt, ConditionResult Cond, SourceLocation RParenLoc, Stmt *ThenVal, SourceLocation ElseLoc, Stmt *ElseVal); StmtResult ActOnStartOfSwitchStmt(SourceLocation SwitchLoc, SourceLocation LParenLoc, Stmt *InitStmt, ConditionResult Cond, SourceLocation RParenLoc); StmtResult ActOnFinishSwitchStmt(SourceLocation SwitchLoc, Stmt *Switch, Stmt *Body); StmtResult ActOnWhileStmt(SourceLocation WhileLoc, SourceLocation LParenLoc, ConditionResult Cond, SourceLocation RParenLoc, Stmt *Body); StmtResult ActOnDoStmt(SourceLocation DoLoc, Stmt *Body, SourceLocation WhileLoc, SourceLocation CondLParen, Expr *Cond, SourceLocation CondRParen); StmtResult ActOnForStmt(SourceLocation ForLoc, SourceLocation LParenLoc, Stmt *First, ConditionResult Second, FullExprArg Third, SourceLocation RParenLoc, Stmt *Body); ExprResult CheckObjCForCollectionOperand(SourceLocation forLoc, Expr *collection); StmtResult ActOnObjCForCollectionStmt(SourceLocation ForColLoc, Stmt *First, Expr *collection, SourceLocation RParenLoc); StmtResult FinishObjCForCollectionStmt(Stmt *ForCollection, Stmt *Body); enum BuildForRangeKind { /// Initial building of a for-range statement. BFRK_Build, /// Instantiation or recovery rebuild of a for-range statement. Don't /// attempt any typo-correction. BFRK_Rebuild, /// Determining whether a for-range statement could be built. Avoid any /// unnecessary or irreversible actions. BFRK_Check }; StmtResult ActOnCXXForRangeStmt(Scope *S, SourceLocation ForLoc, SourceLocation CoawaitLoc, Stmt *InitStmt, Stmt *LoopVar, SourceLocation ColonLoc, Expr *Collection, SourceLocation RParenLoc, BuildForRangeKind Kind); StmtResult BuildCXXForRangeStmt(SourceLocation ForLoc, SourceLocation CoawaitLoc, Stmt *InitStmt, SourceLocation ColonLoc, Stmt *RangeDecl, Stmt *Begin, Stmt *End, Expr *Cond, Expr *Inc, Stmt *LoopVarDecl, SourceLocation RParenLoc, BuildForRangeKind Kind); StmtResult FinishCXXForRangeStmt(Stmt *ForRange, Stmt *Body); StmtResult ActOnGotoStmt(SourceLocation GotoLoc, SourceLocation LabelLoc, LabelDecl *TheDecl); StmtResult ActOnIndirectGotoStmt(SourceLocation GotoLoc, SourceLocation StarLoc, Expr *DestExp); StmtResult ActOnContinueStmt(SourceLocation ContinueLoc, Scope *CurScope); StmtResult ActOnBreakStmt(SourceLocation BreakLoc, Scope *CurScope); void ActOnCapturedRegionStart(SourceLocation Loc, Scope *CurScope, CapturedRegionKind Kind, unsigned NumParams); typedef std::pair<StringRef, QualType> CapturedParamNameType; void ActOnCapturedRegionStart(SourceLocation Loc, Scope *CurScope, CapturedRegionKind Kind, ArrayRef<CapturedParamNameType> Params, unsigned OpenMPCaptureLevel = 0); StmtResult ActOnCapturedRegionEnd(Stmt *S); void ActOnCapturedRegionError(); RecordDecl *CreateCapturedStmtRecordDecl(CapturedDecl *&CD, SourceLocation Loc, unsigned NumParams); struct NamedReturnInfo { const VarDecl *Candidate; enum Status : uint8_t { None, MoveEligible, MoveEligibleAndCopyElidable }; Status S; bool isMoveEligible() const { return S != None; }; bool isCopyElidable() const { return S == MoveEligibleAndCopyElidable; } }; enum class SimplerImplicitMoveMode { ForceOff, Normal, ForceOn }; NamedReturnInfo getNamedReturnInfo( Expr *&E, SimplerImplicitMoveMode Mode = SimplerImplicitMoveMode::Normal); NamedReturnInfo getNamedReturnInfo(const VarDecl *VD); const VarDecl *getCopyElisionCandidate(NamedReturnInfo &Info, QualType ReturnType); ExprResult PerformMoveOrCopyInitialization(const InitializedEntity &Entity, const NamedReturnInfo &NRInfo, Expr *Value, bool SupressSimplerImplicitMoves = false); StmtResult ActOnReturnStmt(SourceLocation ReturnLoc, Expr *RetValExp, Scope *CurScope); StmtResult BuildReturnStmt(SourceLocation ReturnLoc, Expr *RetValExp); StmtResult ActOnCapScopeReturnStmt(SourceLocation ReturnLoc, Expr *RetValExp, NamedReturnInfo &NRInfo, bool SupressSimplerImplicitMoves); StmtResult ActOnGCCAsmStmt(SourceLocation AsmLoc, bool IsSimple, bool IsVolatile, unsigned NumOutputs, unsigned NumInputs, IdentifierInfo **Names, MultiExprArg Constraints, MultiExprArg Exprs, Expr *AsmString, MultiExprArg Clobbers, unsigned NumLabels, SourceLocation RParenLoc); void FillInlineAsmIdentifierInfo(Expr *Res, llvm::InlineAsmIdentifierInfo &Info); ExprResult LookupInlineAsmIdentifier(CXXScopeSpec &SS, SourceLocation TemplateKWLoc, UnqualifiedId &Id, bool IsUnevaluatedContext); bool LookupInlineAsmField(StringRef Base, StringRef Member, unsigned &Offset, SourceLocation AsmLoc); ExprResult LookupInlineAsmVarDeclField(Expr *RefExpr, StringRef Member, SourceLocation AsmLoc); StmtResult ActOnMSAsmStmt(SourceLocation AsmLoc, SourceLocation LBraceLoc, ArrayRef<Token> AsmToks, StringRef AsmString, unsigned NumOutputs, unsigned NumInputs, ArrayRef<StringRef> Constraints, ArrayRef<StringRef> Clobbers, ArrayRef<Expr*> Exprs, SourceLocation EndLoc); LabelDecl *GetOrCreateMSAsmLabel(StringRef ExternalLabelName, SourceLocation Location, bool AlwaysCreate); VarDecl *BuildObjCExceptionDecl(TypeSourceInfo *TInfo, QualType ExceptionType, SourceLocation StartLoc, SourceLocation IdLoc, IdentifierInfo *Id, bool Invalid = false); Decl *ActOnObjCExceptionDecl(Scope *S, Declarator &D); StmtResult ActOnObjCAtCatchStmt(SourceLocation AtLoc, SourceLocation RParen, Decl *Parm, Stmt *Body); StmtResult ActOnObjCAtFinallyStmt(SourceLocation AtLoc, Stmt *Body); StmtResult ActOnObjCAtTryStmt(SourceLocation AtLoc, Stmt *Try, MultiStmtArg Catch, Stmt *Finally); StmtResult BuildObjCAtThrowStmt(SourceLocation AtLoc, Expr *Throw); StmtResult ActOnObjCAtThrowStmt(SourceLocation AtLoc, Expr *Throw, Scope *CurScope); ExprResult ActOnObjCAtSynchronizedOperand(SourceLocation atLoc, Expr *operand); StmtResult ActOnObjCAtSynchronizedStmt(SourceLocation AtLoc, Expr *SynchExpr, Stmt *SynchBody); StmtResult ActOnObjCAutoreleasePoolStmt(SourceLocation AtLoc, Stmt *Body); VarDecl *BuildExceptionDeclaration(Scope *S, TypeSourceInfo *TInfo, SourceLocation StartLoc, SourceLocation IdLoc, IdentifierInfo *Id); Decl *ActOnExceptionDeclarator(Scope *S, Declarator &D); StmtResult ActOnCXXCatchBlock(SourceLocation CatchLoc, Decl *ExDecl, Stmt *HandlerBlock); StmtResult ActOnCXXTryBlock(SourceLocation TryLoc, Stmt *TryBlock, ArrayRef<Stmt *> Handlers); StmtResult ActOnSEHTryBlock(bool IsCXXTry, // try (true) or __try (false) ? SourceLocation TryLoc, Stmt *TryBlock, Stmt *Handler); StmtResult ActOnSEHExceptBlock(SourceLocation Loc, Expr *FilterExpr, Stmt *Block); void ActOnStartSEHFinallyBlock(); void ActOnAbortSEHFinallyBlock(); StmtResult ActOnFinishSEHFinallyBlock(SourceLocation Loc, Stmt *Block); StmtResult ActOnSEHLeaveStmt(SourceLocation Loc, Scope *CurScope); void DiagnoseReturnInConstructorExceptionHandler(CXXTryStmt *TryBlock); bool ShouldWarnIfUnusedFileScopedDecl(const DeclaratorDecl *D) const; /// If it's a file scoped decl that must warn if not used, keep track /// of it. void MarkUnusedFileScopedDecl(const DeclaratorDecl *D); /// DiagnoseUnusedExprResult - If the statement passed in is an expression /// whose result is unused, warn. void DiagnoseUnusedExprResult(const Stmt *S, unsigned DiagID); void DiagnoseUnusedNestedTypedefs(const RecordDecl *D); void DiagnoseUnusedDecl(const NamedDecl *ND); /// If VD is set but not otherwise used, diagnose, for a parameter or a /// variable. void DiagnoseUnusedButSetDecl(const VarDecl *VD); /// Emit \p DiagID if statement located on \p StmtLoc has a suspicious null /// statement as a \p Body, and it is located on the same line. /// /// This helps prevent bugs due to typos, such as: /// if (condition); /// do_stuff(); void DiagnoseEmptyStmtBody(SourceLocation StmtLoc, const Stmt *Body, unsigned DiagID); /// Warn if a for/while loop statement \p S, which is followed by /// \p PossibleBody, has a suspicious null statement as a body. void DiagnoseEmptyLoopBody(const Stmt *S, const Stmt *PossibleBody); /// Warn if a value is moved to itself. void DiagnoseSelfMove(const Expr *LHSExpr, const Expr *RHSExpr, SourceLocation OpLoc); /// Warn if we're implicitly casting from a _Nullable pointer type to a /// _Nonnull one. void diagnoseNullableToNonnullConversion(QualType DstType, QualType SrcType, SourceLocation Loc); /// Warn when implicitly casting 0 to nullptr. void diagnoseZeroToNullptrConversion(CastKind Kind, const Expr *E); ParsingDeclState PushParsingDeclaration(sema::DelayedDiagnosticPool &pool) { return DelayedDiagnostics.push(pool); } void PopParsingDeclaration(ParsingDeclState state, Decl *decl); typedef ProcessingContextState ParsingClassState; ParsingClassState PushParsingClass() { ParsingClassDepth++; return DelayedDiagnostics.pushUndelayed(); } void PopParsingClass(ParsingClassState state) { ParsingClassDepth--; DelayedDiagnostics.popUndelayed(state); } void redelayDiagnostics(sema::DelayedDiagnosticPool &pool); void DiagnoseAvailabilityOfDecl(NamedDecl *D, ArrayRef<SourceLocation> Locs, const ObjCInterfaceDecl *UnknownObjCClass, bool ObjCPropertyAccess, bool AvoidPartialAvailabilityChecks = false, ObjCInterfaceDecl *ClassReceiver = nullptr); bool makeUnavailableInSystemHeader(SourceLocation loc, UnavailableAttr::ImplicitReason reason); /// Issue any -Wunguarded-availability warnings in \c FD void DiagnoseUnguardedAvailabilityViolations(Decl *FD); void handleDelayedAvailabilityCheck(sema::DelayedDiagnostic &DD, Decl *Ctx); //===--------------------------------------------------------------------===// // Expression Parsing Callbacks: SemaExpr.cpp. bool CanUseDecl(NamedDecl *D, bool TreatUnavailableAsInvalid); bool DiagnoseUseOfDecl(NamedDecl *D, ArrayRef<SourceLocation> Locs, const ObjCInterfaceDecl *UnknownObjCClass = nullptr, bool ObjCPropertyAccess = false, bool AvoidPartialAvailabilityChecks = false, ObjCInterfaceDecl *ClassReciever = nullptr); void NoteDeletedFunction(FunctionDecl *FD); void NoteDeletedInheritingConstructor(CXXConstructorDecl *CD); bool DiagnosePropertyAccessorMismatch(ObjCPropertyDecl *PD, ObjCMethodDecl *Getter, SourceLocation Loc); void DiagnoseSentinelCalls(NamedDecl *D, SourceLocation Loc, ArrayRef<Expr *> Args); void PushExpressionEvaluationContext( ExpressionEvaluationContext NewContext, Decl *LambdaContextDecl = nullptr, ExpressionEvaluationContextRecord::ExpressionKind Type = ExpressionEvaluationContextRecord::EK_Other); enum ReuseLambdaContextDecl_t { ReuseLambdaContextDecl }; void PushExpressionEvaluationContext( ExpressionEvaluationContext NewContext, ReuseLambdaContextDecl_t, ExpressionEvaluationContextRecord::ExpressionKind Type = ExpressionEvaluationContextRecord::EK_Other); void PopExpressionEvaluationContext(); void DiscardCleanupsInEvaluationContext(); ExprResult TransformToPotentiallyEvaluated(Expr *E); ExprResult HandleExprEvaluationContextForTypeof(Expr *E); ExprResult CheckUnevaluatedOperand(Expr *E); void CheckUnusedVolatileAssignment(Expr *E); ExprResult ActOnConstantExpression(ExprResult Res); // Functions for marking a declaration referenced. These functions also // contain the relevant logic for marking if a reference to a function or // variable is an odr-use (in the C++11 sense). There are separate variants // for expressions referring to a decl; these exist because odr-use marking // needs to be delayed for some constant variables when we build one of the // named expressions. // // MightBeOdrUse indicates whether the use could possibly be an odr-use, and // should usually be true. This only needs to be set to false if the lack of // odr-use cannot be determined from the current context (for instance, // because the name denotes a virtual function and was written without an // explicit nested-name-specifier). void MarkAnyDeclReferenced(SourceLocation Loc, Decl *D, bool MightBeOdrUse); void MarkFunctionReferenced(SourceLocation Loc, FunctionDecl *Func, bool MightBeOdrUse = true); void MarkVariableReferenced(SourceLocation Loc, VarDecl *Var); void MarkDeclRefReferenced(DeclRefExpr *E, const Expr *Base = nullptr); void MarkMemberReferenced(MemberExpr *E); void MarkFunctionParmPackReferenced(FunctionParmPackExpr *E); void MarkCaptureUsedInEnclosingContext(VarDecl *Capture, SourceLocation Loc, unsigned CapturingScopeIndex); ExprResult CheckLValueToRValueConversionOperand(Expr *E); void CleanupVarDeclMarking(); enum TryCaptureKind { TryCapture_Implicit, TryCapture_ExplicitByVal, TryCapture_ExplicitByRef }; /// Try to capture the given variable. /// /// \param Var The variable to capture. /// /// \param Loc The location at which the capture occurs. /// /// \param Kind The kind of capture, which may be implicit (for either a /// block or a lambda), or explicit by-value or by-reference (for a lambda). /// /// \param EllipsisLoc The location of the ellipsis, if one is provided in /// an explicit lambda capture. /// /// \param BuildAndDiagnose Whether we are actually supposed to add the /// captures or diagnose errors. If false, this routine merely check whether /// the capture can occur without performing the capture itself or complaining /// if the variable cannot be captured. /// /// \param CaptureType Will be set to the type of the field used to capture /// this variable in the innermost block or lambda. Only valid when the /// variable can be captured. /// /// \param DeclRefType Will be set to the type of a reference to the capture /// from within the current scope. Only valid when the variable can be /// captured. /// /// \param FunctionScopeIndexToStopAt If non-null, it points to the index /// of the FunctionScopeInfo stack beyond which we do not attempt to capture. /// This is useful when enclosing lambdas must speculatively capture /// variables that may or may not be used in certain specializations of /// a nested generic lambda. /// /// \returns true if an error occurred (i.e., the variable cannot be /// captured) and false if the capture succeeded. bool tryCaptureVariable(VarDecl *Var, SourceLocation Loc, TryCaptureKind Kind, SourceLocation EllipsisLoc, bool BuildAndDiagnose, QualType &CaptureType, QualType &DeclRefType, const unsigned *const FunctionScopeIndexToStopAt); /// Try to capture the given variable. bool tryCaptureVariable(VarDecl *Var, SourceLocation Loc, TryCaptureKind Kind = TryCapture_Implicit, SourceLocation EllipsisLoc = SourceLocation()); /// Checks if the variable must be captured. bool NeedToCaptureVariable(VarDecl *Var, SourceLocation Loc); /// Given a variable, determine the type that a reference to that /// variable will have in the given scope. QualType getCapturedDeclRefType(VarDecl *Var, SourceLocation Loc); /// Mark all of the declarations referenced within a particular AST node as /// referenced. Used when template instantiation instantiates a non-dependent /// type -- entities referenced by the type are now referenced. void MarkDeclarationsReferencedInType(SourceLocation Loc, QualType T); void MarkDeclarationsReferencedInExpr(Expr *E, bool SkipLocalVariables = false); /// Try to recover by turning the given expression into a /// call. Returns true if recovery was attempted or an error was /// emitted; this may also leave the ExprResult invalid. bool tryToRecoverWithCall(ExprResult &E, const PartialDiagnostic &PD, bool ForceComplain = false, bool (*IsPlausibleResult)(QualType) = nullptr); /// Figure out if an expression could be turned into a call. bool tryExprAsCall(Expr &E, QualType &ZeroArgCallReturnTy, UnresolvedSetImpl &NonTemplateOverloads); /// Try to convert an expression \p E to type \p Ty. Returns the result of the /// conversion. ExprResult tryConvertExprToType(Expr *E, QualType Ty); /// Conditionally issue a diagnostic based on the statements's reachability /// analysis. /// /// \param Stmts If Stmts is non-empty, delay reporting the diagnostic until /// the function body is parsed, and then do a basic reachability analysis to /// determine if the statement is reachable. If it is unreachable, the /// diagnostic will not be emitted. bool DiagIfReachable(SourceLocation Loc, ArrayRef<const Stmt *> Stmts, const PartialDiagnostic &PD); /// Conditionally issue a diagnostic based on the current /// evaluation context. /// /// \param Statement If Statement is non-null, delay reporting the /// diagnostic until the function body is parsed, and then do a basic /// reachability analysis to determine if the statement is reachable. /// If it is unreachable, the diagnostic will not be emitted. bool DiagRuntimeBehavior(SourceLocation Loc, const Stmt *Statement, const PartialDiagnostic &PD); /// Similar, but diagnostic is only produced if all the specified statements /// are reachable. bool DiagRuntimeBehavior(SourceLocation Loc, ArrayRef<const Stmt*> Stmts, const PartialDiagnostic &PD); // Primary Expressions. SourceRange getExprRange(Expr *E) const; ExprResult ActOnIdExpression( Scope *S, CXXScopeSpec &SS, SourceLocation TemplateKWLoc, UnqualifiedId &Id, bool HasTrailingLParen, bool IsAddressOfOperand, CorrectionCandidateCallback *CCC = nullptr, bool IsInlineAsmIdentifier = false, Token *KeywordReplacement = nullptr); void DecomposeUnqualifiedId(const UnqualifiedId &Id, TemplateArgumentListInfo &Buffer, DeclarationNameInfo &NameInfo, const TemplateArgumentListInfo *&TemplateArgs); bool DiagnoseDependentMemberLookup(LookupResult &R); bool DiagnoseEmptyLookup(Scope *S, CXXScopeSpec &SS, LookupResult &R, CorrectionCandidateCallback &CCC, TemplateArgumentListInfo *ExplicitTemplateArgs = nullptr, ArrayRef<Expr *> Args = None, TypoExpr **Out = nullptr); DeclResult LookupIvarInObjCMethod(LookupResult &Lookup, Scope *S, IdentifierInfo *II); ExprResult BuildIvarRefExpr(Scope *S, SourceLocation Loc, ObjCIvarDecl *IV); ExprResult LookupInObjCMethod(LookupResult &LookUp, Scope *S, IdentifierInfo *II, bool AllowBuiltinCreation=false); ExprResult ActOnDependentIdExpression(const CXXScopeSpec &SS, SourceLocation TemplateKWLoc, const DeclarationNameInfo &NameInfo, bool isAddressOfOperand, const TemplateArgumentListInfo *TemplateArgs); /// If \p D cannot be odr-used in the current expression evaluation context, /// return a reason explaining why. Otherwise, return NOUR_None. NonOdrUseReason getNonOdrUseReasonInCurrentContext(ValueDecl *D); DeclRefExpr *BuildDeclRefExpr(ValueDecl *D, QualType Ty, ExprValueKind VK, SourceLocation Loc, const CXXScopeSpec *SS = nullptr); DeclRefExpr * BuildDeclRefExpr(ValueDecl *D, QualType Ty, ExprValueKind VK, const DeclarationNameInfo &NameInfo, const CXXScopeSpec *SS = nullptr, NamedDecl *FoundD = nullptr, SourceLocation TemplateKWLoc = SourceLocation(), const TemplateArgumentListInfo *TemplateArgs = nullptr); DeclRefExpr * BuildDeclRefExpr(ValueDecl *D, QualType Ty, ExprValueKind VK, const DeclarationNameInfo &NameInfo, NestedNameSpecifierLoc NNS, NamedDecl *FoundD = nullptr, SourceLocation TemplateKWLoc = SourceLocation(), const TemplateArgumentListInfo *TemplateArgs = nullptr); ExprResult BuildAnonymousStructUnionMemberReference( const CXXScopeSpec &SS, SourceLocation nameLoc, IndirectFieldDecl *indirectField, DeclAccessPair FoundDecl = DeclAccessPair::make(nullptr, AS_none), Expr *baseObjectExpr = nullptr, SourceLocation opLoc = SourceLocation()); ExprResult BuildPossibleImplicitMemberExpr( const CXXScopeSpec &SS, SourceLocation TemplateKWLoc, LookupResult &R, const TemplateArgumentListInfo *TemplateArgs, const Scope *S, UnresolvedLookupExpr *AsULE = nullptr); ExprResult BuildImplicitMemberExpr(const CXXScopeSpec &SS, SourceLocation TemplateKWLoc, LookupResult &R, const TemplateArgumentListInfo *TemplateArgs, bool IsDefiniteInstance, const Scope *S); bool UseArgumentDependentLookup(const CXXScopeSpec &SS, const LookupResult &R, bool HasTrailingLParen); ExprResult BuildQualifiedDeclarationNameExpr(CXXScopeSpec &SS, const DeclarationNameInfo &NameInfo, bool IsAddressOfOperand, const Scope *S, TypeSourceInfo **RecoveryTSI = nullptr); ExprResult BuildDependentDeclRefExpr(const CXXScopeSpec &SS, SourceLocation TemplateKWLoc, const DeclarationNameInfo &NameInfo, const TemplateArgumentListInfo *TemplateArgs); ExprResult BuildDeclarationNameExpr(const CXXScopeSpec &SS, LookupResult &R, bool NeedsADL, bool AcceptInvalidDecl = false); ExprResult BuildDeclarationNameExpr( const CXXScopeSpec &SS, const DeclarationNameInfo &NameInfo, NamedDecl *D, NamedDecl *FoundD = nullptr, const TemplateArgumentListInfo *TemplateArgs = nullptr, bool AcceptInvalidDecl = false); ExprResult BuildLiteralOperatorCall(LookupResult &R, DeclarationNameInfo &SuffixInfo, ArrayRef<Expr *> Args, SourceLocation LitEndLoc, TemplateArgumentListInfo *ExplicitTemplateArgs = nullptr); ExprResult BuildPredefinedExpr(SourceLocation Loc, PredefinedExpr::IdentKind IK); ExprResult ActOnPredefinedExpr(SourceLocation Loc, tok::TokenKind Kind); ExprResult ActOnIntegerConstant(SourceLocation Loc, uint64_t Val); ExprResult BuildSYCLUniqueStableNameExpr(SourceLocation OpLoc, SourceLocation LParen, SourceLocation RParen, TypeSourceInfo *TSI); ExprResult ActOnSYCLUniqueStableNameExpr(SourceLocation OpLoc, SourceLocation LParen, SourceLocation RParen, ParsedType ParsedTy); ExprResult BuildSYCLUniqueStableIdExpr(SourceLocation OpLoc, SourceLocation LParen, SourceLocation RParen, Expr *E); ExprResult ActOnSYCLUniqueStableIdExpr(SourceLocation OpLoc, SourceLocation LParen, SourceLocation RParen, Expr *E); bool CheckLoopHintExpr(Expr *E, SourceLocation Loc); ExprResult ActOnNumericConstant(const Token &Tok, Scope *UDLScope = nullptr); ExprResult ActOnCharacterConstant(const Token &Tok, Scope *UDLScope = nullptr); ExprResult ActOnParenExpr(SourceLocation L, SourceLocation R, Expr *E); ExprResult ActOnParenListExpr(SourceLocation L, SourceLocation R, MultiExprArg Val); /// ActOnStringLiteral - The specified tokens were lexed as pasted string /// fragments (e.g. "foo" "bar" L"baz"). ExprResult ActOnStringLiteral(ArrayRef<Token> StringToks, Scope *UDLScope = nullptr); ExprResult ActOnGenericSelectionExpr(SourceLocation KeyLoc, SourceLocation DefaultLoc, SourceLocation RParenLoc, Expr *ControllingExpr, ArrayRef<ParsedType> ArgTypes, ArrayRef<Expr *> ArgExprs); ExprResult CreateGenericSelectionExpr(SourceLocation KeyLoc, SourceLocation DefaultLoc, SourceLocation RParenLoc, Expr *ControllingExpr, ArrayRef<TypeSourceInfo *> Types, ArrayRef<Expr *> Exprs); // Binary/Unary Operators. 'Tok' is the token for the operator. ExprResult CreateBuiltinUnaryOp(SourceLocation OpLoc, UnaryOperatorKind Opc, Expr *InputExpr); ExprResult BuildUnaryOp(Scope *S, SourceLocation OpLoc, UnaryOperatorKind Opc, Expr *Input); ExprResult ActOnUnaryOp(Scope *S, SourceLocation OpLoc, tok::TokenKind Op, Expr *Input); bool isQualifiedMemberAccess(Expr *E); QualType CheckAddressOfOperand(ExprResult &Operand, SourceLocation OpLoc); ExprResult CreateUnaryExprOrTypeTraitExpr(TypeSourceInfo *TInfo, SourceLocation OpLoc, UnaryExprOrTypeTrait ExprKind, SourceRange R); ExprResult CreateUnaryExprOrTypeTraitExpr(Expr *E, SourceLocation OpLoc, UnaryExprOrTypeTrait ExprKind); ExprResult ActOnUnaryExprOrTypeTraitExpr(SourceLocation OpLoc, UnaryExprOrTypeTrait ExprKind, bool IsType, void *TyOrEx, SourceRange ArgRange); ExprResult CheckPlaceholderExpr(Expr *E); bool CheckVecStepExpr(Expr *E); bool CheckUnaryExprOrTypeTraitOperand(Expr *E, UnaryExprOrTypeTrait ExprKind); bool CheckUnaryExprOrTypeTraitOperand(QualType ExprType, SourceLocation OpLoc, SourceRange ExprRange, UnaryExprOrTypeTrait ExprKind); ExprResult ActOnSizeofParameterPackExpr(Scope *S, SourceLocation OpLoc, IdentifierInfo &Name, SourceLocation NameLoc, SourceLocation RParenLoc); ExprResult ActOnPostfixUnaryOp(Scope *S, SourceLocation OpLoc, tok::TokenKind Kind, Expr *Input); ExprResult ActOnArraySubscriptExpr(Scope *S, Expr *Base, SourceLocation LLoc, Expr *Idx, SourceLocation RLoc); ExprResult CreateBuiltinArraySubscriptExpr(Expr *Base, SourceLocation LLoc, Expr *Idx, SourceLocation RLoc); ExprResult CreateBuiltinMatrixSubscriptExpr(Expr *Base, Expr *RowIdx, Expr *ColumnIdx, SourceLocation RBLoc); ExprResult ActOnOMPArraySectionExpr(Expr *Base, SourceLocation LBLoc, Expr *LowerBound, SourceLocation ColonLocFirst, SourceLocation ColonLocSecond, Expr *Length, Expr *Stride, SourceLocation RBLoc); ExprResult ActOnOMPArrayShapingExpr(Expr *Base, SourceLocation LParenLoc, SourceLocation RParenLoc, ArrayRef<Expr *> Dims, ArrayRef<SourceRange> Brackets); /// Data structure for iterator expression. struct OMPIteratorData { IdentifierInfo *DeclIdent = nullptr; SourceLocation DeclIdentLoc; ParsedType Type; OMPIteratorExpr::IteratorRange Range; SourceLocation AssignLoc; SourceLocation ColonLoc; SourceLocation SecColonLoc; }; ExprResult ActOnOMPIteratorExpr(Scope *S, SourceLocation IteratorKwLoc, SourceLocation LLoc, SourceLocation RLoc, ArrayRef<OMPIteratorData> Data); // This struct is for use by ActOnMemberAccess to allow // BuildMemberReferenceExpr to be able to reinvoke ActOnMemberAccess after // changing the access operator from a '.' to a '->' (to see if that is the // change needed to fix an error about an unknown member, e.g. when the class // defines a custom operator->). struct ActOnMemberAccessExtraArgs { Scope *S; UnqualifiedId &Id; Decl *ObjCImpDecl; }; ExprResult BuildMemberReferenceExpr( Expr *Base, QualType BaseType, SourceLocation OpLoc, bool IsArrow, CXXScopeSpec &SS, SourceLocation TemplateKWLoc, NamedDecl *FirstQualifierInScope, const DeclarationNameInfo &NameInfo, const TemplateArgumentListInfo *TemplateArgs, const Scope *S, ActOnMemberAccessExtraArgs *ExtraArgs = nullptr); ExprResult BuildMemberReferenceExpr(Expr *Base, QualType BaseType, SourceLocation OpLoc, bool IsArrow, const CXXScopeSpec &SS, SourceLocation TemplateKWLoc, NamedDecl *FirstQualifierInScope, LookupResult &R, const TemplateArgumentListInfo *TemplateArgs, const Scope *S, bool SuppressQualifierCheck = false, ActOnMemberAccessExtraArgs *ExtraArgs = nullptr); ExprResult BuildFieldReferenceExpr(Expr *BaseExpr, bool IsArrow, SourceLocation OpLoc, const CXXScopeSpec &SS, FieldDecl *Field, DeclAccessPair FoundDecl, const DeclarationNameInfo &MemberNameInfo); ExprResult PerformMemberExprBaseConversion(Expr *Base, bool IsArrow); bool CheckQualifiedMemberReference(Expr *BaseExpr, QualType BaseType, const CXXScopeSpec &SS, const LookupResult &R); ExprResult ActOnDependentMemberExpr(Expr *Base, QualType BaseType, bool IsArrow, SourceLocation OpLoc, const CXXScopeSpec &SS, SourceLocation TemplateKWLoc, NamedDecl *FirstQualifierInScope, const DeclarationNameInfo &NameInfo, const TemplateArgumentListInfo *TemplateArgs); ExprResult ActOnMemberAccessExpr(Scope *S, Expr *Base, SourceLocation OpLoc, tok::TokenKind OpKind, CXXScopeSpec &SS, SourceLocation TemplateKWLoc, UnqualifiedId &Member, Decl *ObjCImpDecl); MemberExpr * BuildMemberExpr(Expr *Base, bool IsArrow, SourceLocation OpLoc, const CXXScopeSpec *SS, SourceLocation TemplateKWLoc, ValueDecl *Member, DeclAccessPair FoundDecl, bool HadMultipleCandidates, const DeclarationNameInfo &MemberNameInfo, QualType Ty, ExprValueKind VK, ExprObjectKind OK, const TemplateArgumentListInfo *TemplateArgs = nullptr); MemberExpr * BuildMemberExpr(Expr *Base, bool IsArrow, SourceLocation OpLoc, NestedNameSpecifierLoc NNS, SourceLocation TemplateKWLoc, ValueDecl *Member, DeclAccessPair FoundDecl, bool HadMultipleCandidates, const DeclarationNameInfo &MemberNameInfo, QualType Ty, ExprValueKind VK, ExprObjectKind OK, const TemplateArgumentListInfo *TemplateArgs = nullptr); void ActOnDefaultCtorInitializers(Decl *CDtorDecl); bool ConvertArgumentsForCall(CallExpr *Call, Expr *Fn, FunctionDecl *FDecl, const FunctionProtoType *Proto, ArrayRef<Expr *> Args, SourceLocation RParenLoc, bool ExecConfig = false); void CheckStaticArrayArgument(SourceLocation CallLoc, ParmVarDecl *Param, const Expr *ArgExpr); /// ActOnCallExpr - Handle a call to Fn with the specified array of arguments. /// This provides the location of the left/right parens and a list of comma /// locations. ExprResult ActOnCallExpr(Scope *S, Expr *Fn, SourceLocation LParenLoc, MultiExprArg ArgExprs, SourceLocation RParenLoc, Expr *ExecConfig = nullptr); ExprResult BuildCallExpr(Scope *S, Expr *Fn, SourceLocation LParenLoc, MultiExprArg ArgExprs, SourceLocation RParenLoc, Expr *ExecConfig = nullptr, bool IsExecConfig = false, bool AllowRecovery = false); Expr *BuildBuiltinCallExpr(SourceLocation Loc, Builtin::ID Id, MultiExprArg CallArgs); enum class AtomicArgumentOrder { API, AST }; ExprResult BuildAtomicExpr(SourceRange CallRange, SourceRange ExprRange, SourceLocation RParenLoc, MultiExprArg Args, AtomicExpr::AtomicOp Op, AtomicArgumentOrder ArgOrder = AtomicArgumentOrder::API); ExprResult BuildResolvedCallExpr(Expr *Fn, NamedDecl *NDecl, SourceLocation LParenLoc, ArrayRef<Expr *> Arg, SourceLocation RParenLoc, Expr *Config = nullptr, bool IsExecConfig = false, ADLCallKind UsesADL = ADLCallKind::NotADL); ExprResult ActOnCUDAExecConfigExpr(Scope *S, SourceLocation LLLLoc, MultiExprArg ExecConfig, SourceLocation GGGLoc); ExprResult ActOnCastExpr(Scope *S, SourceLocation LParenLoc, Declarator &D, ParsedType &Ty, SourceLocation RParenLoc, Expr *CastExpr); ExprResult BuildCStyleCastExpr(SourceLocation LParenLoc, TypeSourceInfo *Ty, SourceLocation RParenLoc, Expr *Op); CastKind PrepareScalarCast(ExprResult &src, QualType destType); /// Build an altivec or OpenCL literal. ExprResult BuildVectorLiteral(SourceLocation LParenLoc, SourceLocation RParenLoc, Expr *E, TypeSourceInfo *TInfo); ExprResult MaybeConvertParenListExprToParenExpr(Scope *S, Expr *ME); ExprResult ActOnCompoundLiteral(SourceLocation LParenLoc, ParsedType Ty, SourceLocation RParenLoc, Expr *InitExpr); ExprResult BuildCompoundLiteralExpr(SourceLocation LParenLoc, TypeSourceInfo *TInfo, SourceLocation RParenLoc, Expr *LiteralExpr); ExprResult ActOnInitList(SourceLocation LBraceLoc, MultiExprArg InitArgList, SourceLocation RBraceLoc); ExprResult BuildInitList(SourceLocation LBraceLoc, MultiExprArg InitArgList, SourceLocation RBraceLoc); ExprResult ActOnDesignatedInitializer(Designation &Desig, SourceLocation EqualOrColonLoc, bool GNUSyntax, ExprResult Init); private: static BinaryOperatorKind ConvertTokenKindToBinaryOpcode(tok::TokenKind Kind); public: ExprResult ActOnBinOp(Scope *S, SourceLocation TokLoc, tok::TokenKind Kind, Expr *LHSExpr, Expr *RHSExpr); ExprResult BuildBinOp(Scope *S, SourceLocation OpLoc, BinaryOperatorKind Opc, Expr *LHSExpr, Expr *RHSExpr); ExprResult CreateBuiltinBinOp(SourceLocation OpLoc, BinaryOperatorKind Opc, Expr *LHSExpr, Expr *RHSExpr); void LookupBinOp(Scope *S, SourceLocation OpLoc, BinaryOperatorKind Opc, UnresolvedSetImpl &Functions); void DiagnoseCommaOperator(const Expr *LHS, SourceLocation Loc); /// ActOnConditionalOp - Parse a ?: operation. Note that 'LHS' may be null /// in the case of a the GNU conditional expr extension. ExprResult ActOnConditionalOp(SourceLocation QuestionLoc, SourceLocation ColonLoc, Expr *CondExpr, Expr *LHSExpr, Expr *RHSExpr); /// ActOnAddrLabel - Parse the GNU address of label extension: "&&foo". ExprResult ActOnAddrLabel(SourceLocation OpLoc, SourceLocation LabLoc, LabelDecl *TheDecl); void ActOnStartStmtExpr(); ExprResult ActOnStmtExpr(Scope *S, SourceLocation LPLoc, Stmt *SubStmt, SourceLocation RPLoc); ExprResult BuildStmtExpr(SourceLocation LPLoc, Stmt *SubStmt, SourceLocation RPLoc, unsigned TemplateDepth); // Handle the final expression in a statement expression. ExprResult ActOnStmtExprResult(ExprResult E); void ActOnStmtExprError(); // __builtin_offsetof(type, identifier(.identifier|[expr])*) struct OffsetOfComponent { SourceLocation LocStart, LocEnd; bool isBrackets; // true if [expr], false if .ident union { IdentifierInfo *IdentInfo; Expr *E; } U; }; /// __builtin_offsetof(type, a.b[123][456].c) ExprResult BuildBuiltinOffsetOf(SourceLocation BuiltinLoc, TypeSourceInfo *TInfo, ArrayRef<OffsetOfComponent> Components, SourceLocation RParenLoc); ExprResult ActOnBuiltinOffsetOf(Scope *S, SourceLocation BuiltinLoc, SourceLocation TypeLoc, ParsedType ParsedArgTy, ArrayRef<OffsetOfComponent> Components, SourceLocation RParenLoc); // __builtin_choose_expr(constExpr, expr1, expr2) ExprResult ActOnChooseExpr(SourceLocation BuiltinLoc, Expr *CondExpr, Expr *LHSExpr, Expr *RHSExpr, SourceLocation RPLoc); // __builtin_va_arg(expr, type) ExprResult ActOnVAArg(SourceLocation BuiltinLoc, Expr *E, ParsedType Ty, SourceLocation RPLoc); ExprResult BuildVAArgExpr(SourceLocation BuiltinLoc, Expr *E, TypeSourceInfo *TInfo, SourceLocation RPLoc); // __builtin_LINE(), __builtin_FUNCTION(), __builtin_FILE(), // __builtin_COLUMN() ExprResult ActOnSourceLocExpr(SourceLocExpr::IdentKind Kind, SourceLocation BuiltinLoc, SourceLocation RPLoc); // Build a potentially resolved SourceLocExpr. ExprResult BuildSourceLocExpr(SourceLocExpr::IdentKind Kind, SourceLocation BuiltinLoc, SourceLocation RPLoc, DeclContext *ParentContext); // __null ExprResult ActOnGNUNullExpr(SourceLocation TokenLoc); bool CheckCaseExpression(Expr *E); /// Describes the result of an "if-exists" condition check. enum IfExistsResult { /// The symbol exists. IER_Exists, /// The symbol does not exist. IER_DoesNotExist, /// The name is a dependent name, so the results will differ /// from one instantiation to the next. IER_Dependent, /// An error occurred. IER_Error }; IfExistsResult CheckMicrosoftIfExistsSymbol(Scope *S, CXXScopeSpec &SS, const DeclarationNameInfo &TargetNameInfo); IfExistsResult CheckMicrosoftIfExistsSymbol(Scope *S, SourceLocation KeywordLoc, bool IsIfExists, CXXScopeSpec &SS, UnqualifiedId &Name); StmtResult BuildMSDependentExistsStmt(SourceLocation KeywordLoc, bool IsIfExists, NestedNameSpecifierLoc QualifierLoc, DeclarationNameInfo NameInfo, Stmt *Nested); StmtResult ActOnMSDependentExistsStmt(SourceLocation KeywordLoc, bool IsIfExists, CXXScopeSpec &SS, UnqualifiedId &Name, Stmt *Nested); //===------------------------- "Block" Extension ------------------------===// /// ActOnBlockStart - This callback is invoked when a block literal is /// started. void ActOnBlockStart(SourceLocation CaretLoc, Scope *CurScope); /// ActOnBlockArguments - This callback allows processing of block arguments. /// If there are no arguments, this is still invoked. void ActOnBlockArguments(SourceLocation CaretLoc, Declarator &ParamInfo, Scope *CurScope); /// ActOnBlockError - If there is an error parsing a block, this callback /// is invoked to pop the information about the block from the action impl. void ActOnBlockError(SourceLocation CaretLoc, Scope *CurScope); /// ActOnBlockStmtExpr - This is called when the body of a block statement /// literal was successfully completed. ^(int x){...} ExprResult ActOnBlockStmtExpr(SourceLocation CaretLoc, Stmt *Body, Scope *CurScope); //===---------------------------- Clang Extensions ----------------------===// /// __builtin_convertvector(...) ExprResult ActOnConvertVectorExpr(Expr *E, ParsedType ParsedDestTy, SourceLocation BuiltinLoc, SourceLocation RParenLoc); //===---------------------------- OpenCL Features -----------------------===// /// __builtin_astype(...) ExprResult ActOnAsTypeExpr(Expr *E, ParsedType ParsedDestTy, SourceLocation BuiltinLoc, SourceLocation RParenLoc); ExprResult BuildAsTypeExpr(Expr *E, QualType DestTy, SourceLocation BuiltinLoc, SourceLocation RParenLoc); //===---------------------------- C++ Features --------------------------===// // Act on C++ namespaces Decl *ActOnStartNamespaceDef(Scope *S, SourceLocation InlineLoc, SourceLocation NamespaceLoc, SourceLocation IdentLoc, IdentifierInfo *Ident, SourceLocation LBrace, const ParsedAttributesView &AttrList, UsingDirectiveDecl *&UsingDecl); void ActOnFinishNamespaceDef(Decl *Dcl, SourceLocation RBrace); NamespaceDecl *getStdNamespace() const; NamespaceDecl *getOrCreateStdNamespace(); NamespaceDecl *lookupStdExperimentalNamespace(); CXXRecordDecl *getStdBadAlloc() const; EnumDecl *getStdAlignValT() const; private: // A cache representing if we've fully checked the various comparison category // types stored in ASTContext. The bit-index corresponds to the integer value // of a ComparisonCategoryType enumerator. llvm::SmallBitVector FullyCheckedComparisonCategories; ValueDecl *tryLookupCtorInitMemberDecl(CXXRecordDecl *ClassDecl, CXXScopeSpec &SS, ParsedType TemplateTypeTy, IdentifierInfo *MemberOrBase); public: enum class ComparisonCategoryUsage { /// The '<=>' operator was used in an expression and a builtin operator /// was selected. OperatorInExpression, /// A defaulted 'operator<=>' needed the comparison category. This /// typically only applies to 'std::strong_ordering', due to the implicit /// fallback return value. DefaultedOperator, }; /// Lookup the specified comparison category types in the standard /// library, an check the VarDecls possibly returned by the operator<=> /// builtins for that type. /// /// \return The type of the comparison category type corresponding to the /// specified Kind, or a null type if an error occurs QualType CheckComparisonCategoryType(ComparisonCategoryType Kind, SourceLocation Loc, ComparisonCategoryUsage Usage); /// Tests whether Ty is an instance of std::initializer_list and, if /// it is and Element is not NULL, assigns the element type to Element. bool isStdInitializerList(QualType Ty, QualType *Element); /// Looks for the std::initializer_list template and instantiates it /// with Element, or emits an error if it's not found. /// /// \returns The instantiated template, or null on error. QualType BuildStdInitializerList(QualType Element, SourceLocation Loc); /// Determine whether Ctor is an initializer-list constructor, as /// defined in [dcl.init.list]p2. bool isInitListConstructor(const FunctionDecl *Ctor); Decl *ActOnUsingDirective(Scope *CurScope, SourceLocation UsingLoc, SourceLocation NamespcLoc, CXXScopeSpec &SS, SourceLocation IdentLoc, IdentifierInfo *NamespcName, const ParsedAttributesView &AttrList); void PushUsingDirective(Scope *S, UsingDirectiveDecl *UDir); Decl *ActOnNamespaceAliasDef(Scope *CurScope, SourceLocation NamespaceLoc, SourceLocation AliasLoc, IdentifierInfo *Alias, CXXScopeSpec &SS, SourceLocation IdentLoc, IdentifierInfo *Ident); void FilterUsingLookup(Scope *S, LookupResult &lookup); void HideUsingShadowDecl(Scope *S, UsingShadowDecl *Shadow); bool CheckUsingShadowDecl(BaseUsingDecl *BUD, NamedDecl *Target, const LookupResult &PreviousDecls, UsingShadowDecl *&PrevShadow); UsingShadowDecl *BuildUsingShadowDecl(Scope *S, BaseUsingDecl *BUD, NamedDecl *Target, UsingShadowDecl *PrevDecl); bool CheckUsingDeclRedeclaration(SourceLocation UsingLoc, bool HasTypenameKeyword, const CXXScopeSpec &SS, SourceLocation NameLoc, const LookupResult &Previous); bool CheckUsingDeclQualifier(SourceLocation UsingLoc, bool HasTypename, const CXXScopeSpec &SS, const DeclarationNameInfo &NameInfo, SourceLocation NameLoc, const LookupResult *R = nullptr, const UsingDecl *UD = nullptr); NamedDecl *BuildUsingDeclaration( Scope *S, AccessSpecifier AS, SourceLocation UsingLoc, bool HasTypenameKeyword, SourceLocation TypenameLoc, CXXScopeSpec &SS, DeclarationNameInfo NameInfo, SourceLocation EllipsisLoc, const ParsedAttributesView &AttrList, bool IsInstantiation, bool IsUsingIfExists); NamedDecl *BuildUsingEnumDeclaration(Scope *S, AccessSpecifier AS, SourceLocation UsingLoc, SourceLocation EnumLoc, SourceLocation NameLoc, EnumDecl *ED); NamedDecl *BuildUsingPackDecl(NamedDecl *InstantiatedFrom, ArrayRef<NamedDecl *> Expansions); bool CheckInheritingConstructorUsingDecl(UsingDecl *UD); /// Given a derived-class using shadow declaration for a constructor and the /// correspnding base class constructor, find or create the implicit /// synthesized derived class constructor to use for this initialization. CXXConstructorDecl * findInheritingConstructor(SourceLocation Loc, CXXConstructorDecl *BaseCtor, ConstructorUsingShadowDecl *DerivedShadow); Decl *ActOnUsingDeclaration(Scope *CurScope, AccessSpecifier AS, SourceLocation UsingLoc, SourceLocation TypenameLoc, CXXScopeSpec &SS, UnqualifiedId &Name, SourceLocation EllipsisLoc, const ParsedAttributesView &AttrList); Decl *ActOnUsingEnumDeclaration(Scope *CurScope, AccessSpecifier AS, SourceLocation UsingLoc, SourceLocation EnumLoc, const DeclSpec &); Decl *ActOnAliasDeclaration(Scope *CurScope, AccessSpecifier AS, MultiTemplateParamsArg TemplateParams, SourceLocation UsingLoc, UnqualifiedId &Name, const ParsedAttributesView &AttrList, TypeResult Type, Decl *DeclFromDeclSpec); /// BuildCXXConstructExpr - Creates a complete call to a constructor, /// including handling of its default argument expressions. /// /// \param ConstructKind - a CXXConstructExpr::ConstructionKind ExprResult BuildCXXConstructExpr(SourceLocation ConstructLoc, QualType DeclInitType, NamedDecl *FoundDecl, CXXConstructorDecl *Constructor, MultiExprArg Exprs, bool HadMultipleCandidates, bool IsListInitialization, bool IsStdInitListInitialization, bool RequiresZeroInit, unsigned ConstructKind, SourceRange ParenRange); /// Build a CXXConstructExpr whose constructor has already been resolved if /// it denotes an inherited constructor. ExprResult BuildCXXConstructExpr(SourceLocation ConstructLoc, QualType DeclInitType, CXXConstructorDecl *Constructor, bool Elidable, MultiExprArg Exprs, bool HadMultipleCandidates, bool IsListInitialization, bool IsStdInitListInitialization, bool RequiresZeroInit, unsigned ConstructKind, SourceRange ParenRange); // FIXME: Can we remove this and have the above BuildCXXConstructExpr check if // the constructor can be elidable? ExprResult BuildCXXConstructExpr(SourceLocation ConstructLoc, QualType DeclInitType, NamedDecl *FoundDecl, CXXConstructorDecl *Constructor, bool Elidable, MultiExprArg Exprs, bool HadMultipleCandidates, bool IsListInitialization, bool IsStdInitListInitialization, bool RequiresZeroInit, unsigned ConstructKind, SourceRange ParenRange); ExprResult BuildCXXDefaultInitExpr(SourceLocation Loc, FieldDecl *Field); /// Instantiate or parse a C++ default argument expression as necessary. /// Return true on error. bool CheckCXXDefaultArgExpr(SourceLocation CallLoc, FunctionDecl *FD, ParmVarDecl *Param); /// BuildCXXDefaultArgExpr - Creates a CXXDefaultArgExpr, instantiating /// the default expr if needed. ExprResult BuildCXXDefaultArgExpr(SourceLocation CallLoc, FunctionDecl *FD, ParmVarDecl *Param); /// FinalizeVarWithDestructor - Prepare for calling destructor on the /// constructed variable. void FinalizeVarWithDestructor(VarDecl *VD, const RecordType *DeclInitType); /// Helper class that collects exception specifications for /// implicitly-declared special member functions. class ImplicitExceptionSpecification { // Pointer to allow copying Sema *Self; // We order exception specifications thus: // noexcept is the most restrictive, but is only used in C++11. // throw() comes next. // Then a throw(collected exceptions) // Finally no specification, which is expressed as noexcept(false). // throw(...) is used instead if any called function uses it. ExceptionSpecificationType ComputedEST; llvm::SmallPtrSet<CanQualType, 4> ExceptionsSeen; SmallVector<QualType, 4> Exceptions; void ClearExceptions() { ExceptionsSeen.clear(); Exceptions.clear(); } public: explicit ImplicitExceptionSpecification(Sema &Self) : Self(&Self), ComputedEST(EST_BasicNoexcept) { if (!Self.getLangOpts().CPlusPlus11) ComputedEST = EST_DynamicNone; } /// Get the computed exception specification type. ExceptionSpecificationType getExceptionSpecType() const { assert(!isComputedNoexcept(ComputedEST) && "noexcept(expr) should not be a possible result"); return ComputedEST; } /// The number of exceptions in the exception specification. unsigned size() const { return Exceptions.size(); } /// The set of exceptions in the exception specification. const QualType *data() const { return Exceptions.data(); } /// Integrate another called method into the collected data. void CalledDecl(SourceLocation CallLoc, const CXXMethodDecl *Method); /// Integrate an invoked expression into the collected data. void CalledExpr(Expr *E) { CalledStmt(E); } /// Integrate an invoked statement into the collected data. void CalledStmt(Stmt *S); /// Overwrite an EPI's exception specification with this /// computed exception specification. FunctionProtoType::ExceptionSpecInfo getExceptionSpec() const { FunctionProtoType::ExceptionSpecInfo ESI; ESI.Type = getExceptionSpecType(); if (ESI.Type == EST_Dynamic) { ESI.Exceptions = Exceptions; } else if (ESI.Type == EST_None) { /// C++11 [except.spec]p14: /// The exception-specification is noexcept(false) if the set of /// potential exceptions of the special member function contains "any" ESI.Type = EST_NoexceptFalse; ESI.NoexceptExpr = Self->ActOnCXXBoolLiteral(SourceLocation(), tok::kw_false).get(); } return ESI; } }; /// Evaluate the implicit exception specification for a defaulted /// special member function. void EvaluateImplicitExceptionSpec(SourceLocation Loc, FunctionDecl *FD); /// Check the given noexcept-specifier, convert its expression, and compute /// the appropriate ExceptionSpecificationType. ExprResult ActOnNoexceptSpec(Expr *NoexceptExpr, ExceptionSpecificationType &EST); /// Check the given exception-specification and update the /// exception specification information with the results. void checkExceptionSpecification(bool IsTopLevel, ExceptionSpecificationType EST, ArrayRef<ParsedType> DynamicExceptions, ArrayRef<SourceRange> DynamicExceptionRanges, Expr *NoexceptExpr, SmallVectorImpl<QualType> &Exceptions, FunctionProtoType::ExceptionSpecInfo &ESI); /// Determine if we're in a case where we need to (incorrectly) eagerly /// parse an exception specification to work around a libstdc++ bug. bool isLibstdcxxEagerExceptionSpecHack(const Declarator &D); /// Add an exception-specification to the given member function /// (or member function template). The exception-specification was parsed /// after the method itself was declared. void actOnDelayedExceptionSpecification(Decl *Method, ExceptionSpecificationType EST, SourceRange SpecificationRange, ArrayRef<ParsedType> DynamicExceptions, ArrayRef<SourceRange> DynamicExceptionRanges, Expr *NoexceptExpr); class InheritedConstructorInfo; /// Determine if a special member function should have a deleted /// definition when it is defaulted. bool ShouldDeleteSpecialMember(CXXMethodDecl *MD, CXXSpecialMember CSM, InheritedConstructorInfo *ICI = nullptr, bool Diagnose = false); /// Produce notes explaining why a defaulted function was defined as deleted. void DiagnoseDeletedDefaultedFunction(FunctionDecl *FD); /// Declare the implicit default constructor for the given class. /// /// \param ClassDecl The class declaration into which the implicit /// default constructor will be added. /// /// \returns The implicitly-declared default constructor. CXXConstructorDecl *DeclareImplicitDefaultConstructor( CXXRecordDecl *ClassDecl); /// DefineImplicitDefaultConstructor - Checks for feasibility of /// defining this constructor as the default constructor. void DefineImplicitDefaultConstructor(SourceLocation CurrentLocation, CXXConstructorDecl *Constructor); /// Declare the implicit destructor for the given class. /// /// \param ClassDecl The class declaration into which the implicit /// destructor will be added. /// /// \returns The implicitly-declared destructor. CXXDestructorDecl *DeclareImplicitDestructor(CXXRecordDecl *ClassDecl); /// DefineImplicitDestructor - Checks for feasibility of /// defining this destructor as the default destructor. void DefineImplicitDestructor(SourceLocation CurrentLocation, CXXDestructorDecl *Destructor); /// Build an exception spec for destructors that don't have one. /// /// C++11 says that user-defined destructors with no exception spec get one /// that looks as if the destructor was implicitly declared. void AdjustDestructorExceptionSpec(CXXDestructorDecl *Destructor); /// Define the specified inheriting constructor. void DefineInheritingConstructor(SourceLocation UseLoc, CXXConstructorDecl *Constructor); /// Declare the implicit copy constructor for the given class. /// /// \param ClassDecl The class declaration into which the implicit /// copy constructor will be added. /// /// \returns The implicitly-declared copy constructor. CXXConstructorDecl *DeclareImplicitCopyConstructor(CXXRecordDecl *ClassDecl); /// DefineImplicitCopyConstructor - Checks for feasibility of /// defining this constructor as the copy constructor. void DefineImplicitCopyConstructor(SourceLocation CurrentLocation, CXXConstructorDecl *Constructor); /// Declare the implicit move constructor for the given class. /// /// \param ClassDecl The Class declaration into which the implicit /// move constructor will be added. /// /// \returns The implicitly-declared move constructor, or NULL if it wasn't /// declared. CXXConstructorDecl *DeclareImplicitMoveConstructor(CXXRecordDecl *ClassDecl); /// DefineImplicitMoveConstructor - Checks for feasibility of /// defining this constructor as the move constructor. void DefineImplicitMoveConstructor(SourceLocation CurrentLocation, CXXConstructorDecl *Constructor); /// Declare the implicit copy assignment operator for the given class. /// /// \param ClassDecl The class declaration into which the implicit /// copy assignment operator will be added. /// /// \returns The implicitly-declared copy assignment operator. CXXMethodDecl *DeclareImplicitCopyAssignment(CXXRecordDecl *ClassDecl); /// Defines an implicitly-declared copy assignment operator. void DefineImplicitCopyAssignment(SourceLocation CurrentLocation, CXXMethodDecl *MethodDecl); /// Declare the implicit move assignment operator for the given class. /// /// \param ClassDecl The Class declaration into which the implicit /// move assignment operator will be added. /// /// \returns The implicitly-declared move assignment operator, or NULL if it /// wasn't declared. CXXMethodDecl *DeclareImplicitMoveAssignment(CXXRecordDecl *ClassDecl); /// Defines an implicitly-declared move assignment operator. void DefineImplicitMoveAssignment(SourceLocation CurrentLocation, CXXMethodDecl *MethodDecl); /// Force the declaration of any implicitly-declared members of this /// class. void ForceDeclarationOfImplicitMembers(CXXRecordDecl *Class); /// Check a completed declaration of an implicit special member. void CheckImplicitSpecialMemberDeclaration(Scope *S, FunctionDecl *FD); /// Determine whether the given function is an implicitly-deleted /// special member function. bool isImplicitlyDeleted(FunctionDecl *FD); /// Check whether 'this' shows up in the type of a static member /// function after the (naturally empty) cv-qualifier-seq would be. /// /// \returns true if an error occurred. bool checkThisInStaticMemberFunctionType(CXXMethodDecl *Method); /// Whether this' shows up in the exception specification of a static /// member function. bool checkThisInStaticMemberFunctionExceptionSpec(CXXMethodDecl *Method); /// Check whether 'this' shows up in the attributes of the given /// static member function. /// /// \returns true if an error occurred. bool checkThisInStaticMemberFunctionAttributes(CXXMethodDecl *Method); /// MaybeBindToTemporary - If the passed in expression has a record type with /// a non-trivial destructor, this will return CXXBindTemporaryExpr. Otherwise /// it simply returns the passed in expression. ExprResult MaybeBindToTemporary(Expr *E); /// Wrap the expression in a ConstantExpr if it is a potential immediate /// invocation. ExprResult CheckForImmediateInvocation(ExprResult E, FunctionDecl *Decl); bool CompleteConstructorCall(CXXConstructorDecl *Constructor, QualType DeclInitType, MultiExprArg ArgsPtr, SourceLocation Loc, SmallVectorImpl<Expr *> &ConvertedArgs, bool AllowExplicit = false, bool IsListInitialization = false); ParsedType getInheritingConstructorName(CXXScopeSpec &SS, SourceLocation NameLoc, IdentifierInfo &Name); ParsedType getConstructorName(IdentifierInfo &II, SourceLocation NameLoc, Scope *S, CXXScopeSpec &SS, bool EnteringContext); ParsedType getDestructorName(SourceLocation TildeLoc, IdentifierInfo &II, SourceLocation NameLoc, Scope *S, CXXScopeSpec &SS, ParsedType ObjectType, bool EnteringContext); ParsedType getDestructorTypeForDecltype(const DeclSpec &DS, ParsedType ObjectType); // Checks that reinterpret casts don't have undefined behavior. void CheckCompatibleReinterpretCast(QualType SrcType, QualType DestType, bool IsDereference, SourceRange Range); // Checks that the vector type should be initialized from a scalar // by splatting the value rather than populating a single element. // This is the case for AltiVecVector types as well as with // AltiVecPixel and AltiVecBool when -faltivec-src-compat=xl is specified. bool ShouldSplatAltivecScalarInCast(const VectorType *VecTy); // Checks if the -faltivec-src-compat=gcc option is specified. // If so, AltiVecVector, AltiVecBool and AltiVecPixel types are // treated the same way as they are when trying to initialize // these vectors on gcc (an error is emitted). bool CheckAltivecInitFromScalar(SourceRange R, QualType VecTy, QualType SrcTy); /// ActOnCXXNamedCast - Parse /// {dynamic,static,reinterpret,const,addrspace}_cast's. ExprResult ActOnCXXNamedCast(SourceLocation OpLoc, tok::TokenKind Kind, SourceLocation LAngleBracketLoc, Declarator &D, SourceLocation RAngleBracketLoc, SourceLocation LParenLoc, Expr *E, SourceLocation RParenLoc); ExprResult BuildCXXNamedCast(SourceLocation OpLoc, tok::TokenKind Kind, TypeSourceInfo *Ty, Expr *E, SourceRange AngleBrackets, SourceRange Parens); ExprResult ActOnBuiltinBitCastExpr(SourceLocation KWLoc, Declarator &Dcl, ExprResult Operand, SourceLocation RParenLoc); ExprResult BuildBuiltinBitCastExpr(SourceLocation KWLoc, TypeSourceInfo *TSI, Expr *Operand, SourceLocation RParenLoc); ExprResult BuildCXXTypeId(QualType TypeInfoType, SourceLocation TypeidLoc, TypeSourceInfo *Operand, SourceLocation RParenLoc); ExprResult BuildCXXTypeId(QualType TypeInfoType, SourceLocation TypeidLoc, Expr *Operand, SourceLocation RParenLoc); /// ActOnCXXTypeid - Parse typeid( something ). ExprResult ActOnCXXTypeid(SourceLocation OpLoc, SourceLocation LParenLoc, bool isType, void *TyOrExpr, SourceLocation RParenLoc); ExprResult BuildCXXUuidof(QualType TypeInfoType, SourceLocation TypeidLoc, TypeSourceInfo *Operand, SourceLocation RParenLoc); ExprResult BuildCXXUuidof(QualType TypeInfoType, SourceLocation TypeidLoc, Expr *Operand, SourceLocation RParenLoc); /// ActOnCXXUuidof - Parse __uuidof( something ). ExprResult ActOnCXXUuidof(SourceLocation OpLoc, SourceLocation LParenLoc, bool isType, void *TyOrExpr, SourceLocation RParenLoc); /// Handle a C++1z fold-expression: ( expr op ... op expr ). ExprResult ActOnCXXFoldExpr(Scope *S, SourceLocation LParenLoc, Expr *LHS, tok::TokenKind Operator, SourceLocation EllipsisLoc, Expr *RHS, SourceLocation RParenLoc); ExprResult BuildCXXFoldExpr(UnresolvedLookupExpr *Callee, SourceLocation LParenLoc, Expr *LHS, BinaryOperatorKind Operator, SourceLocation EllipsisLoc, Expr *RHS, SourceLocation RParenLoc, Optional<unsigned> NumExpansions); ExprResult BuildEmptyCXXFoldExpr(SourceLocation EllipsisLoc, BinaryOperatorKind Operator); //// ActOnCXXThis - Parse 'this' pointer. ExprResult ActOnCXXThis(SourceLocation loc); /// Build a CXXThisExpr and mark it referenced in the current context. Expr *BuildCXXThisExpr(SourceLocation Loc, QualType Type, bool IsImplicit); void MarkThisReferenced(CXXThisExpr *This); /// Try to retrieve the type of the 'this' pointer. /// /// \returns The type of 'this', if possible. Otherwise, returns a NULL type. QualType getCurrentThisType(); /// When non-NULL, the C++ 'this' expression is allowed despite the /// current context not being a non-static member function. In such cases, /// this provides the type used for 'this'. QualType CXXThisTypeOverride; /// RAII object used to temporarily allow the C++ 'this' expression /// to be used, with the given qualifiers on the current class type. class CXXThisScopeRAII { Sema &S; QualType OldCXXThisTypeOverride; bool Enabled; public: /// Introduce a new scope where 'this' may be allowed (when enabled), /// using the given declaration (which is either a class template or a /// class) along with the given qualifiers. /// along with the qualifiers placed on '*this'. CXXThisScopeRAII(Sema &S, Decl *ContextDecl, Qualifiers CXXThisTypeQuals, bool Enabled = true); ~CXXThisScopeRAII(); }; /// Make sure the value of 'this' is actually available in the current /// context, if it is a potentially evaluated context. /// /// \param Loc The location at which the capture of 'this' occurs. /// /// \param Explicit Whether 'this' is explicitly captured in a lambda /// capture list. /// /// \param FunctionScopeIndexToStopAt If non-null, it points to the index /// of the FunctionScopeInfo stack beyond which we do not attempt to capture. /// This is useful when enclosing lambdas must speculatively capture /// 'this' that may or may not be used in certain specializations of /// a nested generic lambda (depending on whether the name resolves to /// a non-static member function or a static function). /// \return returns 'true' if failed, 'false' if success. bool CheckCXXThisCapture(SourceLocation Loc, bool Explicit = false, bool BuildAndDiagnose = true, const unsigned *const FunctionScopeIndexToStopAt = nullptr, bool ByCopy = false); /// Determine whether the given type is the type of *this that is used /// outside of the body of a member function for a type that is currently /// being defined. bool isThisOutsideMemberFunctionBody(QualType BaseType); /// ActOnCXXBoolLiteral - Parse {true,false} literals. ExprResult ActOnCXXBoolLiteral(SourceLocation OpLoc, tok::TokenKind Kind); /// ActOnObjCBoolLiteral - Parse {__objc_yes,__objc_no} literals. ExprResult ActOnObjCBoolLiteral(SourceLocation OpLoc, tok::TokenKind Kind); ExprResult ActOnObjCAvailabilityCheckExpr(llvm::ArrayRef<AvailabilitySpec> AvailSpecs, SourceLocation AtLoc, SourceLocation RParen); /// ActOnCXXNullPtrLiteral - Parse 'nullptr'. ExprResult ActOnCXXNullPtrLiteral(SourceLocation Loc); //// ActOnCXXThrow - Parse throw expressions. ExprResult ActOnCXXThrow(Scope *S, SourceLocation OpLoc, Expr *expr); ExprResult BuildCXXThrow(SourceLocation OpLoc, Expr *Ex, bool IsThrownVarInScope); bool CheckCXXThrowOperand(SourceLocation ThrowLoc, QualType ThrowTy, Expr *E); /// ActOnCXXTypeConstructExpr - Parse construction of a specified type. /// Can be interpreted either as function-style casting ("int(x)") /// or class type construction ("ClassType(x,y,z)") /// or creation of a value-initialized type ("int()"). ExprResult ActOnCXXTypeConstructExpr(ParsedType TypeRep, SourceLocation LParenOrBraceLoc, MultiExprArg Exprs, SourceLocation RParenOrBraceLoc, bool ListInitialization); ExprResult BuildCXXTypeConstructExpr(TypeSourceInfo *Type, SourceLocation LParenLoc, MultiExprArg Exprs, SourceLocation RParenLoc, bool ListInitialization); /// ActOnCXXNew - Parsed a C++ 'new' expression. ExprResult ActOnCXXNew(SourceLocation StartLoc, bool UseGlobal, SourceLocation PlacementLParen, MultiExprArg PlacementArgs, SourceLocation PlacementRParen, SourceRange TypeIdParens, Declarator &D, Expr *Initializer); ExprResult BuildCXXNew(SourceRange Range, bool UseGlobal, SourceLocation PlacementLParen, MultiExprArg PlacementArgs, SourceLocation PlacementRParen, SourceRange TypeIdParens, QualType AllocType, TypeSourceInfo *AllocTypeInfo, Optional<Expr *> ArraySize, SourceRange DirectInitRange, Expr *Initializer); /// Determine whether \p FD is an aligned allocation or deallocation /// function that is unavailable. bool isUnavailableAlignedAllocationFunction(const FunctionDecl &FD) const; /// Produce diagnostics if \p FD is an aligned allocation or deallocation /// function that is unavailable. void diagnoseUnavailableAlignedAllocation(const FunctionDecl &FD, SourceLocation Loc); bool CheckAllocatedType(QualType AllocType, SourceLocation Loc, SourceRange R); /// The scope in which to find allocation functions. enum AllocationFunctionScope { /// Only look for allocation functions in the global scope. AFS_Global, /// Only look for allocation functions in the scope of the /// allocated class. AFS_Class, /// Look for allocation functions in both the global scope /// and in the scope of the allocated class. AFS_Both }; /// Finds the overloads of operator new and delete that are appropriate /// for the allocation. bool FindAllocationFunctions(SourceLocation StartLoc, SourceRange Range, AllocationFunctionScope NewScope, AllocationFunctionScope DeleteScope, QualType AllocType, bool IsArray, bool &PassAlignment, MultiExprArg PlaceArgs, FunctionDecl *&OperatorNew, FunctionDecl *&OperatorDelete, bool Diagnose = true); void DeclareGlobalNewDelete(); void DeclareGlobalAllocationFunction(DeclarationName Name, QualType Return, ArrayRef<QualType> Params); bool FindDeallocationFunction(SourceLocation StartLoc, CXXRecordDecl *RD, DeclarationName Name, FunctionDecl* &Operator, bool Diagnose = true); FunctionDecl *FindUsualDeallocationFunction(SourceLocation StartLoc, bool CanProvideSize, bool Overaligned, DeclarationName Name); FunctionDecl *FindDeallocationFunctionForDestructor(SourceLocation StartLoc, CXXRecordDecl *RD); /// ActOnCXXDelete - Parsed a C++ 'delete' expression ExprResult ActOnCXXDelete(SourceLocation StartLoc, bool UseGlobal, bool ArrayForm, Expr *Operand); void CheckVirtualDtorCall(CXXDestructorDecl *dtor, SourceLocation Loc, bool IsDelete, bool CallCanBeVirtual, bool WarnOnNonAbstractTypes, SourceLocation DtorLoc); ExprResult ActOnNoexceptExpr(SourceLocation KeyLoc, SourceLocation LParen, Expr *Operand, SourceLocation RParen); ExprResult BuildCXXNoexceptExpr(SourceLocation KeyLoc, Expr *Operand, SourceLocation RParen); /// Parsed one of the type trait support pseudo-functions. ExprResult ActOnTypeTrait(TypeTrait Kind, SourceLocation KWLoc, ArrayRef<ParsedType> Args, SourceLocation RParenLoc); ExprResult BuildTypeTrait(TypeTrait Kind, SourceLocation KWLoc, ArrayRef<TypeSourceInfo *> Args, SourceLocation RParenLoc); /// ActOnArrayTypeTrait - Parsed one of the binary type trait support /// pseudo-functions. ExprResult ActOnArrayTypeTrait(ArrayTypeTrait ATT, SourceLocation KWLoc, ParsedType LhsTy, Expr *DimExpr, SourceLocation RParen); ExprResult BuildArrayTypeTrait(ArrayTypeTrait ATT, SourceLocation KWLoc, TypeSourceInfo *TSInfo, Expr *DimExpr, SourceLocation RParen); /// ActOnExpressionTrait - Parsed one of the unary type trait support /// pseudo-functions. ExprResult ActOnExpressionTrait(ExpressionTrait OET, SourceLocation KWLoc, Expr *Queried, SourceLocation RParen); ExprResult BuildExpressionTrait(ExpressionTrait OET, SourceLocation KWLoc, Expr *Queried, SourceLocation RParen); ExprResult ActOnStartCXXMemberReference(Scope *S, Expr *Base, SourceLocation OpLoc, tok::TokenKind OpKind, ParsedType &ObjectType, bool &MayBePseudoDestructor); ExprResult BuildPseudoDestructorExpr(Expr *Base, SourceLocation OpLoc, tok::TokenKind OpKind, const CXXScopeSpec &SS, TypeSourceInfo *ScopeType, SourceLocation CCLoc, SourceLocation TildeLoc, PseudoDestructorTypeStorage DestroyedType); ExprResult ActOnPseudoDestructorExpr(Scope *S, Expr *Base, SourceLocation OpLoc, tok::TokenKind OpKind, CXXScopeSpec &SS, UnqualifiedId &FirstTypeName, SourceLocation CCLoc, SourceLocation TildeLoc, UnqualifiedId &SecondTypeName); ExprResult ActOnPseudoDestructorExpr(Scope *S, Expr *Base, SourceLocation OpLoc, tok::TokenKind OpKind, SourceLocation TildeLoc, const DeclSpec& DS); /// MaybeCreateExprWithCleanups - If the current full-expression /// requires any cleanups, surround it with a ExprWithCleanups node. /// Otherwise, just returns the passed-in expression. Expr *MaybeCreateExprWithCleanups(Expr *SubExpr); Stmt *MaybeCreateStmtWithCleanups(Stmt *SubStmt); ExprResult MaybeCreateExprWithCleanups(ExprResult SubExpr); MaterializeTemporaryExpr * CreateMaterializeTemporaryExpr(QualType T, Expr *Temporary, bool BoundToLvalueReference); ExprResult ActOnFinishFullExpr(Expr *Expr, bool DiscardedValue) { return ActOnFinishFullExpr( Expr, Expr ? Expr->getExprLoc() : SourceLocation(), DiscardedValue); } ExprResult ActOnFinishFullExpr(Expr *Expr, SourceLocation CC, bool DiscardedValue, bool IsConstexpr = false); StmtResult ActOnFinishFullStmt(Stmt *Stmt); // Marks SS invalid if it represents an incomplete type. bool RequireCompleteDeclContext(CXXScopeSpec &SS, DeclContext *DC); // Complete an enum decl, maybe without a scope spec. bool RequireCompleteEnumDecl(EnumDecl *D, SourceLocation L, CXXScopeSpec *SS = nullptr); DeclContext *computeDeclContext(QualType T); DeclContext *computeDeclContext(const CXXScopeSpec &SS, bool EnteringContext = false); bool isDependentScopeSpecifier(const CXXScopeSpec &SS); CXXRecordDecl *getCurrentInstantiationOf(NestedNameSpecifier *NNS); /// The parser has parsed a global nested-name-specifier '::'. /// /// \param CCLoc The location of the '::'. /// /// \param SS The nested-name-specifier, which will be updated in-place /// to reflect the parsed nested-name-specifier. /// /// \returns true if an error occurred, false otherwise. bool ActOnCXXGlobalScopeSpecifier(SourceLocation CCLoc, CXXScopeSpec &SS); /// The parser has parsed a '__super' nested-name-specifier. /// /// \param SuperLoc The location of the '__super' keyword. /// /// \param ColonColonLoc The location of the '::'. /// /// \param SS The nested-name-specifier, which will be updated in-place /// to reflect the parsed nested-name-specifier. /// /// \returns true if an error occurred, false otherwise. bool ActOnSuperScopeSpecifier(SourceLocation SuperLoc, SourceLocation ColonColonLoc, CXXScopeSpec &SS); bool isAcceptableNestedNameSpecifier(const NamedDecl *SD, bool *CanCorrect = nullptr); NamedDecl *FindFirstQualifierInScope(Scope *S, NestedNameSpecifier *NNS); /// Keeps information about an identifier in a nested-name-spec. /// struct NestedNameSpecInfo { /// The type of the object, if we're parsing nested-name-specifier in /// a member access expression. ParsedType ObjectType; /// The identifier preceding the '::'. IdentifierInfo *Identifier; /// The location of the identifier. SourceLocation IdentifierLoc; /// The location of the '::'. SourceLocation CCLoc; /// Creates info object for the most typical case. NestedNameSpecInfo(IdentifierInfo *II, SourceLocation IdLoc, SourceLocation ColonColonLoc, ParsedType ObjectType = ParsedType()) : ObjectType(ObjectType), Identifier(II), IdentifierLoc(IdLoc), CCLoc(ColonColonLoc) { } NestedNameSpecInfo(IdentifierInfo *II, SourceLocation IdLoc, SourceLocation ColonColonLoc, QualType ObjectType) : ObjectType(ParsedType::make(ObjectType)), Identifier(II), IdentifierLoc(IdLoc), CCLoc(ColonColonLoc) { } }; bool isNonTypeNestedNameSpecifier(Scope *S, CXXScopeSpec &SS, NestedNameSpecInfo &IdInfo); bool BuildCXXNestedNameSpecifier(Scope *S, NestedNameSpecInfo &IdInfo, bool EnteringContext, CXXScopeSpec &SS, NamedDecl *ScopeLookupResult, bool ErrorRecoveryLookup, bool *IsCorrectedToColon = nullptr, bool OnlyNamespace = false); /// The parser has parsed a nested-name-specifier 'identifier::'. /// /// \param S The scope in which this nested-name-specifier occurs. /// /// \param IdInfo Parser information about an identifier in the /// nested-name-spec. /// /// \param EnteringContext Whether we're entering the context nominated by /// this nested-name-specifier. /// /// \param SS The nested-name-specifier, which is both an input /// parameter (the nested-name-specifier before this type) and an /// output parameter (containing the full nested-name-specifier, /// including this new type). /// /// \param ErrorRecoveryLookup If true, then this method is called to improve /// error recovery. In this case do not emit error message. /// /// \param IsCorrectedToColon If not null, suggestions to replace '::' -> ':' /// are allowed. The bool value pointed by this parameter is set to 'true' /// if the identifier is treated as if it was followed by ':', not '::'. /// /// \param OnlyNamespace If true, only considers namespaces in lookup. /// /// \returns true if an error occurred, false otherwise. bool ActOnCXXNestedNameSpecifier(Scope *S, NestedNameSpecInfo &IdInfo, bool EnteringContext, CXXScopeSpec &SS, bool ErrorRecoveryLookup = false, bool *IsCorrectedToColon = nullptr, bool OnlyNamespace = false); ExprResult ActOnDecltypeExpression(Expr *E); bool ActOnCXXNestedNameSpecifierDecltype(CXXScopeSpec &SS, const DeclSpec &DS, SourceLocation ColonColonLoc); bool IsInvalidUnlessNestedName(Scope *S, CXXScopeSpec &SS, NestedNameSpecInfo &IdInfo, bool EnteringContext); /// The parser has parsed a nested-name-specifier /// 'template[opt] template-name < template-args >::'. /// /// \param S The scope in which this nested-name-specifier occurs. /// /// \param SS The nested-name-specifier, which is both an input /// parameter (the nested-name-specifier before this type) and an /// output parameter (containing the full nested-name-specifier, /// including this new type). /// /// \param TemplateKWLoc the location of the 'template' keyword, if any. /// \param TemplateName the template name. /// \param TemplateNameLoc The location of the template name. /// \param LAngleLoc The location of the opening angle bracket ('<'). /// \param TemplateArgs The template arguments. /// \param RAngleLoc The location of the closing angle bracket ('>'). /// \param CCLoc The location of the '::'. /// /// \param EnteringContext Whether we're entering the context of the /// nested-name-specifier. /// /// /// \returns true if an error occurred, false otherwise. bool ActOnCXXNestedNameSpecifier(Scope *S, CXXScopeSpec &SS, SourceLocation TemplateKWLoc, TemplateTy TemplateName, SourceLocation TemplateNameLoc, SourceLocation LAngleLoc, ASTTemplateArgsPtr TemplateArgs, SourceLocation RAngleLoc, SourceLocation CCLoc, bool EnteringContext); /// Given a C++ nested-name-specifier, produce an annotation value /// that the parser can use later to reconstruct the given /// nested-name-specifier. /// /// \param SS A nested-name-specifier. /// /// \returns A pointer containing all of the information in the /// nested-name-specifier \p SS. void *SaveNestedNameSpecifierAnnotation(CXXScopeSpec &SS); /// Given an annotation pointer for a nested-name-specifier, restore /// the nested-name-specifier structure. /// /// \param Annotation The annotation pointer, produced by /// \c SaveNestedNameSpecifierAnnotation(). /// /// \param AnnotationRange The source range corresponding to the annotation. /// /// \param SS The nested-name-specifier that will be updated with the contents /// of the annotation pointer. void RestoreNestedNameSpecifierAnnotation(void *Annotation, SourceRange AnnotationRange, CXXScopeSpec &SS); bool ShouldEnterDeclaratorScope(Scope *S, const CXXScopeSpec &SS); /// ActOnCXXEnterDeclaratorScope - Called when a C++ scope specifier (global /// scope or nested-name-specifier) is parsed, part of a declarator-id. /// After this method is called, according to [C++ 3.4.3p3], names should be /// looked up in the declarator-id's scope, until the declarator is parsed and /// ActOnCXXExitDeclaratorScope is called. /// The 'SS' should be a non-empty valid CXXScopeSpec. bool ActOnCXXEnterDeclaratorScope(Scope *S, CXXScopeSpec &SS); /// ActOnCXXExitDeclaratorScope - Called when a declarator that previously /// invoked ActOnCXXEnterDeclaratorScope(), is finished. 'SS' is the same /// CXXScopeSpec that was passed to ActOnCXXEnterDeclaratorScope as well. /// Used to indicate that names should revert to being looked up in the /// defining scope. void ActOnCXXExitDeclaratorScope(Scope *S, const CXXScopeSpec &SS); /// ActOnCXXEnterDeclInitializer - Invoked when we are about to parse an /// initializer for the declaration 'Dcl'. /// After this method is called, according to [C++ 3.4.1p13], if 'Dcl' is a /// static data member of class X, names should be looked up in the scope of /// class X. void ActOnCXXEnterDeclInitializer(Scope *S, Decl *Dcl); /// ActOnCXXExitDeclInitializer - Invoked after we are finished parsing an /// initializer for the declaration 'Dcl'. void ActOnCXXExitDeclInitializer(Scope *S, Decl *Dcl); /// Create a new lambda closure type. CXXRecordDecl *createLambdaClosureType(SourceRange IntroducerRange, TypeSourceInfo *Info, bool KnownDependent, LambdaCaptureDefault CaptureDefault); /// Start the definition of a lambda expression. CXXMethodDecl *startLambdaDefinition(CXXRecordDecl *Class, SourceRange IntroducerRange, TypeSourceInfo *MethodType, SourceLocation EndLoc, ArrayRef<ParmVarDecl *> Params, ConstexprSpecKind ConstexprKind, Expr *TrailingRequiresClause); /// Number lambda for linkage purposes if necessary. void handleLambdaNumbering( CXXRecordDecl *Class, CXXMethodDecl *Method, Optional<std::tuple<bool, unsigned, unsigned, Decl *>> Mangling = None); /// Endow the lambda scope info with the relevant properties. void buildLambdaScope(sema::LambdaScopeInfo *LSI, CXXMethodDecl *CallOperator, SourceRange IntroducerRange, LambdaCaptureDefault CaptureDefault, SourceLocation CaptureDefaultLoc, bool ExplicitParams, bool ExplicitResultType, bool Mutable); /// Perform initialization analysis of the init-capture and perform /// any implicit conversions such as an lvalue-to-rvalue conversion if /// not being used to initialize a reference. ParsedType actOnLambdaInitCaptureInitialization( SourceLocation Loc, bool ByRef, SourceLocation EllipsisLoc, IdentifierInfo *Id, LambdaCaptureInitKind InitKind, Expr *&Init) { return ParsedType::make(buildLambdaInitCaptureInitialization( Loc, ByRef, EllipsisLoc, None, Id, InitKind != LambdaCaptureInitKind::CopyInit, Init)); } QualType buildLambdaInitCaptureInitialization( SourceLocation Loc, bool ByRef, SourceLocation EllipsisLoc, Optional<unsigned> NumExpansions, IdentifierInfo *Id, bool DirectInit, Expr *&Init); /// Create a dummy variable within the declcontext of the lambda's /// call operator, for name lookup purposes for a lambda init capture. /// /// CodeGen handles emission of lambda captures, ignoring these dummy /// variables appropriately. VarDecl *createLambdaInitCaptureVarDecl(SourceLocation Loc, QualType InitCaptureType, SourceLocation EllipsisLoc, IdentifierInfo *Id, unsigned InitStyle, Expr *Init); /// Add an init-capture to a lambda scope. void addInitCapture(sema::LambdaScopeInfo *LSI, VarDecl *Var); /// Note that we have finished the explicit captures for the /// given lambda. void finishLambdaExplicitCaptures(sema::LambdaScopeInfo *LSI); /// \brief This is called after parsing the explicit template parameter list /// on a lambda (if it exists) in C++2a. void ActOnLambdaExplicitTemplateParameterList(SourceLocation LAngleLoc, ArrayRef<NamedDecl *> TParams, SourceLocation RAngleLoc, ExprResult RequiresClause); /// Introduce the lambda parameters into scope. void addLambdaParameters( ArrayRef<LambdaIntroducer::LambdaCapture> Captures, CXXMethodDecl *CallOperator, Scope *CurScope); /// Deduce a block or lambda's return type based on the return /// statements present in the body. void deduceClosureReturnType(sema::CapturingScopeInfo &CSI); /// ActOnStartOfLambdaDefinition - This is called just before we start /// parsing the body of a lambda; it analyzes the explicit captures and /// arguments, and sets up various data-structures for the body of the /// lambda. void ActOnStartOfLambdaDefinition(LambdaIntroducer &Intro, Declarator &ParamInfo, Scope *CurScope); /// ActOnLambdaError - If there is an error parsing a lambda, this callback /// is invoked to pop the information about the lambda. void ActOnLambdaError(SourceLocation StartLoc, Scope *CurScope, bool IsInstantiation = false); /// ActOnLambdaExpr - This is called when the body of a lambda expression /// was successfully completed. ExprResult ActOnLambdaExpr(SourceLocation StartLoc, Stmt *Body, Scope *CurScope); /// Does copying/destroying the captured variable have side effects? bool CaptureHasSideEffects(const sema::Capture &From); /// Diagnose if an explicit lambda capture is unused. Returns true if a /// diagnostic is emitted. bool DiagnoseUnusedLambdaCapture(SourceRange CaptureRange, const sema::Capture &From); /// Build a FieldDecl suitable to hold the given capture. FieldDecl *BuildCaptureField(RecordDecl *RD, const sema::Capture &Capture); /// Initialize the given capture with a suitable expression. ExprResult BuildCaptureInit(const sema::Capture &Capture, SourceLocation ImplicitCaptureLoc, bool IsOpenMPMapping = false); /// Complete a lambda-expression having processed and attached the /// lambda body. ExprResult BuildLambdaExpr(SourceLocation StartLoc, SourceLocation EndLoc, sema::LambdaScopeInfo *LSI); /// Get the return type to use for a lambda's conversion function(s) to /// function pointer type, given the type of the call operator. QualType getLambdaConversionFunctionResultType(const FunctionProtoType *CallOpType, CallingConv CC); /// Define the "body" of the conversion from a lambda object to a /// function pointer. /// /// This routine doesn't actually define a sensible body; rather, it fills /// in the initialization expression needed to copy the lambda object into /// the block, and IR generation actually generates the real body of the /// block pointer conversion. void DefineImplicitLambdaToFunctionPointerConversion( SourceLocation CurrentLoc, CXXConversionDecl *Conv); /// Define the "body" of the conversion from a lambda object to a /// block pointer. /// /// This routine doesn't actually define a sensible body; rather, it fills /// in the initialization expression needed to copy the lambda object into /// the block, and IR generation actually generates the real body of the /// block pointer conversion. void DefineImplicitLambdaToBlockPointerConversion(SourceLocation CurrentLoc, CXXConversionDecl *Conv); ExprResult BuildBlockForLambdaConversion(SourceLocation CurrentLocation, SourceLocation ConvLocation, CXXConversionDecl *Conv, Expr *Src); /// Check whether the given expression is a valid constraint expression. /// A diagnostic is emitted if it is not, false is returned, and /// PossibleNonPrimary will be set to true if the failure might be due to a /// non-primary expression being used as an atomic constraint. bool CheckConstraintExpression(const Expr *CE, Token NextToken = Token(), bool *PossibleNonPrimary = nullptr, bool IsTrailingRequiresClause = false); private: /// Caches pairs of template-like decls whose associated constraints were /// checked for subsumption and whether or not the first's constraints did in /// fact subsume the second's. llvm::DenseMap<std::pair<NamedDecl *, NamedDecl *>, bool> SubsumptionCache; /// Caches the normalized associated constraints of declarations (concepts or /// constrained declarations). If an error occurred while normalizing the /// associated constraints of the template or concept, nullptr will be cached /// here. llvm::DenseMap<NamedDecl *, NormalizedConstraint *> NormalizationCache; llvm::ContextualFoldingSet<ConstraintSatisfaction, const ASTContext &> SatisfactionCache; public: const NormalizedConstraint * getNormalizedAssociatedConstraints( NamedDecl *ConstrainedDecl, ArrayRef<const Expr *> AssociatedConstraints); /// \brief Check whether the given declaration's associated constraints are /// at least as constrained than another declaration's according to the /// partial ordering of constraints. /// /// \param Result If no error occurred, receives the result of true if D1 is /// at least constrained than D2, and false otherwise. /// /// \returns true if an error occurred, false otherwise. bool IsAtLeastAsConstrained(NamedDecl *D1, ArrayRef<const Expr *> AC1, NamedDecl *D2, ArrayRef<const Expr *> AC2, bool &Result); /// If D1 was not at least as constrained as D2, but would've been if a pair /// of atomic constraints involved had been declared in a concept and not /// repeated in two separate places in code. /// \returns true if such a diagnostic was emitted, false otherwise. bool MaybeEmitAmbiguousAtomicConstraintsDiagnostic(NamedDecl *D1, ArrayRef<const Expr *> AC1, NamedDecl *D2, ArrayRef<const Expr *> AC2); /// \brief Check whether the given list of constraint expressions are /// satisfied (as if in a 'conjunction') given template arguments. /// \param Template the template-like entity that triggered the constraints /// check (either a concept or a constrained entity). /// \param ConstraintExprs a list of constraint expressions, treated as if /// they were 'AND'ed together. /// \param TemplateArgs the list of template arguments to substitute into the /// constraint expression. /// \param TemplateIDRange The source range of the template id that /// caused the constraints check. /// \param Satisfaction if true is returned, will contain details of the /// satisfaction, with enough information to diagnose an unsatisfied /// expression. /// \returns true if an error occurred and satisfaction could not be checked, /// false otherwise. bool CheckConstraintSatisfaction( const NamedDecl *Template, ArrayRef<const Expr *> ConstraintExprs, ArrayRef<TemplateArgument> TemplateArgs, SourceRange TemplateIDRange, ConstraintSatisfaction &Satisfaction); /// \brief Check whether the given non-dependent constraint expression is /// satisfied. Returns false and updates Satisfaction with the satisfaction /// verdict if successful, emits a diagnostic and returns true if an error /// occured and satisfaction could not be determined. /// /// \returns true if an error occurred, false otherwise. bool CheckConstraintSatisfaction(const Expr *ConstraintExpr, ConstraintSatisfaction &Satisfaction); /// Check whether the given function decl's trailing requires clause is /// satisfied, if any. Returns false and updates Satisfaction with the /// satisfaction verdict if successful, emits a diagnostic and returns true if /// an error occured and satisfaction could not be determined. /// /// \returns true if an error occurred, false otherwise. bool CheckFunctionConstraints(const FunctionDecl *FD, ConstraintSatisfaction &Satisfaction, SourceLocation UsageLoc = SourceLocation()); /// \brief Ensure that the given template arguments satisfy the constraints /// associated with the given template, emitting a diagnostic if they do not. /// /// \param Template The template to which the template arguments are being /// provided. /// /// \param TemplateArgs The converted, canonicalized template arguments. /// /// \param TemplateIDRange The source range of the template id that /// caused the constraints check. /// /// \returns true if the constrains are not satisfied or could not be checked /// for satisfaction, false if the constraints are satisfied. bool EnsureTemplateArgumentListConstraints(TemplateDecl *Template, ArrayRef<TemplateArgument> TemplateArgs, SourceRange TemplateIDRange); /// \brief Emit diagnostics explaining why a constraint expression was deemed /// unsatisfied. /// \param First whether this is the first time an unsatisfied constraint is /// diagnosed for this error. void DiagnoseUnsatisfiedConstraint(const ConstraintSatisfaction &Satisfaction, bool First = true); /// \brief Emit diagnostics explaining why a constraint expression was deemed /// unsatisfied. void DiagnoseUnsatisfiedConstraint(const ASTConstraintSatisfaction &Satisfaction, bool First = true); // ParseObjCStringLiteral - Parse Objective-C string literals. ExprResult ParseObjCStringLiteral(SourceLocation *AtLocs, ArrayRef<Expr *> Strings); ExprResult BuildObjCStringLiteral(SourceLocation AtLoc, StringLiteral *S); /// BuildObjCNumericLiteral - builds an ObjCBoxedExpr AST node for the /// numeric literal expression. Type of the expression will be "NSNumber *" /// or "id" if NSNumber is unavailable. ExprResult BuildObjCNumericLiteral(SourceLocation AtLoc, Expr *Number); ExprResult ActOnObjCBoolLiteral(SourceLocation AtLoc, SourceLocation ValueLoc, bool Value); ExprResult BuildObjCArrayLiteral(SourceRange SR, MultiExprArg Elements); /// BuildObjCBoxedExpr - builds an ObjCBoxedExpr AST node for the /// '@' prefixed parenthesized expression. The type of the expression will /// either be "NSNumber *", "NSString *" or "NSValue *" depending on the type /// of ValueType, which is allowed to be a built-in numeric type, "char *", /// "const char *" or C structure with attribute 'objc_boxable'. ExprResult BuildObjCBoxedExpr(SourceRange SR, Expr *ValueExpr); ExprResult BuildObjCSubscriptExpression(SourceLocation RB, Expr *BaseExpr, Expr *IndexExpr, ObjCMethodDecl *getterMethod, ObjCMethodDecl *setterMethod); ExprResult BuildObjCDictionaryLiteral(SourceRange SR, MutableArrayRef<ObjCDictionaryElement> Elements); ExprResult BuildObjCEncodeExpression(SourceLocation AtLoc, TypeSourceInfo *EncodedTypeInfo, SourceLocation RParenLoc); ExprResult BuildCXXMemberCallExpr(Expr *Exp, NamedDecl *FoundDecl, CXXConversionDecl *Method, bool HadMultipleCandidates); ExprResult ParseObjCEncodeExpression(SourceLocation AtLoc, SourceLocation EncodeLoc, SourceLocation LParenLoc, ParsedType Ty, SourceLocation RParenLoc); /// ParseObjCSelectorExpression - Build selector expression for \@selector ExprResult ParseObjCSelectorExpression(Selector Sel, SourceLocation AtLoc, SourceLocation SelLoc, SourceLocation LParenLoc, SourceLocation RParenLoc, bool WarnMultipleSelectors); /// ParseObjCProtocolExpression - Build protocol expression for \@protocol ExprResult ParseObjCProtocolExpression(IdentifierInfo * ProtocolName, SourceLocation AtLoc, SourceLocation ProtoLoc, SourceLocation LParenLoc, SourceLocation ProtoIdLoc, SourceLocation RParenLoc); //===--------------------------------------------------------------------===// // C++ Declarations // Decl *ActOnStartLinkageSpecification(Scope *S, SourceLocation ExternLoc, Expr *LangStr, SourceLocation LBraceLoc); Decl *ActOnFinishLinkageSpecification(Scope *S, Decl *LinkageSpec, SourceLocation RBraceLoc); //===--------------------------------------------------------------------===// // C++ Classes // CXXRecordDecl *getCurrentClass(Scope *S, const CXXScopeSpec *SS); bool isCurrentClassName(const IdentifierInfo &II, Scope *S, const CXXScopeSpec *SS = nullptr); bool isCurrentClassNameTypo(IdentifierInfo *&II, const CXXScopeSpec *SS); bool ActOnAccessSpecifier(AccessSpecifier Access, SourceLocation ASLoc, SourceLocation ColonLoc, const ParsedAttributesView &Attrs); NamedDecl *ActOnCXXMemberDeclarator(Scope *S, AccessSpecifier AS, Declarator &D, MultiTemplateParamsArg TemplateParameterLists, Expr *BitfieldWidth, const VirtSpecifiers &VS, InClassInitStyle InitStyle); void ActOnStartCXXInClassMemberInitializer(); void ActOnFinishCXXInClassMemberInitializer(Decl *VarDecl, SourceLocation EqualLoc, Expr *Init); MemInitResult ActOnMemInitializer(Decl *ConstructorD, Scope *S, CXXScopeSpec &SS, IdentifierInfo *MemberOrBase, ParsedType TemplateTypeTy, const DeclSpec &DS, SourceLocation IdLoc, SourceLocation LParenLoc, ArrayRef<Expr *> Args, SourceLocation RParenLoc, SourceLocation EllipsisLoc); MemInitResult ActOnMemInitializer(Decl *ConstructorD, Scope *S, CXXScopeSpec &SS, IdentifierInfo *MemberOrBase, ParsedType TemplateTypeTy, const DeclSpec &DS, SourceLocation IdLoc, Expr *InitList, SourceLocation EllipsisLoc); MemInitResult BuildMemInitializer(Decl *ConstructorD, Scope *S, CXXScopeSpec &SS, IdentifierInfo *MemberOrBase, ParsedType TemplateTypeTy, const DeclSpec &DS, SourceLocation IdLoc, Expr *Init, SourceLocation EllipsisLoc); MemInitResult BuildMemberInitializer(ValueDecl *Member, Expr *Init, SourceLocation IdLoc); MemInitResult BuildBaseInitializer(QualType BaseType, TypeSourceInfo *BaseTInfo, Expr *Init, CXXRecordDecl *ClassDecl, SourceLocation EllipsisLoc); MemInitResult BuildDelegatingInitializer(TypeSourceInfo *TInfo, Expr *Init, CXXRecordDecl *ClassDecl); bool SetDelegatingInitializer(CXXConstructorDecl *Constructor, CXXCtorInitializer *Initializer); bool SetCtorInitializers(CXXConstructorDecl *Constructor, bool AnyErrors, ArrayRef<CXXCtorInitializer *> Initializers = None); void SetIvarInitializers(ObjCImplementationDecl *ObjCImplementation); /// MarkBaseAndMemberDestructorsReferenced - Given a record decl, /// mark all the non-trivial destructors of its members and bases as /// referenced. void MarkBaseAndMemberDestructorsReferenced(SourceLocation Loc, CXXRecordDecl *Record); /// Mark destructors of virtual bases of this class referenced. In the Itanium /// C++ ABI, this is done when emitting a destructor for any non-abstract /// class. In the Microsoft C++ ABI, this is done any time a class's /// destructor is referenced. void MarkVirtualBaseDestructorsReferenced( SourceLocation Location, CXXRecordDecl *ClassDecl, llvm::SmallPtrSetImpl<const RecordType *> *DirectVirtualBases = nullptr); /// Do semantic checks to allow the complete destructor variant to be emitted /// when the destructor is defined in another translation unit. In the Itanium /// C++ ABI, destructor variants are emitted together. In the MS C++ ABI, they /// can be emitted in separate TUs. To emit the complete variant, run a subset /// of the checks performed when emitting a regular destructor. void CheckCompleteDestructorVariant(SourceLocation CurrentLocation, CXXDestructorDecl *Dtor); /// The list of classes whose vtables have been used within /// this translation unit, and the source locations at which the /// first use occurred. typedef std::pair<CXXRecordDecl*, SourceLocation> VTableUse; /// The list of vtables that are required but have not yet been /// materialized. SmallVector<VTableUse, 16> VTableUses; /// The set of classes whose vtables have been used within /// this translation unit, and a bit that will be true if the vtable is /// required to be emitted (otherwise, it should be emitted only if needed /// by code generation). llvm::DenseMap<CXXRecordDecl *, bool> VTablesUsed; /// Load any externally-stored vtable uses. void LoadExternalVTableUses(); /// Note that the vtable for the given class was used at the /// given location. void MarkVTableUsed(SourceLocation Loc, CXXRecordDecl *Class, bool DefinitionRequired = false); /// Mark the exception specifications of all virtual member functions /// in the given class as needed. void MarkVirtualMemberExceptionSpecsNeeded(SourceLocation Loc, const CXXRecordDecl *RD); /// MarkVirtualMembersReferenced - Will mark all members of the given /// CXXRecordDecl referenced. void MarkVirtualMembersReferenced(SourceLocation Loc, const CXXRecordDecl *RD, bool ConstexprOnly = false); /// Define all of the vtables that have been used in this /// translation unit and reference any virtual members used by those /// vtables. /// /// \returns true if any work was done, false otherwise. bool DefineUsedVTables(); void AddImplicitlyDeclaredMembersToClass(CXXRecordDecl *ClassDecl); void ActOnMemInitializers(Decl *ConstructorDecl, SourceLocation ColonLoc, ArrayRef<CXXCtorInitializer*> MemInits, bool AnyErrors); /// Check class-level dllimport/dllexport attribute. The caller must /// ensure that referenceDLLExportedClassMethods is called some point later /// when all outer classes of Class are complete. void checkClassLevelDLLAttribute(CXXRecordDecl *Class); void checkClassLevelCodeSegAttribute(CXXRecordDecl *Class); void referenceDLLExportedClassMethods(); void propagateDLLAttrToBaseClassTemplate( CXXRecordDecl *Class, Attr *ClassAttr, ClassTemplateSpecializationDecl *BaseTemplateSpec, SourceLocation BaseLoc); /// Add gsl::Pointer attribute to std::container::iterator /// \param ND The declaration that introduces the name /// std::container::iterator. \param UnderlyingRecord The record named by ND. void inferGslPointerAttribute(NamedDecl *ND, CXXRecordDecl *UnderlyingRecord); /// Add [[gsl::Owner]] and [[gsl::Pointer]] attributes for std:: types. void inferGslOwnerPointerAttribute(CXXRecordDecl *Record); /// Add [[gsl::Pointer]] attributes for std:: types. void inferGslPointerAttribute(TypedefNameDecl *TD); void CheckCompletedCXXClass(Scope *S, CXXRecordDecl *Record); /// Check that the C++ class annoated with "trivial_abi" satisfies all the /// conditions that are needed for the attribute to have an effect. void checkIllFormedTrivialABIStruct(CXXRecordDecl &RD); void ActOnFinishCXXMemberSpecification(Scope *S, SourceLocation RLoc, Decl *TagDecl, SourceLocation LBrac, SourceLocation RBrac, const ParsedAttributesView &AttrList); void ActOnFinishCXXMemberDecls(); void ActOnFinishCXXNonNestedClass(); void ActOnReenterCXXMethodParameter(Scope *S, ParmVarDecl *Param); unsigned ActOnReenterTemplateScope(Decl *Template, llvm::function_ref<Scope *()> EnterScope); void ActOnStartDelayedMemberDeclarations(Scope *S, Decl *Record); void ActOnStartDelayedCXXMethodDeclaration(Scope *S, Decl *Method); void ActOnDelayedCXXMethodParameter(Scope *S, Decl *Param); void ActOnFinishDelayedMemberDeclarations(Scope *S, Decl *Record); void ActOnFinishDelayedCXXMethodDeclaration(Scope *S, Decl *Method); void ActOnFinishDelayedMemberInitializers(Decl *Record); void MarkAsLateParsedTemplate(FunctionDecl *FD, Decl *FnD, CachedTokens &Toks); void UnmarkAsLateParsedTemplate(FunctionDecl *FD); bool IsInsideALocalClassWithinATemplateFunction(); Decl *ActOnStaticAssertDeclaration(SourceLocation StaticAssertLoc, Expr *AssertExpr, Expr *AssertMessageExpr, SourceLocation RParenLoc); Decl *BuildStaticAssertDeclaration(SourceLocation StaticAssertLoc, Expr *AssertExpr, StringLiteral *AssertMessageExpr, SourceLocation RParenLoc, bool Failed); FriendDecl *CheckFriendTypeDecl(SourceLocation LocStart, SourceLocation FriendLoc, TypeSourceInfo *TSInfo); Decl *ActOnFriendTypeDecl(Scope *S, const DeclSpec &DS, MultiTemplateParamsArg TemplateParams); NamedDecl *ActOnFriendFunctionDecl(Scope *S, Declarator &D, MultiTemplateParamsArg TemplateParams); QualType CheckConstructorDeclarator(Declarator &D, QualType R, StorageClass& SC); void CheckConstructor(CXXConstructorDecl *Constructor); QualType CheckDestructorDeclarator(Declarator &D, QualType R, StorageClass& SC); bool CheckDestructor(CXXDestructorDecl *Destructor); void CheckConversionDeclarator(Declarator &D, QualType &R, StorageClass& SC); Decl *ActOnConversionDeclarator(CXXConversionDecl *Conversion); void CheckDeductionGuideDeclarator(Declarator &D, QualType &R, StorageClass &SC); void CheckDeductionGuideTemplate(FunctionTemplateDecl *TD); void CheckExplicitlyDefaultedFunction(Scope *S, FunctionDecl *MD); bool CheckExplicitlyDefaultedSpecialMember(CXXMethodDecl *MD, CXXSpecialMember CSM); void CheckDelayedMemberExceptionSpecs(); bool CheckExplicitlyDefaultedComparison(Scope *S, FunctionDecl *MD, DefaultedComparisonKind DCK); void DeclareImplicitEqualityComparison(CXXRecordDecl *RD, FunctionDecl *Spaceship); void DefineDefaultedComparison(SourceLocation Loc, FunctionDecl *FD, DefaultedComparisonKind DCK); //===--------------------------------------------------------------------===// // C++ Derived Classes // /// ActOnBaseSpecifier - Parsed a base specifier CXXBaseSpecifier *CheckBaseSpecifier(CXXRecordDecl *Class, SourceRange SpecifierRange, bool Virtual, AccessSpecifier Access, TypeSourceInfo *TInfo, SourceLocation EllipsisLoc); BaseResult ActOnBaseSpecifier(Decl *classdecl, SourceRange SpecifierRange, ParsedAttributes &Attrs, bool Virtual, AccessSpecifier Access, ParsedType basetype, SourceLocation BaseLoc, SourceLocation EllipsisLoc); bool AttachBaseSpecifiers(CXXRecordDecl *Class, MutableArrayRef<CXXBaseSpecifier *> Bases); void ActOnBaseSpecifiers(Decl *ClassDecl, MutableArrayRef<CXXBaseSpecifier *> Bases); bool IsDerivedFrom(SourceLocation Loc, QualType Derived, QualType Base); bool IsDerivedFrom(SourceLocation Loc, QualType Derived, QualType Base, CXXBasePaths &Paths); // FIXME: I don't like this name. void BuildBasePathArray(const CXXBasePaths &Paths, CXXCastPath &BasePath); bool CheckDerivedToBaseConversion(QualType Derived, QualType Base, SourceLocation Loc, SourceRange Range, CXXCastPath *BasePath = nullptr, bool IgnoreAccess = false); bool CheckDerivedToBaseConversion(QualType Derived, QualType Base, unsigned InaccessibleBaseID, unsigned AmbiguousBaseConvID, SourceLocation Loc, SourceRange Range, DeclarationName Name, CXXCastPath *BasePath, bool IgnoreAccess = false); std::string getAmbiguousPathsDisplayString(CXXBasePaths &Paths); bool CheckOverridingFunctionAttributes(const CXXMethodDecl *New, const CXXMethodDecl *Old); /// CheckOverridingFunctionReturnType - Checks whether the return types are /// covariant, according to C++ [class.virtual]p5. bool CheckOverridingFunctionReturnType(const CXXMethodDecl *New, const CXXMethodDecl *Old); /// CheckOverridingFunctionExceptionSpec - Checks whether the exception /// spec is a subset of base spec. bool CheckOverridingFunctionExceptionSpec(const CXXMethodDecl *New, const CXXMethodDecl *Old); bool CheckPureMethod(CXXMethodDecl *Method, SourceRange InitRange); /// CheckOverrideControl - Check C++11 override control semantics. void CheckOverrideControl(NamedDecl *D); /// DiagnoseAbsenceOfOverrideControl - Diagnose if 'override' keyword was /// not used in the declaration of an overriding method. void DiagnoseAbsenceOfOverrideControl(NamedDecl *D, bool Inconsistent); /// CheckForFunctionMarkedFinal - Checks whether a virtual member function /// overrides a virtual member function marked 'final', according to /// C++11 [class.virtual]p4. bool CheckIfOverriddenFunctionIsMarkedFinal(const CXXMethodDecl *New, const CXXMethodDecl *Old); //===--------------------------------------------------------------------===// // C++ Access Control // enum AccessResult { AR_accessible, AR_inaccessible, AR_dependent, AR_delayed }; bool SetMemberAccessSpecifier(NamedDecl *MemberDecl, NamedDecl *PrevMemberDecl, AccessSpecifier LexicalAS); AccessResult CheckUnresolvedMemberAccess(UnresolvedMemberExpr *E, DeclAccessPair FoundDecl); AccessResult CheckUnresolvedLookupAccess(UnresolvedLookupExpr *E, DeclAccessPair FoundDecl); AccessResult CheckAllocationAccess(SourceLocation OperatorLoc, SourceRange PlacementRange, CXXRecordDecl *NamingClass, DeclAccessPair FoundDecl, bool Diagnose = true); AccessResult CheckConstructorAccess(SourceLocation Loc, CXXConstructorDecl *D, DeclAccessPair FoundDecl, const InitializedEntity &Entity, bool IsCopyBindingRefToTemp = false); AccessResult CheckConstructorAccess(SourceLocation Loc, CXXConstructorDecl *D, DeclAccessPair FoundDecl, const InitializedEntity &Entity, const PartialDiagnostic &PDiag); AccessResult CheckDestructorAccess(SourceLocation Loc, CXXDestructorDecl *Dtor, const PartialDiagnostic &PDiag, QualType objectType = QualType()); AccessResult CheckFriendAccess(NamedDecl *D); AccessResult CheckMemberAccess(SourceLocation UseLoc, CXXRecordDecl *NamingClass, DeclAccessPair Found); AccessResult CheckStructuredBindingMemberAccess(SourceLocation UseLoc, CXXRecordDecl *DecomposedClass, DeclAccessPair Field); AccessResult CheckMemberOperatorAccess(SourceLocation Loc, Expr *ObjectExpr, Expr *ArgExpr, DeclAccessPair FoundDecl); AccessResult CheckAddressOfMemberAccess(Expr *OvlExpr, DeclAccessPair FoundDecl); AccessResult CheckBaseClassAccess(SourceLocation AccessLoc, QualType Base, QualType Derived, const CXXBasePath &Path, unsigned DiagID, bool ForceCheck = false, bool ForceUnprivileged = false); void CheckLookupAccess(const LookupResult &R); bool IsSimplyAccessible(NamedDecl *Decl, CXXRecordDecl *NamingClass, QualType BaseType); bool isMemberAccessibleForDeletion(CXXRecordDecl *NamingClass, DeclAccessPair Found, QualType ObjectType, SourceLocation Loc, const PartialDiagnostic &Diag); bool isMemberAccessibleForDeletion(CXXRecordDecl *NamingClass, DeclAccessPair Found, QualType ObjectType) { return isMemberAccessibleForDeletion(NamingClass, Found, ObjectType, SourceLocation(), PDiag()); } void HandleDependentAccessCheck(const DependentDiagnostic &DD, const MultiLevelTemplateArgumentList &TemplateArgs); void PerformDependentDiagnostics(const DeclContext *Pattern, const MultiLevelTemplateArgumentList &TemplateArgs); void HandleDelayedAccessCheck(sema::DelayedDiagnostic &DD, Decl *Ctx); /// When true, access checking violations are treated as SFINAE /// failures rather than hard errors. bool AccessCheckingSFINAE; enum AbstractDiagSelID { AbstractNone = -1, AbstractReturnType, AbstractParamType, AbstractVariableType, AbstractFieldType, AbstractIvarType, AbstractSynthesizedIvarType, AbstractArrayType }; bool isAbstractType(SourceLocation Loc, QualType T); bool RequireNonAbstractType(SourceLocation Loc, QualType T, TypeDiagnoser &Diagnoser); template <typename... Ts> bool RequireNonAbstractType(SourceLocation Loc, QualType T, unsigned DiagID, const Ts &...Args) { BoundTypeDiagnoser<Ts...> Diagnoser(DiagID, Args...); return RequireNonAbstractType(Loc, T, Diagnoser); } void DiagnoseAbstractType(const CXXRecordDecl *RD); //===--------------------------------------------------------------------===// // C++ Overloaded Operators [C++ 13.5] // bool CheckOverloadedOperatorDeclaration(FunctionDecl *FnDecl); bool CheckLiteralOperatorDeclaration(FunctionDecl *FnDecl); //===--------------------------------------------------------------------===// // C++ Templates [C++ 14] // void FilterAcceptableTemplateNames(LookupResult &R, bool AllowFunctionTemplates = true, bool AllowDependent = true); bool hasAnyAcceptableTemplateNames(LookupResult &R, bool AllowFunctionTemplates = true, bool AllowDependent = true, bool AllowNonTemplateFunctions = false); /// Try to interpret the lookup result D as a template-name. /// /// \param D A declaration found by name lookup. /// \param AllowFunctionTemplates Whether function templates should be /// considered valid results. /// \param AllowDependent Whether unresolved using declarations (that might /// name templates) should be considered valid results. static NamedDecl *getAsTemplateNameDecl(NamedDecl *D, bool AllowFunctionTemplates = true, bool AllowDependent = true); enum TemplateNameIsRequiredTag { TemplateNameIsRequired }; /// Whether and why a template name is required in this lookup. class RequiredTemplateKind { public: /// Template name is required if TemplateKWLoc is valid. RequiredTemplateKind(SourceLocation TemplateKWLoc = SourceLocation()) : TemplateKW(TemplateKWLoc) {} /// Template name is unconditionally required. RequiredTemplateKind(TemplateNameIsRequiredTag) : TemplateKW() {} SourceLocation getTemplateKeywordLoc() const { return TemplateKW.getValueOr(SourceLocation()); } bool hasTemplateKeyword() const { return getTemplateKeywordLoc().isValid(); } bool isRequired() const { return TemplateKW != SourceLocation(); } explicit operator bool() const { return isRequired(); } private: llvm::Optional<SourceLocation> TemplateKW; }; enum class AssumedTemplateKind { /// This is not assumed to be a template name. None, /// This is assumed to be a template name because lookup found nothing. FoundNothing, /// This is assumed to be a template name because lookup found one or more /// functions (but no function templates). FoundFunctions, }; bool LookupTemplateName( LookupResult &R, Scope *S, CXXScopeSpec &SS, QualType ObjectType, bool EnteringContext, bool &MemberOfUnknownSpecialization, RequiredTemplateKind RequiredTemplate = SourceLocation(), AssumedTemplateKind *ATK = nullptr, bool AllowTypoCorrection = true); TemplateNameKind isTemplateName(Scope *S, CXXScopeSpec &SS, bool hasTemplateKeyword, const UnqualifiedId &Name, ParsedType ObjectType, bool EnteringContext, TemplateTy &Template, bool &MemberOfUnknownSpecialization, bool Disambiguation = false); /// Try to resolve an undeclared template name as a type template. /// /// Sets II to the identifier corresponding to the template name, and updates /// Name to a corresponding (typo-corrected) type template name and TNK to /// the corresponding kind, if possible. void ActOnUndeclaredTypeTemplateName(Scope *S, TemplateTy &Name, TemplateNameKind &TNK, SourceLocation NameLoc, IdentifierInfo *&II); bool resolveAssumedTemplateNameAsType(Scope *S, TemplateName &Name, SourceLocation NameLoc, bool Diagnose = true); /// Determine whether a particular identifier might be the name in a C++1z /// deduction-guide declaration. bool isDeductionGuideName(Scope *S, const IdentifierInfo &Name, SourceLocation NameLoc, ParsedTemplateTy *Template = nullptr); bool DiagnoseUnknownTemplateName(const IdentifierInfo &II, SourceLocation IILoc, Scope *S, const CXXScopeSpec *SS, TemplateTy &SuggestedTemplate, TemplateNameKind &SuggestedKind); bool DiagnoseUninstantiableTemplate(SourceLocation PointOfInstantiation, NamedDecl *Instantiation, bool InstantiatedFromMember, const NamedDecl *Pattern, const NamedDecl *PatternDef, TemplateSpecializationKind TSK, bool Complain = true); void DiagnoseTemplateParameterShadow(SourceLocation Loc, Decl *PrevDecl); TemplateDecl *AdjustDeclIfTemplate(Decl *&Decl); NamedDecl *ActOnTypeParameter(Scope *S, bool Typename, SourceLocation EllipsisLoc, SourceLocation KeyLoc, IdentifierInfo *ParamName, SourceLocation ParamNameLoc, unsigned Depth, unsigned Position, SourceLocation EqualLoc, ParsedType DefaultArg, bool HasTypeConstraint); bool ActOnTypeConstraint(const CXXScopeSpec &SS, TemplateIdAnnotation *TypeConstraint, TemplateTypeParmDecl *ConstrainedParameter, SourceLocation EllipsisLoc); bool BuildTypeConstraint(const CXXScopeSpec &SS, TemplateIdAnnotation *TypeConstraint, TemplateTypeParmDecl *ConstrainedParameter, SourceLocation EllipsisLoc, bool AllowUnexpandedPack); bool AttachTypeConstraint(NestedNameSpecifierLoc NS, DeclarationNameInfo NameInfo, ConceptDecl *NamedConcept, const TemplateArgumentListInfo *TemplateArgs, TemplateTypeParmDecl *ConstrainedParameter, SourceLocation EllipsisLoc); bool AttachTypeConstraint(AutoTypeLoc TL, NonTypeTemplateParmDecl *ConstrainedParameter, SourceLocation EllipsisLoc); bool RequireStructuralType(QualType T, SourceLocation Loc); QualType CheckNonTypeTemplateParameterType(TypeSourceInfo *&TSI, SourceLocation Loc); QualType CheckNonTypeTemplateParameterType(QualType T, SourceLocation Loc); NamedDecl *ActOnNonTypeTemplateParameter(Scope *S, Declarator &D, unsigned Depth, unsigned Position, SourceLocation EqualLoc, Expr *DefaultArg); NamedDecl *ActOnTemplateTemplateParameter(Scope *S, SourceLocation TmpLoc, TemplateParameterList *Params, SourceLocation EllipsisLoc, IdentifierInfo *ParamName, SourceLocation ParamNameLoc, unsigned Depth, unsigned Position, SourceLocation EqualLoc, ParsedTemplateArgument DefaultArg); TemplateParameterList * ActOnTemplateParameterList(unsigned Depth, SourceLocation ExportLoc, SourceLocation TemplateLoc, SourceLocation LAngleLoc, ArrayRef<NamedDecl *> Params, SourceLocation RAngleLoc, Expr *RequiresClause); /// The context in which we are checking a template parameter list. enum TemplateParamListContext { TPC_ClassTemplate, TPC_VarTemplate, TPC_FunctionTemplate, TPC_ClassTemplateMember, TPC_FriendClassTemplate, TPC_FriendFunctionTemplate, TPC_FriendFunctionTemplateDefinition, TPC_TypeAliasTemplate }; bool CheckTemplateParameterList(TemplateParameterList *NewParams, TemplateParameterList *OldParams, TemplateParamListContext TPC, SkipBodyInfo *SkipBody = nullptr); TemplateParameterList *MatchTemplateParametersToScopeSpecifier( SourceLocation DeclStartLoc, SourceLocation DeclLoc, const CXXScopeSpec &SS, TemplateIdAnnotation *TemplateId, ArrayRef<TemplateParameterList *> ParamLists, bool IsFriend, bool &IsMemberSpecialization, bool &Invalid, bool SuppressDiagnostic = false); DeclResult CheckClassTemplate( Scope *S, unsigned TagSpec, TagUseKind TUK, SourceLocation KWLoc, CXXScopeSpec &SS, IdentifierInfo *Name, SourceLocation NameLoc, const ParsedAttributesView &Attr, TemplateParameterList *TemplateParams, AccessSpecifier AS, SourceLocation ModulePrivateLoc, SourceLocation FriendLoc, unsigned NumOuterTemplateParamLists, TemplateParameterList **OuterTemplateParamLists, SkipBodyInfo *SkipBody = nullptr); TemplateArgumentLoc getTrivialTemplateArgumentLoc(const TemplateArgument &Arg, QualType NTTPType, SourceLocation Loc); /// Get a template argument mapping the given template parameter to itself, /// e.g. for X in \c template<int X>, this would return an expression template /// argument referencing X. TemplateArgumentLoc getIdentityTemplateArgumentLoc(NamedDecl *Param, SourceLocation Location); void translateTemplateArguments(const ASTTemplateArgsPtr &In, TemplateArgumentListInfo &Out); ParsedTemplateArgument ActOnTemplateTypeArgument(TypeResult ParsedType); void NoteAllFoundTemplates(TemplateName Name); QualType CheckTemplateIdType(TemplateName Template, SourceLocation TemplateLoc, TemplateArgumentListInfo &TemplateArgs); TypeResult ActOnTemplateIdType(Scope *S, CXXScopeSpec &SS, SourceLocation TemplateKWLoc, TemplateTy Template, IdentifierInfo *TemplateII, SourceLocation TemplateIILoc, SourceLocation LAngleLoc, ASTTemplateArgsPtr TemplateArgs, SourceLocation RAngleLoc, bool IsCtorOrDtorName = false, bool IsClassName = false); /// Parsed an elaborated-type-specifier that refers to a template-id, /// such as \c class T::template apply<U>. TypeResult ActOnTagTemplateIdType(TagUseKind TUK, TypeSpecifierType TagSpec, SourceLocation TagLoc, CXXScopeSpec &SS, SourceLocation TemplateKWLoc, TemplateTy TemplateD, SourceLocation TemplateLoc, SourceLocation LAngleLoc, ASTTemplateArgsPtr TemplateArgsIn, SourceLocation RAngleLoc); DeclResult ActOnVarTemplateSpecialization( Scope *S, Declarator &D, TypeSourceInfo *DI, SourceLocation TemplateKWLoc, TemplateParameterList *TemplateParams, StorageClass SC, bool IsPartialSpecialization); /// Get the specialization of the given variable template corresponding to /// the specified argument list, or a null-but-valid result if the arguments /// are dependent. DeclResult CheckVarTemplateId(VarTemplateDecl *Template, SourceLocation TemplateLoc, SourceLocation TemplateNameLoc, const TemplateArgumentListInfo &TemplateArgs); /// Form a reference to the specialization of the given variable template /// corresponding to the specified argument list, or a null-but-valid result /// if the arguments are dependent. ExprResult CheckVarTemplateId(const CXXScopeSpec &SS, const DeclarationNameInfo &NameInfo, VarTemplateDecl *Template, SourceLocation TemplateLoc, const TemplateArgumentListInfo *TemplateArgs); ExprResult CheckConceptTemplateId(const CXXScopeSpec &SS, SourceLocation TemplateKWLoc, const DeclarationNameInfo &ConceptNameInfo, NamedDecl *FoundDecl, ConceptDecl *NamedConcept, const TemplateArgumentListInfo *TemplateArgs); void diagnoseMissingTemplateArguments(TemplateName Name, SourceLocation Loc); ExprResult BuildTemplateIdExpr(const CXXScopeSpec &SS, SourceLocation TemplateKWLoc, LookupResult &R, bool RequiresADL, const TemplateArgumentListInfo *TemplateArgs); ExprResult BuildQualifiedTemplateIdExpr(CXXScopeSpec &SS, SourceLocation TemplateKWLoc, const DeclarationNameInfo &NameInfo, const TemplateArgumentListInfo *TemplateArgs); TemplateNameKind ActOnTemplateName( Scope *S, CXXScopeSpec &SS, SourceLocation TemplateKWLoc, const UnqualifiedId &Name, ParsedType ObjectType, bool EnteringContext, TemplateTy &Template, bool AllowInjectedClassName = false); DeclResult ActOnClassTemplateSpecialization( Scope *S, unsigned TagSpec, TagUseKind TUK, SourceLocation KWLoc, SourceLocation ModulePrivateLoc, CXXScopeSpec &SS, TemplateIdAnnotation &TemplateId, const ParsedAttributesView &Attr, MultiTemplateParamsArg TemplateParameterLists, SkipBodyInfo *SkipBody = nullptr); bool CheckTemplatePartialSpecializationArgs(SourceLocation Loc, TemplateDecl *PrimaryTemplate, unsigned NumExplicitArgs, ArrayRef<TemplateArgument> Args); void CheckTemplatePartialSpecialization( ClassTemplatePartialSpecializationDecl *Partial); void CheckTemplatePartialSpecialization( VarTemplatePartialSpecializationDecl *Partial); Decl *ActOnTemplateDeclarator(Scope *S, MultiTemplateParamsArg TemplateParameterLists, Declarator &D); bool CheckSpecializationInstantiationRedecl(SourceLocation NewLoc, TemplateSpecializationKind NewTSK, NamedDecl *PrevDecl, TemplateSpecializationKind PrevTSK, SourceLocation PrevPtOfInstantiation, bool &SuppressNew); bool CheckDependentFunctionTemplateSpecialization(FunctionDecl *FD, const TemplateArgumentListInfo &ExplicitTemplateArgs, LookupResult &Previous); bool CheckFunctionTemplateSpecialization( FunctionDecl *FD, TemplateArgumentListInfo *ExplicitTemplateArgs, LookupResult &Previous, bool QualifiedFriend = false); bool CheckMemberSpecialization(NamedDecl *Member, LookupResult &Previous); void CompleteMemberSpecialization(NamedDecl *Member, LookupResult &Previous); DeclResult ActOnExplicitInstantiation( Scope *S, SourceLocation ExternLoc, SourceLocation TemplateLoc, unsigned TagSpec, SourceLocation KWLoc, const CXXScopeSpec &SS, TemplateTy Template, SourceLocation TemplateNameLoc, SourceLocation LAngleLoc, ASTTemplateArgsPtr TemplateArgs, SourceLocation RAngleLoc, const ParsedAttributesView &Attr); DeclResult ActOnExplicitInstantiation(Scope *S, SourceLocation ExternLoc, SourceLocation TemplateLoc, unsigned TagSpec, SourceLocation KWLoc, CXXScopeSpec &SS, IdentifierInfo *Name, SourceLocation NameLoc, const ParsedAttributesView &Attr); DeclResult ActOnExplicitInstantiation(Scope *S, SourceLocation ExternLoc, SourceLocation TemplateLoc, Declarator &D); TemplateArgumentLoc SubstDefaultTemplateArgumentIfAvailable(TemplateDecl *Template, SourceLocation TemplateLoc, SourceLocation RAngleLoc, Decl *Param, SmallVectorImpl<TemplateArgument> &Converted, bool &HasDefaultArg); /// Specifies the context in which a particular template /// argument is being checked. enum CheckTemplateArgumentKind { /// The template argument was specified in the code or was /// instantiated with some deduced template arguments. CTAK_Specified, /// The template argument was deduced via template argument /// deduction. CTAK_Deduced, /// The template argument was deduced from an array bound /// via template argument deduction. CTAK_DeducedFromArrayBound }; bool CheckTemplateArgument(NamedDecl *Param, TemplateArgumentLoc &Arg, NamedDecl *Template, SourceLocation TemplateLoc, SourceLocation RAngleLoc, unsigned ArgumentPackIndex, SmallVectorImpl<TemplateArgument> &Converted, CheckTemplateArgumentKind CTAK = CTAK_Specified); /// Check that the given template arguments can be be provided to /// the given template, converting the arguments along the way. /// /// \param Template The template to which the template arguments are being /// provided. /// /// \param TemplateLoc The location of the template name in the source. /// /// \param TemplateArgs The list of template arguments. If the template is /// a template template parameter, this function may extend the set of /// template arguments to also include substituted, defaulted template /// arguments. /// /// \param PartialTemplateArgs True if the list of template arguments is /// intentionally partial, e.g., because we're checking just the initial /// set of template arguments. /// /// \param Converted Will receive the converted, canonicalized template /// arguments. /// /// \param UpdateArgsWithConversions If \c true, update \p TemplateArgs to /// contain the converted forms of the template arguments as written. /// Otherwise, \p TemplateArgs will not be modified. /// /// \param ConstraintsNotSatisfied If provided, and an error occured, will /// receive true if the cause for the error is the associated constraints of /// the template not being satisfied by the template arguments. /// /// \returns true if an error occurred, false otherwise. bool CheckTemplateArgumentList(TemplateDecl *Template, SourceLocation TemplateLoc, TemplateArgumentListInfo &TemplateArgs, bool PartialTemplateArgs, SmallVectorImpl<TemplateArgument> &Converted, bool UpdateArgsWithConversions = true, bool *ConstraintsNotSatisfied = nullptr); bool CheckTemplateTypeArgument(TemplateTypeParmDecl *Param, TemplateArgumentLoc &Arg, SmallVectorImpl<TemplateArgument> &Converted); bool CheckTemplateArgument(TypeSourceInfo *Arg); ExprResult CheckTemplateArgument(NonTypeTemplateParmDecl *Param, QualType InstantiatedParamType, Expr *Arg, TemplateArgument &Converted, CheckTemplateArgumentKind CTAK = CTAK_Specified); bool CheckTemplateTemplateArgument(TemplateTemplateParmDecl *Param, TemplateParameterList *Params, TemplateArgumentLoc &Arg); ExprResult BuildExpressionFromDeclTemplateArgument(const TemplateArgument &Arg, QualType ParamType, SourceLocation Loc); ExprResult BuildExpressionFromIntegralTemplateArgument(const TemplateArgument &Arg, SourceLocation Loc); /// Enumeration describing how template parameter lists are compared /// for equality. enum TemplateParameterListEqualKind { /// We are matching the template parameter lists of two templates /// that might be redeclarations. /// /// \code /// template<typename T> struct X; /// template<typename T> struct X; /// \endcode TPL_TemplateMatch, /// We are matching the template parameter lists of two template /// template parameters as part of matching the template parameter lists /// of two templates that might be redeclarations. /// /// \code /// template<template<int I> class TT> struct X; /// template<template<int Value> class Other> struct X; /// \endcode TPL_TemplateTemplateParmMatch, /// We are matching the template parameter lists of a template /// template argument against the template parameter lists of a template /// template parameter. /// /// \code /// template<template<int Value> class Metafun> struct X; /// template<int Value> struct integer_c; /// X<integer_c> xic; /// \endcode TPL_TemplateTemplateArgumentMatch }; bool TemplateParameterListsAreEqual(TemplateParameterList *New, TemplateParameterList *Old, bool Complain, TemplateParameterListEqualKind Kind, SourceLocation TemplateArgLoc = SourceLocation()); bool CheckTemplateDeclScope(Scope *S, TemplateParameterList *TemplateParams); /// Called when the parser has parsed a C++ typename /// specifier, e.g., "typename T::type". /// /// \param S The scope in which this typename type occurs. /// \param TypenameLoc the location of the 'typename' keyword /// \param SS the nested-name-specifier following the typename (e.g., 'T::'). /// \param II the identifier we're retrieving (e.g., 'type' in the example). /// \param IdLoc the location of the identifier. TypeResult ActOnTypenameType(Scope *S, SourceLocation TypenameLoc, const CXXScopeSpec &SS, const IdentifierInfo &II, SourceLocation IdLoc); /// Called when the parser has parsed a C++ typename /// specifier that ends in a template-id, e.g., /// "typename MetaFun::template apply<T1, T2>". /// /// \param S The scope in which this typename type occurs. /// \param TypenameLoc the location of the 'typename' keyword /// \param SS the nested-name-specifier following the typename (e.g., 'T::'). /// \param TemplateLoc the location of the 'template' keyword, if any. /// \param TemplateName The template name. /// \param TemplateII The identifier used to name the template. /// \param TemplateIILoc The location of the template name. /// \param LAngleLoc The location of the opening angle bracket ('<'). /// \param TemplateArgs The template arguments. /// \param RAngleLoc The location of the closing angle bracket ('>'). TypeResult ActOnTypenameType(Scope *S, SourceLocation TypenameLoc, const CXXScopeSpec &SS, SourceLocation TemplateLoc, TemplateTy TemplateName, IdentifierInfo *TemplateII, SourceLocation TemplateIILoc, SourceLocation LAngleLoc, ASTTemplateArgsPtr TemplateArgs, SourceLocation RAngleLoc); QualType CheckTypenameType(ElaboratedTypeKeyword Keyword, SourceLocation KeywordLoc, NestedNameSpecifierLoc QualifierLoc, const IdentifierInfo &II, SourceLocation IILoc, TypeSourceInfo **TSI, bool DeducedTSTContext); QualType CheckTypenameType(ElaboratedTypeKeyword Keyword, SourceLocation KeywordLoc, NestedNameSpecifierLoc QualifierLoc, const IdentifierInfo &II, SourceLocation IILoc, bool DeducedTSTContext = true); TypeSourceInfo *RebuildTypeInCurrentInstantiation(TypeSourceInfo *T, SourceLocation Loc, DeclarationName Name); bool RebuildNestedNameSpecifierInCurrentInstantiation(CXXScopeSpec &SS); ExprResult RebuildExprInCurrentInstantiation(Expr *E); bool RebuildTemplateParamsInCurrentInstantiation( TemplateParameterList *Params); std::string getTemplateArgumentBindingsText(const TemplateParameterList *Params, const TemplateArgumentList &Args); std::string getTemplateArgumentBindingsText(const TemplateParameterList *Params, const TemplateArgument *Args, unsigned NumArgs); //===--------------------------------------------------------------------===// // C++ Concepts //===--------------------------------------------------------------------===// Decl *ActOnConceptDefinition( Scope *S, MultiTemplateParamsArg TemplateParameterLists, IdentifierInfo *Name, SourceLocation NameLoc, Expr *ConstraintExpr); RequiresExprBodyDecl * ActOnStartRequiresExpr(SourceLocation RequiresKWLoc, ArrayRef<ParmVarDecl *> LocalParameters, Scope *BodyScope); void ActOnFinishRequiresExpr(); concepts::Requirement *ActOnSimpleRequirement(Expr *E); concepts::Requirement *ActOnTypeRequirement( SourceLocation TypenameKWLoc, CXXScopeSpec &SS, SourceLocation NameLoc, IdentifierInfo *TypeName, TemplateIdAnnotation *TemplateId); concepts::Requirement *ActOnCompoundRequirement(Expr *E, SourceLocation NoexceptLoc); concepts::Requirement * ActOnCompoundRequirement( Expr *E, SourceLocation NoexceptLoc, CXXScopeSpec &SS, TemplateIdAnnotation *TypeConstraint, unsigned Depth); concepts::Requirement *ActOnNestedRequirement(Expr *Constraint); concepts::ExprRequirement * BuildExprRequirement( Expr *E, bool IsSatisfied, SourceLocation NoexceptLoc, concepts::ExprRequirement::ReturnTypeRequirement ReturnTypeRequirement); concepts::ExprRequirement * BuildExprRequirement( concepts::Requirement::SubstitutionDiagnostic *ExprSubstDiag, bool IsSatisfied, SourceLocation NoexceptLoc, concepts::ExprRequirement::ReturnTypeRequirement ReturnTypeRequirement); concepts::TypeRequirement *BuildTypeRequirement(TypeSourceInfo *Type); concepts::TypeRequirement * BuildTypeRequirement( concepts::Requirement::SubstitutionDiagnostic *SubstDiag); concepts::NestedRequirement *BuildNestedRequirement(Expr *E); concepts::NestedRequirement * BuildNestedRequirement( concepts::Requirement::SubstitutionDiagnostic *SubstDiag); ExprResult ActOnRequiresExpr(SourceLocation RequiresKWLoc, RequiresExprBodyDecl *Body, ArrayRef<ParmVarDecl *> LocalParameters, ArrayRef<concepts::Requirement *> Requirements, SourceLocation ClosingBraceLoc); //===--------------------------------------------------------------------===// // C++ Variadic Templates (C++0x [temp.variadic]) //===--------------------------------------------------------------------===// /// Determine whether an unexpanded parameter pack might be permitted in this /// location. Useful for error recovery. bool isUnexpandedParameterPackPermitted(); /// The context in which an unexpanded parameter pack is /// being diagnosed. /// /// Note that the values of this enumeration line up with the first /// argument to the \c err_unexpanded_parameter_pack diagnostic. enum UnexpandedParameterPackContext { /// An arbitrary expression. UPPC_Expression = 0, /// The base type of a class type. UPPC_BaseType, /// The type of an arbitrary declaration. UPPC_DeclarationType, /// The type of a data member. UPPC_DataMemberType, /// The size of a bit-field. UPPC_BitFieldWidth, /// The expression in a static assertion. UPPC_StaticAssertExpression, /// The fixed underlying type of an enumeration. UPPC_FixedUnderlyingType, /// The enumerator value. UPPC_EnumeratorValue, /// A using declaration. UPPC_UsingDeclaration, /// A friend declaration. UPPC_FriendDeclaration, /// A declaration qualifier. UPPC_DeclarationQualifier, /// An initializer. UPPC_Initializer, /// A default argument. UPPC_DefaultArgument, /// The type of a non-type template parameter. UPPC_NonTypeTemplateParameterType, /// The type of an exception. UPPC_ExceptionType, /// Partial specialization. UPPC_PartialSpecialization, /// Microsoft __if_exists. UPPC_IfExists, /// Microsoft __if_not_exists. UPPC_IfNotExists, /// Lambda expression. UPPC_Lambda, /// Block expression. UPPC_Block, /// A type constraint. UPPC_TypeConstraint, // A requirement in a requires-expression. UPPC_Requirement, // A requires-clause. UPPC_RequiresClause, }; /// Diagnose unexpanded parameter packs. /// /// \param Loc The location at which we should emit the diagnostic. /// /// \param UPPC The context in which we are diagnosing unexpanded /// parameter packs. /// /// \param Unexpanded the set of unexpanded parameter packs. /// /// \returns true if an error occurred, false otherwise. bool DiagnoseUnexpandedParameterPacks(SourceLocation Loc, UnexpandedParameterPackContext UPPC, ArrayRef<UnexpandedParameterPack> Unexpanded); /// If the given type contains an unexpanded parameter pack, /// diagnose the error. /// /// \param Loc The source location where a diagnostc should be emitted. /// /// \param T The type that is being checked for unexpanded parameter /// packs. /// /// \returns true if an error occurred, false otherwise. bool DiagnoseUnexpandedParameterPack(SourceLocation Loc, TypeSourceInfo *T, UnexpandedParameterPackContext UPPC); /// If the given expression contains an unexpanded parameter /// pack, diagnose the error. /// /// \param E The expression that is being checked for unexpanded /// parameter packs. /// /// \returns true if an error occurred, false otherwise. bool DiagnoseUnexpandedParameterPack(Expr *E, UnexpandedParameterPackContext UPPC = UPPC_Expression); /// If the given requirees-expression contains an unexpanded reference to one /// of its own parameter packs, diagnose the error. /// /// \param RE The requiress-expression that is being checked for unexpanded /// parameter packs. /// /// \returns true if an error occurred, false otherwise. bool DiagnoseUnexpandedParameterPackInRequiresExpr(RequiresExpr *RE); /// If the given nested-name-specifier contains an unexpanded /// parameter pack, diagnose the error. /// /// \param SS The nested-name-specifier that is being checked for /// unexpanded parameter packs. /// /// \returns true if an error occurred, false otherwise. bool DiagnoseUnexpandedParameterPack(const CXXScopeSpec &SS, UnexpandedParameterPackContext UPPC); /// If the given name contains an unexpanded parameter pack, /// diagnose the error. /// /// \param NameInfo The name (with source location information) that /// is being checked for unexpanded parameter packs. /// /// \returns true if an error occurred, false otherwise. bool DiagnoseUnexpandedParameterPack(const DeclarationNameInfo &NameInfo, UnexpandedParameterPackContext UPPC); /// If the given template name contains an unexpanded parameter pack, /// diagnose the error. /// /// \param Loc The location of the template name. /// /// \param Template The template name that is being checked for unexpanded /// parameter packs. /// /// \returns true if an error occurred, false otherwise. bool DiagnoseUnexpandedParameterPack(SourceLocation Loc, TemplateName Template, UnexpandedParameterPackContext UPPC); /// If the given template argument contains an unexpanded parameter /// pack, diagnose the error. /// /// \param Arg The template argument that is being checked for unexpanded /// parameter packs. /// /// \returns true if an error occurred, false otherwise. bool DiagnoseUnexpandedParameterPack(TemplateArgumentLoc Arg, UnexpandedParameterPackContext UPPC); /// Collect the set of unexpanded parameter packs within the given /// template argument. /// /// \param Arg The template argument that will be traversed to find /// unexpanded parameter packs. void collectUnexpandedParameterPacks(TemplateArgument Arg, SmallVectorImpl<UnexpandedParameterPack> &Unexpanded); /// Collect the set of unexpanded parameter packs within the given /// template argument. /// /// \param Arg The template argument that will be traversed to find /// unexpanded parameter packs. void collectUnexpandedParameterPacks(TemplateArgumentLoc Arg, SmallVectorImpl<UnexpandedParameterPack> &Unexpanded); /// Collect the set of unexpanded parameter packs within the given /// type. /// /// \param T The type that will be traversed to find /// unexpanded parameter packs. void collectUnexpandedParameterPacks(QualType T, SmallVectorImpl<UnexpandedParameterPack> &Unexpanded); /// Collect the set of unexpanded parameter packs within the given /// type. /// /// \param TL The type that will be traversed to find /// unexpanded parameter packs. void collectUnexpandedParameterPacks(TypeLoc TL, SmallVectorImpl<UnexpandedParameterPack> &Unexpanded); /// Collect the set of unexpanded parameter packs within the given /// nested-name-specifier. /// /// \param NNS The nested-name-specifier that will be traversed to find /// unexpanded parameter packs. void collectUnexpandedParameterPacks(NestedNameSpecifierLoc NNS, SmallVectorImpl<UnexpandedParameterPack> &Unexpanded); /// Collect the set of unexpanded parameter packs within the given /// name. /// /// \param NameInfo The name that will be traversed to find /// unexpanded parameter packs. void collectUnexpandedParameterPacks(const DeclarationNameInfo &NameInfo, SmallVectorImpl<UnexpandedParameterPack> &Unexpanded); /// Invoked when parsing a template argument followed by an /// ellipsis, which creates a pack expansion. /// /// \param Arg The template argument preceding the ellipsis, which /// may already be invalid. /// /// \param EllipsisLoc The location of the ellipsis. ParsedTemplateArgument ActOnPackExpansion(const ParsedTemplateArgument &Arg, SourceLocation EllipsisLoc); /// Invoked when parsing a type followed by an ellipsis, which /// creates a pack expansion. /// /// \param Type The type preceding the ellipsis, which will become /// the pattern of the pack expansion. /// /// \param EllipsisLoc The location of the ellipsis. TypeResult ActOnPackExpansion(ParsedType Type, SourceLocation EllipsisLoc); /// Construct a pack expansion type from the pattern of the pack /// expansion. TypeSourceInfo *CheckPackExpansion(TypeSourceInfo *Pattern, SourceLocation EllipsisLoc, Optional<unsigned> NumExpansions); /// Construct a pack expansion type from the pattern of the pack /// expansion. QualType CheckPackExpansion(QualType Pattern, SourceRange PatternRange, SourceLocation EllipsisLoc, Optional<unsigned> NumExpansions); /// Invoked when parsing an expression followed by an ellipsis, which /// creates a pack expansion. /// /// \param Pattern The expression preceding the ellipsis, which will become /// the pattern of the pack expansion. /// /// \param EllipsisLoc The location of the ellipsis. ExprResult ActOnPackExpansion(Expr *Pattern, SourceLocation EllipsisLoc); /// Invoked when parsing an expression followed by an ellipsis, which /// creates a pack expansion. /// /// \param Pattern The expression preceding the ellipsis, which will become /// the pattern of the pack expansion. /// /// \param EllipsisLoc The location of the ellipsis. ExprResult CheckPackExpansion(Expr *Pattern, SourceLocation EllipsisLoc, Optional<unsigned> NumExpansions); /// Determine whether we could expand a pack expansion with the /// given set of parameter packs into separate arguments by repeatedly /// transforming the pattern. /// /// \param EllipsisLoc The location of the ellipsis that identifies the /// pack expansion. /// /// \param PatternRange The source range that covers the entire pattern of /// the pack expansion. /// /// \param Unexpanded The set of unexpanded parameter packs within the /// pattern. /// /// \param ShouldExpand Will be set to \c true if the transformer should /// expand the corresponding pack expansions into separate arguments. When /// set, \c NumExpansions must also be set. /// /// \param RetainExpansion Whether the caller should add an unexpanded /// pack expansion after all of the expanded arguments. This is used /// when extending explicitly-specified template argument packs per /// C++0x [temp.arg.explicit]p9. /// /// \param NumExpansions The number of separate arguments that will be in /// the expanded form of the corresponding pack expansion. This is both an /// input and an output parameter, which can be set by the caller if the /// number of expansions is known a priori (e.g., due to a prior substitution) /// and will be set by the callee when the number of expansions is known. /// The callee must set this value when \c ShouldExpand is \c true; it may /// set this value in other cases. /// /// \returns true if an error occurred (e.g., because the parameter packs /// are to be instantiated with arguments of different lengths), false /// otherwise. If false, \c ShouldExpand (and possibly \c NumExpansions) /// must be set. bool CheckParameterPacksForExpansion(SourceLocation EllipsisLoc, SourceRange PatternRange, ArrayRef<UnexpandedParameterPack> Unexpanded, const MultiLevelTemplateArgumentList &TemplateArgs, bool &ShouldExpand, bool &RetainExpansion, Optional<unsigned> &NumExpansions); /// Determine the number of arguments in the given pack expansion /// type. /// /// This routine assumes that the number of arguments in the expansion is /// consistent across all of the unexpanded parameter packs in its pattern. /// /// Returns an empty Optional if the type can't be expanded. Optional<unsigned> getNumArgumentsInExpansion(QualType T, const MultiLevelTemplateArgumentList &TemplateArgs); /// Determine whether the given declarator contains any unexpanded /// parameter packs. /// /// This routine is used by the parser to disambiguate function declarators /// with an ellipsis prior to the ')', e.g., /// /// \code /// void f(T...); /// \endcode /// /// To determine whether we have an (unnamed) function parameter pack or /// a variadic function. /// /// \returns true if the declarator contains any unexpanded parameter packs, /// false otherwise. bool containsUnexpandedParameterPacks(Declarator &D); /// Returns the pattern of the pack expansion for a template argument. /// /// \param OrigLoc The template argument to expand. /// /// \param Ellipsis Will be set to the location of the ellipsis. /// /// \param NumExpansions Will be set to the number of expansions that will /// be generated from this pack expansion, if known a priori. TemplateArgumentLoc getTemplateArgumentPackExpansionPattern( TemplateArgumentLoc OrigLoc, SourceLocation &Ellipsis, Optional<unsigned> &NumExpansions) const; /// Given a template argument that contains an unexpanded parameter pack, but /// which has already been substituted, attempt to determine the number of /// elements that will be produced once this argument is fully-expanded. /// /// This is intended for use when transforming 'sizeof...(Arg)' in order to /// avoid actually expanding the pack where possible. Optional<unsigned> getFullyPackExpandedSize(TemplateArgument Arg); //===--------------------------------------------------------------------===// // C++ Template Argument Deduction (C++ [temp.deduct]) //===--------------------------------------------------------------------===// /// Adjust the type \p ArgFunctionType to match the calling convention, /// noreturn, and optionally the exception specification of \p FunctionType. /// Deduction often wants to ignore these properties when matching function /// types. QualType adjustCCAndNoReturn(QualType ArgFunctionType, QualType FunctionType, bool AdjustExceptionSpec = false); /// Describes the result of template argument deduction. /// /// The TemplateDeductionResult enumeration describes the result of /// template argument deduction, as returned from /// DeduceTemplateArguments(). The separate TemplateDeductionInfo /// structure provides additional information about the results of /// template argument deduction, e.g., the deduced template argument /// list (if successful) or the specific template parameters or /// deduced arguments that were involved in the failure. enum TemplateDeductionResult { /// Template argument deduction was successful. TDK_Success = 0, /// The declaration was invalid; do nothing. TDK_Invalid, /// Template argument deduction exceeded the maximum template /// instantiation depth (which has already been diagnosed). TDK_InstantiationDepth, /// Template argument deduction did not deduce a value /// for every template parameter. TDK_Incomplete, /// Template argument deduction did not deduce a value for every /// expansion of an expanded template parameter pack. TDK_IncompletePack, /// Template argument deduction produced inconsistent /// deduced values for the given template parameter. TDK_Inconsistent, /// Template argument deduction failed due to inconsistent /// cv-qualifiers on a template parameter type that would /// otherwise be deduced, e.g., we tried to deduce T in "const T" /// but were given a non-const "X". TDK_Underqualified, /// Substitution of the deduced template argument values /// resulted in an error. TDK_SubstitutionFailure, /// After substituting deduced template arguments, a dependent /// parameter type did not match the corresponding argument. TDK_DeducedMismatch, /// After substituting deduced template arguments, an element of /// a dependent parameter type did not match the corresponding element /// of the corresponding argument (when deducing from an initializer list). TDK_DeducedMismatchNested, /// A non-depnedent component of the parameter did not match the /// corresponding component of the argument. TDK_NonDeducedMismatch, /// When performing template argument deduction for a function /// template, there were too many call arguments. TDK_TooManyArguments, /// When performing template argument deduction for a function /// template, there were too few call arguments. TDK_TooFewArguments, /// The explicitly-specified template arguments were not valid /// template arguments for the given template. TDK_InvalidExplicitArguments, /// Checking non-dependent argument conversions failed. TDK_NonDependentConversionFailure, /// The deduced arguments did not satisfy the constraints associated /// with the template. TDK_ConstraintsNotSatisfied, /// Deduction failed; that's all we know. TDK_MiscellaneousDeductionFailure, /// CUDA Target attributes do not match. TDK_CUDATargetMismatch }; TemplateDeductionResult DeduceTemplateArguments(ClassTemplatePartialSpecializationDecl *Partial, const TemplateArgumentList &TemplateArgs, sema::TemplateDeductionInfo &Info); TemplateDeductionResult DeduceTemplateArguments(VarTemplatePartialSpecializationDecl *Partial, const TemplateArgumentList &TemplateArgs, sema::TemplateDeductionInfo &Info); TemplateDeductionResult SubstituteExplicitTemplateArguments( FunctionTemplateDecl *FunctionTemplate, TemplateArgumentListInfo &ExplicitTemplateArgs, SmallVectorImpl<DeducedTemplateArgument> &Deduced, SmallVectorImpl<QualType> &ParamTypes, QualType *FunctionType, sema::TemplateDeductionInfo &Info); /// brief A function argument from which we performed template argument // deduction for a call. struct OriginalCallArg { OriginalCallArg(QualType OriginalParamType, bool DecomposedParam, unsigned ArgIdx, QualType OriginalArgType) : OriginalParamType(OriginalParamType), DecomposedParam(DecomposedParam), ArgIdx(ArgIdx), OriginalArgType(OriginalArgType) {} QualType OriginalParamType; bool DecomposedParam; unsigned ArgIdx; QualType OriginalArgType; }; TemplateDeductionResult FinishTemplateArgumentDeduction( FunctionTemplateDecl *FunctionTemplate, SmallVectorImpl<DeducedTemplateArgument> &Deduced, unsigned NumExplicitlySpecified, FunctionDecl *&Specialization, sema::TemplateDeductionInfo &Info, SmallVectorImpl<OriginalCallArg> const *OriginalCallArgs = nullptr, bool PartialOverloading = false, llvm::function_ref<bool()> CheckNonDependent = []{ return false; }); TemplateDeductionResult DeduceTemplateArguments( FunctionTemplateDecl *FunctionTemplate, TemplateArgumentListInfo *ExplicitTemplateArgs, ArrayRef<Expr *> Args, FunctionDecl *&Specialization, sema::TemplateDeductionInfo &Info, bool PartialOverloading, llvm::function_ref<bool(ArrayRef<QualType>)> CheckNonDependent); TemplateDeductionResult DeduceTemplateArguments(FunctionTemplateDecl *FunctionTemplate, TemplateArgumentListInfo *ExplicitTemplateArgs, QualType ArgFunctionType, FunctionDecl *&Specialization, sema::TemplateDeductionInfo &Info, bool IsAddressOfFunction = false); TemplateDeductionResult DeduceTemplateArguments(FunctionTemplateDecl *FunctionTemplate, QualType ToType, CXXConversionDecl *&Specialization, sema::TemplateDeductionInfo &Info); TemplateDeductionResult DeduceTemplateArguments(FunctionTemplateDecl *FunctionTemplate, TemplateArgumentListInfo *ExplicitTemplateArgs, FunctionDecl *&Specialization, sema::TemplateDeductionInfo &Info, bool IsAddressOfFunction = false); /// Substitute Replacement for \p auto in \p TypeWithAuto QualType SubstAutoType(QualType TypeWithAuto, QualType Replacement); /// Substitute Replacement for auto in TypeWithAuto TypeSourceInfo* SubstAutoTypeSourceInfo(TypeSourceInfo *TypeWithAuto, QualType Replacement); /// Completely replace the \c auto in \p TypeWithAuto by /// \p Replacement. This does not retain any \c auto type sugar. QualType ReplaceAutoType(QualType TypeWithAuto, QualType Replacement); TypeSourceInfo *ReplaceAutoTypeSourceInfo(TypeSourceInfo *TypeWithAuto, QualType Replacement); /// Result type of DeduceAutoType. enum DeduceAutoResult { DAR_Succeeded, DAR_Failed, DAR_FailedAlreadyDiagnosed }; DeduceAutoResult DeduceAutoType(TypeSourceInfo *AutoType, Expr *&Initializer, QualType &Result, Optional<unsigned> DependentDeductionDepth = None, bool IgnoreConstraints = false); DeduceAutoResult DeduceAutoType(TypeLoc AutoTypeLoc, Expr *&Initializer, QualType &Result, Optional<unsigned> DependentDeductionDepth = None, bool IgnoreConstraints = false); void DiagnoseAutoDeductionFailure(VarDecl *VDecl, Expr *Init); bool DeduceReturnType(FunctionDecl *FD, SourceLocation Loc, bool Diagnose = true); /// Declare implicit deduction guides for a class template if we've /// not already done so. void DeclareImplicitDeductionGuides(TemplateDecl *Template, SourceLocation Loc); QualType DeduceTemplateSpecializationFromInitializer( TypeSourceInfo *TInfo, const InitializedEntity &Entity, const InitializationKind &Kind, MultiExprArg Init); QualType deduceVarTypeFromInitializer(VarDecl *VDecl, DeclarationName Name, QualType Type, TypeSourceInfo *TSI, SourceRange Range, bool DirectInit, Expr *Init); TypeLoc getReturnTypeLoc(FunctionDecl *FD) const; bool DeduceFunctionTypeFromReturnExpr(FunctionDecl *FD, SourceLocation ReturnLoc, Expr *&RetExpr, AutoType *AT); FunctionTemplateDecl *getMoreSpecializedTemplate( FunctionTemplateDecl *FT1, FunctionTemplateDecl *FT2, SourceLocation Loc, TemplatePartialOrderingContext TPOC, unsigned NumCallArguments1, unsigned NumCallArguments2, bool Reversed = false); UnresolvedSetIterator getMostSpecialized(UnresolvedSetIterator SBegin, UnresolvedSetIterator SEnd, TemplateSpecCandidateSet &FailedCandidates, SourceLocation Loc, const PartialDiagnostic &NoneDiag, const PartialDiagnostic &AmbigDiag, const PartialDiagnostic &CandidateDiag, bool Complain = true, QualType TargetType = QualType()); ClassTemplatePartialSpecializationDecl * getMoreSpecializedPartialSpecialization( ClassTemplatePartialSpecializationDecl *PS1, ClassTemplatePartialSpecializationDecl *PS2, SourceLocation Loc); bool isMoreSpecializedThanPrimary(ClassTemplatePartialSpecializationDecl *T, sema::TemplateDeductionInfo &Info); VarTemplatePartialSpecializationDecl *getMoreSpecializedPartialSpecialization( VarTemplatePartialSpecializationDecl *PS1, VarTemplatePartialSpecializationDecl *PS2, SourceLocation Loc); bool isMoreSpecializedThanPrimary(VarTemplatePartialSpecializationDecl *T, sema::TemplateDeductionInfo &Info); bool isTemplateTemplateParameterAtLeastAsSpecializedAs( TemplateParameterList *PParam, TemplateDecl *AArg, SourceLocation Loc); void MarkUsedTemplateParameters(const Expr *E, bool OnlyDeduced, unsigned Depth, llvm::SmallBitVector &Used); void MarkUsedTemplateParameters(const TemplateArgumentList &TemplateArgs, bool OnlyDeduced, unsigned Depth, llvm::SmallBitVector &Used); void MarkDeducedTemplateParameters( const FunctionTemplateDecl *FunctionTemplate, llvm::SmallBitVector &Deduced) { return MarkDeducedTemplateParameters(Context, FunctionTemplate, Deduced); } static void MarkDeducedTemplateParameters(ASTContext &Ctx, const FunctionTemplateDecl *FunctionTemplate, llvm::SmallBitVector &Deduced); //===--------------------------------------------------------------------===// // C++ Template Instantiation // MultiLevelTemplateArgumentList getTemplateInstantiationArgs(NamedDecl *D, const TemplateArgumentList *Innermost = nullptr, bool RelativeToPrimary = false, const FunctionDecl *Pattern = nullptr); /// A context in which code is being synthesized (where a source location /// alone is not sufficient to identify the context). This covers template /// instantiation and various forms of implicitly-generated functions. struct CodeSynthesisContext { /// The kind of template instantiation we are performing enum SynthesisKind { /// We are instantiating a template declaration. The entity is /// the declaration we're instantiating (e.g., a CXXRecordDecl). TemplateInstantiation, /// We are instantiating a default argument for a template /// parameter. The Entity is the template parameter whose argument is /// being instantiated, the Template is the template, and the /// TemplateArgs/NumTemplateArguments provide the template arguments as /// specified. DefaultTemplateArgumentInstantiation, /// We are instantiating a default argument for a function. /// The Entity is the ParmVarDecl, and TemplateArgs/NumTemplateArgs /// provides the template arguments as specified. DefaultFunctionArgumentInstantiation, /// We are substituting explicit template arguments provided for /// a function template. The entity is a FunctionTemplateDecl. ExplicitTemplateArgumentSubstitution, /// We are substituting template argument determined as part of /// template argument deduction for either a class template /// partial specialization or a function template. The /// Entity is either a {Class|Var}TemplatePartialSpecializationDecl or /// a TemplateDecl. DeducedTemplateArgumentSubstitution, /// We are substituting prior template arguments into a new /// template parameter. The template parameter itself is either a /// NonTypeTemplateParmDecl or a TemplateTemplateParmDecl. PriorTemplateArgumentSubstitution, /// We are checking the validity of a default template argument that /// has been used when naming a template-id. DefaultTemplateArgumentChecking, /// We are computing the exception specification for a defaulted special /// member function. ExceptionSpecEvaluation, /// We are instantiating the exception specification for a function /// template which was deferred until it was needed. ExceptionSpecInstantiation, /// We are instantiating a requirement of a requires expression. RequirementInstantiation, /// We are checking the satisfaction of a nested requirement of a requires /// expression. NestedRequirementConstraintsCheck, /// We are declaring an implicit special member function. DeclaringSpecialMember, /// We are declaring an implicit 'operator==' for a defaulted /// 'operator<=>'. DeclaringImplicitEqualityComparison, /// We are defining a synthesized function (such as a defaulted special /// member). DefiningSynthesizedFunction, // We are checking the constraints associated with a constrained entity or // the constraint expression of a concept. This includes the checks that // atomic constraints have the type 'bool' and that they can be constant // evaluated. ConstraintsCheck, // We are substituting template arguments into a constraint expression. ConstraintSubstitution, // We are normalizing a constraint expression. ConstraintNormalization, // We are substituting into the parameter mapping of an atomic constraint // during normalization. ParameterMappingSubstitution, /// We are rewriting a comparison operator in terms of an operator<=>. RewritingOperatorAsSpaceship, /// We are initializing a structured binding. InitializingStructuredBinding, /// We are marking a class as __dllexport. MarkingClassDllexported, /// Added for Template instantiation observation. /// Memoization means we are _not_ instantiating a template because /// it is already instantiated (but we entered a context where we /// would have had to if it was not already instantiated). Memoization } Kind; /// Was the enclosing context a non-instantiation SFINAE context? bool SavedInNonInstantiationSFINAEContext; /// The point of instantiation or synthesis within the source code. SourceLocation PointOfInstantiation; /// The entity that is being synthesized. Decl *Entity; /// The template (or partial specialization) in which we are /// performing the instantiation, for substitutions of prior template /// arguments. NamedDecl *Template; /// The list of template arguments we are substituting, if they /// are not part of the entity. const TemplateArgument *TemplateArgs; // FIXME: Wrap this union around more members, or perhaps store the // kind-specific members in the RAII object owning the context. union { /// The number of template arguments in TemplateArgs. unsigned NumTemplateArgs; /// The special member being declared or defined. CXXSpecialMember SpecialMember; }; ArrayRef<TemplateArgument> template_arguments() const { assert(Kind != DeclaringSpecialMember); return {TemplateArgs, NumTemplateArgs}; } /// The template deduction info object associated with the /// substitution or checking of explicit or deduced template arguments. sema::TemplateDeductionInfo *DeductionInfo; /// The source range that covers the construct that cause /// the instantiation, e.g., the template-id that causes a class /// template instantiation. SourceRange InstantiationRange; CodeSynthesisContext() : Kind(TemplateInstantiation), SavedInNonInstantiationSFINAEContext(false), Entity(nullptr), Template(nullptr), TemplateArgs(nullptr), NumTemplateArgs(0), DeductionInfo(nullptr) {} /// Determines whether this template is an actual instantiation /// that should be counted toward the maximum instantiation depth. bool isInstantiationRecord() const; }; /// List of active code synthesis contexts. /// /// This vector is treated as a stack. As synthesis of one entity requires /// synthesis of another, additional contexts are pushed onto the stack. SmallVector<CodeSynthesisContext, 16> CodeSynthesisContexts; /// Specializations whose definitions are currently being instantiated. llvm::DenseSet<std::pair<Decl *, unsigned>> InstantiatingSpecializations; /// Non-dependent types used in templates that have already been instantiated /// by some template instantiation. llvm::DenseSet<QualType> InstantiatedNonDependentTypes; /// Extra modules inspected when performing a lookup during a template /// instantiation. Computed lazily. SmallVector<Module*, 16> CodeSynthesisContextLookupModules; /// Cache of additional modules that should be used for name lookup /// within the current template instantiation. Computed lazily; use /// getLookupModules() to get a complete set. llvm::DenseSet<Module*> LookupModulesCache; /// Get the set of additional modules that should be checked during /// name lookup. A module and its imports become visible when instanting a /// template defined within it. llvm::DenseSet<Module*> &getLookupModules(); /// Map from the most recent declaration of a namespace to the most /// recent visible declaration of that namespace. llvm::DenseMap<NamedDecl*, NamedDecl*> VisibleNamespaceCache; /// Whether we are in a SFINAE context that is not associated with /// template instantiation. /// /// This is used when setting up a SFINAE trap (\c see SFINAETrap) outside /// of a template instantiation or template argument deduction. bool InNonInstantiationSFINAEContext; /// The number of \p CodeSynthesisContexts that are not template /// instantiations and, therefore, should not be counted as part of the /// instantiation depth. /// /// When the instantiation depth reaches the user-configurable limit /// \p LangOptions::InstantiationDepth we will abort instantiation. // FIXME: Should we have a similar limit for other forms of synthesis? unsigned NonInstantiationEntries; /// The depth of the context stack at the point when the most recent /// error or warning was produced. /// /// This value is used to suppress printing of redundant context stacks /// when there are multiple errors or warnings in the same instantiation. // FIXME: Does this belong in Sema? It's tough to implement it anywhere else. unsigned LastEmittedCodeSynthesisContextDepth = 0; /// The template instantiation callbacks to trace or track /// instantiations (objects can be chained). /// /// This callbacks is used to print, trace or track template /// instantiations as they are being constructed. std::vector<std::unique_ptr<TemplateInstantiationCallback>> TemplateInstCallbacks; /// The current index into pack expansion arguments that will be /// used for substitution of parameter packs. /// /// The pack expansion index will be -1 to indicate that parameter packs /// should be instantiated as themselves. Otherwise, the index specifies /// which argument within the parameter pack will be used for substitution. int ArgumentPackSubstitutionIndex; /// RAII object used to change the argument pack substitution index /// within a \c Sema object. /// /// See \c ArgumentPackSubstitutionIndex for more information. class ArgumentPackSubstitutionIndexRAII { Sema &Self; int OldSubstitutionIndex; public: ArgumentPackSubstitutionIndexRAII(Sema &Self, int NewSubstitutionIndex) : Self(Self), OldSubstitutionIndex(Self.ArgumentPackSubstitutionIndex) { Self.ArgumentPackSubstitutionIndex = NewSubstitutionIndex; } ~ArgumentPackSubstitutionIndexRAII() { Self.ArgumentPackSubstitutionIndex = OldSubstitutionIndex; } }; friend class ArgumentPackSubstitutionRAII; /// For each declaration that involved template argument deduction, the /// set of diagnostics that were suppressed during that template argument /// deduction. /// /// FIXME: Serialize this structure to the AST file. typedef llvm::DenseMap<Decl *, SmallVector<PartialDiagnosticAt, 1> > SuppressedDiagnosticsMap; SuppressedDiagnosticsMap SuppressedDiagnostics; /// A stack object to be created when performing template /// instantiation. /// /// Construction of an object of type \c InstantiatingTemplate /// pushes the current instantiation onto the stack of active /// instantiations. If the size of this stack exceeds the maximum /// number of recursive template instantiations, construction /// produces an error and evaluates true. /// /// Destruction of this object will pop the named instantiation off /// the stack. struct InstantiatingTemplate { /// Note that we are instantiating a class template, /// function template, variable template, alias template, /// or a member thereof. InstantiatingTemplate(Sema &SemaRef, SourceLocation PointOfInstantiation, Decl *Entity, SourceRange InstantiationRange = SourceRange()); struct ExceptionSpecification {}; /// Note that we are instantiating an exception specification /// of a function template. InstantiatingTemplate(Sema &SemaRef, SourceLocation PointOfInstantiation, FunctionDecl *Entity, ExceptionSpecification, SourceRange InstantiationRange = SourceRange()); /// Note that we are instantiating a default argument in a /// template-id. InstantiatingTemplate(Sema &SemaRef, SourceLocation PointOfInstantiation, TemplateParameter Param, TemplateDecl *Template, ArrayRef<TemplateArgument> TemplateArgs, SourceRange InstantiationRange = SourceRange()); /// Note that we are substituting either explicitly-specified or /// deduced template arguments during function template argument deduction. InstantiatingTemplate(Sema &SemaRef, SourceLocation PointOfInstantiation, FunctionTemplateDecl *FunctionTemplate, ArrayRef<TemplateArgument> TemplateArgs, CodeSynthesisContext::SynthesisKind Kind, sema::TemplateDeductionInfo &DeductionInfo, SourceRange InstantiationRange = SourceRange()); /// Note that we are instantiating as part of template /// argument deduction for a class template declaration. InstantiatingTemplate(Sema &SemaRef, SourceLocation PointOfInstantiation, TemplateDecl *Template, ArrayRef<TemplateArgument> TemplateArgs, sema::TemplateDeductionInfo &DeductionInfo, SourceRange InstantiationRange = SourceRange()); /// Note that we are instantiating as part of template /// argument deduction for a class template partial /// specialization. InstantiatingTemplate(Sema &SemaRef, SourceLocation PointOfInstantiation, ClassTemplatePartialSpecializationDecl *PartialSpec, ArrayRef<TemplateArgument> TemplateArgs, sema::TemplateDeductionInfo &DeductionInfo, SourceRange InstantiationRange = SourceRange()); /// Note that we are instantiating as part of template /// argument deduction for a variable template partial /// specialization. InstantiatingTemplate(Sema &SemaRef, SourceLocation PointOfInstantiation, VarTemplatePartialSpecializationDecl *PartialSpec, ArrayRef<TemplateArgument> TemplateArgs, sema::TemplateDeductionInfo &DeductionInfo, SourceRange InstantiationRange = SourceRange()); /// Note that we are instantiating a default argument for a function /// parameter. InstantiatingTemplate(Sema &SemaRef, SourceLocation PointOfInstantiation, ParmVarDecl *Param, ArrayRef<TemplateArgument> TemplateArgs, SourceRange InstantiationRange = SourceRange()); /// Note that we are substituting prior template arguments into a /// non-type parameter. InstantiatingTemplate(Sema &SemaRef, SourceLocation PointOfInstantiation, NamedDecl *Template, NonTypeTemplateParmDecl *Param, ArrayRef<TemplateArgument> TemplateArgs, SourceRange InstantiationRange); /// Note that we are substituting prior template arguments into a /// template template parameter. InstantiatingTemplate(Sema &SemaRef, SourceLocation PointOfInstantiation, NamedDecl *Template, TemplateTemplateParmDecl *Param, ArrayRef<TemplateArgument> TemplateArgs, SourceRange InstantiationRange); /// Note that we are checking the default template argument /// against the template parameter for a given template-id. InstantiatingTemplate(Sema &SemaRef, SourceLocation PointOfInstantiation, TemplateDecl *Template, NamedDecl *Param, ArrayRef<TemplateArgument> TemplateArgs, SourceRange InstantiationRange); struct ConstraintsCheck {}; /// \brief Note that we are checking the constraints associated with some /// constrained entity (a concept declaration or a template with associated /// constraints). InstantiatingTemplate(Sema &SemaRef, SourceLocation PointOfInstantiation, ConstraintsCheck, NamedDecl *Template, ArrayRef<TemplateArgument> TemplateArgs, SourceRange InstantiationRange); struct ConstraintSubstitution {}; /// \brief Note that we are checking a constraint expression associated /// with a template declaration or as part of the satisfaction check of a /// concept. InstantiatingTemplate(Sema &SemaRef, SourceLocation PointOfInstantiation, ConstraintSubstitution, NamedDecl *Template, sema::TemplateDeductionInfo &DeductionInfo, SourceRange InstantiationRange); struct ConstraintNormalization {}; /// \brief Note that we are normalizing a constraint expression. InstantiatingTemplate(Sema &SemaRef, SourceLocation PointOfInstantiation, ConstraintNormalization, NamedDecl *Template, SourceRange InstantiationRange); struct ParameterMappingSubstitution {}; /// \brief Note that we are subtituting into the parameter mapping of an /// atomic constraint during constraint normalization. InstantiatingTemplate(Sema &SemaRef, SourceLocation PointOfInstantiation, ParameterMappingSubstitution, NamedDecl *Template, SourceRange InstantiationRange); /// \brief Note that we are substituting template arguments into a part of /// a requirement of a requires expression. InstantiatingTemplate(Sema &SemaRef, SourceLocation PointOfInstantiation, concepts::Requirement *Req, sema::TemplateDeductionInfo &DeductionInfo, SourceRange InstantiationRange = SourceRange()); /// \brief Note that we are checking the satisfaction of the constraint /// expression inside of a nested requirement. InstantiatingTemplate(Sema &SemaRef, SourceLocation PointOfInstantiation, concepts::NestedRequirement *Req, ConstraintsCheck, SourceRange InstantiationRange = SourceRange()); /// Note that we have finished instantiating this template. void Clear(); ~InstantiatingTemplate() { Clear(); } /// Determines whether we have exceeded the maximum /// recursive template instantiations. bool isInvalid() const { return Invalid; } /// Determine whether we are already instantiating this /// specialization in some surrounding active instantiation. bool isAlreadyInstantiating() const { return AlreadyInstantiating; } private: Sema &SemaRef; bool Invalid; bool AlreadyInstantiating; bool CheckInstantiationDepth(SourceLocation PointOfInstantiation, SourceRange InstantiationRange); InstantiatingTemplate( Sema &SemaRef, CodeSynthesisContext::SynthesisKind Kind, SourceLocation PointOfInstantiation, SourceRange InstantiationRange, Decl *Entity, NamedDecl *Template = nullptr, ArrayRef<TemplateArgument> TemplateArgs = None, sema::TemplateDeductionInfo *DeductionInfo = nullptr); InstantiatingTemplate(const InstantiatingTemplate&) = delete; InstantiatingTemplate& operator=(const InstantiatingTemplate&) = delete; }; void pushCodeSynthesisContext(CodeSynthesisContext Ctx); void popCodeSynthesisContext(); /// Determine whether we are currently performing template instantiation. bool inTemplateInstantiation() const { return CodeSynthesisContexts.size() > NonInstantiationEntries; } void PrintContextStack() { if (!CodeSynthesisContexts.empty() && CodeSynthesisContexts.size() != LastEmittedCodeSynthesisContextDepth) { PrintInstantiationStack(); LastEmittedCodeSynthesisContextDepth = CodeSynthesisContexts.size(); } if (PragmaAttributeCurrentTargetDecl) PrintPragmaAttributeInstantiationPoint(); } void PrintInstantiationStack(); void PrintPragmaAttributeInstantiationPoint(); /// Determines whether we are currently in a context where /// template argument substitution failures are not considered /// errors. /// /// \returns An empty \c Optional if we're not in a SFINAE context. /// Otherwise, contains a pointer that, if non-NULL, contains the nearest /// template-deduction context object, which can be used to capture /// diagnostics that will be suppressed. Optional<sema::TemplateDeductionInfo *> isSFINAEContext() const; /// Determines whether we are currently in a context that /// is not evaluated as per C++ [expr] p5. bool isUnevaluatedContext() const { assert(!ExprEvalContexts.empty() && "Must be in an expression evaluation context"); return ExprEvalContexts.back().isUnevaluated(); } bool isImmediateFunctionContext() const { assert(!ExprEvalContexts.empty() && "Must be in an expression evaluation context"); for (const ExpressionEvaluationContextRecord &context : llvm::reverse(ExprEvalContexts)) { if (context.isImmediateFunctionContext()) return true; if (context.isUnevaluated()) return false; } return false; } /// RAII class used to determine whether SFINAE has /// trapped any errors that occur during template argument /// deduction. class SFINAETrap { Sema &SemaRef; unsigned PrevSFINAEErrors; bool PrevInNonInstantiationSFINAEContext; bool PrevAccessCheckingSFINAE; bool PrevLastDiagnosticIgnored; public: explicit SFINAETrap(Sema &SemaRef, bool AccessCheckingSFINAE = false) : SemaRef(SemaRef), PrevSFINAEErrors(SemaRef.NumSFINAEErrors), PrevInNonInstantiationSFINAEContext( SemaRef.InNonInstantiationSFINAEContext), PrevAccessCheckingSFINAE(SemaRef.AccessCheckingSFINAE), PrevLastDiagnosticIgnored( SemaRef.getDiagnostics().isLastDiagnosticIgnored()) { if (!SemaRef.isSFINAEContext()) SemaRef.InNonInstantiationSFINAEContext = true; SemaRef.AccessCheckingSFINAE = AccessCheckingSFINAE; } ~SFINAETrap() { SemaRef.NumSFINAEErrors = PrevSFINAEErrors; SemaRef.InNonInstantiationSFINAEContext = PrevInNonInstantiationSFINAEContext; SemaRef.AccessCheckingSFINAE = PrevAccessCheckingSFINAE; SemaRef.getDiagnostics().setLastDiagnosticIgnored( PrevLastDiagnosticIgnored); } /// Determine whether any SFINAE errors have been trapped. bool hasErrorOccurred() const { return SemaRef.NumSFINAEErrors > PrevSFINAEErrors; } }; /// RAII class used to indicate that we are performing provisional /// semantic analysis to determine the validity of a construct, so /// typo-correction and diagnostics in the immediate context (not within /// implicitly-instantiated templates) should be suppressed. class TentativeAnalysisScope { Sema &SemaRef; // FIXME: Using a SFINAETrap for this is a hack. SFINAETrap Trap; bool PrevDisableTypoCorrection; public: explicit TentativeAnalysisScope(Sema &SemaRef) : SemaRef(SemaRef), Trap(SemaRef, true), PrevDisableTypoCorrection(SemaRef.DisableTypoCorrection) { SemaRef.DisableTypoCorrection = true; } ~TentativeAnalysisScope() { SemaRef.DisableTypoCorrection = PrevDisableTypoCorrection; } }; /// The current instantiation scope used to store local /// variables. LocalInstantiationScope *CurrentInstantiationScope; /// Tracks whether we are in a context where typo correction is /// disabled. bool DisableTypoCorrection; /// The number of typos corrected by CorrectTypo. unsigned TyposCorrected; typedef llvm::SmallSet<SourceLocation, 2> SrcLocSet; typedef llvm::DenseMap<IdentifierInfo *, SrcLocSet> IdentifierSourceLocations; /// A cache containing identifiers for which typo correction failed and /// their locations, so that repeated attempts to correct an identifier in a /// given location are ignored if typo correction already failed for it. IdentifierSourceLocations TypoCorrectionFailures; /// Worker object for performing CFG-based warnings. sema::AnalysisBasedWarnings AnalysisWarnings; threadSafety::BeforeSet *ThreadSafetyDeclCache; /// An entity for which implicit template instantiation is required. /// /// The source location associated with the declaration is the first place in /// the source code where the declaration was "used". It is not necessarily /// the point of instantiation (which will be either before or after the /// namespace-scope declaration that triggered this implicit instantiation), /// However, it is the location that diagnostics should generally refer to, /// because users will need to know what code triggered the instantiation. typedef std::pair<ValueDecl *, SourceLocation> PendingImplicitInstantiation; /// The queue of implicit template instantiations that are required /// but have not yet been performed. std::deque<PendingImplicitInstantiation> PendingInstantiations; /// Queue of implicit template instantiations that cannot be performed /// eagerly. SmallVector<PendingImplicitInstantiation, 1> LateParsedInstantiations; class GlobalEagerInstantiationScope { public: GlobalEagerInstantiationScope(Sema &S, bool Enabled) : S(S), Enabled(Enabled) { if (!Enabled) return; SavedPendingInstantiations.swap(S.PendingInstantiations); SavedVTableUses.swap(S.VTableUses); } void perform() { if (Enabled) { S.DefineUsedVTables(); S.PerformPendingInstantiations(); } } ~GlobalEagerInstantiationScope() { if (!Enabled) return; // Restore the set of pending vtables. assert(S.VTableUses.empty() && "VTableUses should be empty before it is discarded."); S.VTableUses.swap(SavedVTableUses); // Restore the set of pending implicit instantiations. if (S.TUKind != TU_Prefix || !S.LangOpts.PCHInstantiateTemplates) { assert(S.PendingInstantiations.empty() && "PendingInstantiations should be empty before it is discarded."); S.PendingInstantiations.swap(SavedPendingInstantiations); } else { // Template instantiations in the PCH may be delayed until the TU. S.PendingInstantiations.swap(SavedPendingInstantiations); S.PendingInstantiations.insert(S.PendingInstantiations.end(), SavedPendingInstantiations.begin(), SavedPendingInstantiations.end()); } } private: Sema &S; SmallVector<VTableUse, 16> SavedVTableUses; std::deque<PendingImplicitInstantiation> SavedPendingInstantiations; bool Enabled; }; /// The queue of implicit template instantiations that are required /// and must be performed within the current local scope. /// /// This queue is only used for member functions of local classes in /// templates, which must be instantiated in the same scope as their /// enclosing function, so that they can reference function-local /// types, static variables, enumerators, etc. std::deque<PendingImplicitInstantiation> PendingLocalImplicitInstantiations; class LocalEagerInstantiationScope { public: LocalEagerInstantiationScope(Sema &S) : S(S) { SavedPendingLocalImplicitInstantiations.swap( S.PendingLocalImplicitInstantiations); } void perform() { S.PerformPendingInstantiations(/*LocalOnly=*/true); } ~LocalEagerInstantiationScope() { assert(S.PendingLocalImplicitInstantiations.empty() && "there shouldn't be any pending local implicit instantiations"); SavedPendingLocalImplicitInstantiations.swap( S.PendingLocalImplicitInstantiations); } private: Sema &S; std::deque<PendingImplicitInstantiation> SavedPendingLocalImplicitInstantiations; }; /// A helper class for building up ExtParameterInfos. class ExtParameterInfoBuilder { SmallVector<FunctionProtoType::ExtParameterInfo, 16> Infos; bool HasInteresting = false; public: /// Set the ExtParameterInfo for the parameter at the given index, /// void set(unsigned index, FunctionProtoType::ExtParameterInfo info) { assert(Infos.size() <= index); Infos.resize(index); Infos.push_back(info); if (!HasInteresting) HasInteresting = (info != FunctionProtoType::ExtParameterInfo()); } /// Return a pointer (suitable for setting in an ExtProtoInfo) to the /// ExtParameterInfo array we've built up. const FunctionProtoType::ExtParameterInfo * getPointerOrNull(unsigned numParams) { if (!HasInteresting) return nullptr; Infos.resize(numParams); return Infos.data(); } }; void PerformPendingInstantiations(bool LocalOnly = false); TypeSourceInfo *SubstType(TypeSourceInfo *T, const MultiLevelTemplateArgumentList &TemplateArgs, SourceLocation Loc, DeclarationName Entity, bool AllowDeducedTST = false); QualType SubstType(QualType T, const MultiLevelTemplateArgumentList &TemplateArgs, SourceLocation Loc, DeclarationName Entity); TypeSourceInfo *SubstType(TypeLoc TL, const MultiLevelTemplateArgumentList &TemplateArgs, SourceLocation Loc, DeclarationName Entity); TypeSourceInfo *SubstFunctionDeclType(TypeSourceInfo *T, const MultiLevelTemplateArgumentList &TemplateArgs, SourceLocation Loc, DeclarationName Entity, CXXRecordDecl *ThisContext, Qualifiers ThisTypeQuals); void SubstExceptionSpec(FunctionDecl *New, const FunctionProtoType *Proto, const MultiLevelTemplateArgumentList &Args); bool SubstExceptionSpec(SourceLocation Loc, FunctionProtoType::ExceptionSpecInfo &ESI, SmallVectorImpl<QualType> &ExceptionStorage, const MultiLevelTemplateArgumentList &Args); ParmVarDecl *SubstParmVarDecl(ParmVarDecl *D, const MultiLevelTemplateArgumentList &TemplateArgs, int indexAdjustment, Optional<unsigned> NumExpansions, bool ExpectParameterPack); bool SubstParmTypes(SourceLocation Loc, ArrayRef<ParmVarDecl *> Params, const FunctionProtoType::ExtParameterInfo *ExtParamInfos, const MultiLevelTemplateArgumentList &TemplateArgs, SmallVectorImpl<QualType> &ParamTypes, SmallVectorImpl<ParmVarDecl *> *OutParams, ExtParameterInfoBuilder &ParamInfos); ExprResult SubstExpr(Expr *E, const MultiLevelTemplateArgumentList &TemplateArgs); /// Substitute the given template arguments into a list of /// expressions, expanding pack expansions if required. /// /// \param Exprs The list of expressions to substitute into. /// /// \param IsCall Whether this is some form of call, in which case /// default arguments will be dropped. /// /// \param TemplateArgs The set of template arguments to substitute. /// /// \param Outputs Will receive all of the substituted arguments. /// /// \returns true if an error occurred, false otherwise. bool SubstExprs(ArrayRef<Expr *> Exprs, bool IsCall, const MultiLevelTemplateArgumentList &TemplateArgs, SmallVectorImpl<Expr *> &Outputs); StmtResult SubstStmt(Stmt *S, const MultiLevelTemplateArgumentList &TemplateArgs); TemplateParameterList * SubstTemplateParams(TemplateParameterList *Params, DeclContext *Owner, const MultiLevelTemplateArgumentList &TemplateArgs); bool SubstTemplateArguments(ArrayRef<TemplateArgumentLoc> Args, const MultiLevelTemplateArgumentList &TemplateArgs, TemplateArgumentListInfo &Outputs); Decl *SubstDecl(Decl *D, DeclContext *Owner, const MultiLevelTemplateArgumentList &TemplateArgs); /// Substitute the name and return type of a defaulted 'operator<=>' to form /// an implicit 'operator=='. FunctionDecl *SubstSpaceshipAsEqualEqual(CXXRecordDecl *RD, FunctionDecl *Spaceship); ExprResult SubstInitializer(Expr *E, const MultiLevelTemplateArgumentList &TemplateArgs, bool CXXDirectInit); bool SubstBaseSpecifiers(CXXRecordDecl *Instantiation, CXXRecordDecl *Pattern, const MultiLevelTemplateArgumentList &TemplateArgs); bool InstantiateClass(SourceLocation PointOfInstantiation, CXXRecordDecl *Instantiation, CXXRecordDecl *Pattern, const MultiLevelTemplateArgumentList &TemplateArgs, TemplateSpecializationKind TSK, bool Complain = true); bool InstantiateEnum(SourceLocation PointOfInstantiation, EnumDecl *Instantiation, EnumDecl *Pattern, const MultiLevelTemplateArgumentList &TemplateArgs, TemplateSpecializationKind TSK); bool InstantiateInClassInitializer( SourceLocation PointOfInstantiation, FieldDecl *Instantiation, FieldDecl *Pattern, const MultiLevelTemplateArgumentList &TemplateArgs); struct LateInstantiatedAttribute { const Attr *TmplAttr; LocalInstantiationScope *Scope; Decl *NewDecl; LateInstantiatedAttribute(const Attr *A, LocalInstantiationScope *S, Decl *D) : TmplAttr(A), Scope(S), NewDecl(D) { } }; typedef SmallVector<LateInstantiatedAttribute, 16> LateInstantiatedAttrVec; void InstantiateAttrs(const MultiLevelTemplateArgumentList &TemplateArgs, const Decl *Pattern, Decl *Inst, LateInstantiatedAttrVec *LateAttrs = nullptr, LocalInstantiationScope *OuterMostScope = nullptr); void InstantiateAttrsForDecl(const MultiLevelTemplateArgumentList &TemplateArgs, const Decl *Pattern, Decl *Inst, LateInstantiatedAttrVec *LateAttrs = nullptr, LocalInstantiationScope *OuterMostScope = nullptr); void InstantiateDefaultCtorDefaultArgs(CXXConstructorDecl *Ctor); bool usesPartialOrExplicitSpecialization( SourceLocation Loc, ClassTemplateSpecializationDecl *ClassTemplateSpec); bool InstantiateClassTemplateSpecialization(SourceLocation PointOfInstantiation, ClassTemplateSpecializationDecl *ClassTemplateSpec, TemplateSpecializationKind TSK, bool Complain = true); void InstantiateClassMembers(SourceLocation PointOfInstantiation, CXXRecordDecl *Instantiation, const MultiLevelTemplateArgumentList &TemplateArgs, TemplateSpecializationKind TSK); void InstantiateClassTemplateSpecializationMembers( SourceLocation PointOfInstantiation, ClassTemplateSpecializationDecl *ClassTemplateSpec, TemplateSpecializationKind TSK); NestedNameSpecifierLoc SubstNestedNameSpecifierLoc(NestedNameSpecifierLoc NNS, const MultiLevelTemplateArgumentList &TemplateArgs); DeclarationNameInfo SubstDeclarationNameInfo(const DeclarationNameInfo &NameInfo, const MultiLevelTemplateArgumentList &TemplateArgs); TemplateName SubstTemplateName(NestedNameSpecifierLoc QualifierLoc, TemplateName Name, SourceLocation Loc, const MultiLevelTemplateArgumentList &TemplateArgs); bool SubstTypeConstraint(TemplateTypeParmDecl *Inst, const TypeConstraint *TC, const MultiLevelTemplateArgumentList &TemplateArgs); bool InstantiateDefaultArgument(SourceLocation CallLoc, FunctionDecl *FD, ParmVarDecl *Param); void InstantiateExceptionSpec(SourceLocation PointOfInstantiation, FunctionDecl *Function); bool CheckInstantiatedFunctionTemplateConstraints( SourceLocation PointOfInstantiation, FunctionDecl *Decl, ArrayRef<TemplateArgument> TemplateArgs, ConstraintSatisfaction &Satisfaction); FunctionDecl *InstantiateFunctionDeclaration(FunctionTemplateDecl *FTD, const TemplateArgumentList *Args, SourceLocation Loc); void InstantiateFunctionDefinition(SourceLocation PointOfInstantiation, FunctionDecl *Function, bool Recursive = false, bool DefinitionRequired = false, bool AtEndOfTU = false); VarTemplateSpecializationDecl *BuildVarTemplateInstantiation( VarTemplateDecl *VarTemplate, VarDecl *FromVar, const TemplateArgumentList &TemplateArgList, const TemplateArgumentListInfo &TemplateArgsInfo, SmallVectorImpl<TemplateArgument> &Converted, SourceLocation PointOfInstantiation, LateInstantiatedAttrVec *LateAttrs = nullptr, LocalInstantiationScope *StartingScope = nullptr); VarTemplateSpecializationDecl *CompleteVarTemplateSpecializationDecl( VarTemplateSpecializationDecl *VarSpec, VarDecl *PatternDecl, const MultiLevelTemplateArgumentList &TemplateArgs); void BuildVariableInstantiation(VarDecl *NewVar, VarDecl *OldVar, const MultiLevelTemplateArgumentList &TemplateArgs, LateInstantiatedAttrVec *LateAttrs, DeclContext *Owner, LocalInstantiationScope *StartingScope, bool InstantiatingVarTemplate = false, VarTemplateSpecializationDecl *PrevVTSD = nullptr); void InstantiateVariableInitializer( VarDecl *Var, VarDecl *OldVar, const MultiLevelTemplateArgumentList &TemplateArgs); void InstantiateVariableDefinition(SourceLocation PointOfInstantiation, VarDecl *Var, bool Recursive = false, bool DefinitionRequired = false, bool AtEndOfTU = false); void InstantiateMemInitializers(CXXConstructorDecl *New, const CXXConstructorDecl *Tmpl, const MultiLevelTemplateArgumentList &TemplateArgs); NamedDecl *FindInstantiatedDecl(SourceLocation Loc, NamedDecl *D, const MultiLevelTemplateArgumentList &TemplateArgs, bool FindingInstantiatedContext = false); DeclContext *FindInstantiatedContext(SourceLocation Loc, DeclContext *DC, const MultiLevelTemplateArgumentList &TemplateArgs); // Objective-C declarations. enum ObjCContainerKind { OCK_None = -1, OCK_Interface = 0, OCK_Protocol, OCK_Category, OCK_ClassExtension, OCK_Implementation, OCK_CategoryImplementation }; ObjCContainerKind getObjCContainerKind() const; DeclResult actOnObjCTypeParam(Scope *S, ObjCTypeParamVariance variance, SourceLocation varianceLoc, unsigned index, IdentifierInfo *paramName, SourceLocation paramLoc, SourceLocation colonLoc, ParsedType typeBound); ObjCTypeParamList *actOnObjCTypeParamList(Scope *S, SourceLocation lAngleLoc, ArrayRef<Decl *> typeParams, SourceLocation rAngleLoc); void popObjCTypeParamList(Scope *S, ObjCTypeParamList *typeParamList); Decl *ActOnStartClassInterface( Scope *S, SourceLocation AtInterfaceLoc, IdentifierInfo *ClassName, SourceLocation ClassLoc, ObjCTypeParamList *typeParamList, IdentifierInfo *SuperName, SourceLocation SuperLoc, ArrayRef<ParsedType> SuperTypeArgs, SourceRange SuperTypeArgsRange, Decl *const *ProtoRefs, unsigned NumProtoRefs, const SourceLocation *ProtoLocs, SourceLocation EndProtoLoc, const ParsedAttributesView &AttrList); void ActOnSuperClassOfClassInterface(Scope *S, SourceLocation AtInterfaceLoc, ObjCInterfaceDecl *IDecl, IdentifierInfo *ClassName, SourceLocation ClassLoc, IdentifierInfo *SuperName, SourceLocation SuperLoc, ArrayRef<ParsedType> SuperTypeArgs, SourceRange SuperTypeArgsRange); void ActOnTypedefedProtocols(SmallVectorImpl<Decl *> &ProtocolRefs, SmallVectorImpl<SourceLocation> &ProtocolLocs, IdentifierInfo *SuperName, SourceLocation SuperLoc); Decl *ActOnCompatibilityAlias( SourceLocation AtCompatibilityAliasLoc, IdentifierInfo *AliasName, SourceLocation AliasLocation, IdentifierInfo *ClassName, SourceLocation ClassLocation); bool CheckForwardProtocolDeclarationForCircularDependency( IdentifierInfo *PName, SourceLocation &PLoc, SourceLocation PrevLoc, const ObjCList<ObjCProtocolDecl> &PList); Decl *ActOnStartProtocolInterface( SourceLocation AtProtoInterfaceLoc, IdentifierInfo *ProtocolName, SourceLocation ProtocolLoc, Decl *const *ProtoRefNames, unsigned NumProtoRefs, const SourceLocation *ProtoLocs, SourceLocation EndProtoLoc, const ParsedAttributesView &AttrList); Decl *ActOnStartCategoryInterface( SourceLocation AtInterfaceLoc, IdentifierInfo *ClassName, SourceLocation ClassLoc, ObjCTypeParamList *typeParamList, IdentifierInfo *CategoryName, SourceLocation CategoryLoc, Decl *const *ProtoRefs, unsigned NumProtoRefs, const SourceLocation *ProtoLocs, SourceLocation EndProtoLoc, const ParsedAttributesView &AttrList); Decl *ActOnStartClassImplementation(SourceLocation AtClassImplLoc, IdentifierInfo *ClassName, SourceLocation ClassLoc, IdentifierInfo *SuperClassname, SourceLocation SuperClassLoc, const ParsedAttributesView &AttrList); Decl *ActOnStartCategoryImplementation(SourceLocation AtCatImplLoc, IdentifierInfo *ClassName, SourceLocation ClassLoc, IdentifierInfo *CatName, SourceLocation CatLoc, const ParsedAttributesView &AttrList); DeclGroupPtrTy ActOnFinishObjCImplementation(Decl *ObjCImpDecl, ArrayRef<Decl *> Decls); DeclGroupPtrTy ActOnForwardClassDeclaration(SourceLocation Loc, IdentifierInfo **IdentList, SourceLocation *IdentLocs, ArrayRef<ObjCTypeParamList *> TypeParamLists, unsigned NumElts); DeclGroupPtrTy ActOnForwardProtocolDeclaration(SourceLocation AtProtoclLoc, ArrayRef<IdentifierLocPair> IdentList, const ParsedAttributesView &attrList); void FindProtocolDeclaration(bool WarnOnDeclarations, bool ForObjCContainer, ArrayRef<IdentifierLocPair> ProtocolId, SmallVectorImpl<Decl *> &Protocols); void DiagnoseTypeArgsAndProtocols(IdentifierInfo *ProtocolId, SourceLocation ProtocolLoc, IdentifierInfo *TypeArgId, SourceLocation TypeArgLoc, bool SelectProtocolFirst = false); /// Given a list of identifiers (and their locations), resolve the /// names to either Objective-C protocol qualifiers or type /// arguments, as appropriate. void actOnObjCTypeArgsOrProtocolQualifiers( Scope *S, ParsedType baseType, SourceLocation lAngleLoc, ArrayRef<IdentifierInfo *> identifiers, ArrayRef<SourceLocation> identifierLocs, SourceLocation rAngleLoc, SourceLocation &typeArgsLAngleLoc, SmallVectorImpl<ParsedType> &typeArgs, SourceLocation &typeArgsRAngleLoc, SourceLocation &protocolLAngleLoc, SmallVectorImpl<Decl *> &protocols, SourceLocation &protocolRAngleLoc, bool warnOnIncompleteProtocols); /// Build a an Objective-C protocol-qualified 'id' type where no /// base type was specified. TypeResult actOnObjCProtocolQualifierType( SourceLocation lAngleLoc, ArrayRef<Decl *> protocols, ArrayRef<SourceLocation> protocolLocs, SourceLocation rAngleLoc); /// Build a specialized and/or protocol-qualified Objective-C type. TypeResult actOnObjCTypeArgsAndProtocolQualifiers( Scope *S, SourceLocation Loc, ParsedType BaseType, SourceLocation TypeArgsLAngleLoc, ArrayRef<ParsedType> TypeArgs, SourceLocation TypeArgsRAngleLoc, SourceLocation ProtocolLAngleLoc, ArrayRef<Decl *> Protocols, ArrayRef<SourceLocation> ProtocolLocs, SourceLocation ProtocolRAngleLoc); /// Build an Objective-C type parameter type. QualType BuildObjCTypeParamType(const ObjCTypeParamDecl *Decl, SourceLocation ProtocolLAngleLoc, ArrayRef<ObjCProtocolDecl *> Protocols, ArrayRef<SourceLocation> ProtocolLocs, SourceLocation ProtocolRAngleLoc, bool FailOnError = false); /// Build an Objective-C object pointer type. QualType BuildObjCObjectType(QualType BaseType, SourceLocation Loc, SourceLocation TypeArgsLAngleLoc, ArrayRef<TypeSourceInfo *> TypeArgs, SourceLocation TypeArgsRAngleLoc, SourceLocation ProtocolLAngleLoc, ArrayRef<ObjCProtocolDecl *> Protocols, ArrayRef<SourceLocation> ProtocolLocs, SourceLocation ProtocolRAngleLoc, bool FailOnError = false); /// Ensure attributes are consistent with type. /// \param [in, out] Attributes The attributes to check; they will /// be modified to be consistent with \p PropertyTy. void CheckObjCPropertyAttributes(Decl *PropertyPtrTy, SourceLocation Loc, unsigned &Attributes, bool propertyInPrimaryClass); /// Process the specified property declaration and create decls for the /// setters and getters as needed. /// \param property The property declaration being processed void ProcessPropertyDecl(ObjCPropertyDecl *property); void DiagnosePropertyMismatch(ObjCPropertyDecl *Property, ObjCPropertyDecl *SuperProperty, const IdentifierInfo *Name, bool OverridingProtocolProperty); void DiagnoseClassExtensionDupMethods(ObjCCategoryDecl *CAT, ObjCInterfaceDecl *ID); Decl *ActOnAtEnd(Scope *S, SourceRange AtEnd, ArrayRef<Decl *> allMethods = None, ArrayRef<DeclGroupPtrTy> allTUVars = None); Decl *ActOnProperty(Scope *S, SourceLocation AtLoc, SourceLocation LParenLoc, FieldDeclarator &FD, ObjCDeclSpec &ODS, Selector GetterSel, Selector SetterSel, tok::ObjCKeywordKind MethodImplKind, DeclContext *lexicalDC = nullptr); Decl *ActOnPropertyImplDecl(Scope *S, SourceLocation AtLoc, SourceLocation PropertyLoc, bool ImplKind, IdentifierInfo *PropertyId, IdentifierInfo *PropertyIvar, SourceLocation PropertyIvarLoc, ObjCPropertyQueryKind QueryKind); enum ObjCSpecialMethodKind { OSMK_None, OSMK_Alloc, OSMK_New, OSMK_Copy, OSMK_RetainingInit, OSMK_NonRetainingInit }; struct ObjCArgInfo { IdentifierInfo *Name; SourceLocation NameLoc; // The Type is null if no type was specified, and the DeclSpec is invalid // in this case. ParsedType Type; ObjCDeclSpec DeclSpec; /// ArgAttrs - Attribute list for this argument. ParsedAttributesView ArgAttrs; }; Decl *ActOnMethodDeclaration( Scope *S, SourceLocation BeginLoc, // location of the + or -. SourceLocation EndLoc, // location of the ; or {. tok::TokenKind MethodType, ObjCDeclSpec &ReturnQT, ParsedType ReturnType, ArrayRef<SourceLocation> SelectorLocs, Selector Sel, // optional arguments. The number of types/arguments is obtained // from the Sel.getNumArgs(). ObjCArgInfo *ArgInfo, DeclaratorChunk::ParamInfo *CParamInfo, unsigned CNumArgs, // c-style args const ParsedAttributesView &AttrList, tok::ObjCKeywordKind MethodImplKind, bool isVariadic, bool MethodDefinition); ObjCMethodDecl *LookupMethodInQualifiedType(Selector Sel, const ObjCObjectPointerType *OPT, bool IsInstance); ObjCMethodDecl *LookupMethodInObjectType(Selector Sel, QualType Ty, bool IsInstance); bool CheckARCMethodDecl(ObjCMethodDecl *method); bool inferObjCARCLifetime(ValueDecl *decl); void deduceOpenCLAddressSpace(ValueDecl *decl); ExprResult HandleExprPropertyRefExpr(const ObjCObjectPointerType *OPT, Expr *BaseExpr, SourceLocation OpLoc, DeclarationName MemberName, SourceLocation MemberLoc, SourceLocation SuperLoc, QualType SuperType, bool Super); ExprResult ActOnClassPropertyRefExpr(IdentifierInfo &receiverName, IdentifierInfo &propertyName, SourceLocation receiverNameLoc, SourceLocation propertyNameLoc); ObjCMethodDecl *tryCaptureObjCSelf(SourceLocation Loc); /// Describes the kind of message expression indicated by a message /// send that starts with an identifier. enum ObjCMessageKind { /// The message is sent to 'super'. ObjCSuperMessage, /// The message is an instance message. ObjCInstanceMessage, /// The message is a class message, and the identifier is a type /// name. ObjCClassMessage }; ObjCMessageKind getObjCMessageKind(Scope *S, IdentifierInfo *Name, SourceLocation NameLoc, bool IsSuper, bool HasTrailingDot, ParsedType &ReceiverType); ExprResult ActOnSuperMessage(Scope *S, SourceLocation SuperLoc, Selector Sel, SourceLocation LBracLoc, ArrayRef<SourceLocation> SelectorLocs, SourceLocation RBracLoc, MultiExprArg Args); ExprResult BuildClassMessage(TypeSourceInfo *ReceiverTypeInfo, QualType ReceiverType, SourceLocation SuperLoc, Selector Sel, ObjCMethodDecl *Method, SourceLocation LBracLoc, ArrayRef<SourceLocation> SelectorLocs, SourceLocation RBracLoc, MultiExprArg Args, bool isImplicit = false); ExprResult BuildClassMessageImplicit(QualType ReceiverType, bool isSuperReceiver, SourceLocation Loc, Selector Sel, ObjCMethodDecl *Method, MultiExprArg Args); ExprResult ActOnClassMessage(Scope *S, ParsedType Receiver, Selector Sel, SourceLocation LBracLoc, ArrayRef<SourceLocation> SelectorLocs, SourceLocation RBracLoc, MultiExprArg Args); ExprResult BuildInstanceMessage(Expr *Receiver, QualType ReceiverType, SourceLocation SuperLoc, Selector Sel, ObjCMethodDecl *Method, SourceLocation LBracLoc, ArrayRef<SourceLocation> SelectorLocs, SourceLocation RBracLoc, MultiExprArg Args, bool isImplicit = false); ExprResult BuildInstanceMessageImplicit(Expr *Receiver, QualType ReceiverType, SourceLocation Loc, Selector Sel, ObjCMethodDecl *Method, MultiExprArg Args); ExprResult ActOnInstanceMessage(Scope *S, Expr *Receiver, Selector Sel, SourceLocation LBracLoc, ArrayRef<SourceLocation> SelectorLocs, SourceLocation RBracLoc, MultiExprArg Args); ExprResult BuildObjCBridgedCast(SourceLocation LParenLoc, ObjCBridgeCastKind Kind, SourceLocation BridgeKeywordLoc, TypeSourceInfo *TSInfo, Expr *SubExpr); ExprResult ActOnObjCBridgedCast(Scope *S, SourceLocation LParenLoc, ObjCBridgeCastKind Kind, SourceLocation BridgeKeywordLoc, ParsedType Type, SourceLocation RParenLoc, Expr *SubExpr); void CheckTollFreeBridgeCast(QualType castType, Expr *castExpr); void CheckObjCBridgeRelatedCast(QualType castType, Expr *castExpr); bool CheckTollFreeBridgeStaticCast(QualType castType, Expr *castExpr, CastKind &Kind); bool checkObjCBridgeRelatedComponents(SourceLocation Loc, QualType DestType, QualType SrcType, ObjCInterfaceDecl *&RelatedClass, ObjCMethodDecl *&ClassMethod, ObjCMethodDecl *&InstanceMethod, TypedefNameDecl *&TDNDecl, bool CfToNs, bool Diagnose = true); bool CheckObjCBridgeRelatedConversions(SourceLocation Loc, QualType DestType, QualType SrcType, Expr *&SrcExpr, bool Diagnose = true); bool CheckConversionToObjCLiteral(QualType DstType, Expr *&SrcExpr, bool Diagnose = true); bool checkInitMethod(ObjCMethodDecl *method, QualType receiverTypeIfCall); /// Check whether the given new method is a valid override of the /// given overridden method, and set any properties that should be inherited. void CheckObjCMethodOverride(ObjCMethodDecl *NewMethod, const ObjCMethodDecl *Overridden); /// Describes the compatibility of a result type with its method. enum ResultTypeCompatibilityKind { RTC_Compatible, RTC_Incompatible, RTC_Unknown }; void CheckObjCMethodDirectOverrides(ObjCMethodDecl *method, ObjCMethodDecl *overridden); void CheckObjCMethodOverrides(ObjCMethodDecl *ObjCMethod, ObjCInterfaceDecl *CurrentClass, ResultTypeCompatibilityKind RTC); enum PragmaOptionsAlignKind { POAK_Native, // #pragma options align=native POAK_Natural, // #pragma options align=natural POAK_Packed, // #pragma options align=packed POAK_Power, // #pragma options align=power POAK_Mac68k, // #pragma options align=mac68k POAK_Reset // #pragma options align=reset }; /// ActOnPragmaClangSection - Called on well formed \#pragma clang section void ActOnPragmaClangSection(SourceLocation PragmaLoc, PragmaClangSectionAction Action, PragmaClangSectionKind SecKind, StringRef SecName); /// ActOnPragmaOptionsAlign - Called on well formed \#pragma options align. void ActOnPragmaOptionsAlign(PragmaOptionsAlignKind Kind, SourceLocation PragmaLoc); /// ActOnPragmaPack - Called on well formed \#pragma pack(...). void ActOnPragmaPack(SourceLocation PragmaLoc, PragmaMsStackAction Action, StringRef SlotLabel, Expr *Alignment); enum class PragmaAlignPackDiagnoseKind { NonDefaultStateAtInclude, ChangedStateAtExit }; void DiagnoseNonDefaultPragmaAlignPack(PragmaAlignPackDiagnoseKind Kind, SourceLocation IncludeLoc); void DiagnoseUnterminatedPragmaAlignPack(); /// ActOnPragmaMSStruct - Called on well formed \#pragma ms_struct [on|off]. void ActOnPragmaMSStruct(PragmaMSStructKind Kind); /// ActOnPragmaMSComment - Called on well formed /// \#pragma comment(kind, "arg"). void ActOnPragmaMSComment(SourceLocation CommentLoc, PragmaMSCommentKind Kind, StringRef Arg); /// ActOnPragmaMSPointersToMembers - called on well formed \#pragma /// pointers_to_members(representation method[, general purpose /// representation]). void ActOnPragmaMSPointersToMembers( LangOptions::PragmaMSPointersToMembersKind Kind, SourceLocation PragmaLoc); /// Called on well formed \#pragma vtordisp(). void ActOnPragmaMSVtorDisp(PragmaMsStackAction Action, SourceLocation PragmaLoc, MSVtorDispMode Value); enum PragmaSectionKind { PSK_DataSeg, PSK_BSSSeg, PSK_ConstSeg, PSK_CodeSeg, }; bool UnifySection(StringRef SectionName, int SectionFlags, NamedDecl *TheDecl); bool UnifySection(StringRef SectionName, int SectionFlags, SourceLocation PragmaSectionLocation); /// Called on well formed \#pragma bss_seg/data_seg/const_seg/code_seg. void ActOnPragmaMSSeg(SourceLocation PragmaLocation, PragmaMsStackAction Action, llvm::StringRef StackSlotLabel, StringLiteral *SegmentName, llvm::StringRef PragmaName); /// Called on well formed \#pragma section(). void ActOnPragmaMSSection(SourceLocation PragmaLocation, int SectionFlags, StringLiteral *SegmentName); /// Called on well-formed \#pragma init_seg(). void ActOnPragmaMSInitSeg(SourceLocation PragmaLocation, StringLiteral *SegmentName); /// Called on #pragma clang __debug dump II void ActOnPragmaDump(Scope *S, SourceLocation Loc, IdentifierInfo *II); /// ActOnPragmaDetectMismatch - Call on well-formed \#pragma detect_mismatch void ActOnPragmaDetectMismatch(SourceLocation Loc, StringRef Name, StringRef Value); /// Are precise floating point semantics currently enabled? bool isPreciseFPEnabled() { return !CurFPFeatures.getAllowFPReassociate() && !CurFPFeatures.getNoSignedZero() && !CurFPFeatures.getAllowReciprocal() && !CurFPFeatures.getAllowApproxFunc(); } /// ActOnPragmaFloatControl - Call on well-formed \#pragma float_control void ActOnPragmaFloatControl(SourceLocation Loc, PragmaMsStackAction Action, PragmaFloatControlKind Value); /// ActOnPragmaUnused - Called on well-formed '\#pragma unused'. void ActOnPragmaUnused(const Token &Identifier, Scope *curScope, SourceLocation PragmaLoc); /// ActOnPragmaVisibility - Called on well formed \#pragma GCC visibility... . void ActOnPragmaVisibility(const IdentifierInfo* VisType, SourceLocation PragmaLoc); NamedDecl *DeclClonePragmaWeak(NamedDecl *ND, IdentifierInfo *II, SourceLocation Loc); void DeclApplyPragmaWeak(Scope *S, NamedDecl *ND, WeakInfo &W); /// ActOnPragmaWeakID - Called on well formed \#pragma weak ident. void ActOnPragmaWeakID(IdentifierInfo* WeakName, SourceLocation PragmaLoc, SourceLocation WeakNameLoc); /// ActOnPragmaRedefineExtname - Called on well formed /// \#pragma redefine_extname oldname newname. void ActOnPragmaRedefineExtname(IdentifierInfo* WeakName, IdentifierInfo* AliasName, SourceLocation PragmaLoc, SourceLocation WeakNameLoc, SourceLocation AliasNameLoc); /// ActOnPragmaWeakAlias - Called on well formed \#pragma weak ident = ident. void ActOnPragmaWeakAlias(IdentifierInfo* WeakName, IdentifierInfo* AliasName, SourceLocation PragmaLoc, SourceLocation WeakNameLoc, SourceLocation AliasNameLoc); /// ActOnPragmaFPContract - Called on well formed /// \#pragma {STDC,OPENCL} FP_CONTRACT and /// \#pragma clang fp contract void ActOnPragmaFPContract(SourceLocation Loc, LangOptions::FPModeKind FPC); /// Called on well formed /// \#pragma clang fp reassociate void ActOnPragmaFPReassociate(SourceLocation Loc, bool IsEnabled); /// ActOnPragmaFenvAccess - Called on well formed /// \#pragma STDC FENV_ACCESS void ActOnPragmaFEnvAccess(SourceLocation Loc, bool IsEnabled); /// Called on well formed '\#pragma clang fp' that has option 'exceptions'. void ActOnPragmaFPExceptions(SourceLocation Loc, LangOptions::FPExceptionModeKind); /// Called to set constant rounding mode for floating point operations. void setRoundingMode(SourceLocation Loc, llvm::RoundingMode); /// Called to set exception behavior for floating point operations. void setExceptionMode(SourceLocation Loc, LangOptions::FPExceptionModeKind); /// AddAlignmentAttributesForRecord - Adds any needed alignment attributes to /// a the record decl, to handle '\#pragma pack' and '\#pragma options align'. void AddAlignmentAttributesForRecord(RecordDecl *RD); /// AddMsStructLayoutForRecord - Adds ms_struct layout attribute to record. void AddMsStructLayoutForRecord(RecordDecl *RD); /// PushNamespaceVisibilityAttr - Note that we've entered a /// namespace with a visibility attribute. void PushNamespaceVisibilityAttr(const VisibilityAttr *Attr, SourceLocation Loc); /// AddPushedVisibilityAttribute - If '\#pragma GCC visibility' was used, /// add an appropriate visibility attribute. void AddPushedVisibilityAttribute(Decl *RD); /// PopPragmaVisibility - Pop the top element of the visibility stack; used /// for '\#pragma GCC visibility' and visibility attributes on namespaces. void PopPragmaVisibility(bool IsNamespaceEnd, SourceLocation EndLoc); /// FreeVisContext - Deallocate and null out VisContext. void FreeVisContext(); /// AddCFAuditedAttribute - Check whether we're currently within /// '\#pragma clang arc_cf_code_audited' and, if so, consider adding /// the appropriate attribute. void AddCFAuditedAttribute(Decl *D); void ActOnPragmaAttributeAttribute(ParsedAttr &Attribute, SourceLocation PragmaLoc, attr::ParsedSubjectMatchRuleSet Rules); void ActOnPragmaAttributeEmptyPush(SourceLocation PragmaLoc, const IdentifierInfo *Namespace); /// Called on well-formed '\#pragma clang attribute pop'. void ActOnPragmaAttributePop(SourceLocation PragmaLoc, const IdentifierInfo *Namespace); /// Adds the attributes that have been specified using the /// '\#pragma clang attribute push' directives to the given declaration. void AddPragmaAttributes(Scope *S, Decl *D); void DiagnoseUnterminatedPragmaAttribute(); /// Called on well formed \#pragma clang optimize. void ActOnPragmaOptimize(bool On, SourceLocation PragmaLoc); /// Get the location for the currently active "\#pragma clang optimize /// off". If this location is invalid, then the state of the pragma is "on". SourceLocation getOptimizeOffPragmaLocation() const { return OptimizeOffPragmaLocation; } /// Only called on function definitions; if there is a pragma in scope /// with the effect of a range-based optnone, consider marking the function /// with attribute optnone. void AddRangeBasedOptnone(FunctionDecl *FD); /// Adds the 'optnone' attribute to the function declaration if there /// are no conflicts; Loc represents the location causing the 'optnone' /// attribute to be added (usually because of a pragma). void AddOptnoneAttributeIfNoConflicts(FunctionDecl *FD, SourceLocation Loc); void AddIntelFPGABankBitsAttr(Decl *D, const AttributeCommonInfo &CI, Expr **Exprs, unsigned Size); template <typename AttrType> void addIntelTripleArgAttr(Decl *D, const AttributeCommonInfo &CI, Expr *XDimExpr, Expr *YDimExpr, Expr *ZDimExpr); void AddWorkGroupSizeHintAttr(Decl *D, const AttributeCommonInfo &CI, Expr *XDim, Expr *YDim, Expr *ZDim); WorkGroupSizeHintAttr * MergeWorkGroupSizeHintAttr(Decl *D, const WorkGroupSizeHintAttr &A); void AddIntelReqdSubGroupSize(Decl *D, const AttributeCommonInfo &CI, Expr *E); IntelReqdSubGroupSizeAttr * MergeIntelReqdSubGroupSizeAttr(Decl *D, const IntelReqdSubGroupSizeAttr &A); IntelNamedSubGroupSizeAttr * MergeIntelNamedSubGroupSizeAttr(Decl *D, const IntelNamedSubGroupSizeAttr &A); void AddSYCLIntelNumSimdWorkItemsAttr(Decl *D, const AttributeCommonInfo &CI, Expr *E); SYCLIntelNumSimdWorkItemsAttr * MergeSYCLIntelNumSimdWorkItemsAttr(Decl *D, const SYCLIntelNumSimdWorkItemsAttr &A); void AddSYCLIntelESimdVectorizeAttr(Decl *D, const AttributeCommonInfo &CI, Expr *E); SYCLIntelESimdVectorizeAttr * MergeSYCLIntelESimdVectorizeAttr(Decl *D, const SYCLIntelESimdVectorizeAttr &A); void AddSYCLIntelSchedulerTargetFmaxMhzAttr(Decl *D, const AttributeCommonInfo &CI, Expr *E); SYCLIntelSchedulerTargetFmaxMhzAttr *MergeSYCLIntelSchedulerTargetFmaxMhzAttr( Decl *D, const SYCLIntelSchedulerTargetFmaxMhzAttr &A); void AddSYCLIntelNoGlobalWorkOffsetAttr(Decl *D, const AttributeCommonInfo &CI, Expr *E); SYCLIntelNoGlobalWorkOffsetAttr *MergeSYCLIntelNoGlobalWorkOffsetAttr( Decl *D, const SYCLIntelNoGlobalWorkOffsetAttr &A); void AddSYCLIntelLoopFuseAttr(Decl *D, const AttributeCommonInfo &CI, Expr *E); SYCLIntelLoopFuseAttr * MergeSYCLIntelLoopFuseAttr(Decl *D, const SYCLIntelLoopFuseAttr &A); void AddIntelFPGAPrivateCopiesAttr(Decl *D, const AttributeCommonInfo &CI, Expr *E); void AddIntelFPGAMaxReplicatesAttr(Decl *D, const AttributeCommonInfo &CI, Expr *E); IntelFPGAMaxReplicatesAttr * MergeIntelFPGAMaxReplicatesAttr(Decl *D, const IntelFPGAMaxReplicatesAttr &A); void AddIntelFPGAForcePow2DepthAttr(Decl *D, const AttributeCommonInfo &CI, Expr *E); IntelFPGAForcePow2DepthAttr * MergeIntelFPGAForcePow2DepthAttr(Decl *D, const IntelFPGAForcePow2DepthAttr &A); void AddSYCLIntelFPGAInitiationIntervalAttr(Decl *D, const AttributeCommonInfo &CI, Expr *E); SYCLIntelFPGAInitiationIntervalAttr *MergeSYCLIntelFPGAInitiationIntervalAttr( Decl *D, const SYCLIntelFPGAInitiationIntervalAttr &A); SYCLIntelFPGAMaxConcurrencyAttr *MergeSYCLIntelFPGAMaxConcurrencyAttr( Decl *D, const SYCLIntelFPGAMaxConcurrencyAttr &A); void AddSYCLIntelMaxGlobalWorkDimAttr(Decl *D, const AttributeCommonInfo &CI, Expr *E); SYCLIntelMaxGlobalWorkDimAttr * MergeSYCLIntelMaxGlobalWorkDimAttr(Decl *D, const SYCLIntelMaxGlobalWorkDimAttr &A); void AddIntelFPGABankWidthAttr(Decl *D, const AttributeCommonInfo &CI, Expr *E); IntelFPGABankWidthAttr * MergeIntelFPGABankWidthAttr(Decl *D, const IntelFPGABankWidthAttr &A); void AddIntelFPGANumBanksAttr(Decl *D, const AttributeCommonInfo &CI, Expr *E); IntelFPGANumBanksAttr * MergeIntelFPGANumBanksAttr(Decl *D, const IntelFPGANumBanksAttr &A); /// AddAlignedAttr - Adds an aligned attribute to a particular declaration. void AddAlignedAttr(Decl *D, const AttributeCommonInfo &CI, Expr *E, bool IsPackExpansion); void AddAlignedAttr(Decl *D, const AttributeCommonInfo &CI, TypeSourceInfo *T, bool IsPackExpansion); /// AddAssumeAlignedAttr - Adds an assume_aligned attribute to a particular /// declaration. void AddAssumeAlignedAttr(Decl *D, const AttributeCommonInfo &CI, Expr *E, Expr *OE); /// AddAllocAlignAttr - Adds an alloc_align attribute to a particular /// declaration. void AddAllocAlignAttr(Decl *D, const AttributeCommonInfo &CI, Expr *ParamExpr); /// AddAlignValueAttr - Adds an align_value attribute to a particular /// declaration. void AddAlignValueAttr(Decl *D, const AttributeCommonInfo &CI, Expr *E); /// AddAnnotationAttr - Adds an annotation Annot with Args arguments to D. void AddAnnotationAttr(Decl *D, const AttributeCommonInfo &CI, StringRef Annot, MutableArrayRef<Expr *> Args); /// AddLaunchBoundsAttr - Adds a launch_bounds attribute to a particular /// declaration. void AddLaunchBoundsAttr(Decl *D, const AttributeCommonInfo &CI, Expr *MaxThreads, Expr *MinBlocks); /// AddModeAttr - Adds a mode attribute to a particular declaration. void AddModeAttr(Decl *D, const AttributeCommonInfo &CI, IdentifierInfo *Name, bool InInstantiation = false); void AddParameterABIAttr(Decl *D, const AttributeCommonInfo &CI, ParameterABI ABI); enum class RetainOwnershipKind {NS, CF, OS}; void AddXConsumedAttr(Decl *D, const AttributeCommonInfo &CI, RetainOwnershipKind K, bool IsTemplateInstantiation); /// addAMDGPUFlatWorkGroupSizeAttr - Adds an amdgpu_flat_work_group_size /// attribute to a particular declaration. void addAMDGPUFlatWorkGroupSizeAttr(Decl *D, const AttributeCommonInfo &CI, Expr *Min, Expr *Max); /// addAMDGPUWavePersEUAttr - Adds an amdgpu_waves_per_eu attribute to a /// particular declaration. void addAMDGPUWavesPerEUAttr(Decl *D, const AttributeCommonInfo &CI, Expr *Min, Expr *Max); /// addSYCLIntelPipeIOAttr - Adds a pipe I/O attribute to a particular /// declaration. void addSYCLIntelPipeIOAttr(Decl *D, const AttributeCommonInfo &CI, Expr *ID); /// AddSYCLIntelFPGAMaxConcurrencyAttr - Adds a max_concurrency attribute to a /// particular declaration. void AddSYCLIntelFPGAMaxConcurrencyAttr(Decl *D, const AttributeCommonInfo &CI, Expr *E); bool checkNSReturnsRetainedReturnType(SourceLocation loc, QualType type); bool checkAllowedSYCLInitializer(VarDecl *VD, bool CheckValueDependent = false); //===--------------------------------------------------------------------===// // C++ Coroutines TS // bool ActOnCoroutineBodyStart(Scope *S, SourceLocation KwLoc, StringRef Keyword); ExprResult ActOnCoawaitExpr(Scope *S, SourceLocation KwLoc, Expr *E); ExprResult ActOnCoyieldExpr(Scope *S, SourceLocation KwLoc, Expr *E); StmtResult ActOnCoreturnStmt(Scope *S, SourceLocation KwLoc, Expr *E); ExprResult BuildResolvedCoawaitExpr(SourceLocation KwLoc, Expr *E, bool IsImplicit = false); ExprResult BuildUnresolvedCoawaitExpr(SourceLocation KwLoc, Expr *E, UnresolvedLookupExpr* Lookup); ExprResult BuildCoyieldExpr(SourceLocation KwLoc, Expr *E); StmtResult BuildCoreturnStmt(SourceLocation KwLoc, Expr *E, bool IsImplicit = false); StmtResult BuildCoroutineBodyStmt(CoroutineBodyStmt::CtorArgs); bool buildCoroutineParameterMoves(SourceLocation Loc); VarDecl *buildCoroutinePromise(SourceLocation Loc); void CheckCompletedCoroutineBody(FunctionDecl *FD, Stmt *&Body); ClassTemplateDecl *lookupCoroutineTraits(SourceLocation KwLoc, SourceLocation FuncLoc); /// Check that the expression co_await promise.final_suspend() shall not be /// potentially-throwing. bool checkFinalSuspendNoThrow(const Stmt *FinalSuspend); //===--------------------------------------------------------------------===// // OpenMP directives and clauses. // private: void *VarDataSharingAttributesStack; struct DeclareTargetContextInfo { struct MapInfo { OMPDeclareTargetDeclAttr::MapTypeTy MT; SourceLocation Loc; }; /// Explicitly listed variables and functions in a 'to' or 'link' clause. llvm::DenseMap<NamedDecl *, MapInfo> ExplicitlyMapped; /// The 'device_type' as parsed from the clause. OMPDeclareTargetDeclAttr::DevTypeTy DT = OMPDeclareTargetDeclAttr::DT_Any; /// The directive kind, `begin declare target` or `declare target`. OpenMPDirectiveKind Kind; /// The directive location. SourceLocation Loc; DeclareTargetContextInfo(OpenMPDirectiveKind Kind, SourceLocation Loc) : Kind(Kind), Loc(Loc) {} }; /// Number of nested '#pragma omp declare target' directives. SmallVector<DeclareTargetContextInfo, 4> DeclareTargetNesting; /// Initialization of data-sharing attributes stack. void InitDataSharingAttributesStack(); void DestroyDataSharingAttributesStack(); ExprResult VerifyPositiveIntegerConstantInClause(Expr *Op, OpenMPClauseKind CKind, bool StrictlyPositive = true, bool SuppressExprDiags = false); /// Returns OpenMP nesting level for current directive. unsigned getOpenMPNestingLevel() const; /// Adjusts the function scopes index for the target-based regions. void adjustOpenMPTargetScopeIndex(unsigned &FunctionScopesIndex, unsigned Level) const; /// Returns the number of scopes associated with the construct on the given /// OpenMP level. int getNumberOfConstructScopes(unsigned Level) const; /// Push new OpenMP function region for non-capturing function. void pushOpenMPFunctionRegion(); /// Pop OpenMP function region for non-capturing function. void popOpenMPFunctionRegion(const sema::FunctionScopeInfo *OldFSI); /// Analyzes and checks a loop nest for use by a loop transformation. /// /// \param Kind The loop transformation directive kind. /// \param NumLoops How many nested loops the directive is expecting. /// \param AStmt Associated statement of the transformation directive. /// \param LoopHelpers [out] The loop analysis result. /// \param Body [out] The body code nested in \p NumLoops loop. /// \param OriginalInits [out] Collection of statements and declarations that /// must have been executed/declared before entering the /// loop. /// /// \return Whether there was any error. bool checkTransformableLoopNest( OpenMPDirectiveKind Kind, Stmt *AStmt, int NumLoops, SmallVectorImpl<OMPLoopBasedDirective::HelperExprs> &LoopHelpers, Stmt *&Body, SmallVectorImpl<SmallVector<llvm::PointerUnion<Stmt *, Decl *>, 0>> &OriginalInits); /// Helper to keep information about the current `omp begin/end declare /// variant` nesting. struct OMPDeclareVariantScope { /// The associated OpenMP context selector. OMPTraitInfo *TI; /// The associated OpenMP context selector mangling. std::string NameSuffix; OMPDeclareVariantScope(OMPTraitInfo &TI); }; /// Return the OMPTraitInfo for the surrounding scope, if any. OMPTraitInfo *getOMPTraitInfoForSurroundingScope() { return OMPDeclareVariantScopes.empty() ? nullptr : OMPDeclareVariantScopes.back().TI; } /// The current `omp begin/end declare variant` scopes. SmallVector<OMPDeclareVariantScope, 4> OMPDeclareVariantScopes; /// The current `omp begin/end assumes` scopes. SmallVector<AssumptionAttr *, 4> OMPAssumeScoped; /// All `omp assumes` we encountered so far. SmallVector<AssumptionAttr *, 4> OMPAssumeGlobal; public: /// The declarator \p D defines a function in the scope \p S which is nested /// in an `omp begin/end declare variant` scope. In this method we create a /// declaration for \p D and rename \p D according to the OpenMP context /// selector of the surrounding scope. Return all base functions in \p Bases. void ActOnStartOfFunctionDefinitionInOpenMPDeclareVariantScope( Scope *S, Declarator &D, MultiTemplateParamsArg TemplateParameterLists, SmallVectorImpl<FunctionDecl *> &Bases); /// Register \p D as specialization of all base functions in \p Bases in the /// current `omp begin/end declare variant` scope. void ActOnFinishedFunctionDefinitionInOpenMPDeclareVariantScope( Decl *D, SmallVectorImpl<FunctionDecl *> &Bases); /// Act on \p D, a function definition inside of an `omp [begin/end] assumes`. void ActOnFinishedFunctionDefinitionInOpenMPAssumeScope(Decl *D); /// Can we exit an OpenMP declare variant scope at the moment. bool isInOpenMPDeclareVariantScope() const { return !OMPDeclareVariantScopes.empty(); } /// Given the potential call expression \p Call, determine if there is a /// specialization via the OpenMP declare variant mechanism available. If /// there is, return the specialized call expression, otherwise return the /// original \p Call. ExprResult ActOnOpenMPCall(ExprResult Call, Scope *Scope, SourceLocation LParenLoc, MultiExprArg ArgExprs, SourceLocation RParenLoc, Expr *ExecConfig); /// Handle a `omp begin declare variant`. void ActOnOpenMPBeginDeclareVariant(SourceLocation Loc, OMPTraitInfo &TI); /// Handle a `omp end declare variant`. void ActOnOpenMPEndDeclareVariant(); /// Checks if the variant/multiversion functions are compatible. bool areMultiversionVariantFunctionsCompatible( const FunctionDecl *OldFD, const FunctionDecl *NewFD, const PartialDiagnostic &NoProtoDiagID, const PartialDiagnosticAt &NoteCausedDiagIDAt, const PartialDiagnosticAt &NoSupportDiagIDAt, const PartialDiagnosticAt &DiffDiagIDAt, bool TemplatesSupported, bool ConstexprSupported, bool CLinkageMayDiffer); /// Function tries to capture lambda's captured variables in the OpenMP region /// before the original lambda is captured. void tryCaptureOpenMPLambdas(ValueDecl *V); /// Return true if the provided declaration \a VD should be captured by /// reference. /// \param Level Relative level of nested OpenMP construct for that the check /// is performed. /// \param OpenMPCaptureLevel Capture level within an OpenMP construct. bool isOpenMPCapturedByRef(const ValueDecl *D, unsigned Level, unsigned OpenMPCaptureLevel) const; /// Check if the specified variable is used in one of the private /// clauses (private, firstprivate, lastprivate, reduction etc.) in OpenMP /// constructs. VarDecl *isOpenMPCapturedDecl(ValueDecl *D, bool CheckScopeInfo = false, unsigned StopAt = 0); ExprResult getOpenMPCapturedExpr(VarDecl *Capture, ExprValueKind VK, ExprObjectKind OK, SourceLocation Loc); /// If the current region is a loop-based region, mark the start of the loop /// construct. void startOpenMPLoop(); /// If the current region is a range loop-based region, mark the start of the /// loop construct. void startOpenMPCXXRangeFor(); /// Check if the specified variable is used in 'private' clause. /// \param Level Relative level of nested OpenMP construct for that the check /// is performed. OpenMPClauseKind isOpenMPPrivateDecl(ValueDecl *D, unsigned Level, unsigned CapLevel) const; /// Sets OpenMP capture kind (OMPC_private, OMPC_firstprivate, OMPC_map etc.) /// for \p FD based on DSA for the provided corresponding captured declaration /// \p D. void setOpenMPCaptureKind(FieldDecl *FD, const ValueDecl *D, unsigned Level); /// Check if the specified variable is captured by 'target' directive. /// \param Level Relative level of nested OpenMP construct for that the check /// is performed. bool isOpenMPTargetCapturedDecl(const ValueDecl *D, unsigned Level, unsigned CaptureLevel) const; /// Check if the specified global variable must be captured by outer capture /// regions. /// \param Level Relative level of nested OpenMP construct for that /// the check is performed. bool isOpenMPGlobalCapturedDecl(ValueDecl *D, unsigned Level, unsigned CaptureLevel) const; ExprResult PerformOpenMPImplicitIntegerConversion(SourceLocation OpLoc, Expr *Op); /// Called on start of new data sharing attribute block. void StartOpenMPDSABlock(OpenMPDirectiveKind K, const DeclarationNameInfo &DirName, Scope *CurScope, SourceLocation Loc); /// Start analysis of clauses. void StartOpenMPClause(OpenMPClauseKind K); /// End analysis of clauses. void EndOpenMPClause(); /// Called on end of data sharing attribute block. void EndOpenMPDSABlock(Stmt *CurDirective); /// Check if the current region is an OpenMP loop region and if it is, /// mark loop control variable, used in \p Init for loop initialization, as /// private by default. /// \param Init First part of the for loop. void ActOnOpenMPLoopInitialization(SourceLocation ForLoc, Stmt *Init); /// Called on well-formed '\#pragma omp metadirective' after parsing /// of the associated statement. StmtResult ActOnOpenMPMetaDirective(ArrayRef<OMPClause *> Clauses, Stmt *AStmt, SourceLocation StartLoc, SourceLocation EndLoc); // OpenMP directives and clauses. /// Called on correct id-expression from the '#pragma omp /// threadprivate'. ExprResult ActOnOpenMPIdExpression(Scope *CurScope, CXXScopeSpec &ScopeSpec, const DeclarationNameInfo &Id, OpenMPDirectiveKind Kind); /// Called on well-formed '#pragma omp threadprivate'. DeclGroupPtrTy ActOnOpenMPThreadprivateDirective( SourceLocation Loc, ArrayRef<Expr *> VarList); /// Builds a new OpenMPThreadPrivateDecl and checks its correctness. OMPThreadPrivateDecl *CheckOMPThreadPrivateDecl(SourceLocation Loc, ArrayRef<Expr *> VarList); /// Called on well-formed '#pragma omp allocate'. DeclGroupPtrTy ActOnOpenMPAllocateDirective(SourceLocation Loc, ArrayRef<Expr *> VarList, ArrayRef<OMPClause *> Clauses, DeclContext *Owner = nullptr); /// Called on well-formed '#pragma omp [begin] assume[s]'. void ActOnOpenMPAssumesDirective(SourceLocation Loc, OpenMPDirectiveKind DKind, ArrayRef<std::string> Assumptions, bool SkippedClauses); /// Check if there is an active global `omp begin assumes` directive. bool isInOpenMPAssumeScope() const { return !OMPAssumeScoped.empty(); } /// Check if there is an active global `omp assumes` directive. bool hasGlobalOpenMPAssumes() const { return !OMPAssumeGlobal.empty(); } /// Called on well-formed '#pragma omp end assumes'. void ActOnOpenMPEndAssumesDirective(); /// Called on well-formed '#pragma omp requires'. DeclGroupPtrTy ActOnOpenMPRequiresDirective(SourceLocation Loc, ArrayRef<OMPClause *> ClauseList); /// Check restrictions on Requires directive OMPRequiresDecl *CheckOMPRequiresDecl(SourceLocation Loc, ArrayRef<OMPClause *> Clauses); /// Check if the specified type is allowed to be used in 'omp declare /// reduction' construct. QualType ActOnOpenMPDeclareReductionType(SourceLocation TyLoc, TypeResult ParsedType); /// Called on start of '#pragma omp declare reduction'. DeclGroupPtrTy ActOnOpenMPDeclareReductionDirectiveStart( Scope *S, DeclContext *DC, DeclarationName Name, ArrayRef<std::pair<QualType, SourceLocation>> ReductionTypes, AccessSpecifier AS, Decl *PrevDeclInScope = nullptr); /// Initialize declare reduction construct initializer. void ActOnOpenMPDeclareReductionCombinerStart(Scope *S, Decl *D); /// Finish current declare reduction construct initializer. void ActOnOpenMPDeclareReductionCombinerEnd(Decl *D, Expr *Combiner); /// Initialize declare reduction construct initializer. /// \return omp_priv variable. VarDecl *ActOnOpenMPDeclareReductionInitializerStart(Scope *S, Decl *D); /// Finish current declare reduction construct initializer. void ActOnOpenMPDeclareReductionInitializerEnd(Decl *D, Expr *Initializer, VarDecl *OmpPrivParm); /// Called at the end of '#pragma omp declare reduction'. DeclGroupPtrTy ActOnOpenMPDeclareReductionDirectiveEnd( Scope *S, DeclGroupPtrTy DeclReductions, bool IsValid); /// Check variable declaration in 'omp declare mapper' construct. TypeResult ActOnOpenMPDeclareMapperVarDecl(Scope *S, Declarator &D); /// Check if the specified type is allowed to be used in 'omp declare /// mapper' construct. QualType ActOnOpenMPDeclareMapperType(SourceLocation TyLoc, TypeResult ParsedType); /// Called on start of '#pragma omp declare mapper'. DeclGroupPtrTy ActOnOpenMPDeclareMapperDirective( Scope *S, DeclContext *DC, DeclarationName Name, QualType MapperType, SourceLocation StartLoc, DeclarationName VN, AccessSpecifier AS, Expr *MapperVarRef, ArrayRef<OMPClause *> Clauses, Decl *PrevDeclInScope = nullptr); /// Build the mapper variable of '#pragma omp declare mapper'. ExprResult ActOnOpenMPDeclareMapperDirectiveVarDecl(Scope *S, QualType MapperType, SourceLocation StartLoc, DeclarationName VN); bool isOpenMPDeclareMapperVarDeclAllowed(const VarDecl *VD) const; const ValueDecl *getOpenMPDeclareMapperVarName() const; /// Called on the start of target region i.e. '#pragma omp declare target'. bool ActOnStartOpenMPDeclareTargetContext(DeclareTargetContextInfo &DTCI); /// Called at the end of target region i.e. '#pragma omp end declare target'. const DeclareTargetContextInfo ActOnOpenMPEndDeclareTargetDirective(); /// Called once a target context is completed, that can be when a /// '#pragma omp end declare target' was encountered or when a /// '#pragma omp declare target' without declaration-definition-seq was /// encountered. void ActOnFinishedOpenMPDeclareTargetContext(DeclareTargetContextInfo &DTCI); /// Searches for the provided declaration name for OpenMP declare target /// directive. NamedDecl *lookupOpenMPDeclareTargetName(Scope *CurScope, CXXScopeSpec &ScopeSpec, const DeclarationNameInfo &Id); /// Called on correct id-expression from the '#pragma omp declare target'. void ActOnOpenMPDeclareTargetName(NamedDecl *ND, SourceLocation Loc, OMPDeclareTargetDeclAttr::MapTypeTy MT, OMPDeclareTargetDeclAttr::DevTypeTy DT); /// Check declaration inside target region. void checkDeclIsAllowedInOpenMPTarget(Expr *E, Decl *D, SourceLocation IdLoc = SourceLocation()); /// Finishes analysis of the deferred functions calls that may be declared as /// host/nohost during device/host compilation. void finalizeOpenMPDelayedAnalysis(const FunctionDecl *Caller, const FunctionDecl *Callee, SourceLocation Loc); /// Return true inside OpenMP declare target region. bool isInOpenMPDeclareTargetContext() const { return !DeclareTargetNesting.empty(); } /// Return true inside OpenMP target region. bool isInOpenMPTargetExecutionDirective() const; /// Return the number of captured regions created for an OpenMP directive. static int getOpenMPCaptureLevels(OpenMPDirectiveKind Kind); /// Initialization of captured region for OpenMP region. void ActOnOpenMPRegionStart(OpenMPDirectiveKind DKind, Scope *CurScope); /// Called for syntactical loops (ForStmt or CXXForRangeStmt) associated to /// an OpenMP loop directive. StmtResult ActOnOpenMPCanonicalLoop(Stmt *AStmt); /// Process a canonical OpenMP loop nest that can either be a canonical /// literal loop (ForStmt or CXXForRangeStmt), or the generated loop of an /// OpenMP loop transformation construct. StmtResult ActOnOpenMPLoopnest(Stmt *AStmt); /// End of OpenMP region. /// /// \param S Statement associated with the current OpenMP region. /// \param Clauses List of clauses for the current OpenMP region. /// /// \returns Statement for finished OpenMP region. StmtResult ActOnOpenMPRegionEnd(StmtResult S, ArrayRef<OMPClause *> Clauses); StmtResult ActOnOpenMPExecutableDirective( OpenMPDirectiveKind Kind, const DeclarationNameInfo &DirName, OpenMPDirectiveKind CancelRegion, ArrayRef<OMPClause *> Clauses, Stmt *AStmt, SourceLocation StartLoc, SourceLocation EndLoc); /// Called on well-formed '\#pragma omp parallel' after parsing /// of the associated statement. StmtResult ActOnOpenMPParallelDirective(ArrayRef<OMPClause *> Clauses, Stmt *AStmt, SourceLocation StartLoc, SourceLocation EndLoc); using VarsWithInheritedDSAType = llvm::SmallDenseMap<const ValueDecl *, const Expr *, 4>; /// Called on well-formed '\#pragma omp simd' after parsing /// of the associated statement. StmtResult ActOnOpenMPSimdDirective(ArrayRef<OMPClause *> Clauses, Stmt *AStmt, SourceLocation StartLoc, SourceLocation EndLoc, VarsWithInheritedDSAType &VarsWithImplicitDSA); /// Called on well-formed '#pragma omp tile' after parsing of its clauses and /// the associated statement. StmtResult ActOnOpenMPTileDirective(ArrayRef<OMPClause *> Clauses, Stmt *AStmt, SourceLocation StartLoc, SourceLocation EndLoc); /// Called on well-formed '#pragma omp unroll' after parsing of its clauses /// and the associated statement. StmtResult ActOnOpenMPUnrollDirective(ArrayRef<OMPClause *> Clauses, Stmt *AStmt, SourceLocation StartLoc, SourceLocation EndLoc); /// Called on well-formed '\#pragma omp for' after parsing /// of the associated statement. StmtResult ActOnOpenMPForDirective(ArrayRef<OMPClause *> Clauses, Stmt *AStmt, SourceLocation StartLoc, SourceLocation EndLoc, VarsWithInheritedDSAType &VarsWithImplicitDSA); /// Called on well-formed '\#pragma omp for simd' after parsing /// of the associated statement. StmtResult ActOnOpenMPForSimdDirective(ArrayRef<OMPClause *> Clauses, Stmt *AStmt, SourceLocation StartLoc, SourceLocation EndLoc, VarsWithInheritedDSAType &VarsWithImplicitDSA); /// Called on well-formed '\#pragma omp sections' after parsing /// of the associated statement. StmtResult ActOnOpenMPSectionsDirective(ArrayRef<OMPClause *> Clauses, Stmt *AStmt, SourceLocation StartLoc, SourceLocation EndLoc); /// Called on well-formed '\#pragma omp section' after parsing of the /// associated statement. StmtResult ActOnOpenMPSectionDirective(Stmt *AStmt, SourceLocation StartLoc, SourceLocation EndLoc); /// Called on well-formed '\#pragma omp single' after parsing of the /// associated statement. StmtResult ActOnOpenMPSingleDirective(ArrayRef<OMPClause *> Clauses, Stmt *AStmt, SourceLocation StartLoc, SourceLocation EndLoc); /// Called on well-formed '\#pragma omp master' after parsing of the /// associated statement. StmtResult ActOnOpenMPMasterDirective(Stmt *AStmt, SourceLocation StartLoc, SourceLocation EndLoc); /// Called on well-formed '\#pragma omp critical' after parsing of the /// associated statement. StmtResult ActOnOpenMPCriticalDirective(const DeclarationNameInfo &DirName, ArrayRef<OMPClause *> Clauses, Stmt *AStmt, SourceLocation StartLoc, SourceLocation EndLoc); /// Called on well-formed '\#pragma omp parallel for' after parsing /// of the associated statement. StmtResult ActOnOpenMPParallelForDirective( ArrayRef<OMPClause *> Clauses, Stmt *AStmt, SourceLocation StartLoc, SourceLocation EndLoc, VarsWithInheritedDSAType &VarsWithImplicitDSA); /// Called on well-formed '\#pragma omp parallel for simd' after /// parsing of the associated statement. StmtResult ActOnOpenMPParallelForSimdDirective( ArrayRef<OMPClause *> Clauses, Stmt *AStmt, SourceLocation StartLoc, SourceLocation EndLoc, VarsWithInheritedDSAType &VarsWithImplicitDSA); /// Called on well-formed '\#pragma omp parallel master' after /// parsing of the associated statement. StmtResult ActOnOpenMPParallelMasterDirective(ArrayRef<OMPClause *> Clauses, Stmt *AStmt, SourceLocation StartLoc, SourceLocation EndLoc); /// Called on well-formed '\#pragma omp parallel sections' after /// parsing of the associated statement. StmtResult ActOnOpenMPParallelSectionsDirective(ArrayRef<OMPClause *> Clauses, Stmt *AStmt, SourceLocation StartLoc, SourceLocation EndLoc); /// Called on well-formed '\#pragma omp task' after parsing of the /// associated statement. StmtResult ActOnOpenMPTaskDirective(ArrayRef<OMPClause *> Clauses, Stmt *AStmt, SourceLocation StartLoc, SourceLocation EndLoc); /// Called on well-formed '\#pragma omp taskyield'. StmtResult ActOnOpenMPTaskyieldDirective(SourceLocation StartLoc, SourceLocation EndLoc); /// Called on well-formed '\#pragma omp barrier'. StmtResult ActOnOpenMPBarrierDirective(SourceLocation StartLoc, SourceLocation EndLoc); /// Called on well-formed '\#pragma omp taskwait'. StmtResult ActOnOpenMPTaskwaitDirective(SourceLocation StartLoc, SourceLocation EndLoc); /// Called on well-formed '\#pragma omp taskgroup'. StmtResult ActOnOpenMPTaskgroupDirective(ArrayRef<OMPClause *> Clauses, Stmt *AStmt, SourceLocation StartLoc, SourceLocation EndLoc); /// Called on well-formed '\#pragma omp flush'. StmtResult ActOnOpenMPFlushDirective(ArrayRef<OMPClause *> Clauses, SourceLocation StartLoc, SourceLocation EndLoc); /// Called on well-formed '\#pragma omp depobj'. StmtResult ActOnOpenMPDepobjDirective(ArrayRef<OMPClause *> Clauses, SourceLocation StartLoc, SourceLocation EndLoc); /// Called on well-formed '\#pragma omp scan'. StmtResult ActOnOpenMPScanDirective(ArrayRef<OMPClause *> Clauses, SourceLocation StartLoc, SourceLocation EndLoc); /// Called on well-formed '\#pragma omp ordered' after parsing of the /// associated statement. StmtResult ActOnOpenMPOrderedDirective(ArrayRef<OMPClause *> Clauses, Stmt *AStmt, SourceLocation StartLoc, SourceLocation EndLoc); /// Called on well-formed '\#pragma omp atomic' after parsing of the /// associated statement. StmtResult ActOnOpenMPAtomicDirective(ArrayRef<OMPClause *> Clauses, Stmt *AStmt, SourceLocation StartLoc, SourceLocation EndLoc); /// Called on well-formed '\#pragma omp target' after parsing of the /// associated statement. StmtResult ActOnOpenMPTargetDirective(ArrayRef<OMPClause *> Clauses, Stmt *AStmt, SourceLocation StartLoc, SourceLocation EndLoc); /// Called on well-formed '\#pragma omp target data' after parsing of /// the associated statement. StmtResult ActOnOpenMPTargetDataDirective(ArrayRef<OMPClause *> Clauses, Stmt *AStmt, SourceLocation StartLoc, SourceLocation EndLoc); /// Called on well-formed '\#pragma omp target enter data' after /// parsing of the associated statement. StmtResult ActOnOpenMPTargetEnterDataDirective(ArrayRef<OMPClause *> Clauses, SourceLocation StartLoc, SourceLocation EndLoc, Stmt *AStmt); /// Called on well-formed '\#pragma omp target exit data' after /// parsing of the associated statement. StmtResult ActOnOpenMPTargetExitDataDirective(ArrayRef<OMPClause *> Clauses, SourceLocation StartLoc, SourceLocation EndLoc, Stmt *AStmt); /// Called on well-formed '\#pragma omp target parallel' after /// parsing of the associated statement. StmtResult ActOnOpenMPTargetParallelDirective(ArrayRef<OMPClause *> Clauses, Stmt *AStmt, SourceLocation StartLoc, SourceLocation EndLoc); /// Called on well-formed '\#pragma omp target parallel for' after /// parsing of the associated statement. StmtResult ActOnOpenMPTargetParallelForDirective( ArrayRef<OMPClause *> Clauses, Stmt *AStmt, SourceLocation StartLoc, SourceLocation EndLoc, VarsWithInheritedDSAType &VarsWithImplicitDSA); /// Called on well-formed '\#pragma omp teams' after parsing of the /// associated statement. StmtResult ActOnOpenMPTeamsDirective(ArrayRef<OMPClause *> Clauses, Stmt *AStmt, SourceLocation StartLoc, SourceLocation EndLoc); /// Called on well-formed '\#pragma omp cancellation point'. StmtResult ActOnOpenMPCancellationPointDirective(SourceLocation StartLoc, SourceLocation EndLoc, OpenMPDirectiveKind CancelRegion); /// Called on well-formed '\#pragma omp cancel'. StmtResult ActOnOpenMPCancelDirective(ArrayRef<OMPClause *> Clauses, SourceLocation StartLoc, SourceLocation EndLoc, OpenMPDirectiveKind CancelRegion); /// Called on well-formed '\#pragma omp taskloop' after parsing of the /// associated statement. StmtResult ActOnOpenMPTaskLoopDirective(ArrayRef<OMPClause *> Clauses, Stmt *AStmt, SourceLocation StartLoc, SourceLocation EndLoc, VarsWithInheritedDSAType &VarsWithImplicitDSA); /// Called on well-formed '\#pragma omp taskloop simd' after parsing of /// the associated statement. StmtResult ActOnOpenMPTaskLoopSimdDirective( ArrayRef<OMPClause *> Clauses, Stmt *AStmt, SourceLocation StartLoc, SourceLocation EndLoc, VarsWithInheritedDSAType &VarsWithImplicitDSA); /// Called on well-formed '\#pragma omp master taskloop' after parsing of the /// associated statement. StmtResult ActOnOpenMPMasterTaskLoopDirective( ArrayRef<OMPClause *> Clauses, Stmt *AStmt, SourceLocation StartLoc, SourceLocation EndLoc, VarsWithInheritedDSAType &VarsWithImplicitDSA); /// Called on well-formed '\#pragma omp master taskloop simd' after parsing of /// the associated statement. StmtResult ActOnOpenMPMasterTaskLoopSimdDirective( ArrayRef<OMPClause *> Clauses, Stmt *AStmt, SourceLocation StartLoc, SourceLocation EndLoc, VarsWithInheritedDSAType &VarsWithImplicitDSA); /// Called on well-formed '\#pragma omp parallel master taskloop' after /// parsing of the associated statement. StmtResult ActOnOpenMPParallelMasterTaskLoopDirective( ArrayRef<OMPClause *> Clauses, Stmt *AStmt, SourceLocation StartLoc, SourceLocation EndLoc, VarsWithInheritedDSAType &VarsWithImplicitDSA); /// Called on well-formed '\#pragma omp parallel master taskloop simd' after /// parsing of the associated statement. StmtResult ActOnOpenMPParallelMasterTaskLoopSimdDirective( ArrayRef<OMPClause *> Clauses, Stmt *AStmt, SourceLocation StartLoc, SourceLocation EndLoc, VarsWithInheritedDSAType &VarsWithImplicitDSA); /// Called on well-formed '\#pragma omp distribute' after parsing /// of the associated statement. StmtResult ActOnOpenMPDistributeDirective(ArrayRef<OMPClause *> Clauses, Stmt *AStmt, SourceLocation StartLoc, SourceLocation EndLoc, VarsWithInheritedDSAType &VarsWithImplicitDSA); /// Called on well-formed '\#pragma omp target update'. StmtResult ActOnOpenMPTargetUpdateDirective(ArrayRef<OMPClause *> Clauses, SourceLocation StartLoc, SourceLocation EndLoc, Stmt *AStmt); /// Called on well-formed '\#pragma omp distribute parallel for' after /// parsing of the associated statement. StmtResult ActOnOpenMPDistributeParallelForDirective( ArrayRef<OMPClause *> Clauses, Stmt *AStmt, SourceLocation StartLoc, SourceLocation EndLoc, VarsWithInheritedDSAType &VarsWithImplicitDSA); /// Called on well-formed '\#pragma omp distribute parallel for simd' /// after parsing of the associated statement. StmtResult ActOnOpenMPDistributeParallelForSimdDirective( ArrayRef<OMPClause *> Clauses, Stmt *AStmt, SourceLocation StartLoc, SourceLocation EndLoc, VarsWithInheritedDSAType &VarsWithImplicitDSA); /// Called on well-formed '\#pragma omp distribute simd' after /// parsing of the associated statement. StmtResult ActOnOpenMPDistributeSimdDirective( ArrayRef<OMPClause *> Clauses, Stmt *AStmt, SourceLocation StartLoc, SourceLocation EndLoc, VarsWithInheritedDSAType &VarsWithImplicitDSA); /// Called on well-formed '\#pragma omp target parallel for simd' after /// parsing of the associated statement. StmtResult ActOnOpenMPTargetParallelForSimdDirective( ArrayRef<OMPClause *> Clauses, Stmt *AStmt, SourceLocation StartLoc, SourceLocation EndLoc, VarsWithInheritedDSAType &VarsWithImplicitDSA); /// Called on well-formed '\#pragma omp target simd' after parsing of /// the associated statement. StmtResult ActOnOpenMPTargetSimdDirective(ArrayRef<OMPClause *> Clauses, Stmt *AStmt, SourceLocation StartLoc, SourceLocation EndLoc, VarsWithInheritedDSAType &VarsWithImplicitDSA); /// Called on well-formed '\#pragma omp teams distribute' after parsing of /// the associated statement. StmtResult ActOnOpenMPTeamsDistributeDirective( ArrayRef<OMPClause *> Clauses, Stmt *AStmt, SourceLocation StartLoc, SourceLocation EndLoc, VarsWithInheritedDSAType &VarsWithImplicitDSA); /// Called on well-formed '\#pragma omp teams distribute simd' after parsing /// of the associated statement. StmtResult ActOnOpenMPTeamsDistributeSimdDirective( ArrayRef<OMPClause *> Clauses, Stmt *AStmt, SourceLocation StartLoc, SourceLocation EndLoc, VarsWithInheritedDSAType &VarsWithImplicitDSA); /// Called on well-formed '\#pragma omp teams distribute parallel for simd' /// after parsing of the associated statement. StmtResult ActOnOpenMPTeamsDistributeParallelForSimdDirective( ArrayRef<OMPClause *> Clauses, Stmt *AStmt, SourceLocation StartLoc, SourceLocation EndLoc, VarsWithInheritedDSAType &VarsWithImplicitDSA); /// Called on well-formed '\#pragma omp teams distribute parallel for' /// after parsing of the associated statement. StmtResult ActOnOpenMPTeamsDistributeParallelForDirective( ArrayRef<OMPClause *> Clauses, Stmt *AStmt, SourceLocation StartLoc, SourceLocation EndLoc, VarsWithInheritedDSAType &VarsWithImplicitDSA); /// Called on well-formed '\#pragma omp target teams' after parsing of the /// associated statement. StmtResult ActOnOpenMPTargetTeamsDirective(ArrayRef<OMPClause *> Clauses, Stmt *AStmt, SourceLocation StartLoc, SourceLocation EndLoc); /// Called on well-formed '\#pragma omp target teams distribute' after parsing /// of the associated statement. StmtResult ActOnOpenMPTargetTeamsDistributeDirective( ArrayRef<OMPClause *> Clauses, Stmt *AStmt, SourceLocation StartLoc, SourceLocation EndLoc, VarsWithInheritedDSAType &VarsWithImplicitDSA); /// Called on well-formed '\#pragma omp target teams distribute parallel for' /// after parsing of the associated statement. StmtResult ActOnOpenMPTargetTeamsDistributeParallelForDirective( ArrayRef<OMPClause *> Clauses, Stmt *AStmt, SourceLocation StartLoc, SourceLocation EndLoc, VarsWithInheritedDSAType &VarsWithImplicitDSA); /// Called on well-formed '\#pragma omp target teams distribute parallel for /// simd' after parsing of the associated statement. StmtResult ActOnOpenMPTargetTeamsDistributeParallelForSimdDirective( ArrayRef<OMPClause *> Clauses, Stmt *AStmt, SourceLocation StartLoc, SourceLocation EndLoc, VarsWithInheritedDSAType &VarsWithImplicitDSA); /// Called on well-formed '\#pragma omp target teams distribute simd' after /// parsing of the associated statement. StmtResult ActOnOpenMPTargetTeamsDistributeSimdDirective( ArrayRef<OMPClause *> Clauses, Stmt *AStmt, SourceLocation StartLoc, SourceLocation EndLoc, VarsWithInheritedDSAType &VarsWithImplicitDSA); /// Called on well-formed '\#pragma omp interop'. StmtResult ActOnOpenMPInteropDirective(ArrayRef<OMPClause *> Clauses, SourceLocation StartLoc, SourceLocation EndLoc); /// Called on well-formed '\#pragma omp dispatch' after parsing of the // /associated statement. StmtResult ActOnOpenMPDispatchDirective(ArrayRef<OMPClause *> Clauses, Stmt *AStmt, SourceLocation StartLoc, SourceLocation EndLoc); /// Called on well-formed '\#pragma omp masked' after parsing of the // /associated statement. StmtResult ActOnOpenMPMaskedDirective(ArrayRef<OMPClause *> Clauses, Stmt *AStmt, SourceLocation StartLoc, SourceLocation EndLoc); /// Called on well-formed '\#pragma omp loop' after parsing of the /// associated statement. StmtResult ActOnOpenMPGenericLoopDirective( ArrayRef<OMPClause *> Clauses, Stmt *AStmt, SourceLocation StartLoc, SourceLocation EndLoc, VarsWithInheritedDSAType &VarsWithImplicitDSA); /// Checks correctness of linear modifiers. bool CheckOpenMPLinearModifier(OpenMPLinearClauseKind LinKind, SourceLocation LinLoc); /// Checks that the specified declaration matches requirements for the linear /// decls. bool CheckOpenMPLinearDecl(const ValueDecl *D, SourceLocation ELoc, OpenMPLinearClauseKind LinKind, QualType Type, bool IsDeclareSimd = false); /// Called on well-formed '\#pragma omp declare simd' after parsing of /// the associated method/function. DeclGroupPtrTy ActOnOpenMPDeclareSimdDirective( DeclGroupPtrTy DG, OMPDeclareSimdDeclAttr::BranchStateTy BS, Expr *Simdlen, ArrayRef<Expr *> Uniforms, ArrayRef<Expr *> Aligneds, ArrayRef<Expr *> Alignments, ArrayRef<Expr *> Linears, ArrayRef<unsigned> LinModifiers, ArrayRef<Expr *> Steps, SourceRange SR); /// Checks '\#pragma omp declare variant' variant function and original /// functions after parsing of the associated method/function. /// \param DG Function declaration to which declare variant directive is /// applied to. /// \param VariantRef Expression that references the variant function, which /// must be used instead of the original one, specified in \p DG. /// \param TI The trait info object representing the match clause. /// \param NumAppendArgs The number of omp_interop_t arguments to account for /// in checking. /// \returns None, if the function/variant function are not compatible with /// the pragma, pair of original function/variant ref expression otherwise. Optional<std::pair<FunctionDecl *, Expr *>> checkOpenMPDeclareVariantFunction(DeclGroupPtrTy DG, Expr *VariantRef, OMPTraitInfo &TI, unsigned NumAppendArgs, SourceRange SR); /// Called on well-formed '\#pragma omp declare variant' after parsing of /// the associated method/function. /// \param FD Function declaration to which declare variant directive is /// applied to. /// \param VariantRef Expression that references the variant function, which /// must be used instead of the original one, specified in \p DG. /// \param TI The context traits associated with the function variant. /// \param AdjustArgsNothing The list of 'nothing' arguments. /// \param AdjustArgsNeedDevicePtr The list of 'need_device_ptr' arguments. /// \param AppendArgs The list of 'append_args' arguments. /// \param AdjustArgsLoc The Location of an 'adjust_args' clause. /// \param AppendArgsLoc The Location of an 'append_args' clause. /// \param SR The SourceRange of the 'declare variant' directive. void ActOnOpenMPDeclareVariantDirective( FunctionDecl *FD, Expr *VariantRef, OMPTraitInfo &TI, ArrayRef<Expr *> AdjustArgsNothing, ArrayRef<Expr *> AdjustArgsNeedDevicePtr, ArrayRef<OMPDeclareVariantAttr::InteropType> AppendArgs, SourceLocation AdjustArgsLoc, SourceLocation AppendArgsLoc, SourceRange SR); OMPClause *ActOnOpenMPSingleExprClause(OpenMPClauseKind Kind, Expr *Expr, SourceLocation StartLoc, SourceLocation LParenLoc, SourceLocation EndLoc); /// Called on well-formed 'allocator' clause. OMPClause *ActOnOpenMPAllocatorClause(Expr *Allocator, SourceLocation StartLoc, SourceLocation LParenLoc, SourceLocation EndLoc); /// Called on well-formed 'if' clause. OMPClause *ActOnOpenMPIfClause(OpenMPDirectiveKind NameModifier, Expr *Condition, SourceLocation StartLoc, SourceLocation LParenLoc, SourceLocation NameModifierLoc, SourceLocation ColonLoc, SourceLocation EndLoc); /// Called on well-formed 'final' clause. OMPClause *ActOnOpenMPFinalClause(Expr *Condition, SourceLocation StartLoc, SourceLocation LParenLoc, SourceLocation EndLoc); /// Called on well-formed 'num_threads' clause. OMPClause *ActOnOpenMPNumThreadsClause(Expr *NumThreads, SourceLocation StartLoc, SourceLocation LParenLoc, SourceLocation EndLoc); /// Called on well-formed 'safelen' clause. OMPClause *ActOnOpenMPSafelenClause(Expr *Length, SourceLocation StartLoc, SourceLocation LParenLoc, SourceLocation EndLoc); /// Called on well-formed 'simdlen' clause. OMPClause *ActOnOpenMPSimdlenClause(Expr *Length, SourceLocation StartLoc, SourceLocation LParenLoc, SourceLocation EndLoc); /// Called on well-form 'sizes' clause. OMPClause *ActOnOpenMPSizesClause(ArrayRef<Expr *> SizeExprs, SourceLocation StartLoc, SourceLocation LParenLoc, SourceLocation EndLoc); /// Called on well-form 'full' clauses. OMPClause *ActOnOpenMPFullClause(SourceLocation StartLoc, SourceLocation EndLoc); /// Called on well-form 'partial' clauses. OMPClause *ActOnOpenMPPartialClause(Expr *FactorExpr, SourceLocation StartLoc, SourceLocation LParenLoc, SourceLocation EndLoc); /// Called on well-formed 'collapse' clause. OMPClause *ActOnOpenMPCollapseClause(Expr *NumForLoops, SourceLocation StartLoc, SourceLocation LParenLoc, SourceLocation EndLoc); /// Called on well-formed 'ordered' clause. OMPClause * ActOnOpenMPOrderedClause(SourceLocation StartLoc, SourceLocation EndLoc, SourceLocation LParenLoc = SourceLocation(), Expr *NumForLoops = nullptr); /// Called on well-formed 'grainsize' clause. OMPClause *ActOnOpenMPGrainsizeClause(Expr *Size, SourceLocation StartLoc, SourceLocation LParenLoc, SourceLocation EndLoc); /// Called on well-formed 'num_tasks' clause. OMPClause *ActOnOpenMPNumTasksClause(Expr *NumTasks, SourceLocation StartLoc, SourceLocation LParenLoc, SourceLocation EndLoc); /// Called on well-formed 'hint' clause. OMPClause *ActOnOpenMPHintClause(Expr *Hint, SourceLocation StartLoc, SourceLocation LParenLoc, SourceLocation EndLoc); /// Called on well-formed 'detach' clause. OMPClause *ActOnOpenMPDetachClause(Expr *Evt, SourceLocation StartLoc, SourceLocation LParenLoc, SourceLocation EndLoc); OMPClause *ActOnOpenMPSimpleClause(OpenMPClauseKind Kind, unsigned Argument, SourceLocation ArgumentLoc, SourceLocation StartLoc, SourceLocation LParenLoc, SourceLocation EndLoc); /// Called on well-formed 'when' clause. OMPClause *ActOnOpenMPWhenClause(OMPTraitInfo &TI, SourceLocation StartLoc, SourceLocation LParenLoc, SourceLocation EndLoc); /// Called on well-formed 'default' clause. OMPClause *ActOnOpenMPDefaultClause(llvm::omp::DefaultKind Kind, SourceLocation KindLoc, SourceLocation StartLoc, SourceLocation LParenLoc, SourceLocation EndLoc); /// Called on well-formed 'proc_bind' clause. OMPClause *ActOnOpenMPProcBindClause(llvm::omp::ProcBindKind Kind, SourceLocation KindLoc, SourceLocation StartLoc, SourceLocation LParenLoc, SourceLocation EndLoc); /// Called on well-formed 'order' clause. OMPClause *ActOnOpenMPOrderClause(OpenMPOrderClauseKind Kind, SourceLocation KindLoc, SourceLocation StartLoc, SourceLocation LParenLoc, SourceLocation EndLoc); /// Called on well-formed 'update' clause. OMPClause *ActOnOpenMPUpdateClause(OpenMPDependClauseKind Kind, SourceLocation KindLoc, SourceLocation StartLoc, SourceLocation LParenLoc, SourceLocation EndLoc); OMPClause *ActOnOpenMPSingleExprWithArgClause( OpenMPClauseKind Kind, ArrayRef<unsigned> Arguments, Expr *Expr, SourceLocation StartLoc, SourceLocation LParenLoc, ArrayRef<SourceLocation> ArgumentsLoc, SourceLocation DelimLoc, SourceLocation EndLoc); /// Called on well-formed 'schedule' clause. OMPClause *ActOnOpenMPScheduleClause( OpenMPScheduleClauseModifier M1, OpenMPScheduleClauseModifier M2, OpenMPScheduleClauseKind Kind, Expr *ChunkSize, SourceLocation StartLoc, SourceLocation LParenLoc, SourceLocation M1Loc, SourceLocation M2Loc, SourceLocation KindLoc, SourceLocation CommaLoc, SourceLocation EndLoc); OMPClause *ActOnOpenMPClause(OpenMPClauseKind Kind, SourceLocation StartLoc, SourceLocation EndLoc); /// Called on well-formed 'nowait' clause. OMPClause *ActOnOpenMPNowaitClause(SourceLocation StartLoc, SourceLocation EndLoc); /// Called on well-formed 'untied' clause. OMPClause *ActOnOpenMPUntiedClause(SourceLocation StartLoc, SourceLocation EndLoc); /// Called on well-formed 'mergeable' clause. OMPClause *ActOnOpenMPMergeableClause(SourceLocation StartLoc, SourceLocation EndLoc); /// Called on well-formed 'read' clause. OMPClause *ActOnOpenMPReadClause(SourceLocation StartLoc, SourceLocation EndLoc); /// Called on well-formed 'write' clause. OMPClause *ActOnOpenMPWriteClause(SourceLocation StartLoc, SourceLocation EndLoc); /// Called on well-formed 'update' clause. OMPClause *ActOnOpenMPUpdateClause(SourceLocation StartLoc, SourceLocation EndLoc); /// Called on well-formed 'capture' clause. OMPClause *ActOnOpenMPCaptureClause(SourceLocation StartLoc, SourceLocation EndLoc); /// Called on well-formed 'seq_cst' clause. OMPClause *ActOnOpenMPSeqCstClause(SourceLocation StartLoc, SourceLocation EndLoc); /// Called on well-formed 'acq_rel' clause. OMPClause *ActOnOpenMPAcqRelClause(SourceLocation StartLoc, SourceLocation EndLoc); /// Called on well-formed 'acquire' clause. OMPClause *ActOnOpenMPAcquireClause(SourceLocation StartLoc, SourceLocation EndLoc); /// Called on well-formed 'release' clause. OMPClause *ActOnOpenMPReleaseClause(SourceLocation StartLoc, SourceLocation EndLoc); /// Called on well-formed 'relaxed' clause. OMPClause *ActOnOpenMPRelaxedClause(SourceLocation StartLoc, SourceLocation EndLoc); /// Called on well-formed 'init' clause. OMPClause *ActOnOpenMPInitClause(Expr *InteropVar, ArrayRef<Expr *> PrefExprs, bool IsTarget, bool IsTargetSync, SourceLocation StartLoc, SourceLocation LParenLoc, SourceLocation VarLoc, SourceLocation EndLoc); /// Called on well-formed 'use' clause. OMPClause *ActOnOpenMPUseClause(Expr *InteropVar, SourceLocation StartLoc, SourceLocation LParenLoc, SourceLocation VarLoc, SourceLocation EndLoc); /// Called on well-formed 'destroy' clause. OMPClause *ActOnOpenMPDestroyClause(Expr *InteropVar, SourceLocation StartLoc, SourceLocation LParenLoc, SourceLocation VarLoc, SourceLocation EndLoc); /// Called on well-formed 'novariants' clause. OMPClause *ActOnOpenMPNovariantsClause(Expr *Condition, SourceLocation StartLoc, SourceLocation LParenLoc, SourceLocation EndLoc); /// Called on well-formed 'nocontext' clause. OMPClause *ActOnOpenMPNocontextClause(Expr *Condition, SourceLocation StartLoc, SourceLocation LParenLoc, SourceLocation EndLoc); /// Called on well-formed 'filter' clause. OMPClause *ActOnOpenMPFilterClause(Expr *ThreadID, SourceLocation StartLoc, SourceLocation LParenLoc, SourceLocation EndLoc); /// Called on well-formed 'threads' clause. OMPClause *ActOnOpenMPThreadsClause(SourceLocation StartLoc, SourceLocation EndLoc); /// Called on well-formed 'simd' clause. OMPClause *ActOnOpenMPSIMDClause(SourceLocation StartLoc, SourceLocation EndLoc); /// Called on well-formed 'nogroup' clause. OMPClause *ActOnOpenMPNogroupClause(SourceLocation StartLoc, SourceLocation EndLoc); /// Called on well-formed 'unified_address' clause. OMPClause *ActOnOpenMPUnifiedAddressClause(SourceLocation StartLoc, SourceLocation EndLoc); /// Called on well-formed 'unified_address' clause. OMPClause *ActOnOpenMPUnifiedSharedMemoryClause(SourceLocation StartLoc, SourceLocation EndLoc); /// Called on well-formed 'reverse_offload' clause. OMPClause *ActOnOpenMPReverseOffloadClause(SourceLocation StartLoc, SourceLocation EndLoc); /// Called on well-formed 'dynamic_allocators' clause. OMPClause *ActOnOpenMPDynamicAllocatorsClause(SourceLocation StartLoc, SourceLocation EndLoc); /// Called on well-formed 'atomic_default_mem_order' clause. OMPClause *ActOnOpenMPAtomicDefaultMemOrderClause( OpenMPAtomicDefaultMemOrderClauseKind Kind, SourceLocation KindLoc, SourceLocation StartLoc, SourceLocation LParenLoc, SourceLocation EndLoc); OMPClause *ActOnOpenMPVarListClause( OpenMPClauseKind Kind, ArrayRef<Expr *> Vars, Expr *DepModOrTailExpr, const OMPVarListLocTy &Locs, SourceLocation ColonLoc, CXXScopeSpec &ReductionOrMapperIdScopeSpec, DeclarationNameInfo &ReductionOrMapperId, int ExtraModifier, ArrayRef<OpenMPMapModifierKind> MapTypeModifiers, ArrayRef<SourceLocation> MapTypeModifiersLoc, bool IsMapTypeImplicit, SourceLocation ExtraModifierLoc, ArrayRef<OpenMPMotionModifierKind> MotionModifiers, ArrayRef<SourceLocation> MotionModifiersLoc); /// Called on well-formed 'inclusive' clause. OMPClause *ActOnOpenMPInclusiveClause(ArrayRef<Expr *> VarList, SourceLocation StartLoc, SourceLocation LParenLoc, SourceLocation EndLoc); /// Called on well-formed 'exclusive' clause. OMPClause *ActOnOpenMPExclusiveClause(ArrayRef<Expr *> VarList, SourceLocation StartLoc, SourceLocation LParenLoc, SourceLocation EndLoc); /// Called on well-formed 'allocate' clause. OMPClause * ActOnOpenMPAllocateClause(Expr *Allocator, ArrayRef<Expr *> VarList, SourceLocation StartLoc, SourceLocation ColonLoc, SourceLocation LParenLoc, SourceLocation EndLoc); /// Called on well-formed 'private' clause. OMPClause *ActOnOpenMPPrivateClause(ArrayRef<Expr *> VarList, SourceLocation StartLoc, SourceLocation LParenLoc, SourceLocation EndLoc); /// Called on well-formed 'firstprivate' clause. OMPClause *ActOnOpenMPFirstprivateClause(ArrayRef<Expr *> VarList, SourceLocation StartLoc, SourceLocation LParenLoc, SourceLocation EndLoc); /// Called on well-formed 'lastprivate' clause. OMPClause *ActOnOpenMPLastprivateClause( ArrayRef<Expr *> VarList, OpenMPLastprivateModifier LPKind, SourceLocation LPKindLoc, SourceLocation ColonLoc, SourceLocation StartLoc, SourceLocation LParenLoc, SourceLocation EndLoc); /// Called on well-formed 'shared' clause. OMPClause *ActOnOpenMPSharedClause(ArrayRef<Expr *> VarList, SourceLocation StartLoc, SourceLocation LParenLoc, SourceLocation EndLoc); /// Called on well-formed 'reduction' clause. OMPClause *ActOnOpenMPReductionClause( ArrayRef<Expr *> VarList, OpenMPReductionClauseModifier Modifier, SourceLocation StartLoc, SourceLocation LParenLoc, SourceLocation ModifierLoc, SourceLocation ColonLoc, SourceLocation EndLoc, CXXScopeSpec &ReductionIdScopeSpec, const DeclarationNameInfo &ReductionId, ArrayRef<Expr *> UnresolvedReductions = llvm::None); /// Called on well-formed 'task_reduction' clause. OMPClause *ActOnOpenMPTaskReductionClause( ArrayRef<Expr *> VarList, SourceLocation StartLoc, SourceLocation LParenLoc, SourceLocation ColonLoc, SourceLocation EndLoc, CXXScopeSpec &ReductionIdScopeSpec, const DeclarationNameInfo &ReductionId, ArrayRef<Expr *> UnresolvedReductions = llvm::None); /// Called on well-formed 'in_reduction' clause. OMPClause *ActOnOpenMPInReductionClause( ArrayRef<Expr *> VarList, SourceLocation StartLoc, SourceLocation LParenLoc, SourceLocation ColonLoc, SourceLocation EndLoc, CXXScopeSpec &ReductionIdScopeSpec, const DeclarationNameInfo &ReductionId, ArrayRef<Expr *> UnresolvedReductions = llvm::None); /// Called on well-formed 'linear' clause. OMPClause * ActOnOpenMPLinearClause(ArrayRef<Expr *> VarList, Expr *Step, SourceLocation StartLoc, SourceLocation LParenLoc, OpenMPLinearClauseKind LinKind, SourceLocation LinLoc, SourceLocation ColonLoc, SourceLocation EndLoc); /// Called on well-formed 'aligned' clause. OMPClause *ActOnOpenMPAlignedClause(ArrayRef<Expr *> VarList, Expr *Alignment, SourceLocation StartLoc, SourceLocation LParenLoc, SourceLocation ColonLoc, SourceLocation EndLoc); /// Called on well-formed 'copyin' clause. OMPClause *ActOnOpenMPCopyinClause(ArrayRef<Expr *> VarList, SourceLocation StartLoc, SourceLocation LParenLoc, SourceLocation EndLoc); /// Called on well-formed 'copyprivate' clause. OMPClause *ActOnOpenMPCopyprivateClause(ArrayRef<Expr *> VarList, SourceLocation StartLoc, SourceLocation LParenLoc, SourceLocation EndLoc); /// Called on well-formed 'flush' pseudo clause. OMPClause *ActOnOpenMPFlushClause(ArrayRef<Expr *> VarList, SourceLocation StartLoc, SourceLocation LParenLoc, SourceLocation EndLoc); /// Called on well-formed 'depobj' pseudo clause. OMPClause *ActOnOpenMPDepobjClause(Expr *Depobj, SourceLocation StartLoc, SourceLocation LParenLoc, SourceLocation EndLoc); /// Called on well-formed 'depend' clause. OMPClause * ActOnOpenMPDependClause(Expr *DepModifier, OpenMPDependClauseKind DepKind, SourceLocation DepLoc, SourceLocation ColonLoc, ArrayRef<Expr *> VarList, SourceLocation StartLoc, SourceLocation LParenLoc, SourceLocation EndLoc); /// Called on well-formed 'device' clause. OMPClause *ActOnOpenMPDeviceClause(OpenMPDeviceClauseModifier Modifier, Expr *Device, SourceLocation StartLoc, SourceLocation LParenLoc, SourceLocation ModifierLoc, SourceLocation EndLoc); /// Called on well-formed 'map' clause. OMPClause *ActOnOpenMPMapClause( ArrayRef<OpenMPMapModifierKind> MapTypeModifiers, ArrayRef<SourceLocation> MapTypeModifiersLoc, CXXScopeSpec &MapperIdScopeSpec, DeclarationNameInfo &MapperId, OpenMPMapClauseKind MapType, bool IsMapTypeImplicit, SourceLocation MapLoc, SourceLocation ColonLoc, ArrayRef<Expr *> VarList, const OMPVarListLocTy &Locs, bool NoDiagnose = false, ArrayRef<Expr *> UnresolvedMappers = llvm::None); /// Called on well-formed 'num_teams' clause. OMPClause *ActOnOpenMPNumTeamsClause(Expr *NumTeams, SourceLocation StartLoc, SourceLocation LParenLoc, SourceLocation EndLoc); /// Called on well-formed 'thread_limit' clause. OMPClause *ActOnOpenMPThreadLimitClause(Expr *ThreadLimit, SourceLocation StartLoc, SourceLocation LParenLoc, SourceLocation EndLoc); /// Called on well-formed 'priority' clause. OMPClause *ActOnOpenMPPriorityClause(Expr *Priority, SourceLocation StartLoc, SourceLocation LParenLoc, SourceLocation EndLoc); /// Called on well-formed 'dist_schedule' clause. OMPClause *ActOnOpenMPDistScheduleClause( OpenMPDistScheduleClauseKind Kind, Expr *ChunkSize, SourceLocation StartLoc, SourceLocation LParenLoc, SourceLocation KindLoc, SourceLocation CommaLoc, SourceLocation EndLoc); /// Called on well-formed 'defaultmap' clause. OMPClause *ActOnOpenMPDefaultmapClause( OpenMPDefaultmapClauseModifier M, OpenMPDefaultmapClauseKind Kind, SourceLocation StartLoc, SourceLocation LParenLoc, SourceLocation MLoc, SourceLocation KindLoc, SourceLocation EndLoc); /// Called on well-formed 'to' clause. OMPClause * ActOnOpenMPToClause(ArrayRef<OpenMPMotionModifierKind> MotionModifiers, ArrayRef<SourceLocation> MotionModifiersLoc, CXXScopeSpec &MapperIdScopeSpec, DeclarationNameInfo &MapperId, SourceLocation ColonLoc, ArrayRef<Expr *> VarList, const OMPVarListLocTy &Locs, ArrayRef<Expr *> UnresolvedMappers = llvm::None); /// Called on well-formed 'from' clause. OMPClause * ActOnOpenMPFromClause(ArrayRef<OpenMPMotionModifierKind> MotionModifiers, ArrayRef<SourceLocation> MotionModifiersLoc, CXXScopeSpec &MapperIdScopeSpec, DeclarationNameInfo &MapperId, SourceLocation ColonLoc, ArrayRef<Expr *> VarList, const OMPVarListLocTy &Locs, ArrayRef<Expr *> UnresolvedMappers = llvm::None); /// Called on well-formed 'use_device_ptr' clause. OMPClause *ActOnOpenMPUseDevicePtrClause(ArrayRef<Expr *> VarList, const OMPVarListLocTy &Locs); /// Called on well-formed 'use_device_addr' clause. OMPClause *ActOnOpenMPUseDeviceAddrClause(ArrayRef<Expr *> VarList, const OMPVarListLocTy &Locs); /// Called on well-formed 'is_device_ptr' clause. OMPClause *ActOnOpenMPIsDevicePtrClause(ArrayRef<Expr *> VarList, const OMPVarListLocTy &Locs); /// Called on well-formed 'nontemporal' clause. OMPClause *ActOnOpenMPNontemporalClause(ArrayRef<Expr *> VarList, SourceLocation StartLoc, SourceLocation LParenLoc, SourceLocation EndLoc); /// Data for list of allocators. struct UsesAllocatorsData { /// Allocator. Expr *Allocator = nullptr; /// Allocator traits. Expr *AllocatorTraits = nullptr; /// Locations of '(' and ')' symbols. SourceLocation LParenLoc, RParenLoc; }; /// Called on well-formed 'uses_allocators' clause. OMPClause *ActOnOpenMPUsesAllocatorClause(SourceLocation StartLoc, SourceLocation LParenLoc, SourceLocation EndLoc, ArrayRef<UsesAllocatorsData> Data); /// Called on well-formed 'affinity' clause. OMPClause *ActOnOpenMPAffinityClause(SourceLocation StartLoc, SourceLocation LParenLoc, SourceLocation ColonLoc, SourceLocation EndLoc, Expr *Modifier, ArrayRef<Expr *> Locators); /// The kind of conversion being performed. enum CheckedConversionKind { /// An implicit conversion. CCK_ImplicitConversion, /// A C-style cast. CCK_CStyleCast, /// A functional-style cast. CCK_FunctionalCast, /// A cast other than a C-style cast. CCK_OtherCast, /// A conversion for an operand of a builtin overloaded operator. CCK_ForBuiltinOverloadedOp }; static bool isCast(CheckedConversionKind CCK) { return CCK == CCK_CStyleCast || CCK == CCK_FunctionalCast || CCK == CCK_OtherCast; } /// ImpCastExprToType - If Expr is not of type 'Type', insert an implicit /// cast. If there is already an implicit cast, merge into the existing one. /// If isLvalue, the result of the cast is an lvalue. ExprResult ImpCastExprToType(Expr *E, QualType Type, CastKind CK, ExprValueKind VK = VK_PRValue, const CXXCastPath *BasePath = nullptr, CheckedConversionKind CCK = CCK_ImplicitConversion); /// ScalarTypeToBooleanCastKind - Returns the cast kind corresponding /// to the conversion from scalar type ScalarTy to the Boolean type. static CastKind ScalarTypeToBooleanCastKind(QualType ScalarTy); /// IgnoredValueConversions - Given that an expression's result is /// syntactically ignored, perform any conversions that are /// required. ExprResult IgnoredValueConversions(Expr *E); // UsualUnaryConversions - promotes integers (C99 6.3.1.1p2) and converts // functions and arrays to their respective pointers (C99 6.3.2.1). ExprResult UsualUnaryConversions(Expr *E); /// CallExprUnaryConversions - a special case of an unary conversion /// performed on a function designator of a call expression. ExprResult CallExprUnaryConversions(Expr *E); // DefaultFunctionArrayConversion - converts functions and arrays // to their respective pointers (C99 6.3.2.1). ExprResult DefaultFunctionArrayConversion(Expr *E, bool Diagnose = true); // DefaultFunctionArrayLvalueConversion - converts functions and // arrays to their respective pointers and performs the // lvalue-to-rvalue conversion. ExprResult DefaultFunctionArrayLvalueConversion(Expr *E, bool Diagnose = true); // DefaultLvalueConversion - performs lvalue-to-rvalue conversion on // the operand. This function is a no-op if the operand has a function type // or an array type. ExprResult DefaultLvalueConversion(Expr *E); // DefaultArgumentPromotion (C99 6.5.2.2p6). Used for function calls that // do not have a prototype. Integer promotions are performed on each // argument, and arguments that have type float are promoted to double. ExprResult DefaultArgumentPromotion(Expr *E); /// If \p E is a prvalue denoting an unmaterialized temporary, materialize /// it as an xvalue. In C++98, the result will still be a prvalue, because /// we don't have xvalues there. ExprResult TemporaryMaterializationConversion(Expr *E); // Used for emitting the right warning by DefaultVariadicArgumentPromotion enum VariadicCallType { VariadicFunction, VariadicBlock, VariadicMethod, VariadicConstructor, VariadicDoesNotApply }; VariadicCallType getVariadicCallType(FunctionDecl *FDecl, const FunctionProtoType *Proto, Expr *Fn); // Used for determining in which context a type is allowed to be passed to a // vararg function. enum VarArgKind { VAK_Valid, VAK_ValidInCXX11, VAK_Undefined, VAK_MSVCUndefined, VAK_Invalid }; // Determines which VarArgKind fits an expression. VarArgKind isValidVarArgType(const QualType &Ty); /// Check to see if the given expression is a valid argument to a variadic /// function, issuing a diagnostic if not. void checkVariadicArgument(const Expr *E, VariadicCallType CT); /// Check whether the given statement can have musttail applied to it, /// issuing a diagnostic and returning false if not. In the success case, /// the statement is rewritten to remove implicit nodes from the return /// value. bool checkAndRewriteMustTailAttr(Stmt *St, const Attr &MTA); private: /// Check whether the given statement can have musttail applied to it, /// issuing a diagnostic and returning false if not. bool checkMustTailAttr(const Stmt *St, const Attr &MTA); public: /// Check to see if a given expression could have '.c_str()' called on it. bool hasCStrMethod(const Expr *E); /// GatherArgumentsForCall - Collector argument expressions for various /// form of call prototypes. bool GatherArgumentsForCall(SourceLocation CallLoc, FunctionDecl *FDecl, const FunctionProtoType *Proto, unsigned FirstParam, ArrayRef<Expr *> Args, SmallVectorImpl<Expr *> &AllArgs, VariadicCallType CallType = VariadicDoesNotApply, bool AllowExplicit = false, bool IsListInitialization = false); // DefaultVariadicArgumentPromotion - Like DefaultArgumentPromotion, but // will create a runtime trap if the resulting type is not a POD type. ExprResult DefaultVariadicArgumentPromotion(Expr *E, VariadicCallType CT, FunctionDecl *FDecl); /// Context in which we're performing a usual arithmetic conversion. enum ArithConvKind { /// An arithmetic operation. ACK_Arithmetic, /// A bitwise operation. ACK_BitwiseOp, /// A comparison. ACK_Comparison, /// A conditional (?:) operator. ACK_Conditional, /// A compound assignment expression. ACK_CompAssign, }; // UsualArithmeticConversions - performs the UsualUnaryConversions on it's // operands and then handles various conversions that are common to binary // operators (C99 6.3.1.8). If both operands aren't arithmetic, this // routine returns the first non-arithmetic type found. The client is // responsible for emitting appropriate error diagnostics. QualType UsualArithmeticConversions(ExprResult &LHS, ExprResult &RHS, SourceLocation Loc, ArithConvKind ACK); /// AssignConvertType - All of the 'assignment' semantic checks return this /// enum to indicate whether the assignment was allowed. These checks are /// done for simple assignments, as well as initialization, return from /// function, argument passing, etc. The query is phrased in terms of a /// source and destination type. enum AssignConvertType { /// Compatible - the types are compatible according to the standard. Compatible, /// PointerToInt - The assignment converts a pointer to an int, which we /// accept as an extension. PointerToInt, /// IntToPointer - The assignment converts an int to a pointer, which we /// accept as an extension. IntToPointer, /// FunctionVoidPointer - The assignment is between a function pointer and /// void*, which the standard doesn't allow, but we accept as an extension. FunctionVoidPointer, /// IncompatiblePointer - The assignment is between two pointers types that /// are not compatible, but we accept them as an extension. IncompatiblePointer, /// IncompatibleFunctionPointer - The assignment is between two function /// pointers types that are not compatible, but we accept them as an /// extension. IncompatibleFunctionPointer, /// IncompatiblePointerSign - The assignment is between two pointers types /// which point to integers which have a different sign, but are otherwise /// identical. This is a subset of the above, but broken out because it's by /// far the most common case of incompatible pointers. IncompatiblePointerSign, /// CompatiblePointerDiscardsQualifiers - The assignment discards /// c/v/r qualifiers, which we accept as an extension. CompatiblePointerDiscardsQualifiers, /// IncompatiblePointerDiscardsQualifiers - The assignment /// discards qualifiers that we don't permit to be discarded, /// like address spaces. IncompatiblePointerDiscardsQualifiers, /// IncompatibleNestedPointerAddressSpaceMismatch - The assignment /// changes address spaces in nested pointer types which is not allowed. /// For instance, converting __private int ** to __generic int ** is /// illegal even though __private could be converted to __generic. IncompatibleNestedPointerAddressSpaceMismatch, /// IncompatibleNestedPointerQualifiers - The assignment is between two /// nested pointer types, and the qualifiers other than the first two /// levels differ e.g. char ** -> const char **, but we accept them as an /// extension. IncompatibleNestedPointerQualifiers, /// IncompatibleVectors - The assignment is between two vector types that /// have the same size, which we accept as an extension. IncompatibleVectors, /// IntToBlockPointer - The assignment converts an int to a block /// pointer. We disallow this. IntToBlockPointer, /// IncompatibleBlockPointer - The assignment is between two block /// pointers types that are not compatible. IncompatibleBlockPointer, /// IncompatibleObjCQualifiedId - The assignment is between a qualified /// id type and something else (that is incompatible with it). For example, /// "id <XXX>" = "Foo *", where "Foo *" doesn't implement the XXX protocol. IncompatibleObjCQualifiedId, /// IncompatibleObjCWeakRef - Assigning a weak-unavailable object to an /// object with __weak qualifier. IncompatibleObjCWeakRef, /// Incompatible - We reject this conversion outright, it is invalid to /// represent it in the AST. Incompatible }; /// DiagnoseAssignmentResult - Emit a diagnostic, if required, for the /// assignment conversion type specified by ConvTy. This returns true if the /// conversion was invalid or false if the conversion was accepted. bool DiagnoseAssignmentResult(AssignConvertType ConvTy, SourceLocation Loc, QualType DstType, QualType SrcType, Expr *SrcExpr, AssignmentAction Action, bool *Complained = nullptr); /// IsValueInFlagEnum - Determine if a value is allowed as part of a flag /// enum. If AllowMask is true, then we also allow the complement of a valid /// value, to be used as a mask. bool IsValueInFlagEnum(const EnumDecl *ED, const llvm::APInt &Val, bool AllowMask) const; /// DiagnoseAssignmentEnum - Warn if assignment to enum is a constant /// integer not in the range of enum values. void DiagnoseAssignmentEnum(QualType DstType, QualType SrcType, Expr *SrcExpr); /// CheckAssignmentConstraints - Perform type checking for assignment, /// argument passing, variable initialization, and function return values. /// C99 6.5.16. AssignConvertType CheckAssignmentConstraints(SourceLocation Loc, QualType LHSType, QualType RHSType); /// Check assignment constraints and optionally prepare for a conversion of /// the RHS to the LHS type. The conversion is prepared for if ConvertRHS /// is true. AssignConvertType CheckAssignmentConstraints(QualType LHSType, ExprResult &RHS, CastKind &Kind, bool ConvertRHS = true); /// Check assignment constraints for an assignment of RHS to LHSType. /// /// \param LHSType The destination type for the assignment. /// \param RHS The source expression for the assignment. /// \param Diagnose If \c true, diagnostics may be produced when checking /// for assignability. If a diagnostic is produced, \p RHS will be /// set to ExprError(). Note that this function may still return /// without producing a diagnostic, even for an invalid assignment. /// \param DiagnoseCFAudited If \c true, the target is a function parameter /// in an audited Core Foundation API and does not need to be checked /// for ARC retain issues. /// \param ConvertRHS If \c true, \p RHS will be updated to model the /// conversions necessary to perform the assignment. If \c false, /// \p Diagnose must also be \c false. AssignConvertType CheckSingleAssignmentConstraints( QualType LHSType, ExprResult &RHS, bool Diagnose = true, bool DiagnoseCFAudited = false, bool ConvertRHS = true); // If the lhs type is a transparent union, check whether we // can initialize the transparent union with the given expression. AssignConvertType CheckTransparentUnionArgumentConstraints(QualType ArgType, ExprResult &RHS); bool IsStringLiteralToNonConstPointerConversion(Expr *From, QualType ToType); bool CheckExceptionSpecCompatibility(Expr *From, QualType ToType); ExprResult PerformImplicitConversion(Expr *From, QualType ToType, AssignmentAction Action, bool AllowExplicit = false); ExprResult PerformImplicitConversion(Expr *From, QualType ToType, const ImplicitConversionSequence& ICS, AssignmentAction Action, CheckedConversionKind CCK = CCK_ImplicitConversion); ExprResult PerformImplicitConversion(Expr *From, QualType ToType, const StandardConversionSequence& SCS, AssignmentAction Action, CheckedConversionKind CCK); ExprResult PerformQualificationConversion( Expr *E, QualType Ty, ExprValueKind VK = VK_PRValue, CheckedConversionKind CCK = CCK_ImplicitConversion); /// the following "Check" methods will return a valid/converted QualType /// or a null QualType (indicating an error diagnostic was issued). /// type checking binary operators (subroutines of CreateBuiltinBinOp). QualType InvalidOperands(SourceLocation Loc, ExprResult &LHS, ExprResult &RHS); QualType InvalidLogicalVectorOperands(SourceLocation Loc, ExprResult &LHS, ExprResult &RHS); QualType CheckPointerToMemberOperands( // C++ 5.5 ExprResult &LHS, ExprResult &RHS, ExprValueKind &VK, SourceLocation OpLoc, bool isIndirect); QualType CheckMultiplyDivideOperands( // C99 6.5.5 ExprResult &LHS, ExprResult &RHS, SourceLocation Loc, bool IsCompAssign, bool IsDivide); QualType CheckRemainderOperands( // C99 6.5.5 ExprResult &LHS, ExprResult &RHS, SourceLocation Loc, bool IsCompAssign = false); QualType CheckAdditionOperands( // C99 6.5.6 ExprResult &LHS, ExprResult &RHS, SourceLocation Loc, BinaryOperatorKind Opc, QualType* CompLHSTy = nullptr); QualType CheckSubtractionOperands( // C99 6.5.6 ExprResult &LHS, ExprResult &RHS, SourceLocation Loc, QualType* CompLHSTy = nullptr); QualType CheckShiftOperands( // C99 6.5.7 ExprResult &LHS, ExprResult &RHS, SourceLocation Loc, BinaryOperatorKind Opc, bool IsCompAssign = false); void CheckPtrComparisonWithNullChar(ExprResult &E, ExprResult &NullE); QualType CheckCompareOperands( // C99 6.5.8/9 ExprResult &LHS, ExprResult &RHS, SourceLocation Loc, BinaryOperatorKind Opc); QualType CheckBitwiseOperands( // C99 6.5.[10...12] ExprResult &LHS, ExprResult &RHS, SourceLocation Loc, BinaryOperatorKind Opc); QualType CheckLogicalOperands( // C99 6.5.[13,14] ExprResult &LHS, ExprResult &RHS, SourceLocation Loc, BinaryOperatorKind Opc); // CheckAssignmentOperands is used for both simple and compound assignment. // For simple assignment, pass both expressions and a null converted type. // For compound assignment, pass both expressions and the converted type. QualType CheckAssignmentOperands( // C99 6.5.16.[1,2] Expr *LHSExpr, ExprResult &RHS, SourceLocation Loc, QualType CompoundType); ExprResult checkPseudoObjectIncDec(Scope *S, SourceLocation OpLoc, UnaryOperatorKind Opcode, Expr *Op); ExprResult checkPseudoObjectAssignment(Scope *S, SourceLocation OpLoc, BinaryOperatorKind Opcode, Expr *LHS, Expr *RHS); ExprResult checkPseudoObjectRValue(Expr *E); Expr *recreateSyntacticForm(PseudoObjectExpr *E); QualType CheckConditionalOperands( // C99 6.5.15 ExprResult &Cond, ExprResult &LHS, ExprResult &RHS, ExprValueKind &VK, ExprObjectKind &OK, SourceLocation QuestionLoc); QualType CXXCheckConditionalOperands( // C++ 5.16 ExprResult &cond, ExprResult &lhs, ExprResult &rhs, ExprValueKind &VK, ExprObjectKind &OK, SourceLocation questionLoc); QualType CheckVectorConditionalTypes(ExprResult &Cond, ExprResult &LHS, ExprResult &RHS, SourceLocation QuestionLoc); QualType FindCompositePointerType(SourceLocation Loc, Expr *&E1, Expr *&E2, bool ConvertArgs = true); QualType FindCompositePointerType(SourceLocation Loc, ExprResult &E1, ExprResult &E2, bool ConvertArgs = true) { Expr *E1Tmp = E1.get(), *E2Tmp = E2.get(); QualType Composite = FindCompositePointerType(Loc, E1Tmp, E2Tmp, ConvertArgs); E1 = E1Tmp; E2 = E2Tmp; return Composite; } QualType FindCompositeObjCPointerType(ExprResult &LHS, ExprResult &RHS, SourceLocation QuestionLoc); bool DiagnoseConditionalForNull(Expr *LHSExpr, Expr *RHSExpr, SourceLocation QuestionLoc); void DiagnoseAlwaysNonNullPointer(Expr *E, Expr::NullPointerConstantKind NullType, bool IsEqual, SourceRange Range); /// type checking for vector binary operators. QualType CheckVectorOperands(ExprResult &LHS, ExprResult &RHS, SourceLocation Loc, bool IsCompAssign, bool AllowBothBool, bool AllowBoolConversion); QualType GetSignedVectorType(QualType V); QualType CheckVectorCompareOperands(ExprResult &LHS, ExprResult &RHS, SourceLocation Loc, BinaryOperatorKind Opc); QualType CheckVectorLogicalOperands(ExprResult &LHS, ExprResult &RHS, SourceLocation Loc); /// Type checking for matrix binary operators. QualType CheckMatrixElementwiseOperands(ExprResult &LHS, ExprResult &RHS, SourceLocation Loc, bool IsCompAssign); QualType CheckMatrixMultiplyOperands(ExprResult &LHS, ExprResult &RHS, SourceLocation Loc, bool IsCompAssign); bool isValidSveBitcast(QualType srcType, QualType destType); bool areMatrixTypesOfTheSameDimension(QualType srcTy, QualType destTy); bool areVectorTypesSameSize(QualType srcType, QualType destType); bool areLaxCompatibleVectorTypes(QualType srcType, QualType destType); bool isLaxVectorConversion(QualType srcType, QualType destType); /// type checking declaration initializers (C99 6.7.8) bool CheckForConstantInitializer(Expr *e, QualType t); // type checking C++ declaration initializers (C++ [dcl.init]). /// ReferenceCompareResult - Expresses the result of comparing two /// types (cv1 T1 and cv2 T2) to determine their compatibility for the /// purposes of initialization by reference (C++ [dcl.init.ref]p4). enum ReferenceCompareResult { /// Ref_Incompatible - The two types are incompatible, so direct /// reference binding is not possible. Ref_Incompatible = 0, /// Ref_Related - The two types are reference-related, which means /// that their unqualified forms (T1 and T2) are either the same /// or T1 is a base class of T2. Ref_Related, /// Ref_Compatible - The two types are reference-compatible. Ref_Compatible }; // Fake up a scoped enumeration that still contextually converts to bool. struct ReferenceConversionsScope { /// The conversions that would be performed on an lvalue of type T2 when /// binding a reference of type T1 to it, as determined when evaluating /// whether T1 is reference-compatible with T2. enum ReferenceConversions { Qualification = 0x1, NestedQualification = 0x2, Function = 0x4, DerivedToBase = 0x8, ObjC = 0x10, ObjCLifetime = 0x20, LLVM_MARK_AS_BITMASK_ENUM(/*LargestValue=*/ObjCLifetime) }; }; using ReferenceConversions = ReferenceConversionsScope::ReferenceConversions; ReferenceCompareResult CompareReferenceRelationship(SourceLocation Loc, QualType T1, QualType T2, ReferenceConversions *Conv = nullptr); ExprResult checkUnknownAnyCast(SourceRange TypeRange, QualType CastType, Expr *CastExpr, CastKind &CastKind, ExprValueKind &VK, CXXCastPath &Path); /// Force an expression with unknown-type to an expression of the /// given type. ExprResult forceUnknownAnyToType(Expr *E, QualType ToType); /// Type-check an expression that's being passed to an /// __unknown_anytype parameter. ExprResult checkUnknownAnyArg(SourceLocation callLoc, Expr *result, QualType &paramType); // CheckMatrixCast - Check type constraints for matrix casts. // We allow casting between matrixes of the same dimensions i.e. when they // have the same number of rows and column. Returns true if the cast is // invalid. bool CheckMatrixCast(SourceRange R, QualType DestTy, QualType SrcTy, CastKind &Kind); // CheckVectorCast - check type constraints for vectors. // Since vectors are an extension, there are no C standard reference for this. // We allow casting between vectors and integer datatypes of the same size. // returns true if the cast is invalid bool CheckVectorCast(SourceRange R, QualType VectorTy, QualType Ty, CastKind &Kind); /// Prepare `SplattedExpr` for a vector splat operation, adding /// implicit casts if necessary. ExprResult prepareVectorSplat(QualType VectorTy, Expr *SplattedExpr); // CheckExtVectorCast - check type constraints for extended vectors. // Since vectors are an extension, there are no C standard reference for this. // We allow casting between vectors and integer datatypes of the same size, // or vectors and the element type of that vector. // returns the cast expr ExprResult CheckExtVectorCast(SourceRange R, QualType DestTy, Expr *CastExpr, CastKind &Kind); ExprResult BuildCXXFunctionalCastExpr(TypeSourceInfo *TInfo, QualType Type, SourceLocation LParenLoc, Expr *CastExpr, SourceLocation RParenLoc); enum ARCConversionResult { ACR_okay, ACR_unbridged, ACR_error }; /// Checks for invalid conversions and casts between /// retainable pointers and other pointer kinds for ARC and Weak. ARCConversionResult CheckObjCConversion(SourceRange castRange, QualType castType, Expr *&op, CheckedConversionKind CCK, bool Diagnose = true, bool DiagnoseCFAudited = false, BinaryOperatorKind Opc = BO_PtrMemD ); Expr *stripARCUnbridgedCast(Expr *e); void diagnoseARCUnbridgedCast(Expr *e); bool CheckObjCARCUnavailableWeakConversion(QualType castType, QualType ExprType); /// checkRetainCycles - Check whether an Objective-C message send /// might create an obvious retain cycle. void checkRetainCycles(ObjCMessageExpr *msg); void checkRetainCycles(Expr *receiver, Expr *argument); void checkRetainCycles(VarDecl *Var, Expr *Init); /// checkUnsafeAssigns - Check whether +1 expr is being assigned /// to weak/__unsafe_unretained type. bool checkUnsafeAssigns(SourceLocation Loc, QualType LHS, Expr *RHS); /// checkUnsafeExprAssigns - Check whether +1 expr is being assigned /// to weak/__unsafe_unretained expression. void checkUnsafeExprAssigns(SourceLocation Loc, Expr *LHS, Expr *RHS); /// CheckMessageArgumentTypes - Check types in an Obj-C message send. /// \param Method - May be null. /// \param [out] ReturnType - The return type of the send. /// \return true iff there were any incompatible types. bool CheckMessageArgumentTypes(const Expr *Receiver, QualType ReceiverType, MultiExprArg Args, Selector Sel, ArrayRef<SourceLocation> SelectorLocs, ObjCMethodDecl *Method, bool isClassMessage, bool isSuperMessage, SourceLocation lbrac, SourceLocation rbrac, SourceRange RecRange, QualType &ReturnType, ExprValueKind &VK); /// Determine the result of a message send expression based on /// the type of the receiver, the method expected to receive the message, /// and the form of the message send. QualType getMessageSendResultType(const Expr *Receiver, QualType ReceiverType, ObjCMethodDecl *Method, bool isClassMessage, bool isSuperMessage); /// If the given expression involves a message send to a method /// with a related result type, emit a note describing what happened. void EmitRelatedResultTypeNote(const Expr *E); /// Given that we had incompatible pointer types in a return /// statement, check whether we're in a method with a related result /// type, and if so, emit a note describing what happened. void EmitRelatedResultTypeNoteForReturn(QualType destType); class ConditionResult { Decl *ConditionVar; FullExprArg Condition; bool Invalid; bool HasKnownValue; bool KnownValue; friend class Sema; ConditionResult(Sema &S, Decl *ConditionVar, FullExprArg Condition, bool IsConstexpr) : ConditionVar(ConditionVar), Condition(Condition), Invalid(false), HasKnownValue(IsConstexpr && Condition.get() && !Condition.get()->isValueDependent()), KnownValue(HasKnownValue && !!Condition.get()->EvaluateKnownConstInt(S.Context)) {} explicit ConditionResult(bool Invalid) : ConditionVar(nullptr), Condition(nullptr), Invalid(Invalid), HasKnownValue(false), KnownValue(false) {} public: ConditionResult() : ConditionResult(false) {} bool isInvalid() const { return Invalid; } std::pair<VarDecl *, Expr *> get() const { return std::make_pair(cast_or_null<VarDecl>(ConditionVar), Condition.get()); } llvm::Optional<bool> getKnownValue() const { if (!HasKnownValue) return None; return KnownValue; } }; static ConditionResult ConditionError() { return ConditionResult(true); } enum class ConditionKind { Boolean, ///< A boolean condition, from 'if', 'while', 'for', or 'do'. ConstexprIf, ///< A constant boolean condition from 'if constexpr'. Switch ///< An integral condition for a 'switch' statement. }; ConditionResult ActOnCondition(Scope *S, SourceLocation Loc, Expr *SubExpr, ConditionKind CK); ConditionResult ActOnConditionVariable(Decl *ConditionVar, SourceLocation StmtLoc, ConditionKind CK); DeclResult ActOnCXXConditionDeclaration(Scope *S, Declarator &D); ExprResult CheckConditionVariable(VarDecl *ConditionVar, SourceLocation StmtLoc, ConditionKind CK); ExprResult CheckSwitchCondition(SourceLocation SwitchLoc, Expr *Cond); /// CheckBooleanCondition - Diagnose problems involving the use of /// the given expression as a boolean condition (e.g. in an if /// statement). Also performs the standard function and array /// decays, possibly changing the input variable. /// /// \param Loc - A location associated with the condition, e.g. the /// 'if' keyword. /// \return true iff there were any errors ExprResult CheckBooleanCondition(SourceLocation Loc, Expr *E, bool IsConstexpr = false); /// ActOnExplicitBoolSpecifier - Build an ExplicitSpecifier from an expression /// found in an explicit(bool) specifier. ExplicitSpecifier ActOnExplicitBoolSpecifier(Expr *E); /// tryResolveExplicitSpecifier - Attempt to resolve the explict specifier. /// Returns true if the explicit specifier is now resolved. bool tryResolveExplicitSpecifier(ExplicitSpecifier &ExplicitSpec); /// DiagnoseAssignmentAsCondition - Given that an expression is /// being used as a boolean condition, warn if it's an assignment. void DiagnoseAssignmentAsCondition(Expr *E); /// Redundant parentheses over an equality comparison can indicate /// that the user intended an assignment used as condition. void DiagnoseEqualityWithExtraParens(ParenExpr *ParenE); /// CheckCXXBooleanCondition - Returns true if conversion to bool is invalid. ExprResult CheckCXXBooleanCondition(Expr *CondExpr, bool IsConstexpr = false); /// ConvertIntegerToTypeWarnOnOverflow - Convert the specified APInt to have /// the specified width and sign. If an overflow occurs, detect it and emit /// the specified diagnostic. void ConvertIntegerToTypeWarnOnOverflow(llvm::APSInt &OldVal, unsigned NewWidth, bool NewSign, SourceLocation Loc, unsigned DiagID); /// Checks that the Objective-C declaration is declared in the global scope. /// Emits an error and marks the declaration as invalid if it's not declared /// in the global scope. bool CheckObjCDeclScope(Decl *D); /// Abstract base class used for diagnosing integer constant /// expression violations. class VerifyICEDiagnoser { public: bool Suppress; VerifyICEDiagnoser(bool Suppress = false) : Suppress(Suppress) { } virtual SemaDiagnosticBuilder diagnoseNotICEType(Sema &S, SourceLocation Loc, QualType T); virtual SemaDiagnosticBuilder diagnoseNotICE(Sema &S, SourceLocation Loc) = 0; virtual SemaDiagnosticBuilder diagnoseFold(Sema &S, SourceLocation Loc); virtual ~VerifyICEDiagnoser() {} }; enum AllowFoldKind { NoFold, AllowFold, }; /// VerifyIntegerConstantExpression - Verifies that an expression is an ICE, /// and reports the appropriate diagnostics. Returns false on success. /// Can optionally return the value of the expression. ExprResult VerifyIntegerConstantExpression(Expr *E, llvm::APSInt *Result, VerifyICEDiagnoser &Diagnoser, AllowFoldKind CanFold = NoFold); ExprResult VerifyIntegerConstantExpression(Expr *E, llvm::APSInt *Result, unsigned DiagID, AllowFoldKind CanFold = NoFold); ExprResult VerifyIntegerConstantExpression(Expr *E, llvm::APSInt *Result = nullptr, AllowFoldKind CanFold = NoFold); ExprResult VerifyIntegerConstantExpression(Expr *E, AllowFoldKind CanFold = NoFold) { return VerifyIntegerConstantExpression(E, nullptr, CanFold); } /// VerifyBitField - verifies that a bit field expression is an ICE and has /// the correct width, and that the field type is valid. /// Returns false on success. /// Can optionally return whether the bit-field is of width 0 ExprResult VerifyBitField(SourceLocation FieldLoc, IdentifierInfo *FieldName, QualType FieldTy, bool IsMsStruct, Expr *BitWidth, bool *ZeroWidth = nullptr); private: unsigned ForceCUDAHostDeviceDepth = 0; public: /// Increments our count of the number of times we've seen a pragma forcing /// functions to be __host__ __device__. So long as this count is greater /// than zero, all functions encountered will be __host__ __device__. void PushForceCUDAHostDevice(); /// Decrements our count of the number of times we've seen a pragma forcing /// functions to be __host__ __device__. Returns false if the count is 0 /// before incrementing, so you can emit an error. bool PopForceCUDAHostDevice(); class DeviceDeferredDiagnostic { public: DeviceDeferredDiagnostic(SourceLocation SL, const PartialDiagnostic &PD, DeviceDiagnosticReason R) : Diagnostic(SL, PD), Reason(R) {} PartialDiagnosticAt &getDiag() { return Diagnostic; } DeviceDiagnosticReason getReason() const { return Reason; } private: PartialDiagnosticAt Diagnostic; DeviceDiagnosticReason Reason; }; /// Diagnostics that are emitted only if we discover that the given function /// must be codegen'ed. Because handling these correctly adds overhead to /// compilation, this is currently only enabled for CUDA compilations. llvm::DenseMap<CanonicalDeclPtr<FunctionDecl>, std::vector<DeviceDeferredDiagnostic>> DeviceDeferredDiags; /// A pair of a canonical FunctionDecl and a SourceLocation. When used as the /// key in a hashtable, both the FD and location are hashed. struct FunctionDeclAndLoc { CanonicalDeclPtr<FunctionDecl> FD; SourceLocation Loc; }; /// FunctionDecls and SourceLocations for which CheckCUDACall has emitted a /// (maybe deferred) "bad call" diagnostic. We use this to avoid emitting the /// same deferred diag twice. llvm::DenseSet<FunctionDeclAndLoc> LocsWithCUDACallDiags; /// An inverse call graph, mapping known-emitted functions to one of their /// known-emitted callers (plus the location of the call). /// /// Functions that we can tell a priori must be emitted aren't added to this /// map. llvm::DenseMap</* Callee = */ CanonicalDeclPtr<FunctionDecl>, /* Caller = */ FunctionDeclAndLoc> DeviceKnownEmittedFns; /// Creates a SemaDiagnosticBuilder that emits the diagnostic if the current /// context is "used as device code". /// /// - If CurContext is a __host__ function, does not emit any diagnostics /// unless \p EmitOnBothSides is true. /// - If CurContext is a __device__ or __global__ function, emits the /// diagnostics immediately. /// - If CurContext is a __host__ __device__ function and we are compiling for /// the device, creates a diagnostic which is emitted if and when we realize /// that the function will be codegen'ed. /// /// Example usage: /// /// // Variable-length arrays are not allowed in CUDA device code. /// if (CUDADiagIfDeviceCode(Loc, diag::err_cuda_vla) << CurrentCUDATarget()) /// return ExprError(); /// // Otherwise, continue parsing as normal. SemaDiagnosticBuilder CUDADiagIfDeviceCode(SourceLocation Loc, unsigned DiagID); /// Creates a SemaDiagnosticBuilder that emits the diagnostic if the current /// context is "used as host code". /// /// Same as CUDADiagIfDeviceCode, with "host" and "device" switched. SemaDiagnosticBuilder CUDADiagIfHostCode(SourceLocation Loc, unsigned DiagID); /// Creates a SemaDiagnosticBuilder that emits the diagnostic if the current /// context is "used as device code". /// /// - If CurContext is a `declare target` function or it is known that the /// function is emitted for the device, emits the diagnostics immediately. /// - If CurContext is a non-`declare target` function and we are compiling /// for the device, creates a diagnostic which is emitted if and when we /// realize that the function will be codegen'ed. /// /// Example usage: /// /// // Variable-length arrays are not allowed in NVPTX device code. /// if (diagIfOpenMPDeviceCode(Loc, diag::err_vla_unsupported)) /// return ExprError(); /// // Otherwise, continue parsing as normal. SemaDiagnosticBuilder diagIfOpenMPDeviceCode(SourceLocation Loc, unsigned DiagID, FunctionDecl *FD); /// Creates a SemaDiagnosticBuilder that emits the diagnostic if the current /// context is "used as host code". /// /// - If CurContext is a `declare target` function or it is known that the /// function is emitted for the host, emits the diagnostics immediately. /// - If CurContext is a non-host function, just ignore it. /// /// Example usage: /// /// // Variable-length arrays are not allowed in NVPTX device code. /// if (diagIfOpenMPHostode(Loc, diag::err_vla_unsupported)) /// return ExprError(); /// // Otherwise, continue parsing as normal. SemaDiagnosticBuilder diagIfOpenMPHostCode(SourceLocation Loc, unsigned DiagID, FunctionDecl *FD); SemaDiagnosticBuilder targetDiag(SourceLocation Loc, unsigned DiagID, FunctionDecl *FD = nullptr); SemaDiagnosticBuilder targetDiag(SourceLocation Loc, const PartialDiagnostic &PD, FunctionDecl *FD = nullptr) { return targetDiag(Loc, PD.getDiagID(), FD) << PD; } /// Check if the type is allowed to be used for the current target. void checkTypeSupport(QualType Ty, SourceLocation Loc, ValueDecl *D = nullptr); enum CUDAFunctionTarget { CFT_Device, CFT_Global, CFT_Host, CFT_HostDevice, CFT_InvalidTarget }; /// Determines whether the given function is a CUDA device/host/kernel/etc. /// function. /// /// Use this rather than examining the function's attributes yourself -- you /// will get it wrong. Returns CFT_Host if D is null. CUDAFunctionTarget IdentifyCUDATarget(const FunctionDecl *D, bool IgnoreImplicitHDAttr = false); CUDAFunctionTarget IdentifyCUDATarget(const ParsedAttributesView &Attrs); enum CUDAVariableTarget { CVT_Device, /// Emitted on device side with a shadow variable on host side CVT_Host, /// Emitted on host side only CVT_Both, /// Emitted on both sides with different addresses CVT_Unified, /// Emitted as a unified address, e.g. managed variables }; /// Determines whether the given variable is emitted on host or device side. CUDAVariableTarget IdentifyCUDATarget(const VarDecl *D); /// Gets the CUDA target for the current context. CUDAFunctionTarget CurrentCUDATarget() { return IdentifyCUDATarget(dyn_cast<FunctionDecl>(CurContext)); } static bool isCUDAImplicitHostDeviceFunction(const FunctionDecl *D); // CUDA function call preference. Must be ordered numerically from // worst to best. enum CUDAFunctionPreference { CFP_Never, // Invalid caller/callee combination. CFP_WrongSide, // Calls from host-device to host or device // function that do not match current compilation // mode. CFP_HostDevice, // Any calls to host/device functions. CFP_SameSide, // Calls from host-device to host or device // function matching current compilation mode. CFP_Native, // host-to-host or device-to-device calls. }; /// Identifies relative preference of a given Caller/Callee /// combination, based on their host/device attributes. /// \param Caller function which needs address of \p Callee. /// nullptr in case of global context. /// \param Callee target function /// /// \returns preference value for particular Caller/Callee combination. CUDAFunctionPreference IdentifyCUDAPreference(const FunctionDecl *Caller, const FunctionDecl *Callee); /// Determines whether Caller may invoke Callee, based on their CUDA /// host/device attributes. Returns false if the call is not allowed. /// /// Note: Will return true for CFP_WrongSide calls. These may appear in /// semantically correct CUDA programs, but only if they're never codegen'ed. bool IsAllowedCUDACall(const FunctionDecl *Caller, const FunctionDecl *Callee) { return IdentifyCUDAPreference(Caller, Callee) != CFP_Never; } /// May add implicit CUDAHostAttr and CUDADeviceAttr attributes to FD, /// depending on FD and the current compilation settings. void maybeAddCUDAHostDeviceAttrs(FunctionDecl *FD, const LookupResult &Previous); /// May add implicit CUDAConstantAttr attribute to VD, depending on VD /// and current compilation settings. void MaybeAddCUDAConstantAttr(VarDecl *VD); public: /// Check whether we're allowed to call Callee from the current context. /// /// - If the call is never allowed in a semantically-correct program /// (CFP_Never), emits an error and returns false. /// /// - If the call is allowed in semantically-correct programs, but only if /// it's never codegen'ed (CFP_WrongSide), creates a deferred diagnostic to /// be emitted if and when the caller is codegen'ed, and returns true. /// /// Will only create deferred diagnostics for a given SourceLocation once, /// so you can safely call this multiple times without generating duplicate /// deferred errors. /// /// - Otherwise, returns true without emitting any diagnostics. bool CheckCUDACall(SourceLocation Loc, FunctionDecl *Callee); void CUDACheckLambdaCapture(CXXMethodDecl *D, const sema::Capture &Capture); /// Set __device__ or __host__ __device__ attributes on the given lambda /// operator() method. /// /// CUDA lambdas by default is host device function unless it has explicit /// host or device attribute. void CUDASetLambdaAttrs(CXXMethodDecl *Method); /// Finds a function in \p Matches with highest calling priority /// from \p Caller context and erases all functions with lower /// calling priority. void EraseUnwantedCUDAMatches( const FunctionDecl *Caller, SmallVectorImpl<std::pair<DeclAccessPair, FunctionDecl *>> &Matches); /// Given a implicit special member, infer its CUDA target from the /// calls it needs to make to underlying base/field special members. /// \param ClassDecl the class for which the member is being created. /// \param CSM the kind of special member. /// \param MemberDecl the special member itself. /// \param ConstRHS true if this is a copy operation with a const object on /// its RHS. /// \param Diagnose true if this call should emit diagnostics. /// \return true if there was an error inferring. /// The result of this call is implicit CUDA target attribute(s) attached to /// the member declaration. bool inferCUDATargetForImplicitSpecialMember(CXXRecordDecl *ClassDecl, CXXSpecialMember CSM, CXXMethodDecl *MemberDecl, bool ConstRHS, bool Diagnose); /// \return true if \p CD can be considered empty according to CUDA /// (E.2.3.1 in CUDA 7.5 Programming guide). bool isEmptyCudaConstructor(SourceLocation Loc, CXXConstructorDecl *CD); bool isEmptyCudaDestructor(SourceLocation Loc, CXXDestructorDecl *CD); // \brief Checks that initializers of \p Var satisfy CUDA restrictions. In // case of error emits appropriate diagnostic and invalidates \p Var. // // \details CUDA allows only empty constructors as initializers for global // variables (see E.2.3.1, CUDA 7.5). The same restriction also applies to all // __shared__ variables whether they are local or not (they all are implicitly // static in CUDA). One exception is that CUDA allows constant initializers // for __constant__ and __device__ variables. void checkAllowedCUDAInitializer(VarDecl *VD); /// Check whether NewFD is a valid overload for CUDA. Emits /// diagnostics and invalidates NewFD if not. void checkCUDATargetOverload(FunctionDecl *NewFD, const LookupResult &Previous); /// Copies target attributes from the template TD to the function FD. void inheritCUDATargetAttrs(FunctionDecl *FD, const FunctionTemplateDecl &TD); /// Returns the name of the launch configuration function. This is the name /// of the function that will be called to configure kernel call, with the /// parameters specified via <<<>>>. std::string getCudaConfigureFuncName() const; /// \name Code completion //@{ /// Describes the context in which code completion occurs. enum ParserCompletionContext { /// Code completion occurs at top-level or namespace context. PCC_Namespace, /// Code completion occurs within a class, struct, or union. PCC_Class, /// Code completion occurs within an Objective-C interface, protocol, /// or category. PCC_ObjCInterface, /// Code completion occurs within an Objective-C implementation or /// category implementation PCC_ObjCImplementation, /// Code completion occurs within the list of instance variables /// in an Objective-C interface, protocol, category, or implementation. PCC_ObjCInstanceVariableList, /// Code completion occurs following one or more template /// headers. PCC_Template, /// Code completion occurs following one or more template /// headers within a class. PCC_MemberTemplate, /// Code completion occurs within an expression. PCC_Expression, /// Code completion occurs within a statement, which may /// also be an expression or a declaration. PCC_Statement, /// Code completion occurs at the beginning of the /// initialization statement (or expression) in a for loop. PCC_ForInit, /// Code completion occurs within the condition of an if, /// while, switch, or for statement. PCC_Condition, /// Code completion occurs within the body of a function on a /// recovery path, where we do not have a specific handle on our position /// in the grammar. PCC_RecoveryInFunction, /// Code completion occurs where only a type is permitted. PCC_Type, /// Code completion occurs in a parenthesized expression, which /// might also be a type cast. PCC_ParenthesizedExpression, /// Code completion occurs within a sequence of declaration /// specifiers within a function, method, or block. PCC_LocalDeclarationSpecifiers }; void CodeCompleteModuleImport(SourceLocation ImportLoc, ModuleIdPath Path); void CodeCompleteOrdinaryName(Scope *S, ParserCompletionContext CompletionContext); void CodeCompleteDeclSpec(Scope *S, DeclSpec &DS, bool AllowNonIdentifiers, bool AllowNestedNameSpecifiers); struct CodeCompleteExpressionData; void CodeCompleteExpression(Scope *S, const CodeCompleteExpressionData &Data); void CodeCompleteExpression(Scope *S, QualType PreferredType, bool IsParenthesized = false); void CodeCompleteMemberReferenceExpr(Scope *S, Expr *Base, Expr *OtherOpBase, SourceLocation OpLoc, bool IsArrow, bool IsBaseExprStatement, QualType PreferredType); void CodeCompletePostfixExpression(Scope *S, ExprResult LHS, QualType PreferredType); void CodeCompleteTag(Scope *S, unsigned TagSpec); void CodeCompleteTypeQualifiers(DeclSpec &DS); void CodeCompleteFunctionQualifiers(DeclSpec &DS, Declarator &D, const VirtSpecifiers *VS = nullptr); void CodeCompleteBracketDeclarator(Scope *S); void CodeCompleteCase(Scope *S); enum class AttributeCompletion { Attribute, Scope, None, }; void CodeCompleteAttribute( AttributeCommonInfo::Syntax Syntax, AttributeCompletion Completion = AttributeCompletion::Attribute, const IdentifierInfo *Scope = nullptr); /// Determines the preferred type of the current function argument, by /// examining the signatures of all possible overloads. /// Returns null if unknown or ambiguous, or if code completion is off. /// /// If the code completion point has been reached, also reports the function /// signatures that were considered. /// /// FIXME: rename to GuessCallArgumentType to reduce confusion. QualType ProduceCallSignatureHelp(Scope *S, Expr *Fn, ArrayRef<Expr *> Args, SourceLocation OpenParLoc); QualType ProduceConstructorSignatureHelp(Scope *S, QualType Type, SourceLocation Loc, ArrayRef<Expr *> Args, SourceLocation OpenParLoc); QualType ProduceCtorInitMemberSignatureHelp(Scope *S, Decl *ConstructorDecl, CXXScopeSpec SS, ParsedType TemplateTypeTy, ArrayRef<Expr *> ArgExprs, IdentifierInfo *II, SourceLocation OpenParLoc); void CodeCompleteInitializer(Scope *S, Decl *D); /// Trigger code completion for a record of \p BaseType. \p InitExprs are /// expressions in the initializer list seen so far and \p D is the current /// Designation being parsed. void CodeCompleteDesignator(const QualType BaseType, llvm::ArrayRef<Expr *> InitExprs, const Designation &D); void CodeCompleteAfterIf(Scope *S, bool IsBracedThen); void CodeCompleteQualifiedId(Scope *S, CXXScopeSpec &SS, bool EnteringContext, bool IsUsingDeclaration, QualType BaseType, QualType PreferredType); void CodeCompleteUsing(Scope *S); void CodeCompleteUsingDirective(Scope *S); void CodeCompleteNamespaceDecl(Scope *S); void CodeCompleteNamespaceAliasDecl(Scope *S); void CodeCompleteOperatorName(Scope *S); void CodeCompleteConstructorInitializer( Decl *Constructor, ArrayRef<CXXCtorInitializer *> Initializers); void CodeCompleteLambdaIntroducer(Scope *S, LambdaIntroducer &Intro, bool AfterAmpersand); void CodeCompleteAfterFunctionEquals(Declarator &D); void CodeCompleteObjCAtDirective(Scope *S); void CodeCompleteObjCAtVisibility(Scope *S); void CodeCompleteObjCAtStatement(Scope *S); void CodeCompleteObjCAtExpression(Scope *S); void CodeCompleteObjCPropertyFlags(Scope *S, ObjCDeclSpec &ODS); void CodeCompleteObjCPropertyGetter(Scope *S); void CodeCompleteObjCPropertySetter(Scope *S); void CodeCompleteObjCPassingType(Scope *S, ObjCDeclSpec &DS, bool IsParameter); void CodeCompleteObjCMessageReceiver(Scope *S); void CodeCompleteObjCSuperMessage(Scope *S, SourceLocation SuperLoc, ArrayRef<IdentifierInfo *> SelIdents, bool AtArgumentExpression); void CodeCompleteObjCClassMessage(Scope *S, ParsedType Receiver, ArrayRef<IdentifierInfo *> SelIdents, bool AtArgumentExpression, bool IsSuper = false); void CodeCompleteObjCInstanceMessage(Scope *S, Expr *Receiver, ArrayRef<IdentifierInfo *> SelIdents, bool AtArgumentExpression, ObjCInterfaceDecl *Super = nullptr); void CodeCompleteObjCForCollection(Scope *S, DeclGroupPtrTy IterationVar); void CodeCompleteObjCSelector(Scope *S, ArrayRef<IdentifierInfo *> SelIdents); void CodeCompleteObjCProtocolReferences( ArrayRef<IdentifierLocPair> Protocols); void CodeCompleteObjCProtocolDecl(Scope *S); void CodeCompleteObjCInterfaceDecl(Scope *S); void CodeCompleteObjCSuperclass(Scope *S, IdentifierInfo *ClassName, SourceLocation ClassNameLoc); void CodeCompleteObjCImplementationDecl(Scope *S); void CodeCompleteObjCInterfaceCategory(Scope *S, IdentifierInfo *ClassName, SourceLocation ClassNameLoc); void CodeCompleteObjCImplementationCategory(Scope *S, IdentifierInfo *ClassName, SourceLocation ClassNameLoc); void CodeCompleteObjCPropertyDefinition(Scope *S); void CodeCompleteObjCPropertySynthesizeIvar(Scope *S, IdentifierInfo *PropertyName); void CodeCompleteObjCMethodDecl(Scope *S, Optional<bool> IsInstanceMethod, ParsedType ReturnType); void CodeCompleteObjCMethodDeclSelector(Scope *S, bool IsInstanceMethod, bool AtParameterName, ParsedType ReturnType, ArrayRef<IdentifierInfo *> SelIdents); void CodeCompleteObjCClassPropertyRefExpr(Scope *S, IdentifierInfo &ClassName, SourceLocation ClassNameLoc, bool IsBaseExprStatement); void CodeCompletePreprocessorDirective(bool InConditional); void CodeCompleteInPreprocessorConditionalExclusion(Scope *S); void CodeCompletePreprocessorMacroName(bool IsDefinition); void CodeCompletePreprocessorExpression(); void CodeCompletePreprocessorMacroArgument(Scope *S, IdentifierInfo *Macro, MacroInfo *MacroInfo, unsigned Argument); void CodeCompleteIncludedFile(llvm::StringRef Dir, bool IsAngled); void CodeCompleteNaturalLanguage(); void CodeCompleteAvailabilityPlatformName(); void GatherGlobalCodeCompletions(CodeCompletionAllocator &Allocator, CodeCompletionTUInfo &CCTUInfo, SmallVectorImpl<CodeCompletionResult> &Results); //@} //===--------------------------------------------------------------------===// // Extra semantic analysis beyond the C type system public: SourceLocation getLocationOfStringLiteralByte(const StringLiteral *SL, unsigned ByteNo) const; private: void CheckArrayAccess(const Expr *BaseExpr, const Expr *IndexExpr, const ArraySubscriptExpr *ASE=nullptr, bool AllowOnePastEnd=true, bool IndexNegated=false); void CheckArrayAccess(const Expr *E); // Used to grab the relevant information from a FormatAttr and a // FunctionDeclaration. struct FormatStringInfo { unsigned FormatIdx; unsigned FirstDataArg; bool HasVAListArg; }; static bool getFormatStringInfo(const FormatAttr *Format, bool IsCXXMember, FormatStringInfo *FSI); bool CheckFunctionCall(FunctionDecl *FDecl, CallExpr *TheCall, const FunctionProtoType *Proto); bool CheckObjCMethodCall(ObjCMethodDecl *Method, SourceLocation loc, ArrayRef<const Expr *> Args); bool CheckPointerCall(NamedDecl *NDecl, CallExpr *TheCall, const FunctionProtoType *Proto); bool CheckOtherCall(CallExpr *TheCall, const FunctionProtoType *Proto); void CheckConstructorCall(FunctionDecl *FDecl, QualType ThisType, ArrayRef<const Expr *> Args, const FunctionProtoType *Proto, SourceLocation Loc); void CheckArgAlignment(SourceLocation Loc, NamedDecl *FDecl, StringRef ParamName, QualType ArgTy, QualType ParamTy); void checkCall(NamedDecl *FDecl, const FunctionProtoType *Proto, const Expr *ThisArg, ArrayRef<const Expr *> Args, bool IsMemberFunction, SourceLocation Loc, SourceRange Range, VariadicCallType CallType); void CheckSYCLKernelCall(FunctionDecl *CallerFunc, SourceRange CallLoc, ArrayRef<const Expr *> Args); bool CheckObjCString(Expr *Arg); ExprResult CheckOSLogFormatStringArg(Expr *Arg); ExprResult CheckBuiltinFunctionCall(FunctionDecl *FDecl, unsigned BuiltinID, CallExpr *TheCall); bool CheckTSBuiltinFunctionCall(const TargetInfo &TI, unsigned BuiltinID, CallExpr *TheCall); void checkFortifiedBuiltinMemoryFunction(FunctionDecl *FD, CallExpr *TheCall); bool CheckARMBuiltinExclusiveCall(unsigned BuiltinID, CallExpr *TheCall, unsigned MaxWidth); bool CheckNeonBuiltinFunctionCall(const TargetInfo &TI, unsigned BuiltinID, CallExpr *TheCall); bool CheckMVEBuiltinFunctionCall(unsigned BuiltinID, CallExpr *TheCall); bool CheckSVEBuiltinFunctionCall(unsigned BuiltinID, CallExpr *TheCall); bool CheckCDEBuiltinFunctionCall(const TargetInfo &TI, unsigned BuiltinID, CallExpr *TheCall); bool CheckARMCoprocessorImmediate(const TargetInfo &TI, const Expr *CoprocArg, bool WantCDE); bool CheckARMBuiltinFunctionCall(const TargetInfo &TI, unsigned BuiltinID, CallExpr *TheCall); bool CheckAArch64BuiltinFunctionCall(const TargetInfo &TI, unsigned BuiltinID, CallExpr *TheCall); bool CheckBPFBuiltinFunctionCall(unsigned BuiltinID, CallExpr *TheCall); bool CheckHexagonBuiltinFunctionCall(unsigned BuiltinID, CallExpr *TheCall); bool CheckHexagonBuiltinArgument(unsigned BuiltinID, CallExpr *TheCall); bool CheckMipsBuiltinFunctionCall(const TargetInfo &TI, unsigned BuiltinID, CallExpr *TheCall); bool CheckMipsBuiltinCpu(const TargetInfo &TI, unsigned BuiltinID, CallExpr *TheCall); bool CheckMipsBuiltinArgument(unsigned BuiltinID, CallExpr *TheCall); bool CheckSystemZBuiltinFunctionCall(unsigned BuiltinID, CallExpr *TheCall); bool CheckX86BuiltinRoundingOrSAE(unsigned BuiltinID, CallExpr *TheCall); bool CheckX86BuiltinGatherScatterScale(unsigned BuiltinID, CallExpr *TheCall); bool CheckX86BuiltinTileArguments(unsigned BuiltinID, CallExpr *TheCall); bool CheckX86BuiltinTileArgumentsRange(CallExpr *TheCall, ArrayRef<int> ArgNums); bool CheckX86BuiltinTileDuplicate(CallExpr *TheCall, ArrayRef<int> ArgNums); bool CheckX86BuiltinTileRangeAndDuplicate(CallExpr *TheCall, ArrayRef<int> ArgNums); bool CheckX86BuiltinFunctionCall(const TargetInfo &TI, unsigned BuiltinID, CallExpr *TheCall); bool CheckPPCBuiltinFunctionCall(const TargetInfo &TI, unsigned BuiltinID, CallExpr *TheCall); bool CheckAMDGCNBuiltinFunctionCall(unsigned BuiltinID, CallExpr *TheCall); bool CheckRISCVLMUL(CallExpr *TheCall, unsigned ArgNum); bool CheckRISCVBuiltinFunctionCall(const TargetInfo &TI, unsigned BuiltinID, CallExpr *TheCall); bool CheckIntelFPGARegBuiltinFunctionCall(unsigned BuiltinID, CallExpr *Call); bool CheckIntelFPGAMemBuiltinFunctionCall(CallExpr *Call); bool SemaBuiltinVAStart(unsigned BuiltinID, CallExpr *TheCall); bool SemaBuiltinVAStartARMMicrosoft(CallExpr *Call); bool SemaBuiltinUnorderedCompare(CallExpr *TheCall); bool SemaBuiltinFPClassification(CallExpr *TheCall, unsigned NumArgs); bool SemaBuiltinComplex(CallExpr *TheCall); bool SemaBuiltinVSX(CallExpr *TheCall); bool SemaBuiltinOSLogFormat(CallExpr *TheCall); bool SemaValueIsRunOfOnes(CallExpr *TheCall, unsigned ArgNum); public: // Used by C++ template instantiation. ExprResult SemaBuiltinShuffleVector(CallExpr *TheCall); ExprResult SemaConvertVectorExpr(Expr *E, TypeSourceInfo *TInfo, SourceLocation BuiltinLoc, SourceLocation RParenLoc); private: bool SemaBuiltinPrefetch(CallExpr *TheCall); bool SemaBuiltinAllocaWithAlign(CallExpr *TheCall); bool SemaBuiltinArithmeticFence(CallExpr *TheCall); bool SemaBuiltinAssume(CallExpr *TheCall); bool SemaBuiltinAssumeAligned(CallExpr *TheCall); bool SemaBuiltinLongjmp(CallExpr *TheCall); bool SemaBuiltinSetjmp(CallExpr *TheCall); ExprResult SemaBuiltinAtomicOverloaded(ExprResult TheCallResult); ExprResult SemaBuiltinNontemporalOverloaded(ExprResult TheCallResult); ExprResult SemaAtomicOpsOverloaded(ExprResult TheCallResult, AtomicExpr::AtomicOp Op); ExprResult SemaBuiltinOperatorNewDeleteOverloaded(ExprResult TheCallResult, bool IsDelete); bool SemaBuiltinConstantArg(CallExpr *TheCall, int ArgNum, llvm::APSInt &Result); bool SemaBuiltinConstantArgRange(CallExpr *TheCall, int ArgNum, int Low, int High, bool RangeIsError = true); bool SemaBuiltinConstantArgMultiple(CallExpr *TheCall, int ArgNum, unsigned Multiple); bool SemaBuiltinConstantArgPower2(CallExpr *TheCall, int ArgNum); bool SemaBuiltinConstantArgShiftedByte(CallExpr *TheCall, int ArgNum, unsigned ArgBits); bool SemaBuiltinConstantArgShiftedByteOrXXFF(CallExpr *TheCall, int ArgNum, unsigned ArgBits); bool SemaBuiltinARMSpecialReg(unsigned BuiltinID, CallExpr *TheCall, int ArgNum, unsigned ExpectedFieldNum, bool AllowName); bool SemaBuiltinARMMemoryTaggingCall(unsigned BuiltinID, CallExpr *TheCall); bool SemaBuiltinPPCMMACall(CallExpr *TheCall, unsigned BuiltinID, const char *TypeDesc); bool CheckPPCMMAType(QualType Type, SourceLocation TypeLoc); bool SemaBuiltinElementwiseMath(CallExpr *TheCall); bool SemaBuiltinElementwiseMathOneArg(CallExpr *TheCall); // Matrix builtin handling. ExprResult SemaBuiltinMatrixTranspose(CallExpr *TheCall, ExprResult CallResult); ExprResult SemaBuiltinMatrixColumnMajorLoad(CallExpr *TheCall, ExprResult CallResult); ExprResult SemaBuiltinMatrixColumnMajorStore(CallExpr *TheCall, ExprResult CallResult); public: enum FormatStringType { FST_Scanf, FST_Printf, FST_NSString, FST_Strftime, FST_Strfmon, FST_Kprintf, FST_FreeBSDKPrintf, FST_OSTrace, FST_OSLog, FST_Unknown }; static FormatStringType GetFormatStringType(const FormatAttr *Format); bool FormatStringHasSArg(const StringLiteral *FExpr); static bool GetFormatNSStringIdx(const FormatAttr *Format, unsigned &Idx); private: bool CheckFormatArguments(const FormatAttr *Format, ArrayRef<const Expr *> Args, bool IsCXXMember, VariadicCallType CallType, SourceLocation Loc, SourceRange Range, llvm::SmallBitVector &CheckedVarArgs); bool CheckFormatArguments(ArrayRef<const Expr *> Args, bool HasVAListArg, unsigned format_idx, unsigned firstDataArg, FormatStringType Type, VariadicCallType CallType, SourceLocation Loc, SourceRange range, llvm::SmallBitVector &CheckedVarArgs); void CheckAbsoluteValueFunction(const CallExpr *Call, const FunctionDecl *FDecl); void CheckMaxUnsignedZero(const CallExpr *Call, const FunctionDecl *FDecl); void CheckMemaccessArguments(const CallExpr *Call, unsigned BId, IdentifierInfo *FnName); void CheckStrlcpycatArguments(const CallExpr *Call, IdentifierInfo *FnName); void CheckStrncatArguments(const CallExpr *Call, IdentifierInfo *FnName); void CheckFreeArguments(const CallExpr *E); void CheckReturnValExpr(Expr *RetValExp, QualType lhsType, SourceLocation ReturnLoc, bool isObjCMethod = false, const AttrVec *Attrs = nullptr, const FunctionDecl *FD = nullptr); public: void CheckFloatComparison(SourceLocation Loc, Expr *LHS, Expr *RHS); private: void CheckImplicitConversions(Expr *E, SourceLocation CC = SourceLocation()); void CheckBoolLikeConversion(Expr *E, SourceLocation CC); void CheckForIntOverflow(Expr *E); void CheckUnsequencedOperations(const Expr *E); /// Perform semantic checks on a completed expression. This will either /// be a full-expression or a default argument expression. void CheckCompletedExpr(Expr *E, SourceLocation CheckLoc = SourceLocation(), bool IsConstexpr = false); void CheckBitFieldInitialization(SourceLocation InitLoc, FieldDecl *Field, Expr *Init); /// Check if there is a field shadowing. void CheckShadowInheritedFields(const SourceLocation &Loc, DeclarationName FieldName, const CXXRecordDecl *RD, bool DeclIsField = true); /// Check if the given expression contains 'break' or 'continue' /// statement that produces control flow different from GCC. void CheckBreakContinueBinding(Expr *E); /// Check whether receiver is mutable ObjC container which /// attempts to add itself into the container void CheckObjCCircularContainer(ObjCMessageExpr *Message); void CheckTCBEnforcement(const CallExpr *TheCall, const FunctionDecl *Callee); void AnalyzeDeleteExprMismatch(const CXXDeleteExpr *DE); void AnalyzeDeleteExprMismatch(FieldDecl *Field, SourceLocation DeleteLoc, bool DeleteWasArrayForm); public: /// Register a magic integral constant to be used as a type tag. void RegisterTypeTagForDatatype(const IdentifierInfo *ArgumentKind, uint64_t MagicValue, QualType Type, bool LayoutCompatible, bool MustBeNull); struct TypeTagData { TypeTagData() {} TypeTagData(QualType Type, bool LayoutCompatible, bool MustBeNull) : Type(Type), LayoutCompatible(LayoutCompatible), MustBeNull(MustBeNull) {} QualType Type; /// If true, \c Type should be compared with other expression's types for /// layout-compatibility. unsigned LayoutCompatible : 1; unsigned MustBeNull : 1; }; /// A pair of ArgumentKind identifier and magic value. This uniquely /// identifies the magic value. typedef std::pair<const IdentifierInfo *, uint64_t> TypeTagMagicValue; private: /// A map from magic value to type information. std::unique_ptr<llvm::DenseMap<TypeTagMagicValue, TypeTagData>> TypeTagForDatatypeMagicValues; /// Peform checks on a call of a function with argument_with_type_tag /// or pointer_with_type_tag attributes. void CheckArgumentWithTypeTag(const ArgumentWithTypeTagAttr *Attr, const ArrayRef<const Expr *> ExprArgs, SourceLocation CallSiteLoc); /// Check if we are taking the address of a packed field /// as this may be a problem if the pointer value is dereferenced. void CheckAddressOfPackedMember(Expr *rhs); /// The parser's current scope. /// /// The parser maintains this state here. Scope *CurScope; mutable IdentifierInfo *Ident_super; mutable IdentifierInfo *Ident___float128; /// Nullability type specifiers. IdentifierInfo *Ident__Nonnull = nullptr; IdentifierInfo *Ident__Nullable = nullptr; IdentifierInfo *Ident__Nullable_result = nullptr; IdentifierInfo *Ident__Null_unspecified = nullptr; IdentifierInfo *Ident_NSError = nullptr; /// The handler for the FileChanged preprocessor events. /// /// Used for diagnostics that implement custom semantic analysis for #include /// directives, like -Wpragma-pack. sema::SemaPPCallbacks *SemaPPCallbackHandler; protected: friend class Parser; friend class InitializationSequence; friend class ASTReader; friend class ASTDeclReader; friend class ASTWriter; public: /// Retrieve the keyword associated IdentifierInfo *getNullabilityKeyword(NullabilityKind nullability); /// The struct behind the CFErrorRef pointer. RecordDecl *CFError = nullptr; bool isCFError(RecordDecl *D); /// Retrieve the identifier "NSError". IdentifierInfo *getNSErrorIdent(); /// Retrieve the parser's current scope. /// /// This routine must only be used when it is certain that semantic analysis /// and the parser are in precisely the same context, which is not the case /// when, e.g., we are performing any kind of template instantiation. /// Therefore, the only safe places to use this scope are in the parser /// itself and in routines directly invoked from the parser and *never* from /// template substitution or instantiation. Scope *getCurScope() const { return CurScope; } void incrementMSManglingNumber() const { return CurScope->incrementMSManglingNumber(); } IdentifierInfo *getSuperIdentifier() const; IdentifierInfo *getFloat128Identifier() const; Decl *getObjCDeclContext() const; DeclContext *getCurLexicalContext() const { return OriginalLexicalContext ? OriginalLexicalContext : CurContext; } const DeclContext *getCurObjCLexicalContext() const { const DeclContext *DC = getCurLexicalContext(); // A category implicitly has the attribute of the interface. if (const ObjCCategoryDecl *CatD = dyn_cast<ObjCCategoryDecl>(DC)) DC = CatD->getClassInterface(); return DC; } /// Determine the number of levels of enclosing template parameters. This is /// only usable while parsing. Note that this does not include dependent /// contexts in which no template parameters have yet been declared, such as /// in a terse function template or generic lambda before the first 'auto' is /// encountered. unsigned getTemplateDepth(Scope *S) const; /// To be used for checking whether the arguments being passed to /// function exceeds the number of parameters expected for it. static bool TooManyArguments(size_t NumParams, size_t NumArgs, bool PartialOverloading = false) { // We check whether we're just after a comma in code-completion. if (NumArgs > 0 && PartialOverloading) return NumArgs + 1 > NumParams; // If so, we view as an extra argument. return NumArgs > NumParams; } // Emitting members of dllexported classes is delayed until the class // (including field initializers) is fully parsed. SmallVector<CXXRecordDecl*, 4> DelayedDllExportClasses; SmallVector<CXXMethodDecl*, 4> DelayedDllExportMemberFunctions; private: int ParsingClassDepth = 0; class SavePendingParsedClassStateRAII { public: SavePendingParsedClassStateRAII(Sema &S) : S(S) { swapSavedState(); } ~SavePendingParsedClassStateRAII() { assert(S.DelayedOverridingExceptionSpecChecks.empty() && "there shouldn't be any pending delayed exception spec checks"); assert(S.DelayedEquivalentExceptionSpecChecks.empty() && "there shouldn't be any pending delayed exception spec checks"); swapSavedState(); } private: Sema &S; decltype(DelayedOverridingExceptionSpecChecks) SavedOverridingExceptionSpecChecks; decltype(DelayedEquivalentExceptionSpecChecks) SavedEquivalentExceptionSpecChecks; void swapSavedState() { SavedOverridingExceptionSpecChecks.swap( S.DelayedOverridingExceptionSpecChecks); SavedEquivalentExceptionSpecChecks.swap( S.DelayedEquivalentExceptionSpecChecks); } }; /// Helper class that collects misaligned member designations and /// their location info for delayed diagnostics. struct MisalignedMember { Expr *E; RecordDecl *RD; ValueDecl *MD; CharUnits Alignment; MisalignedMember() : E(), RD(), MD(), Alignment() {} MisalignedMember(Expr *E, RecordDecl *RD, ValueDecl *MD, CharUnits Alignment) : E(E), RD(RD), MD(MD), Alignment(Alignment) {} explicit MisalignedMember(Expr *E) : MisalignedMember(E, nullptr, nullptr, CharUnits()) {} bool operator==(const MisalignedMember &m) { return this->E == m.E; } }; /// Small set of gathered accesses to potentially misaligned members /// due to the packed attribute. SmallVector<MisalignedMember, 4> MisalignedMembers; /// Adds an expression to the set of gathered misaligned members. void AddPotentialMisalignedMembers(Expr *E, RecordDecl *RD, ValueDecl *MD, CharUnits Alignment); public: /// Diagnoses the current set of gathered accesses. This typically /// happens at full expression level. The set is cleared after emitting the /// diagnostics. void DiagnoseMisalignedMembers(); /// This function checks if the expression is in the sef of potentially /// misaligned members and it is converted to some pointer type T with lower /// or equal alignment requirements. If so it removes it. This is used when /// we do not want to diagnose such misaligned access (e.g. in conversions to /// void*). void DiscardMisalignedMemberAddress(const Type *T, Expr *E); /// This function calls Action when it determines that E designates a /// misaligned member due to the packed attribute. This is used to emit /// local diagnostics like in reference binding. void RefersToMemberWithReducedAlignment( Expr *E, llvm::function_ref<void(Expr *, RecordDecl *, FieldDecl *, CharUnits)> Action); /// Describes the reason a calling convention specification was ignored, used /// for diagnostics. enum class CallingConventionIgnoredReason { ForThisTarget = 0, VariadicFunction, ConstructorDestructor, BuiltinFunction }; private: // We store SYCL Kernels here and handle separately -- which is a hack. // FIXME: It would be best to refactor this. llvm::SetVector<Decl *> SyclDeviceDecls; // SYCL integration header instance for current compilation unit this Sema // is associated with. std::unique_ptr<SYCLIntegrationHeader> SyclIntHeader; std::unique_ptr<SYCLIntegrationFooter> SyclIntFooter; // We need to store the list of the sycl_kernel functions and their associated // generated OpenCL Kernels so we can go back and re-name these after the // fact. llvm::SmallVector<std::pair<const FunctionDecl *, FunctionDecl *>> SyclKernelsToOpenCLKernels; // Used to suppress diagnostics during kernel construction, since these were // already emitted earlier. Diagnosing during Kernel emissions also skips the // useful notes that shows where the kernel was called. bool DiagnosingSYCLKernel = false; public: void addSyclOpenCLKernel(const FunctionDecl *SyclKernel, FunctionDecl *OpenCLKernel) { SyclKernelsToOpenCLKernels.emplace_back(SyclKernel, OpenCLKernel); } void addSyclDeviceDecl(Decl *d) { SyclDeviceDecls.insert(d); } llvm::SetVector<Decl *> &syclDeviceDecls() { return SyclDeviceDecls; } /// Lazily creates and returns SYCL integration header instance. SYCLIntegrationHeader &getSyclIntegrationHeader() { if (SyclIntHeader == nullptr) SyclIntHeader = std::make_unique<SYCLIntegrationHeader>(*this); return *SyclIntHeader.get(); } SYCLIntegrationFooter &getSyclIntegrationFooter() { if (SyclIntFooter == nullptr) SyclIntFooter = std::make_unique<SYCLIntegrationFooter>(*this); return *SyclIntFooter.get(); } void addSyclVarDecl(VarDecl *VD) { if (LangOpts.SYCLIsDevice && !LangOpts.SYCLIntFooter.empty()) getSyclIntegrationFooter().addVarDecl(VD); } enum SYCLRestrictKind { KernelGlobalVariable, KernelRTTI, KernelNonConstStaticDataVariable, KernelCallVirtualFunction, KernelUseExceptions, KernelCallRecursiveFunction, KernelCallFunctionPointer, KernelAllocateStorage, KernelUseAssembly, KernelCallDllimportFunction, KernelCallVariadicFunction, KernelCallUndefinedFunction, KernelConstStaticVariable }; bool isKnownGoodSYCLDecl(const Decl *D); void checkSYCLDeviceVarDecl(VarDecl *Var); void copySYCLKernelAttrs(const CXXRecordDecl *KernelObj); void ConstructOpenCLKernel(FunctionDecl *KernelCallerFunc, MangleContext &MC); void SetSYCLKernelNames(); void MarkDevices(); /// Get the number of fields or captures within the parsed type. ExprResult ActOnSYCLBuiltinNumFieldsExpr(ParsedType PT); ExprResult BuildSYCLBuiltinNumFieldsExpr(SourceLocation Loc, QualType SourceTy); /// Get a value based on the type of the given field number so that callers /// can wrap it in a decltype() to get the actual type of the field. ExprResult ActOnSYCLBuiltinFieldTypeExpr(ParsedType PT, Expr *Idx); ExprResult BuildSYCLBuiltinFieldTypeExpr(SourceLocation Loc, QualType SourceTy, Expr *Idx); /// Get the number of base classes within the parsed type. ExprResult ActOnSYCLBuiltinNumBasesExpr(ParsedType PT); ExprResult BuildSYCLBuiltinNumBasesExpr(SourceLocation Loc, QualType SourceTy); /// Get a value based on the type of the given base number so that callers /// can wrap it in a decltype() to get the actual type of the base class. ExprResult ActOnSYCLBuiltinBaseTypeExpr(ParsedType PT, Expr *Idx); ExprResult BuildSYCLBuiltinBaseTypeExpr(SourceLocation Loc, QualType SourceTy, Expr *Idx); /// Emit a diagnostic about the given attribute having a deprecated name, and /// also emit a fixit hint to generate the new attribute name. void DiagnoseDeprecatedAttribute(const ParsedAttr &A, StringRef NewScope, StringRef NewName); /// Diagnoses an attribute in the 'intelfpga' namespace and suggests using /// the attribute in the 'intel' namespace instead. void CheckDeprecatedSYCLAttributeSpelling(const ParsedAttr &A, StringRef NewName = ""); /// Creates a SemaDiagnosticBuilder that emits the diagnostic if the current /// context is "used as device code". /// /// - If CurLexicalContext is a kernel function or it is known that the /// function will be emitted for the device, emits the diagnostics /// immediately. /// - If CurLexicalContext is a function and we are compiling /// for the device, but we don't know that this function will be codegen'ed /// for devive yet, creates a diagnostic which is emitted if and when we /// realize that the function will be codegen'ed. /// /// Example usage: /// /// Diagnose __float128 type usage only from SYCL device code if the current /// target doesn't support it /// if (!S.Context.getTargetInfo().hasFloat128Type() && /// S.getLangOpts().SYCLIsDevice) /// SYCLDiagIfDeviceCode(Loc, diag::err_type_unsupported) << "__float128"; SemaDiagnosticBuilder SYCLDiagIfDeviceCode( SourceLocation Loc, unsigned DiagID, DeviceDiagnosticReason Reason = DeviceDiagnosticReason::Sycl | DeviceDiagnosticReason::Esimd); /// Check whether we're allowed to call Callee from the current context. /// /// - If the call is never allowed in a semantically-correct program /// emits an error and returns false. /// /// - If the call is allowed in semantically-correct programs, but only if /// it's never codegen'ed, creates a deferred diagnostic to be emitted if /// and when the caller is codegen'ed, and returns true. /// /// - Otherwise, returns true without emitting any diagnostics. /// /// Adds Callee to DeviceCallGraph if we don't know if its caller will be /// codegen'ed yet. bool checkSYCLDeviceFunction(SourceLocation Loc, FunctionDecl *Callee); /// Finishes analysis of the deferred functions calls that may be not /// properly declared for device compilation. void finalizeSYCLDelayedAnalysis(const FunctionDecl *Caller, const FunctionDecl *Callee, SourceLocation Loc, DeviceDiagnosticReason Reason); /// Tells whether given variable is a SYCL explicit SIMD extension's "private /// global" variable - global variable in the private address space. bool isSYCLEsimdPrivateGlobal(VarDecl *VDecl) { return getLangOpts().SYCLIsDevice && VDecl->hasAttr<SYCLSimdAttr>() && VDecl->hasGlobalStorage() && (VDecl->getType().getAddressSpace() == LangAS::sycl_private); } }; inline Expr *checkMaxWorkSizeAttrExpr(Sema &S, const AttributeCommonInfo &CI, Expr *E) { assert(E && "Attribute must have an argument."); if (!E->isInstantiationDependent()) { llvm::APSInt ArgVal; ExprResult ICE = S.VerifyIntegerConstantExpression(E, &ArgVal); if (ICE.isInvalid()) return nullptr; E = ICE.get(); if (ArgVal.isNegative()) { S.Diag(E->getExprLoc(), diag::warn_attribute_requires_non_negative_integer_argument) << E->getType() << S.Context.UnsignedLongLongTy << E->getSourceRange(); return E; } unsigned Val = ArgVal.getZExtValue(); if (Val == 0) { S.Diag(E->getExprLoc(), diag::err_attribute_argument_is_zero) << CI << E->getSourceRange(); return nullptr; } } return E; } template <typename WorkGroupAttrType> void Sema::addIntelTripleArgAttr(Decl *D, const AttributeCommonInfo &CI, Expr *XDimExpr, Expr *YDimExpr, Expr *ZDimExpr) { assert((XDimExpr && YDimExpr && ZDimExpr) && "argument has unexpected null value"); // Accept template arguments for now as they depend on something else. // We'll get to check them when they eventually get instantiated. if (!XDimExpr->isValueDependent() && !YDimExpr->isValueDependent() && !ZDimExpr->isValueDependent()) { // Save ConstantExpr in semantic attribute XDimExpr = checkMaxWorkSizeAttrExpr(*this, CI, XDimExpr); YDimExpr = checkMaxWorkSizeAttrExpr(*this, CI, YDimExpr); ZDimExpr = checkMaxWorkSizeAttrExpr(*this, CI, ZDimExpr); if (!XDimExpr || !YDimExpr || !ZDimExpr) return; } D->addAttr(::new (Context) WorkGroupAttrType(Context, CI, XDimExpr, YDimExpr, ZDimExpr)); } /// RAII object that enters a new expression evaluation context. class EnterExpressionEvaluationContext { Sema &Actions; bool Entered = true; public: EnterExpressionEvaluationContext( Sema &Actions, Sema::ExpressionEvaluationContext NewContext, Decl *LambdaContextDecl = nullptr, Sema::ExpressionEvaluationContextRecord::ExpressionKind ExprContext = Sema::ExpressionEvaluationContextRecord::EK_Other, bool ShouldEnter = true) : Actions(Actions), Entered(ShouldEnter) { if (Entered) Actions.PushExpressionEvaluationContext(NewContext, LambdaContextDecl, ExprContext); } EnterExpressionEvaluationContext( Sema &Actions, Sema::ExpressionEvaluationContext NewContext, Sema::ReuseLambdaContextDecl_t, Sema::ExpressionEvaluationContextRecord::ExpressionKind ExprContext = Sema::ExpressionEvaluationContextRecord::EK_Other) : Actions(Actions) { Actions.PushExpressionEvaluationContext( NewContext, Sema::ReuseLambdaContextDecl, ExprContext); } enum InitListTag { InitList }; EnterExpressionEvaluationContext(Sema &Actions, InitListTag, bool ShouldEnter = true) : Actions(Actions), Entered(false) { // In C++11 onwards, narrowing checks are performed on the contents of // braced-init-lists, even when they occur within unevaluated operands. // Therefore we still need to instantiate constexpr functions used in such // a context. if (ShouldEnter && Actions.isUnevaluatedContext() && Actions.getLangOpts().CPlusPlus11) { Actions.PushExpressionEvaluationContext( Sema::ExpressionEvaluationContext::UnevaluatedList); Entered = true; } } ~EnterExpressionEvaluationContext() { if (Entered) Actions.PopExpressionEvaluationContext(); } }; DeductionFailureInfo MakeDeductionFailureInfo(ASTContext &Context, Sema::TemplateDeductionResult TDK, sema::TemplateDeductionInfo &Info); /// Contains a late templated function. /// Will be parsed at the end of the translation unit, used by Sema & Parser. struct LateParsedTemplate { CachedTokens Toks; /// The template function declaration to be late parsed. Decl *D; }; template <> void Sema::PragmaStack<Sema::AlignPackInfo>::Act(SourceLocation PragmaLocation, PragmaMsStackAction Action, llvm::StringRef StackSlotLabel, AlignPackInfo Value); } // end namespace clang namespace llvm { // Hash a FunctionDeclAndLoc by looking at both its FunctionDecl and its // SourceLocation. template <> struct DenseMapInfo<clang::Sema::FunctionDeclAndLoc> { using FunctionDeclAndLoc = clang::Sema::FunctionDeclAndLoc; using FDBaseInfo = DenseMapInfo<clang::CanonicalDeclPtr<clang::FunctionDecl>>; static FunctionDeclAndLoc getEmptyKey() { return {FDBaseInfo::getEmptyKey(), clang::SourceLocation()}; } static FunctionDeclAndLoc getTombstoneKey() { return {FDBaseInfo::getTombstoneKey(), clang::SourceLocation()}; } static unsigned getHashValue(const FunctionDeclAndLoc &FDL) { return hash_combine(FDBaseInfo::getHashValue(FDL.FD), FDL.Loc.getHashValue()); } static bool isEqual(const FunctionDeclAndLoc &LHS, const FunctionDeclAndLoc &RHS) { return LHS.FD == RHS.FD && LHS.Loc == RHS.Loc; } }; } // namespace llvm #endif

3d25pt.c

/* * Order-2, 3D 25 point stencil * Adapted from PLUTO and Pochoir test bench * * Tareq Malas */ #include <stdio.h> #include <stdlib.h> #include <sys/time.h> #ifdef LIKWID_PERFMON #include <likwid.h> #endif #include "print_utils.h" #define TESTS 2 #define MAX(a,b) ((a) > (b) ? a : b) #define MIN(a,b) ((a) < (b) ? a : b) #ifndef min #define min(x,y) ((x) < (y)? (x) : (y)) #endif /* Subtract the `struct timeval' values X and Y, * storing the result in RESULT. * * Return 1 if the difference is negative, otherwise 0. */ int timeval_subtract(struct timeval *result, struct timeval *x, struct timeval *y) { /* Perform the carry for the later subtraction by updating y. */ if (x->tv_usec < y->tv_usec) { int nsec = (y->tv_usec - x->tv_usec) / 1000000 + 1; y->tv_usec -= 1000000 * nsec; y->tv_sec += nsec; } if (x->tv_usec - y->tv_usec > 1000000) { int nsec = (x->tv_usec - y->tv_usec) / 1000000; y->tv_usec += 1000000 * nsec; y->tv_sec -= nsec; } /* Compute the time remaining to wait. * tv_usec is certainly positive. */ result->tv_sec = x->tv_sec - y->tv_sec; result->tv_usec = x->tv_usec - y->tv_usec; /* Return 1 if result is negative. */ return x->tv_sec < y->tv_sec; } int main(int argc, char *argv[]) { int t, i, j, k, test; int Nx, Ny, Nz, Nt; if (argc > 3) { Nx = atoi(argv[1])+8; Ny = atoi(argv[2])+8; Nz = atoi(argv[3])+8; } if (argc > 4) Nt = atoi(argv[4]); double ****A = (double ****) malloc(sizeof(double***)*2); double ***roc2 = (double ***) malloc(sizeof(double**)); A[0] = (double ***) malloc(sizeof(double**)*Nz); A[1] = (double ***) malloc(sizeof(double**)*Nz); roc2 = (double ***) malloc(sizeof(double**)*Nz); for(i=0; i<Nz; i++){ A[0][i] = (double**) malloc(sizeof(double*)*Ny); A[1][i] = (double**) malloc(sizeof(double*)*Ny); roc2[i] = (double**) malloc(sizeof(double*)*Ny); for(j=0;j<Ny;j++){ A[0][i][j] = (double*) malloc(sizeof(double)*Nx); A[1][i][j] = (double*) malloc(sizeof(double)*Nx); roc2[i][j] = (double*) malloc(sizeof(double)*Nx); } } // tile size information, including extra element to decide the list length int *tile_size = (int*) malloc(sizeof(int)); tile_size[0] = -1; // The list is modified here before source-to-source transformations tile_size = (int*) realloc((void *)tile_size, sizeof(int)*5); tile_size[0] = 4; tile_size[1] = 4; tile_size[2] = 4; tile_size[3] = 256; tile_size[4] = -1; // for timekeeping int ts_return = -1; struct timeval start, end, result; double tdiff = 0.0, min_tdiff=1.e100; const int BASE = 1024; // initialize variables // srand(42); for (i = 1; i < Nz; i++) { for (j = 1; j < Ny; j++) { for (k = 1; k < Nx; k++) { A[0][i][j][k] = 1.0 * (rand() % BASE); roc2[i][j][k] = 2.0 * (rand() % BASE); } } } #ifdef LIKWID_PERFMON LIKWID_MARKER_INIT; #pragma omp parallel { LIKWID_MARKER_THREADINIT; #pragma omp barrier LIKWID_MARKER_START("calc"); } #endif int num_threads = 1; #if defined(_OPENMP) num_threads = omp_get_max_threads(); #endif const double coef0 = -0.28472; const double coef1 = 0.16000; const double coef2 = -0.02000; const double coef3 = 0.00254; const double coef4 = -0.00018; for(test=0; test<TESTS; test++){ gettimeofday(&start, 0); // serial execution - Addition: 6 && Multiplication: 2 #pragma scop for (t = 0; t < Nt; t++) { for (i = 4; i < Nz-4; i++) { for (j = 4; j < Ny-4; j++) { for (k = 4; k < Nx-4; k++) { A[(t+1)%2][i][j][k] = 2.0*A[t%2][i][j][k] - A[(t+1)%2][i][j][k] + roc2[i][j][k]*( coef0* A[t%2][i ][j ][k ] + coef1*(A[t%2][i-1][j ][k ] + A[t%2][i+1][j ][k ] + A[t%2][i ][j-1][k ] + A[t%2][i ][j+1][k ] + A[t%2][i ][j ][k-1] + A[t%2][i ][j ][k+1]) + coef2*(A[t%2][i-2][j ][k ] + A[t%2][i+2][j ][k ] + A[t%2][i ][j-2][k ] + A[t%2][i ][j+2][k ] + A[t%2][i ][j ][k-2] + A[t%2][i ][j ][k+2]) + coef3*(A[t%2][i-3][j ][k ] + A[t%2][i+3][j ][k ] + A[t%2][i ][j-3][k ] + A[t%2][i ][j+3][k ] + A[t%2][i ][j ][k-3] + A[t%2][i ][j ][k+3]) + coef4*(A[t%2][i-4][j ][k ] + A[t%2][i+4][j ][k ] + A[t%2][i ][j-4][k ] + A[t%2][i ][j+4][k ] + A[t%2][i ][j ][k-4] + A[t%2][i ][j ][k+4]) ); } } } } #pragma endscop gettimeofday(&end, 0); ts_return = timeval_subtract(&result, &end, &start); tdiff = (double) (result.tv_sec + result.tv_usec * 1.0e-6); min_tdiff = MIN(min_tdiff, tdiff); printf("Rank 0 TEST# %d time: %f\n", test, tdiff); } PRINT_RESULTS(4, "constant") #ifdef LIKWID_PERFMON #pragma omp parallel { LIKWID_MARKER_STOP("calc"); } LIKWID_MARKER_CLOSE; #endif // Free allocated arrays for(i=0; i<Nz; i++){ for(j=0;j<Ny;j++){ free(A[0][i][j]); free(A[1][i][j]); free(roc2[i][j]); } free(A[0][i]); free(A[1][i]); free(roc2[i]); } free(A[0]); free(A[1]); free(roc2); return 0; }

wave_billiard.c

/*********************************************************************************/ /* */ /* Animation of wave equation in a planar domain */ /* */ /* N. Berglund, december 2012, may 2021 */ /* */ /* UPDATE 24/04: distinction between damping and "elasticity" parameters */ /* UPDATE 27/04: new billiard shapes, bug in color scheme fixed */ /* UPDATE 28/04: code made more efficient, with help of Marco Mancini */ /* */ /* Feel free to reuse, but if doing so it would be nice to drop a */ /* line to nils.berglund@univ-orleans.fr - Thanks! */ /* */ /* compile with */ /* gcc -o wave_billiard wave_billiard.c */ /* -L/usr/X11R6/lib -ltiff -lm -lGL -lGLU -lX11 -lXmu -lglut -O3 -fopenmp */ /* */ /* OMP acceleration may be more effective after executing */ /* export OMP_NUM_THREADS=2 in the shell before running the program */ /* */ /* To make a video, set MOVIE to 1 and create subfolder tif_wave */ /* It may be possible to increase parameter PAUSE */ /* */ /* create movie using */ /* ffmpeg -i wave.%05d.tif -vcodec libx264 wave.mp4 */ /* */ /*********************************************************************************/ /*********************************************************************************/ /* */ /* NB: The algorithm used to simulate the wave equation is highly paralellizable */ /* One could make it much faster by using a GPU */ /* */ /*********************************************************************************/ #include <math.h> #include <string.h> #include <GL/glut.h> #include <GL/glu.h> #include <unistd.h> #include <sys/types.h> #include <tiffio.h> /* Sam Leffler's libtiff library. */ #include <omp.h> #define MOVIE 0 /* set to 1 to generate movie */ #define DOUBLE_MOVIE 0 /* set to 1 to produce movies for wave height and energy simultaneously */ /* General geometrical parameters */ #define WINWIDTH 1280 /* window width */ #define WINHEIGHT 720 /* window height */ #define NX 1280 /* number of grid points on x axis */ #define NY 720 /* number of grid points on y axis */ #define XMIN -2.0 #define XMAX 2.0 /* x interval */ #define YMIN -1.125 #define YMAX 1.125 /* y interval for 9/16 aspect ratio */ #define JULIA_SCALE 1.0 /* scaling for Julia sets */ /* Choice of the billiard table */ #define B_DOMAIN 38 /* choice of domain shape, see list in global_pdes.c */ #define CIRCLE_PATTERN 2 /* pattern of circles or polygons, see list in global_pdes.c */ #define P_PERCOL 0.25 /* probability of having a circle in C_RAND_PERCOL arrangement */ #define NPOISSON 300 /* number of points for Poisson C_RAND_POISSON arrangement */ #define RANDOM_POLY_ANGLE 1 /* set to 1 to randomize angle of polygons */ #define LAMBDA 0.9 /* parameter controlling the dimensions of domain */ #define MU 0.03 /* parameter controlling the dimensions of domain */ #define NPOLY 6 /* number of sides of polygon */ #define APOLY 2.0 /* angle by which to turn polygon, in units of Pi/2 */ #define MDEPTH 5 /* depth of computation of Menger gasket */ #define MRATIO 3 /* ratio defining Menger gasket */ #define MANDELLEVEL 1000 /* iteration level for Mandelbrot set */ #define MANDELLIMIT 10.0 /* limit value for approximation of Mandelbrot set */ #define FOCI 1 /* set to 1 to draw focal points of ellipse */ #define NGRIDX 10 /* number of grid point for grid of disks */ #define NGRIDY 12 /* number of grid point for grid of disks */ // #define NGRIDX 16 /* number of grid point for grid of disks */ // #define NGRIDY 20 /* number of grid point for grid of disks */ #define X_SHOOTER -0.2 #define Y_SHOOTER -0.6 #define X_TARGET 0.4 #define Y_TARGET 0.7 /* shooter and target positions in laser fight */ #define ISO_XSHIFT_LEFT -2.9 #define ISO_XSHIFT_RIGHT 1.4 #define ISO_YSHIFT_LEFT -0.15 #define ISO_YSHIFT_RIGHT -0.15 #define ISO_SCALE 0.5 /* coordinates for isospectral billiards */ /* You can add more billiard tables by adapting the functions */ /* xy_in_billiard and draw_billiard below */ /* Physical parameters of wave equation */ #define TWOSPEEDS 0 /* set to 1 to replace hardcore boundary by medium with different speed */ #define OSCILLATE_LEFT 0 /* set to 1 to add oscilating boundary condition on the left */ #define OSCILLATE_TOPBOT 0 /* set to 1 to enforce a planar wave on top and bottom boundary */ #define OMEGA 0.002 /* frequency of periodic excitation */ #define AMPLITUDE 1.0 /* amplitude of periodic excitation */ #define COURANT 0.02 /* Courant number */ #define COURANTB 0.01 /* Courant number in medium B */ #define GAMMA 0.0 /* damping factor in wave equation */ // #define GAMMAB 5.0e-3 /* damping factor in wave equation */ // #define GAMMAB 1.0e-2 /* damping factor in wave equation */ #define GAMMAB 1.0e-6 /* damping factor in wave equation */ #define GAMMA_SIDES 1.0e-4 /* damping factor on boundary */ #define GAMMA_TOPBOT 1.0e-7 /* damping factor on boundary */ #define KAPPA 0.0 /* "elasticity" term enforcing oscillations */ #define KAPPA_SIDES 5.0e-4 /* "elasticity" term on absorbing boundary */ #define KAPPA_TOPBOT 0.0 /* "elasticity" term on absorbing boundary */ /* The Courant number is given by c*DT/DX, where DT is the time step and DX the lattice spacing */ /* The physical damping coefficient is given by GAMMA/(DT)^2 */ /* Increasing COURANT speeds up the simulation, but decreases accuracy */ /* For similar wave forms, COURANT^2*GAMMA should be kept constant */ /* Boundary conditions, see list in global_pdes.c */ #define B_COND 3 /* Parameters for length and speed of simulation */ // #define NSTEPS 500 /* number of frames of movie */ #define NSTEPS 1500 /* number of frames of movie */ #define NVID 40 /* number of iterations between images displayed on screen */ #define NSEG 100 /* number of segments of boundary */ #define INITIAL_TIME 0 /* time after which to start saving frames */ #define BOUNDARY_WIDTH 2 /* width of billiard boundary */ #define PAUSE 1000 /* number of frames after which to pause */ #define PSLEEP 1 /* sleep time during pause */ #define SLEEP1 1 /* initial sleeping time */ #define SLEEP2 1 /* final sleeping time */ #define MID_FRAMES 20 /* number of still frames between parts of two-part movie */ #define END_FRAMES 50 /* number of still frames at end of movie */ /* Parameters of initial condition */ #define INITIAL_AMP 0.75 /* amplitude of initial condition */ // #define INITIAL_VARIANCE 0.0003 /* variance of initial condition */ // #define INITIAL_WAVELENGTH 0.015 /* wavelength of initial condition */ #define INITIAL_VARIANCE 0.0003 /* variance of initial condition */ #define INITIAL_WAVELENGTH 0.015 /* wavelength of initial condition */ /* Plot type, see list in global_pdes.c */ #define PLOT 1 #define PLOT_B 0 /* plot type for second movie */ /* Color schemes */ #define COLOR_PALETTE 14 /* Color palette, see list in global_pdes.c */ #define BLACK 1 /* background */ #define COLOR_SCHEME 3 /* choice of color scheme, see list in global_pdes.c */ #define SCALE 0 /* set to 1 to adjust color scheme to variance of field */ // #define SLOPE 0.25 /* sensitivity of color on wave amplitude */ #define SLOPE 1.0 /* sensitivity of color on wave amplitude */ #define ATTENUATION 0.0 /* exponential attenuation coefficient of contrast with time */ // #define E_SCALE 150.0 /* scaling factor for energy representation */ #define E_SCALE 100.0 /* scaling factor for energy representation */ #define COLORHUE 260 /* initial hue of water color for scheme C_LUM */ #define COLORDRIFT 0.0 /* how much the color hue drifts during the whole simulation */ #define LUMMEAN 0.5 /* amplitude of luminosity variation for scheme C_LUM */ #define LUMAMP 0.3 /* amplitude of luminosity variation for scheme C_LUM */ #define HUEMEAN 180.0 /* mean value of hue for color scheme C_HUE */ // #define HUEMEAN 210.0 /* mean value of hue for color scheme C_HUE */ #define HUEAMP -180.0 /* amplitude of variation of hue for color scheme C_HUE */ // #define HUEAMP -180.0 /* amplitude of variation of hue for color scheme C_HUE */ #define DRAW_COLOR_SCHEME 1 /* set to 1 to plot the color scheme */ #define COLORBAR_RANGE 2.0 /* scale of color scheme bar */ #define COLORBAR_RANGE_B 12.0 /* scale of color scheme bar for 2nd part */ #define ROTATE_COLOR_SCHEME 1 /* set to 1 to draw color scheme horizontally */ #define SAVE_TIME_SERIES 0 /* set to 1 to save wave time series at a point */ /* For debugging purposes only */ #define FLOOR 0 /* set to 1 to limit wave amplitude to VMAX */ #define VMAX 10.0 /* max value of wave amplitude */ #include "global_pdes.c" /* constants and global variables */ #include "sub_wave.c" /* common functions for wave_billiard, heat and schrodinger */ #include "wave_common.c" /* common functions for wave_billiard, wave_comparison, etc */ FILE *time_series_left, *time_series_right; double courant2, courantb2; /* Courant parameters squared */ /*********************/ /* animation part */ /*********************/ void evolve_wave_half_old(double *phi_in[NX], double *psi_in[NX], double *phi_out[NX], double *psi_out[NX], short int *xy_in[NX]) /* time step of field evolution */ /* phi is value of field at time t, psi at time t-1 */ { int i, j, iplus, iminus, jplus, jminus; double delta, x, y, c, cc, gamma; static long time = 0; time++; // c = COURANT; // cc = courant2; #pragma omp parallel for private(i,j,iplus,iminus,jplus,jminus,delta,x,y,c,cc,gamma) for (i=0; i<NX; i++){ for (j=0; j<NY; j++){ // if (xy_in[i][j]) // { // c = COURANT; // cc = courant2; // gamma = GAMMA; // } if (xy_in[i][j] != 0) { c = COURANT; cc = courant2; if (xy_in[i][j] == 1) gamma = GAMMA; else gamma = GAMMAB; } else if (TWOSPEEDS) { c = COURANTB; cc = courantb2; gamma = GAMMAB; } if ((TWOSPEEDS)||(xy_in[i][j] != 0)){ /* discretized Laplacian for various boundary conditions */ if ((B_COND == BC_DIRICHLET)||(B_COND == BC_ABSORBING)) { iplus = (i+1); if (iplus == NX) iplus = NX-1; iminus = (i-1); if (iminus == -1) iminus = 0; jplus = (j+1); if (jplus == NY) jplus = NY-1; jminus = (j-1); if (jminus == -1) jminus = 0; } else if (B_COND == BC_PERIODIC) { iplus = (i+1) % NX; iminus = (i-1) % NX; if (iminus < 0) iminus += NX; jplus = (j+1) % NY; jminus = (j-1) % NY; if (jminus < 0) jminus += NY; } else if (B_COND == BC_VPER_HABS) { iplus = (i+1); if (iplus == NX) iplus = NX-1; iminus = (i-1); if (iminus == -1) iminus = 0; jplus = (j+1) % NY; jminus = (j-1) % NY; if (jminus < 0) jminus += NY; } /* imposing linear wave on top and bottom by making Laplacian 1d */ if (OSCILLATE_TOPBOT) { if (j == NY-1) jminus = NY-1; else if (j == 0) jplus = 0; } delta = phi_in[iplus][j] + phi_in[iminus][j] + phi_in[i][jplus] + phi_in[i][jminus] - 4.0*phi_in[i][j]; x = phi_in[i][j]; y = psi_in[i][j]; /* evolve phi */ if ((B_COND == BC_PERIODIC)||(B_COND == BC_DIRICHLET)) phi_out[i][j] = -y + 2*x + cc*delta - KAPPA*x - gamma*(x-y); else if (B_COND == BC_ABSORBING) { if ((i>0)&&(i<NX-1)&&(j>0)&&(j<NY-1)) phi_out[i][j] = -y + 2*x + cc*delta - KAPPA*x - gamma*(x-y); /* upper border */ else if (j==NY-1) phi_out[i][j] = x - c*(x - phi_in[i][NY-2]) - KAPPA_TOPBOT*x - GAMMA_TOPBOT*(x-y); /* lower border */ else if (j==0) phi_out[i][j] = x - c*(x - phi_in[i][1]) - KAPPA_TOPBOT*x - GAMMA_TOPBOT*(x-y); /* right border */ if (i==NX-1) phi_out[i][j] = x - c*(x - phi_in[NX-2][j]) - KAPPA_SIDES*x - GAMMA_SIDES*(x-y); /* left border */ else if (i==0) phi_out[i][j] = x - c*(x - phi_in[1][j]) - KAPPA_SIDES*x - GAMMA_SIDES*(x-y); } else if (B_COND == BC_VPER_HABS) { if ((i>0)&&(i<NX-1)) phi_out[i][j] = -y + 2*x + cc*delta - KAPPA*x - gamma*(x-y); /* right border */ else if (i==NX-1) phi_out[i][j] = x - c*(x - phi_in[NX-2][j]) - KAPPA_SIDES*x - GAMMA_SIDES*(x-y); /* left border */ else if (i==0) phi_out[i][j] = x - c*(x - phi_in[1][j]) - KAPPA_SIDES*x - GAMMA_SIDES*(x-y); } psi_out[i][j] = x; /* add oscillating boundary condition on the left */ if ((i == 0)&&(OSCILLATE_LEFT)) phi_out[i][j] = AMPLITUDE*cos((double)time*OMEGA); // psi_out[i][j] = x; if (FLOOR) { if (phi_out[i][j] > VMAX) phi_out[i][j] = VMAX; if (phi_out[i][j] < -VMAX) phi_out[i][j] = -VMAX; if (psi_out[i][j] > VMAX) psi_out[i][j] = VMAX; if (psi_out[i][j] < -VMAX) psi_out[i][j] = -VMAX; } } } } // printf("phi(0,0) = %.3lg, psi(0,0) = %.3lg\n", phi[NX/2][NY/2], psi[NX/2][NY/2]); } void evolve_wave_half(double *phi_in[NX], double *psi_in[NX], double *phi_out[NX], double *psi_out[NX], short int *xy_in[NX]) /* time step of field evolution */ /* phi is value of field at time t, psi at time t-1 */ /* this version of the function has been rewritten in order to minimize the number of if-branches */ { int i, j, iplus, iminus, jplus, jminus; double delta, x, y, c, cc, gamma; static long time = 0; static double tc[NX][NY], tcc[NX][NY], tgamma[NX][NY]; static short int first = 1; time++; /* initialize tables with wave speeds and dissipation */ if (first) { for (i=0; i<NX; i++){ for (j=0; j<NY; j++){ if (xy_in[i][j] != 0) { tc[i][j] = COURANT; tcc[i][j] = courant2; if (xy_in[i][j] == 1) tgamma[i][j] = GAMMA; else tgamma[i][j] = GAMMAB; } else if (TWOSPEEDS) { tc[i][j] = COURANTB; tcc[i][j] = courantb2; tgamma[i][j] = GAMMAB; } } } first = 0; } #pragma omp parallel for private(i,j,iplus,iminus,jplus,jminus,delta,x,y) /* evolution in the bulk */ for (i=1; i<NX-1; i++){ for (j=1; j<NY-1; j++){ if ((TWOSPEEDS)||(xy_in[i][j] != 0)){ x = phi_in[i][j]; y = psi_in[i][j]; /* discretized Laplacian */ delta = phi_in[i+1][j] + phi_in[i-1][j] + phi_in[i][j+1] + phi_in[i][j-1] - 4.0*x; /* evolve phi */ phi_out[i][j] = -y + 2*x + tcc[i][j]*delta - KAPPA*x - tgamma[i][j]*(x-y); psi_out[i][j] = x; } } } /* left boundary */ if (OSCILLATE_LEFT) for (j=1; j<NY-1; j++) phi_out[0][j] = AMPLITUDE*cos((double)time*OMEGA); else for (j=1; j<NY-1; j++){ if ((TWOSPEEDS)||(xy_in[0][j] != 0)){ x = phi_in[0][j]; y = psi_in[0][j]; switch (B_COND) { case (BC_DIRICHLET): { delta = phi_in[1][j] + phi_in[0][j+1] + phi_in[0][j-1] - 3.0*x; phi_out[0][j] = -y + 2*x + tcc[0][j]*delta - KAPPA*x - tgamma[0][j]*(x-y); break; } case (BC_PERIODIC): { delta = phi_in[1][j] + phi_in[NX-1][j] + phi_in[0][j+1] + phi_in[0][j-1] - 4.0*x; phi_out[0][j] = -y + 2*x + tcc[0][j]*delta - KAPPA*x - tgamma[0][j]*(x-y); break; } case (BC_ABSORBING): { delta = phi_in[1][j] + phi_in[0][j+1] + phi_in[0][j-1] - 3.0*x; phi_out[0][j] = x - tc[0][j]*(x - phi_in[1][j]) - KAPPA_SIDES*x - GAMMA_SIDES*(x-y); break; } case (BC_VPER_HABS): { delta = phi_in[1][j] + phi_in[0][j+1] + phi_in[0][j-1] - 3.0*x; phi_out[0][j] = x - tc[0][j]*(x - phi_in[1][j]) - KAPPA_SIDES*x - GAMMA_SIDES*(x-y); break; } } psi_out[0][j] = x; } } /* right boundary */ for (j=1; j<NY-1; j++){ if ((TWOSPEEDS)||(xy_in[NX-1][j] != 0)){ x = phi_in[NX-1][j]; y = psi_in[NX-1][j]; switch (B_COND) { case (BC_DIRICHLET): { delta = phi_in[NX-2][j] + phi_in[NX-1][j+1] + phi_in[NX-1][j-1] - 3.0*x; phi_out[NX-1][j] = -y + 2*x + tcc[NX-1][j]*delta - KAPPA*x - tgamma[NX-1][j]*(x-y); break; } case (BC_PERIODIC): { delta = phi_in[NX-2][j] + phi_in[0][j] + phi_in[NX-1][j+1] + phi_in[NX-1][j-1] - 4.0*x; phi_out[NX-1][j] = -y + 2*x + tcc[NX-1][j]*delta - KAPPA*x - tgamma[NX-1][j]*(x-y); break; } case (BC_ABSORBING): { delta = phi_in[NX-2][j] + phi_in[NX-1][j+1] + phi_in[NX-1][j-1] - 3.0*x; phi_out[NX-1][j] = x - tc[NX-1][j]*(x - phi_in[NX-2][j]) - KAPPA_SIDES*x - GAMMA_SIDES*(x-y); break; } case (BC_VPER_HABS): { delta = phi_in[NX-2][j] + phi_in[NX-1][j+1] + phi_in[NX-1][j-1] - 3.0*x; phi_out[NX-1][j] = x - tc[NX-1][j]*(x - phi_in[NX-2][j]) - KAPPA_SIDES*x - GAMMA_SIDES*(x-y); break; } } psi_out[NX-1][j] = x; } } /* top boundary */ for (i=0; i<NX; i++){ if ((TWOSPEEDS)||(xy_in[i][NY-1] != 0)){ x = phi_in[i][NY-1]; y = psi_in[i][NY-1]; switch (B_COND) { case (BC_DIRICHLET): { iplus = i+1; if (iplus == NX) iplus = NX-1; iminus = i-1; if (iminus == -1) iminus = 0; delta = phi_in[iplus][NY-1] + phi_in[iminus][NY-1] + phi_in[i][NY-2] - 3.0*x; phi_out[i][NY-1] = -y + 2*x + tcc[i][NY-1]*delta - KAPPA*x - tgamma[i][NY-1]*(x-y); break; } case (BC_PERIODIC): { iplus = (i+1) % NX; iminus = (i-1) % NX; if (iminus < 0) iminus += NX; delta = phi_in[iplus][NY-1] + phi_in[iminus][NY-1] + phi_in[i][NY-2] + phi_in[i][0] - 4.0*x; phi_out[i][NY-1] = -y + 2*x + tcc[i][NY-1]*delta - KAPPA*x - tgamma[i][NY-1]*(x-y); break; } case (BC_ABSORBING): { iplus = (i+1); if (iplus == NX) iplus = NX-1; iminus = (i-1); if (iminus == -1) iminus = 0; delta = phi_in[iplus][NY-1] + phi_in[iminus][NY-1] + phi_in[i][NY-2] - 3.0*x; phi_out[i][NY-1] = x - tc[i][NY-1]*(x - phi_in[i][NY-2]) - KAPPA_TOPBOT*x - GAMMA_TOPBOT*(x-y); break; } case (BC_VPER_HABS): { iplus = (i+1); if (iplus == NX) iplus = NX-1; iminus = (i-1); if (iminus == -1) iminus = 0; delta = phi_in[iplus][NY-1] + phi_in[iminus][NY-1] + phi_in[i][NY-2] + phi_in[i][0] - 4.0*x; if (i==0) phi_out[0][NY-1] = x - tc[0][NY-1]*(x - phi_in[1][NY-1]) - KAPPA_SIDES*x - GAMMA_SIDES*(x-y); else phi_out[i][NY-1] = -y + 2*x + tcc[i][NY-1]*delta - KAPPA*x - tgamma[i][NY-1]*(x-y); break; } } psi_out[i][NY-1] = x; } } /* bottom boundary */ for (i=0; i<NX; i++){ if ((TWOSPEEDS)||(xy_in[i][0] != 0)){ x = phi_in[i][0]; y = psi_in[i][0]; switch (B_COND) { case (BC_DIRICHLET): { iplus = i+1; if (iplus == NX) iplus = NX-1; iminus = i-1; if (iminus == -1) iminus = 0; delta = phi_in[iplus][0] + phi_in[iminus][0] + phi_in[i][1] - 3.0*x; phi_out[i][0] = -y + 2*x + tcc[i][0]*delta - KAPPA*x - tgamma[i][0]*(x-y); break; } case (BC_PERIODIC): { iplus = (i+1) % NX; iminus = (i-1) % NX; if (iminus < 0) iminus += NX; delta = phi_in[iplus][0] + phi_in[iminus][0] + phi_in[i][1] + phi_in[i][NY-1] - 4.0*x; phi_out[i][0] = -y + 2*x + tcc[i][0]*delta - KAPPA*x - tgamma[i][0]*(x-y); break; } case (BC_ABSORBING): { iplus = (i+1); if (iplus == NX) iplus = NX-1; iminus = (i-1); if (iminus == -1) iminus = 0; delta = phi_in[iplus][0] + phi_in[iminus][0] + phi_in[i][1] - 3.0*x; phi_out[i][0] = x - tc[i][0]*(x - phi_in[i][1]) - KAPPA_TOPBOT*x - GAMMA_TOPBOT*(x-y); break; } case (BC_VPER_HABS): { iplus = (i+1); if (iplus == NX) iplus = NX-1; iminus = (i-1); if (iminus == -1) iminus = 0; delta = phi_in[iplus][0] + phi_in[iminus][0] + phi_in[i][1] + phi_in[i][NY-1] - 4.0*x; if (i==0) phi_out[0][0] = x - tc[0][0]*(x - phi_in[1][0]) - KAPPA_SIDES*x - GAMMA_SIDES*(x-y); else phi_out[i][0] = -y + 2*x + tcc[i][0]*delta - KAPPA*x - tgamma[i][0]*(x-y); break; } } psi_out[i][0] = x; } } /* add oscillating boundary condition on the left corners */ if (OSCILLATE_LEFT) { phi_out[0][0] = AMPLITUDE*cos((double)time*OMEGA); phi_out[0][NY-1] = AMPLITUDE*cos((double)time*OMEGA); } /* for debugging purposes/if there is a risk of blow-up */ if (FLOOR) for (i=0; i<NX; i++){ for (j=0; j<NY; j++){ if (xy_in[i][j] != 0) { if (phi_out[i][j] > VMAX) phi_out[i][j] = VMAX; if (phi_out[i][j] < -VMAX) phi_out[i][j] = -VMAX; if (psi_out[i][j] > VMAX) psi_out[i][j] = VMAX; if (psi_out[i][j] < -VMAX) psi_out[i][j] = -VMAX; } } } } void evolve_wave(double *phi[NX], double *psi[NX], double *phi_tmp[NX], double *psi_tmp[NX], short int *xy_in[NX]) /* time step of field evolution */ /* phi is value of field at time t, psi at time t-1 */ { evolve_wave_half(phi, psi, phi_tmp, psi_tmp, xy_in); evolve_wave_half(phi_tmp, psi_tmp, phi, psi, xy_in); // evolve_wave_half_old(phi, psi, phi_tmp, psi_tmp, xy_in); // evolve_wave_half_old(phi_tmp, psi_tmp, phi, psi, xy_in); } void draw_color_bar(int plot, double range) { if (ROTATE_COLOR_SCHEME) draw_color_scheme(-1.0, -0.8, XMAX - 0.1, -1.0, plot, -range, range); else draw_color_scheme(1.7, YMIN + 0.1, 1.9, YMAX - 0.1, plot, -range, range); } void animation() { double time, scale, ratio, startleft[2], startright[2]; double *phi[NX], *psi[NX], *phi_tmp[NX], *psi_tmp[NX], *total_energy[NX]; short int *xy_in[NX]; int i, j, s, sample_left[2], sample_right[2]; static int counter = 0; long int wave_value; if (SAVE_TIME_SERIES) { time_series_left = fopen("wave_left.dat", "w"); time_series_right = fopen("wave_right.dat", "w"); } /* Since NX and NY are big, it seemed wiser to use some memory allocation here */ for (i=0; i<NX; i++) { phi[i] = (double *)malloc(NY*sizeof(double)); psi[i] = (double *)malloc(NY*sizeof(double)); phi_tmp[i] = (double *)malloc(NY*sizeof(double)); psi_tmp[i] = (double *)malloc(NY*sizeof(double)); total_energy[i] = (double *)malloc(NY*sizeof(double)); xy_in[i] = (short int *)malloc(NY*sizeof(short int)); } /* initialise positions and radii of circles */ if ((B_DOMAIN == D_CIRCLES)||(B_DOMAIN == D_CIRCLES_IN_RECT)) init_circle_config(circles); else if (B_DOMAIN == D_POLYGONS) init_polygon_config(polygons); printf("Polygons initialized\n"); /* initialise polyline for von Koch and simular domains */ npolyline = init_polyline(MDEPTH, polyline); for (i=0; i<npolyline; i++) printf("vertex %i: (%.3f, %.3f)\n", i, polyline[i].x, polyline[i].y); courant2 = COURANT*COURANT; courantb2 = COURANTB*COURANTB; /* initialize wave with a drop at one point, zero elsewhere */ // init_circular_wave(0.0, -LAMBDA, phi, psi, xy_in); /* initialize total energy table */ if ((PLOT == P_MEAN_ENERGY)||(PLOT_B == P_MEAN_ENERGY)) for (i=0; i<NX; i++) for (j=0; j<NY; j++) total_energy[i][j] = 0.0; ratio = (XMAX - XMIN)/8.4; /* for Tokarsky billiard */ // isospectral_initial_point(0.2, 0.0, startleft, startright); /* for isospectral billiards */ homophonic_initial_point(0.5, -0.25, 1.5, -0.25, startleft, startright); // homophonic_initial_point(0.5, -0.25, 1.5, -0.25, startleft, startright); // printf("xleft = (%.3f, %.3f) xright = (%.3f, %.3f)\n", startleft[0], startleft[1], startright[0], startright[1]); xy_to_ij(startleft[0], startleft[1], sample_left); xy_to_ij(startright[0], startright[1], sample_right); // printf("xleft = (%.3f, %.3f) xright = (%.3f, %.3f)\n", xin_left, yin_left, xin_right, yin_right); // init_wave_flat(phi, psi, xy_in); // init_wave_plus(LAMBDA - 0.3*MU, 0.5*MU, phi, psi, xy_in); // init_wave(LAMBDA - 0.3*MU, 0.5*MU, phi, psi, xy_in); // init_circular_wave(X_SHOOTER, Y_SHOOTER, phi, psi, xy_in); // printf("Initializing wave\n"); // init_circular_wave(-1.0, 0.0, phi, psi, xy_in); // printf("Wave initialized\n"); // init_circular_wave(0.0, 0.0, phi, psi, xy_in); // add_circular_wave(-1.0, 0.0, LAMBDA, phi, psi, xy_in); // add_circular_wave(1.0, -LAMBDA, 0.0, phi, psi, xy_in); // add_circular_wave(-1.0, 0.0, -LAMBDA, phi, psi, xy_in); init_circular_wave_xplusminus(startleft[0], startleft[1], startright[0], startright[1], phi, psi, xy_in); // init_circular_wave_xplusminus(-0.9, 0.0, 0.81, 0.0, phi, psi, xy_in); // init_circular_wave(-2.0*ratio, 0.0, phi, psi, xy_in); // init_planar_wave(XMIN + 0.015, 0.0, phi, psi, xy_in); // init_planar_wave(XMIN + 0.02, 0.0, phi, psi, xy_in); // init_planar_wave(XMIN + 0.5, 0.0, phi, psi, xy_in); // init_wave(-1.5, 0.0, phi, psi, xy_in); // init_wave(0.0, 0.0, phi, psi, xy_in); /* add a drop at another point */ // add_drop_to_wave(1.0, 0.7, 0.0, phi, psi); // add_drop_to_wave(1.0, -0.7, 0.0, phi, psi); // add_drop_to_wave(1.0, 0.0, -0.7, phi, psi); blank(); glColor3f(0.0, 0.0, 0.0); // draw_wave(phi, psi, xy_in, 1.0, 0, PLOT); draw_wave_e(phi, psi, total_energy, xy_in, 1.0, 0, PLOT); draw_billiard(); if (DRAW_COLOR_SCHEME) draw_color_bar(PLOT, COLORBAR_RANGE); glutSwapBuffers(); sleep(SLEEP1); for (i=0; i<=INITIAL_TIME + NSTEPS; i++) { //printf("%d\n",i); /* compute the variance of the field to adjust color scheme */ /* the color depends on the field divided by sqrt(1 + variance) */ if (SCALE) { scale = sqrt(1.0 + compute_variance(phi,psi, xy_in)); // printf("Scaling factor: %5lg\n", scale); } else scale = 1.0; // draw_wave(phi, psi, xy_in, scale, i, PLOT); draw_wave_e(phi, psi, total_energy, xy_in, scale, i, PLOT); for (j=0; j<NVID; j++) { evolve_wave(phi, psi, phi_tmp, psi_tmp, xy_in); if (SAVE_TIME_SERIES) { wave_value = (long int)(phi[sample_left[0]][sample_left[1]]*1.0e16); fprintf(time_series_left, "%019ld\n", wave_value); wave_value = (long int)(phi[sample_right[0]][sample_right[1]]*1.0e16); fprintf(time_series_right, "%019ld\n", wave_value); if ((j == 0)&&(i%10 == 0)) printf("Frame %i of %i\n", i, NSTEPS); // fprintf(time_series_right, "%.15f\n", phi[sample_right[0]][sample_right[1]]); } // if (i % 10 == 9) oscillate_linear_wave(0.2*scale, 0.15*(double)(i*NVID + j), -1.5, YMIN, -1.5, YMAX, phi, psi); } draw_billiard(); if (DRAW_COLOR_SCHEME) draw_color_bar(PLOT, COLORBAR_RANGE); /* add oscillating waves */ // if (i%345 == 344) // { // add_circular_wave(1.0, -LAMBDA, 0.0, phi, psi, xy_in); // } glutSwapBuffers(); if (MOVIE) { if (i >= INITIAL_TIME) save_frame(); else printf("Initial phase time %i of %i\n", i, INITIAL_TIME); if ((i >= INITIAL_TIME)&&(DOUBLE_MOVIE)) { // draw_wave(phi, psi, xy_in, scale, i, PLOT_B); draw_wave_e(phi, psi, total_energy, xy_in, scale, i, PLOT_B); if (DRAW_COLOR_SCHEME) draw_color_bar(PLOT_B, COLORBAR_RANGE_B); draw_billiard(); glutSwapBuffers(); save_frame_counter(NSTEPS + 21 + counter); counter++; } /* it seems that saving too many files too fast can cause trouble with the file system */ /* so this is to make a pause from time to time - parameter PAUSE may need adjusting */ if (i % PAUSE == PAUSE - 1) { printf("Making a short pause\n"); sleep(PSLEEP); s = system("mv wave*.tif tif_wave/"); } } } if (MOVIE) { if (DOUBLE_MOVIE) { // draw_wave(phi, psi, xy_in, scale, i, PLOT); draw_wave_e(phi, psi, total_energy, xy_in, scale, NSTEPS, PLOT); draw_billiard(); if (DRAW_COLOR_SCHEME) draw_color_bar(PLOT, COLORBAR_RANGE); glutSwapBuffers(); } for (i=0; i<MID_FRAMES; i++) save_frame(); if (DOUBLE_MOVIE) { // draw_wave(phi, psi, xy_in, scale, i, PLOT_B); draw_wave_e(phi, psi, total_energy, xy_in, scale, NSTEPS, PLOT_B); draw_billiard(); if (DRAW_COLOR_SCHEME) draw_color_bar(PLOT_B, COLORBAR_RANGE_B); glutSwapBuffers(); } for (i=0; i<END_FRAMES; i++) save_frame_counter(NSTEPS + MID_FRAMES + 1 + counter + i); s = system("mv wave*.tif tif_wave/"); } for (i=0; i<NX; i++) { free(phi[i]); free(psi[i]); free(phi_tmp[i]); free(psi_tmp[i]); free(total_energy[i]); free(xy_in[i]); } if (SAVE_TIME_SERIES) { fclose(time_series_left); fclose(time_series_right); } } void display(void) { glPushMatrix(); blank(); glutSwapBuffers(); blank(); glutSwapBuffers(); animation(); sleep(SLEEP2); glPopMatrix(); glutDestroyWindow(glutGetWindow()); } int main(int argc, char** argv) { glutInit(&argc, argv); glutInitDisplayMode(GLUT_RGB | GLUT_DOUBLE | GLUT_DEPTH); glutInitWindowSize(WINWIDTH,WINHEIGHT); glutCreateWindow("Wave equation in a planar domain"); init(); glutDisplayFunc(display); glutMainLoop(); return 0; }

clib.c

/* Generated by Cython 0.29.25 */ /* BEGIN: Cython Metadata { "distutils": { "depends": [], "extra_compile_args": [ "-fopenmp" ], "extra_link_args": [ "-fopenmp" ], "include_dirs": [ "/usr/local/Caskroom/miniconda/base/envs/shakemap/lib/python3.8/site-packages/numpy/core/include" ], "libraries": [ "m", "omp" ], "name": "shakemap.c.clib", "sources": [ "shakemap/c/clib.pyx" ] }, "module_name": "shakemap.c.clib" } END: Cython Metadata */ #ifndef PY_SSIZE_T_CLEAN #define PY_SSIZE_T_CLEAN #endif /* PY_SSIZE_T_CLEAN */ #include "Python.h" #ifndef Py_PYTHON_H #error Python headers needed to compile C extensions, please install development version of Python. #elif PY_VERSION_HEX < 0x02060000 || (0x03000000 <= PY_VERSION_HEX && PY_VERSION_HEX < 0x03030000) #error Cython requires Python 2.6+ or Python 3.3+. #else #define CYTHON_ABI "0_29_25" #define CYTHON_HEX_VERSION 0x001D19F0 #define CYTHON_FUTURE_DIVISION 1 #include <stddef.h> #ifndef offsetof #define offsetof(type, member) ( (size_t) & ((type*)0) -> member ) #endif #if !defined(WIN32) && !defined(MS_WINDOWS) #ifndef __stdcall #define __stdcall #endif #ifndef __cdecl #define __cdecl #endif #ifndef __fastcall #define __fastcall #endif #endif #ifndef DL_IMPORT #define DL_IMPORT(t) t #endif #ifndef DL_EXPORT #define DL_EXPORT(t) t #endif #define __PYX_COMMA , #ifndef HAVE_LONG_LONG #if PY_VERSION_HEX >= 0x02070000 #define HAVE_LONG_LONG #endif #endif #ifndef PY_LONG_LONG #define PY_LONG_LONG LONG_LONG #endif #ifndef Py_HUGE_VAL #define Py_HUGE_VAL HUGE_VAL #endif #ifdef PYPY_VERSION #define CYTHON_COMPILING_IN_PYPY 1 #define CYTHON_COMPILING_IN_PYSTON 0 #define CYTHON_COMPILING_IN_CPYTHON 0 #undef CYTHON_USE_TYPE_SLOTS #define CYTHON_USE_TYPE_SLOTS 0 #undef CYTHON_USE_PYTYPE_LOOKUP #define CYTHON_USE_PYTYPE_LOOKUP 0 #if PY_VERSION_HEX < 0x03050000 #undef CYTHON_USE_ASYNC_SLOTS #define CYTHON_USE_ASYNC_SLOTS 0 #elif !defined(CYTHON_USE_ASYNC_SLOTS) #define CYTHON_USE_ASYNC_SLOTS 1 #endif #undef CYTHON_USE_PYLIST_INTERNALS #define CYTHON_USE_PYLIST_INTERNALS 0 #undef CYTHON_USE_UNICODE_INTERNALS #define CYTHON_USE_UNICODE_INTERNALS 0 #undef CYTHON_USE_UNICODE_WRITER #define CYTHON_USE_UNICODE_WRITER 0 #undef CYTHON_USE_PYLONG_INTERNALS #define CYTHON_USE_PYLONG_INTERNALS 0 #undef CYTHON_AVOID_BORROWED_REFS #define CYTHON_AVOID_BORROWED_REFS 1 #undef CYTHON_ASSUME_SAFE_MACROS #define CYTHON_ASSUME_SAFE_MACROS 0 #undef CYTHON_UNPACK_METHODS #define CYTHON_UNPACK_METHODS 0 #undef CYTHON_FAST_THREAD_STATE #define CYTHON_FAST_THREAD_STATE 0 #undef CYTHON_FAST_PYCALL #define CYTHON_FAST_PYCALL 0 #undef CYTHON_PEP489_MULTI_PHASE_INIT #define CYTHON_PEP489_MULTI_PHASE_INIT 0 #undef CYTHON_USE_TP_FINALIZE #define CYTHON_USE_TP_FINALIZE 0 #undef CYTHON_USE_DICT_VERSIONS #define CYTHON_USE_DICT_VERSIONS 0 #undef CYTHON_USE_EXC_INFO_STACK #define CYTHON_USE_EXC_INFO_STACK 0 #elif defined(PYSTON_VERSION) #define CYTHON_COMPILING_IN_PYPY 0 #define CYTHON_COMPILING_IN_PYSTON 1 #define CYTHON_COMPILING_IN_CPYTHON 0 #ifndef CYTHON_USE_TYPE_SLOTS #define CYTHON_USE_TYPE_SLOTS 1 #endif #undef CYTHON_USE_PYTYPE_LOOKUP #define CYTHON_USE_PYTYPE_LOOKUP 0 #undef CYTHON_USE_ASYNC_SLOTS #define CYTHON_USE_ASYNC_SLOTS 0 #undef CYTHON_USE_PYLIST_INTERNALS #define CYTHON_USE_PYLIST_INTERNALS 0 #ifndef CYTHON_USE_UNICODE_INTERNALS #define CYTHON_USE_UNICODE_INTERNALS 1 #endif #undef CYTHON_USE_UNICODE_WRITER #define CYTHON_USE_UNICODE_WRITER 0 #undef CYTHON_USE_PYLONG_INTERNALS #define CYTHON_USE_PYLONG_INTERNALS 0 #ifndef CYTHON_AVOID_BORROWED_REFS #define CYTHON_AVOID_BORROWED_REFS 0 #endif #ifndef CYTHON_ASSUME_SAFE_MACROS #define CYTHON_ASSUME_SAFE_MACROS 1 #endif #ifndef CYTHON_UNPACK_METHODS #define CYTHON_UNPACK_METHODS 1 #endif #undef CYTHON_FAST_THREAD_STATE #define CYTHON_FAST_THREAD_STATE 0 #undef CYTHON_FAST_PYCALL #define CYTHON_FAST_PYCALL 0 #undef CYTHON_PEP489_MULTI_PHASE_INIT #define CYTHON_PEP489_MULTI_PHASE_INIT 0 #undef CYTHON_USE_TP_FINALIZE #define CYTHON_USE_TP_FINALIZE 0 #undef CYTHON_USE_DICT_VERSIONS #define CYTHON_USE_DICT_VERSIONS 0 #undef CYTHON_USE_EXC_INFO_STACK #define CYTHON_USE_EXC_INFO_STACK 0 #else #define CYTHON_COMPILING_IN_PYPY 0 #define CYTHON_COMPILING_IN_PYSTON 0 #define CYTHON_COMPILING_IN_CPYTHON 1 #ifndef CYTHON_USE_TYPE_SLOTS #define CYTHON_USE_TYPE_SLOTS 1 #endif #if PY_VERSION_HEX < 0x02070000 #undef CYTHON_USE_PYTYPE_LOOKUP #define CYTHON_USE_PYTYPE_LOOKUP 0 #elif !defined(CYTHON_USE_PYTYPE_LOOKUP) #define CYTHON_USE_PYTYPE_LOOKUP 1 #endif #if PY_MAJOR_VERSION < 3 #undef CYTHON_USE_ASYNC_SLOTS #define CYTHON_USE_ASYNC_SLOTS 0 #elif !defined(CYTHON_USE_ASYNC_SLOTS) #define CYTHON_USE_ASYNC_SLOTS 1 #endif #if PY_VERSION_HEX < 0x02070000 #undef CYTHON_USE_PYLONG_INTERNALS #define CYTHON_USE_PYLONG_INTERNALS 0 #elif !defined(CYTHON_USE_PYLONG_INTERNALS) #define CYTHON_USE_PYLONG_INTERNALS 1 #endif #ifndef CYTHON_USE_PYLIST_INTERNALS #define CYTHON_USE_PYLIST_INTERNALS 1 #endif #ifndef CYTHON_USE_UNICODE_INTERNALS #define CYTHON_USE_UNICODE_INTERNALS 1 #endif #if PY_VERSION_HEX < 0x030300F0 || PY_VERSION_HEX >= 0x030B00A2 #undef CYTHON_USE_UNICODE_WRITER #define CYTHON_USE_UNICODE_WRITER 0 #elif !defined(CYTHON_USE_UNICODE_WRITER) #define CYTHON_USE_UNICODE_WRITER 1 #endif #ifndef CYTHON_AVOID_BORROWED_REFS #define CYTHON_AVOID_BORROWED_REFS 0 #endif #ifndef CYTHON_ASSUME_SAFE_MACROS #define CYTHON_ASSUME_SAFE_MACROS 1 #endif #ifndef CYTHON_UNPACK_METHODS #define CYTHON_UNPACK_METHODS 1 #endif #ifndef CYTHON_FAST_THREAD_STATE #define CYTHON_FAST_THREAD_STATE 1 #endif #ifndef CYTHON_FAST_PYCALL #define CYTHON_FAST_PYCALL (PY_VERSION_HEX < 0x030B00A1) #endif #ifndef CYTHON_PEP489_MULTI_PHASE_INIT #define CYTHON_PEP489_MULTI_PHASE_INIT (PY_VERSION_HEX >= 0x03050000) #endif #ifndef CYTHON_USE_TP_FINALIZE #define CYTHON_USE_TP_FINALIZE (PY_VERSION_HEX >= 0x030400a1) #endif #ifndef CYTHON_USE_DICT_VERSIONS #define CYTHON_USE_DICT_VERSIONS (PY_VERSION_HEX >= 0x030600B1) #endif #ifndef CYTHON_USE_EXC_INFO_STACK #define CYTHON_USE_EXC_INFO_STACK (PY_VERSION_HEX >= 0x030700A3) #endif #endif #if !defined(CYTHON_FAST_PYCCALL) #define CYTHON_FAST_PYCCALL (CYTHON_FAST_PYCALL && PY_VERSION_HEX >= 0x030600B1) #endif #if CYTHON_USE_PYLONG_INTERNALS #if PY_MAJOR_VERSION < 3 #include "longintrepr.h" #endif #undef SHIFT #undef BASE #undef MASK #ifdef SIZEOF_VOID_P enum { __pyx_check_sizeof_voidp = 1 / (int)(SIZEOF_VOID_P == sizeof(void*)) }; #endif #endif #ifndef __has_attribute #define __has_attribute(x) 0 #endif #ifndef __has_cpp_attribute #define __has_cpp_attribute(x) 0 #endif #ifndef CYTHON_RESTRICT #if defined(__GNUC__) #define CYTHON_RESTRICT __restrict__ #elif defined(_MSC_VER) && _MSC_VER >= 1400 #define CYTHON_RESTRICT __restrict #elif defined (__STDC_VERSION__) && __STDC_VERSION__ >= 199901L #define CYTHON_RESTRICT restrict #else #define CYTHON_RESTRICT #endif #endif #ifndef CYTHON_UNUSED # if defined(__GNUC__) # if !(defined(__cplusplus)) || (__GNUC__ > 3 || (__GNUC__ == 3 && __GNUC_MINOR__ >= 4)) # define CYTHON_UNUSED __attribute__ ((__unused__)) # else # define CYTHON_UNUSED # endif # elif defined(__ICC) || (defined(__INTEL_COMPILER) && !defined(_MSC_VER)) # define CYTHON_UNUSED __attribute__ ((__unused__)) # else # define CYTHON_UNUSED # endif #endif #ifndef CYTHON_MAYBE_UNUSED_VAR # if defined(__cplusplus) template<class T> void CYTHON_MAYBE_UNUSED_VAR( const T& ) { } # else # define CYTHON_MAYBE_UNUSED_VAR(x) (void)(x) # endif #endif #ifndef CYTHON_NCP_UNUSED # if CYTHON_COMPILING_IN_CPYTHON # define CYTHON_NCP_UNUSED # else # define CYTHON_NCP_UNUSED CYTHON_UNUSED # endif #endif #define __Pyx_void_to_None(void_result) ((void)(void_result), Py_INCREF(Py_None), Py_None) #ifdef _MSC_VER #ifndef _MSC_STDINT_H_ #if _MSC_VER < 1300 typedef unsigned char uint8_t; typedef unsigned int uint32_t; #else typedef unsigned __int8 uint8_t; typedef unsigned __int32 uint32_t; #endif #endif #else #include <stdint.h> #endif #ifndef CYTHON_FALLTHROUGH #if defined(__cplusplus) && __cplusplus >= 201103L #if __has_cpp_attribute(fallthrough) #define CYTHON_FALLTHROUGH [[fallthrough]] #elif __has_cpp_attribute(clang::fallthrough) #define CYTHON_FALLTHROUGH [[clang::fallthrough]] #elif __has_cpp_attribute(gnu::fallthrough) #define CYTHON_FALLTHROUGH [[gnu::fallthrough]] #endif #endif #ifndef CYTHON_FALLTHROUGH #if __has_attribute(fallthrough) #define CYTHON_FALLTHROUGH __attribute__((fallthrough)) #else #define CYTHON_FALLTHROUGH #endif #endif #if defined(__clang__ ) && defined(__apple_build_version__) #if __apple_build_version__ < 7000000 #undef CYTHON_FALLTHROUGH #define CYTHON_FALLTHROUGH #endif #endif #endif #ifndef CYTHON_INLINE #if defined(__clang__) #define CYTHON_INLINE __inline__ __attribute__ ((__unused__)) #elif defined(__GNUC__) #define CYTHON_INLINE __inline__ #elif defined(_MSC_VER) #define CYTHON_INLINE __inline #elif defined (__STDC_VERSION__) && __STDC_VERSION__ >= 199901L #define CYTHON_INLINE inline #else #define CYTHON_INLINE #endif #endif #if CYTHON_COMPILING_IN_PYPY && PY_VERSION_HEX < 0x02070600 && !defined(Py_OptimizeFlag) #define Py_OptimizeFlag 0 #endif #define __PYX_BUILD_PY_SSIZE_T "n" #define CYTHON_FORMAT_SSIZE_T "z" #if PY_MAJOR_VERSION < 3 #define __Pyx_BUILTIN_MODULE_NAME "__builtin__" #define __Pyx_PyCode_New(a, k, l, s, f, code, c, n, v, fv, cell, fn, name, fline, lnos)\ PyCode_New(a+k, l, s, f, code, c, n, v, fv, cell, fn, name, fline, lnos) #define __Pyx_DefaultClassType PyClass_Type #else #define __Pyx_BUILTIN_MODULE_NAME "builtins" #define __Pyx_DefaultClassType PyType_Type #if PY_VERSION_HEX >= 0x030B00A1 static CYTHON_INLINE PyCodeObject* __Pyx_PyCode_New(int a, int k, int l, int s, int f, PyObject *code, PyObject *c, PyObject* n, PyObject *v, PyObject *fv, PyObject *cell, PyObject* fn, PyObject *name, int fline, PyObject *lnos) { PyObject *kwds=NULL, *argcount=NULL, *posonlyargcount=NULL, *kwonlyargcount=NULL; PyObject *nlocals=NULL, *stacksize=NULL, *flags=NULL, *replace=NULL, *call_result=NULL, *empty=NULL; const char *fn_cstr=NULL; const char *name_cstr=NULL; PyCodeObject* co=NULL; PyObject *type, *value, *traceback; PyErr_Fetch(&type, &value, &traceback); if (!(kwds=PyDict_New())) goto end; if (!(argcount=PyLong_FromLong(a))) goto end; if (PyDict_SetItemString(kwds, "co_argcount", argcount) != 0) goto end; if (!(posonlyargcount=PyLong_FromLong(0))) goto end; if (PyDict_SetItemString(kwds, "co_posonlyargcount", posonlyargcount) != 0) goto end; if (!(kwonlyargcount=PyLong_FromLong(k))) goto end; if (PyDict_SetItemString(kwds, "co_kwonlyargcount", kwonlyargcount) != 0) goto end; if (!(nlocals=PyLong_FromLong(l))) goto end; if (PyDict_SetItemString(kwds, "co_nlocals", nlocals) != 0) goto end; if (!(stacksize=PyLong_FromLong(s))) goto end; if (PyDict_SetItemString(kwds, "co_stacksize", stacksize) != 0) goto end; if (!(flags=PyLong_FromLong(f))) goto end; if (PyDict_SetItemString(kwds, "co_flags", flags) != 0) goto end; if (PyDict_SetItemString(kwds, "co_code", code) != 0) goto end; if (PyDict_SetItemString(kwds, "co_consts", c) != 0) goto end; if (PyDict_SetItemString(kwds, "co_names", n) != 0) goto end; if (PyDict_SetItemString(kwds, "co_varnames", v) != 0) goto end; if (PyDict_SetItemString(kwds, "co_freevars", fv) != 0) goto end; if (PyDict_SetItemString(kwds, "co_cellvars", cell) != 0) goto end; if (PyDict_SetItemString(kwds, "co_linetable", lnos) != 0) goto end; if (!(fn_cstr=PyUnicode_AsUTF8AndSize(fn, NULL))) goto end; if (!(name_cstr=PyUnicode_AsUTF8AndSize(name, NULL))) goto end; if (!(co = PyCode_NewEmpty(fn_cstr, name_cstr, fline))) goto end; if (!(replace = PyObject_GetAttrString((PyObject*)co, "replace"))) goto cleanup_code_too; if (!(empty = PyTuple_New(0))) goto cleanup_code_too; // unfortunately __pyx_empty_tuple isn't available here if (!(call_result = PyObject_Call(replace, empty, kwds))) goto cleanup_code_too; Py_XDECREF((PyObject*)co); co = (PyCodeObject*)call_result; call_result = NULL; if (0) { cleanup_code_too: Py_XDECREF((PyObject*)co); co = NULL; } end: Py_XDECREF(kwds); Py_XDECREF(argcount); Py_XDECREF(posonlyargcount); Py_XDECREF(kwonlyargcount); Py_XDECREF(nlocals); Py_XDECREF(stacksize); Py_XDECREF(replace); Py_XDECREF(call_result); Py_XDECREF(empty); if (type) { PyErr_Restore(type, value, traceback); } return co; } #else #define __Pyx_PyCode_New(a, k, l, s, f, code, c, n, v, fv, cell, fn, name, fline, lnos)\ PyCode_New(a, k, l, s, f, code, c, n, v, fv, cell, fn, name, fline, lnos) #endif #define __Pyx_DefaultClassType PyType_Type #endif #ifndef Py_TPFLAGS_CHECKTYPES #define Py_TPFLAGS_CHECKTYPES 0 #endif #ifndef Py_TPFLAGS_HAVE_INDEX #define Py_TPFLAGS_HAVE_INDEX 0 #endif #ifndef Py_TPFLAGS_HAVE_NEWBUFFER #define Py_TPFLAGS_HAVE_NEWBUFFER 0 #endif #ifndef Py_TPFLAGS_HAVE_FINALIZE #define Py_TPFLAGS_HAVE_FINALIZE 0 #endif #ifndef METH_STACKLESS #define METH_STACKLESS 0 #endif #if PY_VERSION_HEX <= 0x030700A3 || !defined(METH_FASTCALL) #ifndef METH_FASTCALL #define METH_FASTCALL 0x80 #endif typedef PyObject *(*__Pyx_PyCFunctionFast) (PyObject *self, PyObject *const *args, Py_ssize_t nargs); typedef PyObject *(*__Pyx_PyCFunctionFastWithKeywords) (PyObject *self, PyObject *const *args, Py_ssize_t nargs, PyObject *kwnames); #else #define __Pyx_PyCFunctionFast _PyCFunctionFast #define __Pyx_PyCFunctionFastWithKeywords _PyCFunctionFastWithKeywords #endif #if CYTHON_FAST_PYCCALL #define __Pyx_PyFastCFunction_Check(func)\ ((PyCFunction_Check(func) && (METH_FASTCALL == (PyCFunction_GET_FLAGS(func) & ~(METH_CLASS | METH_STATIC | METH_COEXIST | METH_KEYWORDS | METH_STACKLESS))))) #else #define __Pyx_PyFastCFunction_Check(func) 0 #endif #if CYTHON_COMPILING_IN_PYPY && !defined(PyObject_Malloc) #define PyObject_Malloc(s) PyMem_Malloc(s) #define PyObject_Free(p) PyMem_Free(p) #define PyObject_Realloc(p) PyMem_Realloc(p) #endif #if CYTHON_COMPILING_IN_CPYTHON && PY_VERSION_HEX < 0x030400A1 #define PyMem_RawMalloc(n) PyMem_Malloc(n) #define PyMem_RawRealloc(p, n) PyMem_Realloc(p, n) #define PyMem_RawFree(p) PyMem_Free(p) #endif #if CYTHON_COMPILING_IN_PYSTON #define __Pyx_PyCode_HasFreeVars(co) PyCode_HasFreeVars(co) #define __Pyx_PyFrame_SetLineNumber(frame, lineno) PyFrame_SetLineNumber(frame, lineno) #else #define __Pyx_PyCode_HasFreeVars(co) (PyCode_GetNumFree(co) > 0) #define __Pyx_PyFrame_SetLineNumber(frame, lineno) (frame)->f_lineno = (lineno) #endif #if !CYTHON_FAST_THREAD_STATE || PY_VERSION_HEX < 0x02070000 #define __Pyx_PyThreadState_Current PyThreadState_GET() #elif PY_VERSION_HEX >= 0x03060000 #define __Pyx_PyThreadState_Current _PyThreadState_UncheckedGet() #elif PY_VERSION_HEX >= 0x03000000 #define __Pyx_PyThreadState_Current PyThreadState_GET() #else #define __Pyx_PyThreadState_Current _PyThreadState_Current #endif #if PY_VERSION_HEX < 0x030700A2 && !defined(PyThread_tss_create) && !defined(Py_tss_NEEDS_INIT) #include "pythread.h" #define Py_tss_NEEDS_INIT 0 typedef int Py_tss_t; static CYTHON_INLINE int PyThread_tss_create(Py_tss_t *key) { *key = PyThread_create_key(); return 0; } static CYTHON_INLINE Py_tss_t * PyThread_tss_alloc(void) { Py_tss_t *key = (Py_tss_t *)PyObject_Malloc(sizeof(Py_tss_t)); *key = Py_tss_NEEDS_INIT; return key; } static CYTHON_INLINE void PyThread_tss_free(Py_tss_t *key) { PyObject_Free(key); } static CYTHON_INLINE int PyThread_tss_is_created(Py_tss_t *key) { return *key != Py_tss_NEEDS_INIT; } static CYTHON_INLINE void PyThread_tss_delete(Py_tss_t *key) { PyThread_delete_key(*key); *key = Py_tss_NEEDS_INIT; } static CYTHON_INLINE int PyThread_tss_set(Py_tss_t *key, void *value) { return PyThread_set_key_value(*key, value); } static CYTHON_INLINE void * PyThread_tss_get(Py_tss_t *key) { return PyThread_get_key_value(*key); } #endif #if CYTHON_COMPILING_IN_CPYTHON || defined(_PyDict_NewPresized) #define __Pyx_PyDict_NewPresized(n) ((n <= 8) ? PyDict_New() : _PyDict_NewPresized(n)) #else #define __Pyx_PyDict_NewPresized(n) PyDict_New() #endif #if PY_MAJOR_VERSION >= 3 || CYTHON_FUTURE_DIVISION #define __Pyx_PyNumber_Divide(x,y) PyNumber_TrueDivide(x,y) #define __Pyx_PyNumber_InPlaceDivide(x,y) PyNumber_InPlaceTrueDivide(x,y) #else #define __Pyx_PyNumber_Divide(x,y) PyNumber_Divide(x,y) #define __Pyx_PyNumber_InPlaceDivide(x,y) PyNumber_InPlaceDivide(x,y) #endif #if CYTHON_COMPILING_IN_CPYTHON && PY_VERSION_HEX >= 0x030500A1 && CYTHON_USE_UNICODE_INTERNALS #define __Pyx_PyDict_GetItemStr(dict, name) _PyDict_GetItem_KnownHash(dict, name, ((PyASCIIObject *) name)->hash) #else #define __Pyx_PyDict_GetItemStr(dict, name) PyDict_GetItem(dict, name) #endif #if PY_VERSION_HEX > 0x03030000 && defined(PyUnicode_KIND) #define CYTHON_PEP393_ENABLED 1 #if defined(PyUnicode_IS_READY) #define __Pyx_PyUnicode_READY(op) (likely(PyUnicode_IS_READY(op)) ?\ 0 : _PyUnicode_Ready((PyObject *)(op))) #else #define __Pyx_PyUnicode_READY(op) (0) #endif #define __Pyx_PyUnicode_GET_LENGTH(u) PyUnicode_GET_LENGTH(u) #define __Pyx_PyUnicode_READ_CHAR(u, i) PyUnicode_READ_CHAR(u, i) #define __Pyx_PyUnicode_MAX_CHAR_VALUE(u) PyUnicode_MAX_CHAR_VALUE(u) #define __Pyx_PyUnicode_KIND(u) PyUnicode_KIND(u) #define __Pyx_PyUnicode_DATA(u) PyUnicode_DATA(u) #define __Pyx_PyUnicode_READ(k, d, i) PyUnicode_READ(k, d, i) #define __Pyx_PyUnicode_WRITE(k, d, i, ch) PyUnicode_WRITE(k, d, i, ch) #if defined(PyUnicode_IS_READY) && defined(PyUnicode_GET_SIZE) #if CYTHON_COMPILING_IN_CPYTHON && PY_VERSION_HEX >= 0x03090000 #define __Pyx_PyUnicode_IS_TRUE(u) (0 != (likely(PyUnicode_IS_READY(u)) ? PyUnicode_GET_LENGTH(u) : ((PyCompactUnicodeObject *)(u))->wstr_length)) #else #define __Pyx_PyUnicode_IS_TRUE(u) (0 != (likely(PyUnicode_IS_READY(u)) ? PyUnicode_GET_LENGTH(u) : PyUnicode_GET_SIZE(u))) #endif #else #define __Pyx_PyUnicode_IS_TRUE(u) (0 != PyUnicode_GET_LENGTH(u)) #endif #else #define CYTHON_PEP393_ENABLED 0 #define PyUnicode_1BYTE_KIND 1 #define PyUnicode_2BYTE_KIND 2 #define PyUnicode_4BYTE_KIND 4 #define __Pyx_PyUnicode_READY(op) (0) #define __Pyx_PyUnicode_GET_LENGTH(u) PyUnicode_GET_SIZE(u) #define __Pyx_PyUnicode_READ_CHAR(u, i) ((Py_UCS4)(PyUnicode_AS_UNICODE(u)[i])) #define __Pyx_PyUnicode_MAX_CHAR_VALUE(u) ((sizeof(Py_UNICODE) == 2) ? 65535 : 1114111) #define __Pyx_PyUnicode_KIND(u) (sizeof(Py_UNICODE)) #define __Pyx_PyUnicode_DATA(u) ((void*)PyUnicode_AS_UNICODE(u)) #define __Pyx_PyUnicode_READ(k, d, i) ((void)(k), (Py_UCS4)(((Py_UNICODE*)d)[i])) #define __Pyx_PyUnicode_WRITE(k, d, i, ch) (((void)(k)), ((Py_UNICODE*)d)[i] = ch) #define __Pyx_PyUnicode_IS_TRUE(u) (0 != PyUnicode_GET_SIZE(u)) #endif #if CYTHON_COMPILING_IN_PYPY #define __Pyx_PyUnicode_Concat(a, b) PyNumber_Add(a, b) #define __Pyx_PyUnicode_ConcatSafe(a, b) PyNumber_Add(a, b) #else #define __Pyx_PyUnicode_Concat(a, b) PyUnicode_Concat(a, b) #define __Pyx_PyUnicode_ConcatSafe(a, b) ((unlikely((a) == Py_None) || unlikely((b) == Py_None)) ?\ PyNumber_Add(a, b) : __Pyx_PyUnicode_Concat(a, b)) #endif #if CYTHON_COMPILING_IN_PYPY && !defined(PyUnicode_Contains) #define PyUnicode_Contains(u, s) PySequence_Contains(u, s) #endif #if CYTHON_COMPILING_IN_PYPY && !defined(PyByteArray_Check) #define PyByteArray_Check(obj) PyObject_TypeCheck(obj, &PyByteArray_Type) #endif #if CYTHON_COMPILING_IN_PYPY && !defined(PyObject_Format) #define PyObject_Format(obj, fmt) PyObject_CallMethod(obj, "__format__", "O", fmt) #endif #define __Pyx_PyString_FormatSafe(a, b) ((unlikely((a) == Py_None || (PyString_Check(b) && !PyString_CheckExact(b)))) ? PyNumber_Remainder(a, b) : __Pyx_PyString_Format(a, b)) #define __Pyx_PyUnicode_FormatSafe(a, b) ((unlikely((a) == Py_None || (PyUnicode_Check(b) && !PyUnicode_CheckExact(b)))) ? PyNumber_Remainder(a, b) : PyUnicode_Format(a, b)) #if PY_MAJOR_VERSION >= 3 #define __Pyx_PyString_Format(a, b) PyUnicode_Format(a, b) #else #define __Pyx_PyString_Format(a, b) PyString_Format(a, b) #endif #if PY_MAJOR_VERSION < 3 && !defined(PyObject_ASCII) #define PyObject_ASCII(o) PyObject_Repr(o) #endif #if PY_MAJOR_VERSION >= 3 #define PyBaseString_Type PyUnicode_Type #define PyStringObject PyUnicodeObject #define PyString_Type PyUnicode_Type #define PyString_Check PyUnicode_Check #define PyString_CheckExact PyUnicode_CheckExact #ifndef PyObject_Unicode #define PyObject_Unicode PyObject_Str #endif #endif #if PY_MAJOR_VERSION >= 3 #define __Pyx_PyBaseString_Check(obj) PyUnicode_Check(obj) #define __Pyx_PyBaseString_CheckExact(obj) PyUnicode_CheckExact(obj) #else #define __Pyx_PyBaseString_Check(obj) (PyString_Check(obj) || PyUnicode_Check(obj)) #define __Pyx_PyBaseString_CheckExact(obj) (PyString_CheckExact(obj) || PyUnicode_CheckExact(obj)) #endif #ifndef PySet_CheckExact #define PySet_CheckExact(obj) (Py_TYPE(obj) == &PySet_Type) #endif #if PY_VERSION_HEX >= 0x030900A4 #define __Pyx_SET_REFCNT(obj, refcnt) Py_SET_REFCNT(obj, refcnt) #define __Pyx_SET_SIZE(obj, size) Py_SET_SIZE(obj, size) #else #define __Pyx_SET_REFCNT(obj, refcnt) Py_REFCNT(obj) = (refcnt) #define __Pyx_SET_SIZE(obj, size) Py_SIZE(obj) = (size) #endif #if CYTHON_ASSUME_SAFE_MACROS #define __Pyx_PySequence_SIZE(seq) Py_SIZE(seq) #else #define __Pyx_PySequence_SIZE(seq) PySequence_Size(seq) #endif #if PY_MAJOR_VERSION >= 3 #define PyIntObject PyLongObject #define PyInt_Type PyLong_Type #define PyInt_Check(op) PyLong_Check(op) #define PyInt_CheckExact(op) PyLong_CheckExact(op) #define PyInt_FromString PyLong_FromString #define PyInt_FromUnicode PyLong_FromUnicode #define PyInt_FromLong PyLong_FromLong #define PyInt_FromSize_t PyLong_FromSize_t #define PyInt_FromSsize_t PyLong_FromSsize_t #define PyInt_AsLong PyLong_AsLong #define PyInt_AS_LONG PyLong_AS_LONG #define PyInt_AsSsize_t PyLong_AsSsize_t #define PyInt_AsUnsignedLongMask PyLong_AsUnsignedLongMask #define PyInt_AsUnsignedLongLongMask PyLong_AsUnsignedLongLongMask #define PyNumber_Int PyNumber_Long #endif #if PY_MAJOR_VERSION >= 3 #define PyBoolObject PyLongObject #endif #if PY_MAJOR_VERSION >= 3 && CYTHON_COMPILING_IN_PYPY #ifndef PyUnicode_InternFromString #define PyUnicode_InternFromString(s) PyUnicode_FromString(s) #endif #endif #if PY_VERSION_HEX < 0x030200A4 typedef long Py_hash_t; #define __Pyx_PyInt_FromHash_t PyInt_FromLong #define __Pyx_PyInt_AsHash_t __Pyx_PyIndex_AsHash_t #else #define __Pyx_PyInt_FromHash_t PyInt_FromSsize_t #define __Pyx_PyInt_AsHash_t __Pyx_PyIndex_AsSsize_t #endif #if PY_MAJOR_VERSION >= 3 #define __Pyx_PyMethod_New(func, self, klass) ((self) ? ((void)(klass), PyMethod_New(func, self)) : __Pyx_NewRef(func)) #else #define __Pyx_PyMethod_New(func, self, klass) PyMethod_New(func, self, klass) #endif #if CYTHON_USE_ASYNC_SLOTS #if PY_VERSION_HEX >= 0x030500B1 #define __Pyx_PyAsyncMethodsStruct PyAsyncMethods #define __Pyx_PyType_AsAsync(obj) (Py_TYPE(obj)->tp_as_async) #else #define __Pyx_PyType_AsAsync(obj) ((__Pyx_PyAsyncMethodsStruct*) (Py_TYPE(obj)->tp_reserved)) #endif #else #define __Pyx_PyType_AsAsync(obj) NULL #endif #ifndef __Pyx_PyAsyncMethodsStruct typedef struct { unaryfunc am_await; unaryfunc am_aiter; unaryfunc am_anext; } __Pyx_PyAsyncMethodsStruct; #endif #if defined(WIN32) || defined(MS_WINDOWS) #define _USE_MATH_DEFINES #endif #include <math.h> #ifdef NAN #define __PYX_NAN() ((float) NAN) #else static CYTHON_INLINE float __PYX_NAN() { float value; memset(&value, 0xFF, sizeof(value)); return value; } #endif #if defined(__CYGWIN__) && defined(_LDBL_EQ_DBL) #define __Pyx_truncl trunc #else #define __Pyx_truncl truncl #endif #define __PYX_MARK_ERR_POS(f_index, lineno) \ { __pyx_filename = __pyx_f[f_index]; (void)__pyx_filename; __pyx_lineno = lineno; (void)__pyx_lineno; __pyx_clineno = __LINE__; (void)__pyx_clineno; } #define __PYX_ERR(f_index, lineno, Ln_error) \ { __PYX_MARK_ERR_POS(f_index, lineno) goto Ln_error; } #ifndef __PYX_EXTERN_C #ifdef __cplusplus #define __PYX_EXTERN_C extern "C" #else #define __PYX_EXTERN_C extern #endif #endif #define __PYX_HAVE__shakemap__c__clib #define __PYX_HAVE_API__shakemap__c__clib /* Early includes */ #include <math.h> #include "pythread.h" #include <string.h> #include <stdlib.h> #include <stdio.h> #include "pystate.h" #ifdef _OPENMP #include <omp.h> #endif /* _OPENMP */ #if defined(PYREX_WITHOUT_ASSERTIONS) && !defined(CYTHON_WITHOUT_ASSERTIONS) #define CYTHON_WITHOUT_ASSERTIONS #endif typedef struct {PyObject **p; const char *s; const Py_ssize_t n; const char* encoding; const char is_unicode; const char is_str; const char intern; } __Pyx_StringTabEntry; #define __PYX_DEFAULT_STRING_ENCODING_IS_ASCII 0 #define __PYX_DEFAULT_STRING_ENCODING_IS_UTF8 0 #define __PYX_DEFAULT_STRING_ENCODING_IS_DEFAULT (PY_MAJOR_VERSION >= 3 && __PYX_DEFAULT_STRING_ENCODING_IS_UTF8) #define __PYX_DEFAULT_STRING_ENCODING "" #define __Pyx_PyObject_FromString __Pyx_PyBytes_FromString #define __Pyx_PyObject_FromStringAndSize __Pyx_PyBytes_FromStringAndSize #define __Pyx_uchar_cast(c) ((unsigned char)c) #define __Pyx_long_cast(x) ((long)x) #define __Pyx_fits_Py_ssize_t(v, type, is_signed) (\ (sizeof(type) < sizeof(Py_ssize_t)) ||\ (sizeof(type) > sizeof(Py_ssize_t) &&\ likely(v < (type)PY_SSIZE_T_MAX ||\ v == (type)PY_SSIZE_T_MAX) &&\ (!is_signed || likely(v > (type)PY_SSIZE_T_MIN ||\ v == (type)PY_SSIZE_T_MIN))) ||\ (sizeof(type) == sizeof(Py_ssize_t) &&\ (is_signed || likely(v < (type)PY_SSIZE_T_MAX ||\ v == (type)PY_SSIZE_T_MAX))) ) static CYTHON_INLINE int __Pyx_is_valid_index(Py_ssize_t i, Py_ssize_t limit) { return (size_t) i < (size_t) limit; } #if defined (__cplusplus) && __cplusplus >= 201103L #include <cstdlib> #define __Pyx_sst_abs(value) std::abs(value) #elif SIZEOF_INT >= SIZEOF_SIZE_T #define __Pyx_sst_abs(value) abs(value) #elif SIZEOF_LONG >= SIZEOF_SIZE_T #define __Pyx_sst_abs(value) labs(value) #elif defined (_MSC_VER) #define __Pyx_sst_abs(value) ((Py_ssize_t)_abs64(value)) #elif defined (__STDC_VERSION__) && __STDC_VERSION__ >= 199901L #define __Pyx_sst_abs(value) llabs(value) #elif defined (__GNUC__) #define __Pyx_sst_abs(value) __builtin_llabs(value) #else #define __Pyx_sst_abs(value) ((value<0) ? -value : value) #endif static CYTHON_INLINE const char* __Pyx_PyObject_AsString(PyObject*); static CYTHON_INLINE const char* __Pyx_PyObject_AsStringAndSize(PyObject*, Py_ssize_t* length); #define __Pyx_PyByteArray_FromString(s) PyByteArray_FromStringAndSize((const char*)s, strlen((const char*)s)) #define __Pyx_PyByteArray_FromStringAndSize(s, l) PyByteArray_FromStringAndSize((const char*)s, l) #define __Pyx_PyBytes_FromString PyBytes_FromString #define __Pyx_PyBytes_FromStringAndSize PyBytes_FromStringAndSize static CYTHON_INLINE PyObject* __Pyx_PyUnicode_FromString(const char*); #if PY_MAJOR_VERSION < 3 #define __Pyx_PyStr_FromString __Pyx_PyBytes_FromString #define __Pyx_PyStr_FromStringAndSize __Pyx_PyBytes_FromStringAndSize #else #define __Pyx_PyStr_FromString __Pyx_PyUnicode_FromString #define __Pyx_PyStr_FromStringAndSize __Pyx_PyUnicode_FromStringAndSize #endif #define __Pyx_PyBytes_AsWritableString(s) ((char*) PyBytes_AS_STRING(s)) #define __Pyx_PyBytes_AsWritableSString(s) ((signed char*) PyBytes_AS_STRING(s)) #define __Pyx_PyBytes_AsWritableUString(s) ((unsigned char*) PyBytes_AS_STRING(s)) #define __Pyx_PyBytes_AsString(s) ((const char*) PyBytes_AS_STRING(s)) #define __Pyx_PyBytes_AsSString(s) ((const signed char*) PyBytes_AS_STRING(s)) #define __Pyx_PyBytes_AsUString(s) ((const unsigned char*) PyBytes_AS_STRING(s)) #define __Pyx_PyObject_AsWritableString(s) ((char*) __Pyx_PyObject_AsString(s)) #define __Pyx_PyObject_AsWritableSString(s) ((signed char*) __Pyx_PyObject_AsString(s)) #define __Pyx_PyObject_AsWritableUString(s) ((unsigned char*) __Pyx_PyObject_AsString(s)) #define __Pyx_PyObject_AsSString(s) ((const signed char*) __Pyx_PyObject_AsString(s)) #define __Pyx_PyObject_AsUString(s) ((const unsigned char*) __Pyx_PyObject_AsString(s)) #define __Pyx_PyObject_FromCString(s) __Pyx_PyObject_FromString((const char*)s) #define __Pyx_PyBytes_FromCString(s) __Pyx_PyBytes_FromString((const char*)s) #define __Pyx_PyByteArray_FromCString(s) __Pyx_PyByteArray_FromString((const char*)s) #define __Pyx_PyStr_FromCString(s) __Pyx_PyStr_FromString((const char*)s) #define __Pyx_PyUnicode_FromCString(s) __Pyx_PyUnicode_FromString((const char*)s) static CYTHON_INLINE size_t __Pyx_Py_UNICODE_strlen(const Py_UNICODE *u) { const Py_UNICODE *u_end = u; while (*u_end++) ; return (size_t)(u_end - u - 1); } #define __Pyx_PyUnicode_FromUnicode(u) PyUnicode_FromUnicode(u, __Pyx_Py_UNICODE_strlen(u)) #define __Pyx_PyUnicode_FromUnicodeAndLength PyUnicode_FromUnicode #define __Pyx_PyUnicode_AsUnicode PyUnicode_AsUnicode #define __Pyx_NewRef(obj) (Py_INCREF(obj), obj) #define __Pyx_Owned_Py_None(b) __Pyx_NewRef(Py_None) static CYTHON_INLINE PyObject * __Pyx_PyBool_FromLong(long b); static CYTHON_INLINE int __Pyx_PyObject_IsTrue(PyObject*); static CYTHON_INLINE int __Pyx_PyObject_IsTrueAndDecref(PyObject*); static CYTHON_INLINE PyObject* __Pyx_PyNumber_IntOrLong(PyObject* x); #define __Pyx_PySequence_Tuple(obj)\ (likely(PyTuple_CheckExact(obj)) ? __Pyx_NewRef(obj) : PySequence_Tuple(obj)) static CYTHON_INLINE Py_ssize_t __Pyx_PyIndex_AsSsize_t(PyObject*); static CYTHON_INLINE PyObject * __Pyx_PyInt_FromSize_t(size_t); static CYTHON_INLINE Py_hash_t __Pyx_PyIndex_AsHash_t(PyObject*); #if CYTHON_ASSUME_SAFE_MACROS #define __pyx_PyFloat_AsDouble(x) (PyFloat_CheckExact(x) ? PyFloat_AS_DOUBLE(x) : PyFloat_AsDouble(x)) #else #define __pyx_PyFloat_AsDouble(x) PyFloat_AsDouble(x) #endif #define __pyx_PyFloat_AsFloat(x) ((float) __pyx_PyFloat_AsDouble(x)) #if PY_MAJOR_VERSION >= 3 #define __Pyx_PyNumber_Int(x) (PyLong_CheckExact(x) ? __Pyx_NewRef(x) : PyNumber_Long(x)) #else #define __Pyx_PyNumber_Int(x) (PyInt_CheckExact(x) ? __Pyx_NewRef(x) : PyNumber_Int(x)) #endif #define __Pyx_PyNumber_Float(x) (PyFloat_CheckExact(x) ? __Pyx_NewRef(x) : PyNumber_Float(x)) #if PY_MAJOR_VERSION < 3 && __PYX_DEFAULT_STRING_ENCODING_IS_ASCII static int __Pyx_sys_getdefaultencoding_not_ascii; static int __Pyx_init_sys_getdefaultencoding_params(void) { PyObject* sys; PyObject* default_encoding = NULL; PyObject* ascii_chars_u = NULL; PyObject* ascii_chars_b = NULL; const char* default_encoding_c; sys = PyImport_ImportModule("sys"); if (!sys) goto bad; default_encoding = PyObject_CallMethod(sys, (char*) "getdefaultencoding", NULL); Py_DECREF(sys); if (!default_encoding) goto bad; default_encoding_c = PyBytes_AsString(default_encoding); if (!default_encoding_c) goto bad; if (strcmp(default_encoding_c, "ascii") == 0) { __Pyx_sys_getdefaultencoding_not_ascii = 0; } else { char ascii_chars[128]; int c; for (c = 0; c < 128; c++) { ascii_chars[c] = c; } __Pyx_sys_getdefaultencoding_not_ascii = 1; ascii_chars_u = PyUnicode_DecodeASCII(ascii_chars, 128, NULL); if (!ascii_chars_u) goto bad; ascii_chars_b = PyUnicode_AsEncodedString(ascii_chars_u, default_encoding_c, NULL); if (!ascii_chars_b || !PyBytes_Check(ascii_chars_b) || memcmp(ascii_chars, PyBytes_AS_STRING(ascii_chars_b), 128) != 0) { PyErr_Format( PyExc_ValueError, "This module compiled with c_string_encoding=ascii, but default encoding '%.200s' is not a superset of ascii.", default_encoding_c); goto bad; } Py_DECREF(ascii_chars_u); Py_DECREF(ascii_chars_b); } Py_DECREF(default_encoding); return 0; bad: Py_XDECREF(default_encoding); Py_XDECREF(ascii_chars_u); Py_XDECREF(ascii_chars_b); return -1; } #endif #if __PYX_DEFAULT_STRING_ENCODING_IS_DEFAULT && PY_MAJOR_VERSION >= 3 #define __Pyx_PyUnicode_FromStringAndSize(c_str, size) PyUnicode_DecodeUTF8(c_str, size, NULL) #else #define __Pyx_PyUnicode_FromStringAndSize(c_str, size) PyUnicode_Decode(c_str, size, __PYX_DEFAULT_STRING_ENCODING, NULL) #if __PYX_DEFAULT_STRING_ENCODING_IS_DEFAULT static char* __PYX_DEFAULT_STRING_ENCODING; static int __Pyx_init_sys_getdefaultencoding_params(void) { PyObject* sys; PyObject* default_encoding = NULL; char* default_encoding_c; sys = PyImport_ImportModule("sys"); if (!sys) goto bad; default_encoding = PyObject_CallMethod(sys, (char*) (const char*) "getdefaultencoding", NULL); Py_DECREF(sys); if (!default_encoding) goto bad; default_encoding_c = PyBytes_AsString(default_encoding); if (!default_encoding_c) goto bad; __PYX_DEFAULT_STRING_ENCODING = (char*) malloc(strlen(default_encoding_c) + 1); if (!__PYX_DEFAULT_STRING_ENCODING) goto bad; strcpy(__PYX_DEFAULT_STRING_ENCODING, default_encoding_c); Py_DECREF(default_encoding); return 0; bad: Py_XDECREF(default_encoding); return -1; } #endif #endif /* Test for GCC > 2.95 */ #if defined(__GNUC__) && (__GNUC__ > 2 || (__GNUC__ == 2 && (__GNUC_MINOR__ > 95))) #define likely(x) __builtin_expect(!!(x), 1) #define unlikely(x) __builtin_expect(!!(x), 0) #else /* !__GNUC__ or GCC < 2.95 */ #define likely(x) (x) #define unlikely(x) (x) #endif /* __GNUC__ */ static CYTHON_INLINE void __Pyx_pretend_to_initialize(void* ptr) { (void)ptr; 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const char* name; size_t offset; } __Pyx_StructField; typedef struct { __Pyx_StructField* field; size_t parent_offset; } __Pyx_BufFmt_StackElem; typedef struct { __Pyx_StructField root; __Pyx_BufFmt_StackElem* head; size_t fmt_offset; size_t new_count, enc_count; size_t struct_alignment; int is_complex; char enc_type; char new_packmode; char enc_packmode; char is_valid_array; } __Pyx_BufFmt_Context; /*--- Type declarations ---*/ struct __pyx_array_obj; struct __pyx_MemviewEnum_obj; struct __pyx_memoryview_obj; struct __pyx_memoryviewslice_obj; /* "View.MemoryView":105 * * @cname("__pyx_array") * cdef class array: # <<<<<<<<<<<<<< * * cdef: */ struct __pyx_array_obj { PyObject_HEAD struct __pyx_vtabstruct_array *__pyx_vtab; char *data; Py_ssize_t len; char *format; int ndim; Py_ssize_t *_shape; Py_ssize_t *_strides; Py_ssize_t itemsize; PyObject *mode; PyObject *_format; void (*callback_free_data)(void *); int free_data; int dtype_is_object; }; /* "View.MemoryView":279 * * @cname('__pyx_MemviewEnum') * cdef class Enum(object): # <<<<<<<<<<<<<< * cdef object name * def __init__(self, name): */ struct __pyx_MemviewEnum_obj { PyObject_HEAD PyObject *name; }; /* "View.MemoryView":330 * * @cname('__pyx_memoryview') * cdef class memoryview(object): # <<<<<<<<<<<<<< * * cdef object obj */ struct __pyx_memoryview_obj { PyObject_HEAD struct __pyx_vtabstruct_memoryview *__pyx_vtab; PyObject *obj; PyObject *_size; PyObject *_array_interface; PyThread_type_lock lock; __pyx_atomic_int acquisition_count[2]; __pyx_atomic_int *acquisition_count_aligned_p; Py_buffer view; int flags; int dtype_is_object; __Pyx_TypeInfo *typeinfo; }; /* "View.MemoryView":965 * * @cname('__pyx_memoryviewslice') * cdef class _memoryviewslice(memoryview): # <<<<<<<<<<<<<< * "Internal class for passing memoryview slices to Python" * */ struct __pyx_memoryviewslice_obj { struct __pyx_memoryview_obj __pyx_base; __Pyx_memviewslice from_slice; PyObject *from_object; PyObject *(*to_object_func)(char *); int (*to_dtype_func)(char *, PyObject *); }; /* "View.MemoryView":105 * * @cname("__pyx_array") * cdef class array: # <<<<<<<<<<<<<< * * cdef: */ struct __pyx_vtabstruct_array { PyObject *(*get_memview)(struct __pyx_array_obj *); }; static struct __pyx_vtabstruct_array *__pyx_vtabptr_array; /* "View.MemoryView":330 * * @cname('__pyx_memoryview') * cdef class memoryview(object): # <<<<<<<<<<<<<< * * cdef object obj */ struct __pyx_vtabstruct_memoryview { char *(*get_item_pointer)(struct __pyx_memoryview_obj *, PyObject *); PyObject *(*is_slice)(struct __pyx_memoryview_obj *, PyObject *); PyObject *(*setitem_slice_assignment)(struct __pyx_memoryview_obj *, PyObject *, PyObject *); PyObject *(*setitem_slice_assign_scalar)(struct __pyx_memoryview_obj *, struct __pyx_memoryview_obj *, PyObject *); PyObject *(*setitem_indexed)(struct __pyx_memoryview_obj *, PyObject *, PyObject *); PyObject *(*convert_item_to_object)(struct __pyx_memoryview_obj *, char *); PyObject *(*assign_item_from_object)(struct __pyx_memoryview_obj *, char *, PyObject *); }; static struct __pyx_vtabstruct_memoryview *__pyx_vtabptr_memoryview; /* "View.MemoryView":965 * * @cname('__pyx_memoryviewslice') * cdef class _memoryviewslice(memoryview): # <<<<<<<<<<<<<< * "Internal class for passing memoryview slices to Python" * */ struct __pyx_vtabstruct__memoryviewslice { struct __pyx_vtabstruct_memoryview __pyx_base; 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static CYTHON_INLINE int __pyx_add_acquisition_count_locked( __pyx_atomic_int *acquisition_count, PyThread_type_lock lock); static CYTHON_INLINE int __pyx_sub_acquisition_count_locked( __pyx_atomic_int *acquisition_count, PyThread_type_lock lock); #define __pyx_get_slice_count_pointer(memview) (memview->acquisition_count_aligned_p) #define __pyx_get_slice_count(memview) (*__pyx_get_slice_count_pointer(memview)) #define __PYX_INC_MEMVIEW(slice, have_gil) __Pyx_INC_MEMVIEW(slice, have_gil, __LINE__) #define __PYX_XDEC_MEMVIEW(slice, have_gil) __Pyx_XDEC_MEMVIEW(slice, have_gil, __LINE__) static CYTHON_INLINE void __Pyx_INC_MEMVIEW(__Pyx_memviewslice *, int, int); static CYTHON_INLINE void __Pyx_XDEC_MEMVIEW(__Pyx_memviewslice *, int, int); /* ArgTypeTest.proto */ #define __Pyx_ArgTypeTest(obj, type, none_allowed, name, exact)\ ((likely((Py_TYPE(obj) == type) | (none_allowed && (obj == Py_None)))) ? 1 :\ __Pyx__ArgTypeTest(obj, type, name, exact)) static int __Pyx__ArgTypeTest(PyObject *obj, PyTypeObject *type, const char *name, int exact); /* PyObjectCall.proto */ #if CYTHON_COMPILING_IN_CPYTHON static CYTHON_INLINE PyObject* __Pyx_PyObject_Call(PyObject *func, PyObject *arg, PyObject *kw); #else #define __Pyx_PyObject_Call(func, arg, kw) PyObject_Call(func, arg, kw) #endif /* PyThreadStateGet.proto */ #if CYTHON_FAST_THREAD_STATE #define __Pyx_PyThreadState_declare PyThreadState *__pyx_tstate; #define __Pyx_PyThreadState_assign __pyx_tstate = __Pyx_PyThreadState_Current; #define __Pyx_PyErr_Occurred() __pyx_tstate->curexc_type #else #define __Pyx_PyThreadState_declare #define __Pyx_PyThreadState_assign #define __Pyx_PyErr_Occurred() PyErr_Occurred() #endif /* PyErrFetchRestore.proto */ #if CYTHON_FAST_THREAD_STATE #define __Pyx_PyErr_Clear() __Pyx_ErrRestore(NULL, NULL, NULL) #define __Pyx_ErrRestoreWithState(type, value, tb) __Pyx_ErrRestoreInState(PyThreadState_GET(), type, value, tb) #define __Pyx_ErrFetchWithState(type, value, tb) __Pyx_ErrFetchInState(PyThreadState_GET(), type, value, tb) #define __Pyx_ErrRestore(type, value, tb) __Pyx_ErrRestoreInState(__pyx_tstate, type, value, tb) #define __Pyx_ErrFetch(type, value, tb) __Pyx_ErrFetchInState(__pyx_tstate, type, value, tb) static CYTHON_INLINE void __Pyx_ErrRestoreInState(PyThreadState *tstate, PyObject *type, PyObject *value, PyObject *tb); static CYTHON_INLINE void __Pyx_ErrFetchInState(PyThreadState *tstate, PyObject **type, PyObject **value, PyObject **tb); #if CYTHON_COMPILING_IN_CPYTHON #define __Pyx_PyErr_SetNone(exc) (Py_INCREF(exc), __Pyx_ErrRestore((exc), NULL, NULL)) #else #define __Pyx_PyErr_SetNone(exc) PyErr_SetNone(exc) #endif #else #define __Pyx_PyErr_Clear() PyErr_Clear() #define __Pyx_PyErr_SetNone(exc) PyErr_SetNone(exc) #define __Pyx_ErrRestoreWithState(type, value, tb) PyErr_Restore(type, value, tb) #define __Pyx_ErrFetchWithState(type, value, tb) PyErr_Fetch(type, value, tb) #define __Pyx_ErrRestoreInState(tstate, type, value, tb) PyErr_Restore(type, value, tb) #define __Pyx_ErrFetchInState(tstate, type, value, tb) PyErr_Fetch(type, value, tb) #define __Pyx_ErrRestore(type, value, tb) PyErr_Restore(type, value, tb) #define __Pyx_ErrFetch(type, value, tb) PyErr_Fetch(type, value, tb) #endif /* RaiseException.proto */ static void __Pyx_Raise(PyObject *type, PyObject *value, PyObject *tb, PyObject *cause); /* PyCFunctionFastCall.proto */ #if CYTHON_FAST_PYCCALL static CYTHON_INLINE PyObject *__Pyx_PyCFunction_FastCall(PyObject *func, PyObject **args, Py_ssize_t nargs); #else #define __Pyx_PyCFunction_FastCall(func, args, nargs) (assert(0), NULL) #endif /* PyFunctionFastCall.proto */ #if CYTHON_FAST_PYCALL #define __Pyx_PyFunction_FastCall(func, args, nargs)\ __Pyx_PyFunction_FastCallDict((func), (args), (nargs), NULL) #if 1 || PY_VERSION_HEX < 0x030600B1 static PyObject *__Pyx_PyFunction_FastCallDict(PyObject *func, PyObject **args, Py_ssize_t nargs, PyObject *kwargs); #else #define __Pyx_PyFunction_FastCallDict(func, args, nargs, kwargs) _PyFunction_FastCallDict(func, args, nargs, kwargs) #endif #define __Pyx_BUILD_ASSERT_EXPR(cond)\ (sizeof(char [1 - 2*!(cond)]) - 1) #ifndef Py_MEMBER_SIZE #define Py_MEMBER_SIZE(type, member) sizeof(((type *)0)->member) #endif #if CYTHON_FAST_PYCALL static size_t __pyx_pyframe_localsplus_offset = 0; #include "frameobject.h" #define __Pxy_PyFrame_Initialize_Offsets()\ ((void)__Pyx_BUILD_ASSERT_EXPR(sizeof(PyFrameObject) == offsetof(PyFrameObject, f_localsplus) + Py_MEMBER_SIZE(PyFrameObject, f_localsplus)),\ (void)(__pyx_pyframe_localsplus_offset = ((size_t)PyFrame_Type.tp_basicsize) - Py_MEMBER_SIZE(PyFrameObject, f_localsplus))) #define __Pyx_PyFrame_GetLocalsplus(frame)\ (assert(__pyx_pyframe_localsplus_offset), (PyObject **)(((char *)(frame)) + __pyx_pyframe_localsplus_offset)) #endif // CYTHON_FAST_PYCALL #endif /* PyObjectCall2Args.proto */ static CYTHON_UNUSED PyObject* __Pyx_PyObject_Call2Args(PyObject* function, PyObject* arg1, PyObject* arg2); /* PyObjectCallMethO.proto */ #if CYTHON_COMPILING_IN_CPYTHON static CYTHON_INLINE PyObject* __Pyx_PyObject_CallMethO(PyObject *func, PyObject *arg); #endif /* PyObjectCallOneArg.proto */ static CYTHON_INLINE PyObject* __Pyx_PyObject_CallOneArg(PyObject *func, PyObject *arg); /* IncludeStringH.proto */ #include <string.h> /* BytesEquals.proto */ static CYTHON_INLINE int __Pyx_PyBytes_Equals(PyObject* s1, PyObject* s2, int equals); /* UnicodeEquals.proto */ static CYTHON_INLINE int __Pyx_PyUnicode_Equals(PyObject* s1, PyObject* s2, int equals); /* StrEquals.proto */ #if PY_MAJOR_VERSION >= 3 #define __Pyx_PyString_Equals __Pyx_PyUnicode_Equals #else #define __Pyx_PyString_Equals __Pyx_PyBytes_Equals #endif /* None.proto */ static CYTHON_INLINE Py_ssize_t __Pyx_div_Py_ssize_t(Py_ssize_t, Py_ssize_t); /* UnaryNegOverflows.proto */ #define UNARY_NEG_WOULD_OVERFLOW(x)\ (((x) < 0) & ((unsigned long)(x) == 0-(unsigned long)(x))) static CYTHON_UNUSED int __pyx_array_getbuffer(PyObject *__pyx_v_self, Py_buffer *__pyx_v_info, int __pyx_v_flags); /*proto*/ static PyObject *__pyx_array_get_memview(struct __pyx_array_obj *); /*proto*/ /* GetAttr.proto */ static CYTHON_INLINE PyObject *__Pyx_GetAttr(PyObject *, PyObject *); /* GetItemInt.proto */ #define __Pyx_GetItemInt(o, i, type, is_signed, to_py_func, is_list, wraparound, boundscheck)\ (__Pyx_fits_Py_ssize_t(i, type, is_signed) ?\ __Pyx_GetItemInt_Fast(o, (Py_ssize_t)i, is_list, wraparound, boundscheck) :\ (is_list ? (PyErr_SetString(PyExc_IndexError, "list index out of range"), (PyObject*)NULL) :\ __Pyx_GetItemInt_Generic(o, to_py_func(i)))) #define __Pyx_GetItemInt_List(o, i, type, is_signed, to_py_func, is_list, wraparound, boundscheck)\ (__Pyx_fits_Py_ssize_t(i, type, is_signed) ?\ __Pyx_GetItemInt_List_Fast(o, (Py_ssize_t)i, wraparound, boundscheck) :\ (PyErr_SetString(PyExc_IndexError, "list index out of range"), (PyObject*)NULL)) static CYTHON_INLINE PyObject *__Pyx_GetItemInt_List_Fast(PyObject *o, Py_ssize_t i, int wraparound, int boundscheck); #define __Pyx_GetItemInt_Tuple(o, i, type, is_signed, to_py_func, is_list, wraparound, boundscheck)\ (__Pyx_fits_Py_ssize_t(i, type, is_signed) ?\ __Pyx_GetItemInt_Tuple_Fast(o, (Py_ssize_t)i, wraparound, boundscheck) :\ (PyErr_SetString(PyExc_IndexError, "tuple index out of range"), (PyObject*)NULL)) static CYTHON_INLINE PyObject *__Pyx_GetItemInt_Tuple_Fast(PyObject *o, Py_ssize_t i, int wraparound, int boundscheck); static PyObject *__Pyx_GetItemInt_Generic(PyObject *o, PyObject* j); static CYTHON_INLINE PyObject *__Pyx_GetItemInt_Fast(PyObject *o, Py_ssize_t i, int is_list, int wraparound, int boundscheck); /* ObjectGetItem.proto */ #if CYTHON_USE_TYPE_SLOTS static CYTHON_INLINE PyObject *__Pyx_PyObject_GetItem(PyObject *obj, PyObject* key); #else #define __Pyx_PyObject_GetItem(obj, key) PyObject_GetItem(obj, key) #endif /* decode_c_string_utf16.proto */ static CYTHON_INLINE PyObject *__Pyx_PyUnicode_DecodeUTF16(const char *s, Py_ssize_t size, const char *errors) { int byteorder = 0; return PyUnicode_DecodeUTF16(s, size, errors, &byteorder); } static CYTHON_INLINE PyObject *__Pyx_PyUnicode_DecodeUTF16LE(const char *s, Py_ssize_t size, const char *errors) { int byteorder = -1; return PyUnicode_DecodeUTF16(s, size, errors, &byteorder); } static CYTHON_INLINE PyObject *__Pyx_PyUnicode_DecodeUTF16BE(const char *s, Py_ssize_t size, const char *errors) { int byteorder = 1; return PyUnicode_DecodeUTF16(s, size, errors, &byteorder); } /* decode_c_string.proto */ static CYTHON_INLINE PyObject* __Pyx_decode_c_string( const char* cstring, Py_ssize_t start, Py_ssize_t stop, const char* encoding, const char* errors, PyObject* (*decode_func)(const char *s, Py_ssize_t size, const char *errors)); /* PyErrExceptionMatches.proto */ #if CYTHON_FAST_THREAD_STATE #define __Pyx_PyErr_ExceptionMatches(err) __Pyx_PyErr_ExceptionMatchesInState(__pyx_tstate, err) static CYTHON_INLINE int __Pyx_PyErr_ExceptionMatchesInState(PyThreadState* tstate, PyObject* err); #else #define __Pyx_PyErr_ExceptionMatches(err) PyErr_ExceptionMatches(err) #endif /* GetAttr3.proto */ static CYTHON_INLINE PyObject *__Pyx_GetAttr3(PyObject *, PyObject *, PyObject *); /* PyDictVersioning.proto */ #if CYTHON_USE_DICT_VERSIONS && CYTHON_USE_TYPE_SLOTS #define __PYX_DICT_VERSION_INIT ((PY_UINT64_T) -1) #define __PYX_GET_DICT_VERSION(dict) (((PyDictObject*)(dict))->ma_version_tag) #define __PYX_UPDATE_DICT_CACHE(dict, value, cache_var, version_var)\ (version_var) = __PYX_GET_DICT_VERSION(dict);\ (cache_var) = (value); #define __PYX_PY_DICT_LOOKUP_IF_MODIFIED(VAR, DICT, LOOKUP) {\ static PY_UINT64_T __pyx_dict_version = 0;\ static PyObject *__pyx_dict_cached_value = NULL;\ if (likely(__PYX_GET_DICT_VERSION(DICT) == __pyx_dict_version)) {\ (VAR) = __pyx_dict_cached_value;\ } else {\ (VAR) = __pyx_dict_cached_value = (LOOKUP);\ __pyx_dict_version = __PYX_GET_DICT_VERSION(DICT);\ }\ } static CYTHON_INLINE PY_UINT64_T __Pyx_get_tp_dict_version(PyObject *obj); static CYTHON_INLINE PY_UINT64_T __Pyx_get_object_dict_version(PyObject *obj); static CYTHON_INLINE int __Pyx_object_dict_version_matches(PyObject* obj, PY_UINT64_T tp_dict_version, PY_UINT64_T obj_dict_version); #else #define __PYX_GET_DICT_VERSION(dict) (0) #define __PYX_UPDATE_DICT_CACHE(dict, value, cache_var, version_var) #define __PYX_PY_DICT_LOOKUP_IF_MODIFIED(VAR, DICT, LOOKUP) (VAR) = (LOOKUP); #endif /* GetModuleGlobalName.proto */ #if CYTHON_USE_DICT_VERSIONS #define __Pyx_GetModuleGlobalName(var, name) {\ static PY_UINT64_T __pyx_dict_version = 0;\ static PyObject *__pyx_dict_cached_value = NULL;\ (var) = (likely(__pyx_dict_version == __PYX_GET_DICT_VERSION(__pyx_d))) ?\ (likely(__pyx_dict_cached_value) ? __Pyx_NewRef(__pyx_dict_cached_value) : __Pyx_GetBuiltinName(name)) :\ __Pyx__GetModuleGlobalName(name, &__pyx_dict_version, &__pyx_dict_cached_value);\ } #define __Pyx_GetModuleGlobalNameUncached(var, name) {\ PY_UINT64_T __pyx_dict_version;\ PyObject *__pyx_dict_cached_value;\ (var) = __Pyx__GetModuleGlobalName(name, &__pyx_dict_version, &__pyx_dict_cached_value);\ } static PyObject *__Pyx__GetModuleGlobalName(PyObject *name, PY_UINT64_T *dict_version, PyObject **dict_cached_value); #else #define __Pyx_GetModuleGlobalName(var, name) (var) = __Pyx__GetModuleGlobalName(name) #define __Pyx_GetModuleGlobalNameUncached(var, name) (var) = __Pyx__GetModuleGlobalName(name) static CYTHON_INLINE PyObject *__Pyx__GetModuleGlobalName(PyObject *name); #endif /* RaiseTooManyValuesToUnpack.proto */ static CYTHON_INLINE void __Pyx_RaiseTooManyValuesError(Py_ssize_t expected); /* RaiseNeedMoreValuesToUnpack.proto */ static CYTHON_INLINE void __Pyx_RaiseNeedMoreValuesError(Py_ssize_t index); /* RaiseNoneIterError.proto */ static CYTHON_INLINE void __Pyx_RaiseNoneNotIterableError(void); /* ExtTypeTest.proto */ static CYTHON_INLINE int __Pyx_TypeTest(PyObject *obj, PyTypeObject *type); /* GetTopmostException.proto */ #if CYTHON_USE_EXC_INFO_STACK static _PyErr_StackItem * __Pyx_PyErr_GetTopmostException(PyThreadState *tstate); #endif /* SaveResetException.proto */ #if CYTHON_FAST_THREAD_STATE #define __Pyx_ExceptionSave(type, value, tb) __Pyx__ExceptionSave(__pyx_tstate, type, value, tb) static CYTHON_INLINE void __Pyx__ExceptionSave(PyThreadState *tstate, PyObject **type, PyObject **value, PyObject **tb); #define __Pyx_ExceptionReset(type, value, tb) __Pyx__ExceptionReset(__pyx_tstate, type, value, tb) static CYTHON_INLINE void __Pyx__ExceptionReset(PyThreadState *tstate, PyObject *type, PyObject *value, PyObject *tb); #else #define __Pyx_ExceptionSave(type, value, tb) PyErr_GetExcInfo(type, value, tb) #define __Pyx_ExceptionReset(type, value, tb) PyErr_SetExcInfo(type, value, tb) #endif /* GetException.proto */ #if CYTHON_FAST_THREAD_STATE #define __Pyx_GetException(type, value, tb) __Pyx__GetException(__pyx_tstate, type, value, tb) static int __Pyx__GetException(PyThreadState *tstate, PyObject **type, PyObject **value, PyObject **tb); #else static int __Pyx_GetException(PyObject **type, PyObject **value, PyObject **tb); #endif /* SwapException.proto */ #if CYTHON_FAST_THREAD_STATE #define __Pyx_ExceptionSwap(type, value, tb) __Pyx__ExceptionSwap(__pyx_tstate, type, value, tb) static CYTHON_INLINE void __Pyx__ExceptionSwap(PyThreadState *tstate, PyObject **type, PyObject **value, PyObject **tb); #else static CYTHON_INLINE void __Pyx_ExceptionSwap(PyObject **type, PyObject **value, PyObject **tb); #endif /* Import.proto */ static PyObject *__Pyx_Import(PyObject *name, PyObject *from_list, int level); /* FastTypeChecks.proto */ #if CYTHON_COMPILING_IN_CPYTHON #define __Pyx_TypeCheck(obj, type) __Pyx_IsSubtype(Py_TYPE(obj), (PyTypeObject *)type) static CYTHON_INLINE int __Pyx_IsSubtype(PyTypeObject *a, PyTypeObject *b); static CYTHON_INLINE int __Pyx_PyErr_GivenExceptionMatches(PyObject *err, PyObject *type); static CYTHON_INLINE int __Pyx_PyErr_GivenExceptionMatches2(PyObject *err, PyObject *type1, PyObject *type2); #else #define __Pyx_TypeCheck(obj, type) PyObject_TypeCheck(obj, (PyTypeObject *)type) #define __Pyx_PyErr_GivenExceptionMatches(err, type) PyErr_GivenExceptionMatches(err, type) #define __Pyx_PyErr_GivenExceptionMatches2(err, type1, type2) (PyErr_GivenExceptionMatches(err, type1) || PyErr_GivenExceptionMatches(err, type2)) #endif #define __Pyx_PyException_Check(obj) __Pyx_TypeCheck(obj, PyExc_Exception) static CYTHON_UNUSED int __pyx_memoryview_getbuffer(PyObject *__pyx_v_self, Py_buffer *__pyx_v_info, int __pyx_v_flags); /*proto*/ /* ListCompAppend.proto */ #if CYTHON_USE_PYLIST_INTERNALS && CYTHON_ASSUME_SAFE_MACROS static CYTHON_INLINE int __Pyx_ListComp_Append(PyObject* list, PyObject* x) { PyListObject* L = (PyListObject*) list; Py_ssize_t len = Py_SIZE(list); if (likely(L->allocated > len)) { Py_INCREF(x); PyList_SET_ITEM(list, len, x); __Pyx_SET_SIZE(list, len + 1); return 0; } return PyList_Append(list, x); } #else #define __Pyx_ListComp_Append(L,x) PyList_Append(L,x) #endif /* PyIntBinop.proto */ #if !CYTHON_COMPILING_IN_PYPY static PyObject* __Pyx_PyInt_AddObjC(PyObject *op1, PyObject *op2, long intval, int inplace, int zerodivision_check); #else #define __Pyx_PyInt_AddObjC(op1, op2, intval, inplace, zerodivision_check)\ (inplace ? PyNumber_InPlaceAdd(op1, op2) : PyNumber_Add(op1, op2)) #endif /* ListExtend.proto */ static CYTHON_INLINE int __Pyx_PyList_Extend(PyObject* L, PyObject* v) { #if CYTHON_COMPILING_IN_CPYTHON PyObject* none = _PyList_Extend((PyListObject*)L, v); if (unlikely(!none)) return -1; Py_DECREF(none); return 0; #else return PyList_SetSlice(L, PY_SSIZE_T_MAX, PY_SSIZE_T_MAX, v); #endif } /* ListAppend.proto */ #if CYTHON_USE_PYLIST_INTERNALS && CYTHON_ASSUME_SAFE_MACROS static CYTHON_INLINE int __Pyx_PyList_Append(PyObject* list, PyObject* x) { PyListObject* L = (PyListObject*) list; Py_ssize_t len = Py_SIZE(list); if (likely(L->allocated > len) & likely(len > (L->allocated >> 1))) { Py_INCREF(x); PyList_SET_ITEM(list, len, x); __Pyx_SET_SIZE(list, len + 1); return 0; } return PyList_Append(list, x); } #else #define __Pyx_PyList_Append(L,x) PyList_Append(L,x) #endif /* None.proto */ static CYTHON_INLINE void __Pyx_RaiseUnboundLocalError(const char *varname); /* None.proto */ static CYTHON_INLINE long __Pyx_div_long(long, long); /* ImportFrom.proto */ static PyObject* __Pyx_ImportFrom(PyObject* module, PyObject* name); /* HasAttr.proto */ static CYTHON_INLINE int __Pyx_HasAttr(PyObject *, PyObject *); /* PyObject_GenericGetAttrNoDict.proto */ #if CYTHON_USE_TYPE_SLOTS && CYTHON_USE_PYTYPE_LOOKUP && PY_VERSION_HEX < 0x03070000 static CYTHON_INLINE PyObject* __Pyx_PyObject_GenericGetAttrNoDict(PyObject* obj, PyObject* attr_name); #else #define __Pyx_PyObject_GenericGetAttrNoDict PyObject_GenericGetAttr #endif /* PyObject_GenericGetAttr.proto */ #if CYTHON_USE_TYPE_SLOTS && CYTHON_USE_PYTYPE_LOOKUP && PY_VERSION_HEX < 0x03070000 static PyObject* __Pyx_PyObject_GenericGetAttr(PyObject* obj, PyObject* attr_name); #else #define __Pyx_PyObject_GenericGetAttr PyObject_GenericGetAttr #endif /* SetVTable.proto */ static int __Pyx_SetVtable(PyObject *dict, void *vtable); /* PyObjectGetAttrStrNoError.proto */ static CYTHON_INLINE PyObject* __Pyx_PyObject_GetAttrStrNoError(PyObject* obj, PyObject* attr_name); /* SetupReduce.proto */ static int __Pyx_setup_reduce(PyObject* type_obj); /* CLineInTraceback.proto */ #ifdef CYTHON_CLINE_IN_TRACEBACK #define __Pyx_CLineForTraceback(tstate, c_line) (((CYTHON_CLINE_IN_TRACEBACK)) ? c_line : 0) #else static int __Pyx_CLineForTraceback(PyThreadState *tstate, int c_line); #endif /* CodeObjectCache.proto */ typedef struct { PyCodeObject* code_object; int code_line; } __Pyx_CodeObjectCacheEntry; struct __Pyx_CodeObjectCache { int count; int max_count; __Pyx_CodeObjectCacheEntry* entries; }; static struct __Pyx_CodeObjectCache __pyx_code_cache = {0,0,NULL}; static int __pyx_bisect_code_objects(__Pyx_CodeObjectCacheEntry* entries, int count, int code_line); static PyCodeObject *__pyx_find_code_object(int code_line); static void __pyx_insert_code_object(int code_line, PyCodeObject* code_object); /* AddTraceback.proto */ static void __Pyx_AddTraceback(const char *funcname, int c_line, int py_line, const char *filename); #if PY_MAJOR_VERSION < 3 static int __Pyx_GetBuffer(PyObject *obj, Py_buffer *view, int flags); static void __Pyx_ReleaseBuffer(Py_buffer *view); #else #define __Pyx_GetBuffer PyObject_GetBuffer #define __Pyx_ReleaseBuffer PyBuffer_Release #endif /* BufferStructDeclare.proto */ typedef struct { Py_ssize_t shape, strides, suboffsets; } __Pyx_Buf_DimInfo; typedef struct { size_t refcount; Py_buffer pybuffer; } __Pyx_Buffer; typedef struct { __Pyx_Buffer *rcbuffer; char *data; __Pyx_Buf_DimInfo diminfo[8]; } __Pyx_LocalBuf_ND; /* MemviewSliceIsContig.proto */ static int __pyx_memviewslice_is_contig(const __Pyx_memviewslice mvs, char order, int ndim); /* OverlappingSlices.proto */ static int __pyx_slices_overlap(__Pyx_memviewslice *slice1, __Pyx_memviewslice *slice2, int ndim, size_t itemsize); /* Capsule.proto */ static CYTHON_INLINE PyObject *__pyx_capsule_create(void *p, const char *sig); /* IsLittleEndian.proto */ static CYTHON_INLINE int __Pyx_Is_Little_Endian(void); /* BufferFormatCheck.proto */ static const char* __Pyx_BufFmt_CheckString(__Pyx_BufFmt_Context* ctx, const char* ts); static void __Pyx_BufFmt_Init(__Pyx_BufFmt_Context* ctx, __Pyx_BufFmt_StackElem* stack, __Pyx_TypeInfo* type); /* TypeInfoCompare.proto */ static int __pyx_typeinfo_cmp(__Pyx_TypeInfo *a, __Pyx_TypeInfo *b); /* MemviewSliceValidateAndInit.proto */ static int __Pyx_ValidateAndInit_memviewslice( int *axes_specs, int c_or_f_flag, int buf_flags, int ndim, __Pyx_TypeInfo *dtype, __Pyx_BufFmt_StackElem stack[], __Pyx_memviewslice *memviewslice, PyObject *original_obj); /* ObjectToMemviewSlice.proto */ static CYTHON_INLINE __Pyx_memviewslice __Pyx_PyObject_to_MemoryviewSlice_d_dc_double(PyObject *, int writable_flag); /* ObjectToMemviewSlice.proto */ static CYTHON_INLINE __Pyx_memviewslice __Pyx_PyObject_to_MemoryviewSlice_ds_double(PyObject *, int writable_flag); /* ObjectToMemviewSlice.proto */ static CYTHON_INLINE __Pyx_memviewslice __Pyx_PyObject_to_MemoryviewSlice_dc_double(PyObject *, int writable_flag); /* ObjectToMemviewSlice.proto */ static CYTHON_INLINE __Pyx_memviewslice __Pyx_PyObject_to_MemoryviewSlice_d_dc_long(PyObject *, int writable_flag); /* GCCDiagnostics.proto */ #if defined(__GNUC__) && (__GNUC__ > 4 || (__GNUC__ == 4 && __GNUC_MINOR__ >= 6)) #define __Pyx_HAS_GCC_DIAGNOSTIC #endif /* MemviewDtypeToObject.proto */ static CYTHON_INLINE PyObject *__pyx_memview_get_double(const char *itemp); static CYTHON_INLINE int __pyx_memview_set_double(const char *itemp, PyObject *obj); /* MemviewSliceCopyTemplate.proto */ static __Pyx_memviewslice __pyx_memoryview_copy_new_contig(const __Pyx_memviewslice *from_mvs, const char *mode, int ndim, size_t sizeof_dtype, int contig_flag, int dtype_is_object); /* CIntFromPy.proto */ static CYTHON_INLINE long __Pyx_PyInt_As_long(PyObject *); /* CIntFromPy.proto */ static CYTHON_INLINE int __Pyx_PyInt_As_int(PyObject *); /* CIntToPy.proto */ static CYTHON_INLINE PyObject* __Pyx_PyInt_From_int(int value); /* CIntToPy.proto */ static CYTHON_INLINE PyObject* __Pyx_PyInt_From_long(long value); /* CIntFromPy.proto */ static CYTHON_INLINE char __Pyx_PyInt_As_char(PyObject *); /* CheckBinaryVersion.proto */ static int __Pyx_check_binary_version(void); /* InitStrings.proto */ static int __Pyx_InitStrings(__Pyx_StringTabEntry *t); static PyObject *__pyx_array_get_memview(struct __pyx_array_obj *__pyx_v_self); /* proto*/ static char *__pyx_memoryview_get_item_pointer(struct __pyx_memoryview_obj *__pyx_v_self, PyObject *__pyx_v_index); /* proto*/ static PyObject *__pyx_memoryview_is_slice(struct __pyx_memoryview_obj *__pyx_v_self, PyObject *__pyx_v_obj); /* proto*/ static PyObject *__pyx_memoryview_setitem_slice_assignment(struct __pyx_memoryview_obj *__pyx_v_self, PyObject *__pyx_v_dst, PyObject *__pyx_v_src); /* proto*/ static PyObject *__pyx_memoryview_setitem_slice_assign_scalar(struct __pyx_memoryview_obj *__pyx_v_self, struct __pyx_memoryview_obj *__pyx_v_dst, PyObject *__pyx_v_value); /* proto*/ static PyObject *__pyx_memoryview_setitem_indexed(struct __pyx_memoryview_obj *__pyx_v_self, PyObject *__pyx_v_index, PyObject *__pyx_v_value); /* proto*/ static PyObject *__pyx_memoryview_convert_item_to_object(struct __pyx_memoryview_obj *__pyx_v_self, char *__pyx_v_itemp); /* proto*/ static PyObject *__pyx_memoryview_assign_item_from_object(struct __pyx_memoryview_obj *__pyx_v_self, char *__pyx_v_itemp, PyObject *__pyx_v_value); /* proto*/ static PyObject *__pyx_memoryviewslice_convert_item_to_object(struct __pyx_memoryviewslice_obj *__pyx_v_self, char *__pyx_v_itemp); /* proto*/ static PyObject *__pyx_memoryviewslice_assign_item_from_object(struct __pyx_memoryviewslice_obj *__pyx_v_self, char *__pyx_v_itemp, PyObject *__pyx_v_value); /* proto*/ /* Module declarations from 'cython.view' */ /* Module declarations from 'cython' */ /* Module declarations from 'libc.math' */ /* Module declarations from 'shakemap.c.clib' */ static PyTypeObject *__pyx_array_type = 0; static PyTypeObject *__pyx_MemviewEnum_type = 0; static PyTypeObject *__pyx_memoryview_type = 0; static PyTypeObject *__pyx_memoryviewslice_type = 0; static PyObject *generic = 0; static PyObject *strided = 0; static PyObject *indirect = 0; static PyObject *contiguous = 0; static PyObject *indirect_contiguous = 0; static int __pyx_memoryview_thread_locks_used; static PyThread_type_lock __pyx_memoryview_thread_locks[8]; static struct __pyx_array_obj *__pyx_array_new(PyObject *, Py_ssize_t, char *, char *, char *); /*proto*/ static void *__pyx_align_pointer(void *, size_t); /*proto*/ static PyObject *__pyx_memoryview_new(PyObject *, int, int, __Pyx_TypeInfo *); /*proto*/ static CYTHON_INLINE int __pyx_memoryview_check(PyObject *); /*proto*/ static PyObject *_unellipsify(PyObject *, int); /*proto*/ static PyObject *assert_direct_dimensions(Py_ssize_t *, int); /*proto*/ static struct __pyx_memoryview_obj *__pyx_memview_slice(struct __pyx_memoryview_obj *, PyObject *); /*proto*/ static int __pyx_memoryview_slice_memviewslice(__Pyx_memviewslice *, Py_ssize_t, Py_ssize_t, Py_ssize_t, int, int, int *, Py_ssize_t, Py_ssize_t, Py_ssize_t, int, int, int, int); /*proto*/ static char *__pyx_pybuffer_index(Py_buffer *, char *, Py_ssize_t, Py_ssize_t); /*proto*/ static int __pyx_memslice_transpose(__Pyx_memviewslice *); /*proto*/ static PyObject *__pyx_memoryview_fromslice(__Pyx_memviewslice, int, PyObject *(*)(char *), int (*)(char *, PyObject *), int); /*proto*/ static __Pyx_memviewslice *__pyx_memoryview_get_slice_from_memoryview(struct __pyx_memoryview_obj *, __Pyx_memviewslice *); /*proto*/ static void __pyx_memoryview_slice_copy(struct __pyx_memoryview_obj *, __Pyx_memviewslice *); /*proto*/ static PyObject *__pyx_memoryview_copy_object(struct __pyx_memoryview_obj *); /*proto*/ static PyObject *__pyx_memoryview_copy_object_from_slice(struct __pyx_memoryview_obj *, __Pyx_memviewslice *); /*proto*/ static Py_ssize_t abs_py_ssize_t(Py_ssize_t); /*proto*/ static char __pyx_get_best_slice_order(__Pyx_memviewslice *, int); /*proto*/ static void _copy_strided_to_strided(char *, Py_ssize_t *, char *, Py_ssize_t *, Py_ssize_t *, Py_ssize_t *, int, size_t); /*proto*/ static void copy_strided_to_strided(__Pyx_memviewslice *, __Pyx_memviewslice *, int, size_t); /*proto*/ static Py_ssize_t __pyx_memoryview_slice_get_size(__Pyx_memviewslice *, int); /*proto*/ static Py_ssize_t __pyx_fill_contig_strides_array(Py_ssize_t *, Py_ssize_t *, Py_ssize_t, int, char); /*proto*/ static void *__pyx_memoryview_copy_data_to_temp(__Pyx_memviewslice *, __Pyx_memviewslice *, char, int); /*proto*/ static int __pyx_memoryview_err_extents(int, Py_ssize_t, Py_ssize_t); /*proto*/ static int __pyx_memoryview_err_dim(PyObject *, char *, int); /*proto*/ static int __pyx_memoryview_err(PyObject *, char *); /*proto*/ static int __pyx_memoryview_copy_contents(__Pyx_memviewslice, __Pyx_memviewslice, int, int, int); /*proto*/ static void __pyx_memoryview_broadcast_leading(__Pyx_memviewslice *, int, int); /*proto*/ static void __pyx_memoryview_refcount_copying(__Pyx_memviewslice *, int, int, int); /*proto*/ static void __pyx_memoryview_refcount_objects_in_slice_with_gil(char *, Py_ssize_t *, Py_ssize_t *, int, int); /*proto*/ static void __pyx_memoryview_refcount_objects_in_slice(char *, Py_ssize_t *, Py_ssize_t *, int, int); /*proto*/ static void __pyx_memoryview_slice_assign_scalar(__Pyx_memviewslice *, int, size_t, void *, int); /*proto*/ static void __pyx_memoryview__slice_assign_scalar(char *, Py_ssize_t *, Py_ssize_t *, int, size_t, void *); /*proto*/ static PyObject *__pyx_unpickle_Enum__set_state(struct __pyx_MemviewEnum_obj *, PyObject *); /*proto*/ static __Pyx_TypeInfo __Pyx_TypeInfo_double = { "double", NULL, sizeof(double), { 0 }, 0, 'R', 0, 0 }; static __Pyx_TypeInfo __Pyx_TypeInfo_long = { "long", NULL, sizeof(long), { 0 }, 0, IS_UNSIGNED(long) ? 'U' : 'I', IS_UNSIGNED(long), 0 }; #define __Pyx_MODULE_NAME "shakemap.c.clib" extern int __pyx_module_is_main_shakemap__c__clib; int __pyx_module_is_main_shakemap__c__clib = 0; /* Implementation of 'shakemap.c.clib' */ static PyObject *__pyx_builtin_range; static PyObject *__pyx_builtin_ValueError; static PyObject *__pyx_builtin_MemoryError; static PyObject *__pyx_builtin_enumerate; static PyObject *__pyx_builtin_TypeError; static PyObject *__pyx_builtin_Ellipsis; static PyObject *__pyx_builtin_id; static PyObject *__pyx_builtin_IndexError; static const char __pyx_k_O[] = "O"; static const char __pyx_k_c[] = "c"; static const char __pyx_k_h[] = "h"; static const char __pyx_k_i[] = "i"; static const char __pyx_k_j[] = "j"; static const char __pyx_k_x[] = "x"; static const char __pyx_k_y[] = "y"; static const char __pyx_k_b1[] = "b1"; static const char __pyx_k_b2[] = "b2"; static const char __pyx_k_b3[] = "b3"; static const char __pyx_k_hp[] = "hp"; static const char __pyx_k_id[] = "id"; static const char __pyx_k_iy[] = "iy"; static const char __pyx_k_np[] = "np"; static const char __pyx_k_nx[] = "nx"; static const char __pyx_k_ny[] = "ny"; static const char __pyx_k_cap[] = "cap"; static const char __pyx_k_ix1[] = "ix1"; static const char __pyx_k_ix2[] = "ix2"; static const char __pyx_k_new[] = "__new__"; static const char __pyx_k_obj[] = "obj"; static const char __pyx_k_pop[] = "pop"; static const char __pyx_k_rcp[] = "rcp"; static const char __pyx_k_res[] = "res"; static const char __pyx_k_sdg[] = "sdg"; static const char __pyx_k_sgp[] = "sgp"; static const char __pyx_k_tmp[] = "tmp"; static const char __pyx_k_base[] = "base"; static const char __pyx_k_c12p[] = "c12p"; static const char __pyx_k_dict[] = "__dict__"; static const char __pyx_k_hval[] = "hval"; static const char __pyx_k_ix1p[] = "ix1p"; static const char __pyx_k_ix2p[] = "ix2p"; static const char __pyx_k_lat2[] = "lat2"; static const char __pyx_k_lon2[] = "lon2"; static const char __pyx_k_main[] = "__main__"; static const char __pyx_k_mode[] = "mode"; static const char __pyx_k_name[] = "name"; static const char __pyx_k_ndim[] = "ndim"; static const char __pyx_k_pack[] = "pack"; static const char __pyx_k_size[] = "size"; static const char __pyx_k_step[] = "step"; static const char __pyx_k_stop[] = "stop"; static const char __pyx_k_test[] = "__test__"; static const char __pyx_k_ASCII[] = "ASCII"; static const char __pyx_k_afact[] = "afact"; static const char __pyx_k_bfact[] = "bfact"; static const char __pyx_k_class[] = "__class__"; static const char __pyx_k_error[] = "error"; static const char __pyx_k_flags[] = "flags"; static const char __pyx_k_lats1[] = "lats1"; static const char __pyx_k_lats2[] = "lats2"; static const char __pyx_k_lons1[] = "lons1"; static const char __pyx_k_lons2[] = "lons2"; static const char __pyx_k_numpy[] = "numpy"; static const char __pyx_k_range[] = "range"; static const char __pyx_k_sdarr[] = "sdarr"; static const char __pyx_k_sdsta[] = "sdsta"; static const char __pyx_k_sdval[] = "sdval"; static const char __pyx_k_shape[] = "shape"; static const char __pyx_k_start[] = "start"; static const char __pyx_k_corr12[] = "corr12"; static const char __pyx_k_encode[] = "encode"; static const char __pyx_k_format[] = "format"; static const char __pyx_k_import[] = "__import__"; static const char __pyx_k_name_2[] = "__name__"; static const char __pyx_k_pickle[] = "pickle"; static const char __pyx_k_reduce[] = "__reduce__"; static const char __pyx_k_result[] = "result"; static const char __pyx_k_sdgrid[] = "sdgrid"; static const char __pyx_k_struct[] = "struct"; static const char __pyx_k_unpack[] = "unpack"; static const char __pyx_k_update[] = "update"; static const char __pyx_k_fortran[] = "fortran"; static const char __pyx_k_memview[] = "memview"; static const char __pyx_k_sigma12[] = "sigma12"; static const char __pyx_k_Ellipsis[] = "Ellipsis"; static const char __pyx_k_diameter[] = "diameter"; static const char __pyx_k_getstate[] = "__getstate__"; static const char __pyx_k_itemsize[] = "itemsize"; static const char __pyx_k_pout_sd2[] = "pout_sd2"; static const char __pyx_k_pyx_type[] = "__pyx_type"; static const char __pyx_k_rcmatrix[] = "rcmatrix"; static const char __pyx_k_setstate[] = "__setstate__"; static const char __pyx_k_TypeError[] = "TypeError"; static const char __pyx_k_enumerate[] = "enumerate"; static const char __pyx_k_pyx_state[] = "__pyx_state"; static const char __pyx_k_reduce_ex[] = "__reduce_ex__"; static const char __pyx_k_IndexError[] = "IndexError"; static const char __pyx_k_ValueError[] = "ValueError"; static const char __pyx_k_corr_adj12[] = "corr_adj12"; static const char __pyx_k_pyx_result[] = "__pyx_result"; static const char __pyx_k_pyx_vtable[] = "__pyx_vtable__"; static const char __pyx_k_MemoryError[] = "MemoryError"; static const char __pyx_k_PickleError[] = "PickleError"; static const char __pyx_k_EARTH_RADIUS[] = "EARTH_RADIUS"; static const char __pyx_k_pyx_checksum[] = "__pyx_checksum"; static const char __pyx_k_stringsource[] = "stringsource"; static const char __pyx_k_make_sd_array[] = "make_sd_array"; static const char __pyx_k_pyx_getbuffer[] = "__pyx_getbuffer"; static const char __pyx_k_reduce_cython[] = "__reduce_cython__"; static const char __pyx_k_View_MemoryView[] = "View.MemoryView"; static const char __pyx_k_allocate_buffer[] = "allocate_buffer"; static const char __pyx_k_dtype_is_object[] = "dtype_is_object"; static const char __pyx_k_pyx_PickleError[] = "__pyx_PickleError"; static const char __pyx_k_setstate_cython[] = "__setstate_cython__"; static const char __pyx_k_shakemap_c_clib[] = "shakemap.c.clib"; static const char __pyx_k_make_sigma_matrix[] = "make_sigma_matrix"; static const char __pyx_k_pyx_unpickle_Enum[] = "__pyx_unpickle_Enum"; static const char __pyx_k_cline_in_traceback[] = "cline_in_traceback"; static const char __pyx_k_strided_and_direct[] = "<strided and direct>"; static const char __pyx_k_eval_lb_correlation[] = "eval_lb_correlation"; static const char __pyx_k_shakemap_c_clib_pyx[] = "shakemap/c/clib.pyx"; static const char __pyx_k_strided_and_indirect[] = "<strided and indirect>"; static const char __pyx_k_contiguous_and_direct[] = "<contiguous and direct>"; static const char __pyx_k_MemoryView_of_r_object[] = "<MemoryView of %r object>"; static const char __pyx_k_geodetic_distance_fast[] = "geodetic_distance_fast"; static const char __pyx_k_MemoryView_of_r_at_0x_x[] = "<MemoryView of %r at 0x%x>"; static const char __pyx_k_contiguous_and_indirect[] = "<contiguous and indirect>"; static const char __pyx_k_Cannot_index_with_type_s[] = "Cannot index with type '%s'"; static const char __pyx_k_Invalid_shape_in_axis_d_d[] = "Invalid shape in axis %d: %d."; static const char __pyx_k_geodetic_distance_haversine[] = "geodetic_distance_haversine"; static const char __pyx_k_itemsize_0_for_cython_array[] = "itemsize <= 0 for cython.array"; static const char __pyx_k_unable_to_allocate_array_data[] = "unable to allocate array data."; static const char __pyx_k_strided_and_direct_or_indirect[] = "<strided and direct or indirect>"; static const char __pyx_k_Buffer_view_does_not_expose_stri[] = "Buffer view does not expose strides"; static const char __pyx_k_Can_only_create_a_buffer_that_is[] = "Can only create a buffer that is contiguous in memory."; static const char __pyx_k_Cannot_assign_to_read_only_memor[] = "Cannot assign to read-only memoryview"; static const char __pyx_k_Cannot_create_writable_memory_vi[] = "Cannot create writable memory view from read-only memoryview"; static const char __pyx_k_Empty_shape_tuple_for_cython_arr[] = "Empty shape tuple for cython.array"; static const char __pyx_k_Incompatible_checksums_s_vs_0xb0[] = "Incompatible checksums (%s vs 0xb068931 = (name))"; static const char __pyx_k_Indirect_dimensions_not_supporte[] = "Indirect dimensions not supported"; static const char __pyx_k_Invalid_mode_expected_c_or_fortr[] = "Invalid mode, expected 'c' or 'fortran', got %s"; static const char __pyx_k_Out_of_bounds_on_buffer_access_a[] = "Out of bounds on buffer access (axis %d)"; static const char __pyx_k_Unable_to_convert_item_to_object[] = "Unable to convert item to object"; static const char __pyx_k_got_differing_extents_in_dimensi[] = "got differing extents in dimension %d (got %d and %d)"; static const char __pyx_k_no_default___reduce___due_to_non[] = "no default __reduce__ due to non-trivial __cinit__"; static const char __pyx_k_unable_to_allocate_shape_and_str[] = "unable to allocate shape and strides."; static PyObject *__pyx_n_s_ASCII; static PyObject *__pyx_kp_s_Buffer_view_does_not_expose_stri; static PyObject *__pyx_kp_s_Can_only_create_a_buffer_that_is; static PyObject *__pyx_kp_s_Cannot_assign_to_read_only_memor; static PyObject *__pyx_kp_s_Cannot_create_writable_memory_vi; static PyObject *__pyx_kp_s_Cannot_index_with_type_s; static PyObject *__pyx_n_s_EARTH_RADIUS; static PyObject *__pyx_n_s_Ellipsis; static PyObject *__pyx_kp_s_Empty_shape_tuple_for_cython_arr; static PyObject *__pyx_kp_s_Incompatible_checksums_s_vs_0xb0; static PyObject *__pyx_n_s_IndexError; static PyObject *__pyx_kp_s_Indirect_dimensions_not_supporte; static PyObject *__pyx_kp_s_Invalid_mode_expected_c_or_fortr; static PyObject *__pyx_kp_s_Invalid_shape_in_axis_d_d; static PyObject *__pyx_n_s_MemoryError; static PyObject *__pyx_kp_s_MemoryView_of_r_at_0x_x; static PyObject *__pyx_kp_s_MemoryView_of_r_object; static PyObject *__pyx_n_b_O; static PyObject *__pyx_kp_s_Out_of_bounds_on_buffer_access_a; static PyObject *__pyx_n_s_PickleError; static PyObject *__pyx_n_s_TypeError; static PyObject *__pyx_kp_s_Unable_to_convert_item_to_object; static PyObject *__pyx_n_s_ValueError; static PyObject *__pyx_n_s_View_MemoryView; static PyObject *__pyx_n_s_afact; static PyObject *__pyx_n_s_allocate_buffer; static PyObject *__pyx_n_s_b1; static PyObject *__pyx_n_s_b2; static PyObject *__pyx_n_s_b3; static PyObject *__pyx_n_s_base; static PyObject *__pyx_n_s_bfact; static PyObject *__pyx_n_s_c; static PyObject *__pyx_n_u_c; static PyObject *__pyx_n_s_c12p; static PyObject *__pyx_n_s_cap; static PyObject *__pyx_n_s_class; static PyObject *__pyx_n_s_cline_in_traceback; static PyObject *__pyx_kp_s_contiguous_and_direct; static PyObject *__pyx_kp_s_contiguous_and_indirect; static PyObject *__pyx_n_s_corr12; static PyObject *__pyx_n_s_corr_adj12; static PyObject *__pyx_n_s_diameter; static PyObject *__pyx_n_s_dict; static PyObject *__pyx_n_s_dtype_is_object; static PyObject *__pyx_n_s_encode; static PyObject *__pyx_n_s_enumerate; static PyObject *__pyx_n_s_error; static PyObject *__pyx_n_s_eval_lb_correlation; static PyObject *__pyx_n_s_flags; static PyObject *__pyx_n_s_format; static PyObject *__pyx_n_s_fortran; static PyObject *__pyx_n_u_fortran; static PyObject *__pyx_n_s_geodetic_distance_fast; static PyObject *__pyx_n_s_geodetic_distance_haversine; static PyObject *__pyx_n_s_getstate; static PyObject *__pyx_kp_s_got_differing_extents_in_dimensi; static PyObject *__pyx_n_s_h; static PyObject *__pyx_n_s_hp; static PyObject *__pyx_n_s_hval; static PyObject *__pyx_n_s_i; static PyObject *__pyx_n_s_id; static PyObject *__pyx_n_s_import; static PyObject *__pyx_n_s_itemsize; static PyObject *__pyx_kp_s_itemsize_0_for_cython_array; static PyObject *__pyx_n_s_ix1; static PyObject *__pyx_n_s_ix1p; static PyObject *__pyx_n_s_ix2; static PyObject *__pyx_n_s_ix2p; static PyObject *__pyx_n_s_iy; static PyObject *__pyx_n_s_j; static PyObject *__pyx_n_s_lat2; static PyObject *__pyx_n_s_lats1; static PyObject *__pyx_n_s_lats2; static PyObject *__pyx_n_s_lon2; static PyObject *__pyx_n_s_lons1; static PyObject *__pyx_n_s_lons2; static PyObject *__pyx_n_s_main; static PyObject *__pyx_n_s_make_sd_array; static PyObject *__pyx_n_s_make_sigma_matrix; static PyObject *__pyx_n_s_memview; static PyObject *__pyx_n_s_mode; static PyObject *__pyx_n_s_name; static PyObject *__pyx_n_s_name_2; static PyObject *__pyx_n_s_ndim; static PyObject *__pyx_n_s_new; static PyObject *__pyx_kp_s_no_default___reduce___due_to_non; static PyObject *__pyx_n_s_np; static PyObject *__pyx_n_s_numpy; static PyObject *__pyx_n_s_nx; static PyObject *__pyx_n_s_ny; static PyObject *__pyx_n_s_obj; static PyObject *__pyx_n_s_pack; static PyObject *__pyx_n_s_pickle; static PyObject *__pyx_n_s_pop; static PyObject *__pyx_n_s_pout_sd2; static PyObject *__pyx_n_s_pyx_PickleError; static PyObject *__pyx_n_s_pyx_checksum; static PyObject *__pyx_n_s_pyx_getbuffer; static PyObject *__pyx_n_s_pyx_result; static PyObject *__pyx_n_s_pyx_state; static PyObject *__pyx_n_s_pyx_type; static PyObject *__pyx_n_s_pyx_unpickle_Enum; static PyObject *__pyx_n_s_pyx_vtable; static PyObject *__pyx_n_s_range; static PyObject *__pyx_n_s_rcmatrix; static PyObject *__pyx_n_s_rcp; static PyObject *__pyx_n_s_reduce; static PyObject *__pyx_n_s_reduce_cython; static PyObject *__pyx_n_s_reduce_ex; static PyObject *__pyx_n_s_res; static PyObject *__pyx_n_s_result; static PyObject *__pyx_n_s_sdarr; static PyObject *__pyx_n_s_sdg; static PyObject *__pyx_n_s_sdgrid; static PyObject *__pyx_n_s_sdsta; static PyObject *__pyx_n_s_sdval; static PyObject *__pyx_n_s_setstate; static PyObject *__pyx_n_s_setstate_cython; static PyObject *__pyx_n_s_sgp; static PyObject *__pyx_n_s_shakemap_c_clib; static PyObject *__pyx_kp_s_shakemap_c_clib_pyx; static PyObject *__pyx_n_s_shape; static PyObject *__pyx_n_s_sigma12; static PyObject *__pyx_n_s_size; static PyObject *__pyx_n_s_start; static PyObject *__pyx_n_s_step; static PyObject *__pyx_n_s_stop; static PyObject *__pyx_kp_s_strided_and_direct; static PyObject *__pyx_kp_s_strided_and_direct_or_indirect; static PyObject *__pyx_kp_s_strided_and_indirect; static PyObject *__pyx_kp_s_stringsource; static PyObject *__pyx_n_s_struct; static PyObject *__pyx_n_s_test; static PyObject *__pyx_n_s_tmp; static PyObject *__pyx_kp_s_unable_to_allocate_array_data; static PyObject *__pyx_kp_s_unable_to_allocate_shape_and_str; static PyObject *__pyx_n_s_unpack; static PyObject *__pyx_n_s_update; static PyObject *__pyx_n_s_x; static PyObject *__pyx_n_s_y; static PyObject *__pyx_pf_8shakemap_1c_4clib_make_sigma_matrix(CYTHON_UNUSED PyObject *__pyx_self, __Pyx_memviewslice __pyx_v_corr12, __Pyx_memviewslice __pyx_v_corr_adj12, __Pyx_memviewslice __pyx_v_sdsta, __Pyx_memviewslice __pyx_v_sdarr); /* proto */ static PyObject *__pyx_pf_8shakemap_1c_4clib_2geodetic_distance_fast(CYTHON_UNUSED PyObject *__pyx_self, __Pyx_memviewslice __pyx_v_lons1, __Pyx_memviewslice __pyx_v_lats1, __Pyx_memviewslice __pyx_v_lons2, __Pyx_memviewslice __pyx_v_lats2, __Pyx_memviewslice __pyx_v_result); /* proto */ static PyObject *__pyx_pf_8shakemap_1c_4clib_4geodetic_distance_haversine(CYTHON_UNUSED PyObject *__pyx_self, __Pyx_memviewslice __pyx_v_lons1, __Pyx_memviewslice __pyx_v_lats1, __Pyx_memviewslice __pyx_v_lons2, __Pyx_memviewslice __pyx_v_lats2, __Pyx_memviewslice __pyx_v_result); /* proto */ static PyObject *__pyx_pf_8shakemap_1c_4clib_6eval_lb_correlation(CYTHON_UNUSED PyObject *__pyx_self, __Pyx_memviewslice __pyx_v_b1, __Pyx_memviewslice __pyx_v_b2, __Pyx_memviewslice __pyx_v_b3, __Pyx_memviewslice __pyx_v_ix1, __Pyx_memviewslice __pyx_v_ix2, __Pyx_memviewslice __pyx_v_h); /* proto */ static PyObject *__pyx_pf_8shakemap_1c_4clib_8make_sd_array(CYTHON_UNUSED PyObject *__pyx_self, __Pyx_memviewslice __pyx_v_sdgrid, __Pyx_memviewslice __pyx_v_pout_sd2, long __pyx_v_iy, __Pyx_memviewslice __pyx_v_rcmatrix, __Pyx_memviewslice __pyx_v_sigma12); /* proto */ static int __pyx_array___pyx_pf_15View_dot_MemoryView_5array___cinit__(struct __pyx_array_obj *__pyx_v_self, PyObject *__pyx_v_shape, Py_ssize_t __pyx_v_itemsize, PyObject *__pyx_v_format, PyObject *__pyx_v_mode, int __pyx_v_allocate_buffer); /* proto */ static int __pyx_array___pyx_pf_15View_dot_MemoryView_5array_2__getbuffer__(struct __pyx_array_obj *__pyx_v_self, Py_buffer *__pyx_v_info, int __pyx_v_flags); /* proto */ static void __pyx_array___pyx_pf_15View_dot_MemoryView_5array_4__dealloc__(struct __pyx_array_obj *__pyx_v_self); /* proto */ static PyObject *__pyx_pf_15View_dot_MemoryView_5array_7memview___get__(struct __pyx_array_obj *__pyx_v_self); /* proto */ static Py_ssize_t __pyx_array___pyx_pf_15View_dot_MemoryView_5array_6__len__(struct __pyx_array_obj *__pyx_v_self); /* proto */ static PyObject *__pyx_array___pyx_pf_15View_dot_MemoryView_5array_8__getattr__(struct __pyx_array_obj *__pyx_v_self, PyObject *__pyx_v_attr); /* proto */ static PyObject *__pyx_array___pyx_pf_15View_dot_MemoryView_5array_10__getitem__(struct __pyx_array_obj *__pyx_v_self, PyObject *__pyx_v_item); /* proto */ static int __pyx_array___pyx_pf_15View_dot_MemoryView_5array_12__setitem__(struct __pyx_array_obj *__pyx_v_self, PyObject *__pyx_v_item, PyObject *__pyx_v_value); /* proto */ static PyObject *__pyx_pf___pyx_array___reduce_cython__(CYTHON_UNUSED struct __pyx_array_obj *__pyx_v_self); /* proto */ static PyObject *__pyx_pf___pyx_array_2__setstate_cython__(CYTHON_UNUSED struct __pyx_array_obj *__pyx_v_self, CYTHON_UNUSED PyObject *__pyx_v___pyx_state); /* proto */ static int __pyx_MemviewEnum___pyx_pf_15View_dot_MemoryView_4Enum___init__(struct __pyx_MemviewEnum_obj *__pyx_v_self, PyObject *__pyx_v_name); /* proto */ static PyObject *__pyx_MemviewEnum___pyx_pf_15View_dot_MemoryView_4Enum_2__repr__(struct __pyx_MemviewEnum_obj *__pyx_v_self); /* proto */ static PyObject *__pyx_pf___pyx_MemviewEnum___reduce_cython__(struct __pyx_MemviewEnum_obj *__pyx_v_self); /* proto */ static PyObject *__pyx_pf___pyx_MemviewEnum_2__setstate_cython__(struct __pyx_MemviewEnum_obj *__pyx_v_self, PyObject *__pyx_v___pyx_state); /* proto */ static int __pyx_memoryview___pyx_pf_15View_dot_MemoryView_10memoryview___cinit__(struct __pyx_memoryview_obj *__pyx_v_self, PyObject *__pyx_v_obj, int __pyx_v_flags, int __pyx_v_dtype_is_object); /* proto */ static void __pyx_memoryview___pyx_pf_15View_dot_MemoryView_10memoryview_2__dealloc__(struct __pyx_memoryview_obj *__pyx_v_self); /* proto */ static PyObject *__pyx_memoryview___pyx_pf_15View_dot_MemoryView_10memoryview_4__getitem__(struct __pyx_memoryview_obj *__pyx_v_self, PyObject *__pyx_v_index); /* proto */ static int __pyx_memoryview___pyx_pf_15View_dot_MemoryView_10memoryview_6__setitem__(struct __pyx_memoryview_obj *__pyx_v_self, PyObject *__pyx_v_index, PyObject *__pyx_v_value); /* proto */ static int __pyx_memoryview___pyx_pf_15View_dot_MemoryView_10memoryview_8__getbuffer__(struct __pyx_memoryview_obj *__pyx_v_self, Py_buffer *__pyx_v_info, int __pyx_v_flags); /* proto */ static PyObject *__pyx_pf_15View_dot_MemoryView_10memoryview_1T___get__(struct __pyx_memoryview_obj *__pyx_v_self); /* proto */ static PyObject *__pyx_pf_15View_dot_MemoryView_10memoryview_4base___get__(struct __pyx_memoryview_obj *__pyx_v_self); /* proto */ static PyObject *__pyx_pf_15View_dot_MemoryView_10memoryview_5shape___get__(struct __pyx_memoryview_obj *__pyx_v_self); /* proto */ static PyObject *__pyx_pf_15View_dot_MemoryView_10memoryview_7strides___get__(struct __pyx_memoryview_obj *__pyx_v_self); /* proto */ static PyObject *__pyx_pf_15View_dot_MemoryView_10memoryview_10suboffsets___get__(struct __pyx_memoryview_obj *__pyx_v_self); /* proto */ static PyObject *__pyx_pf_15View_dot_MemoryView_10memoryview_4ndim___get__(struct __pyx_memoryview_obj *__pyx_v_self); /* proto */ static PyObject *__pyx_pf_15View_dot_MemoryView_10memoryview_8itemsize___get__(struct __pyx_memoryview_obj *__pyx_v_self); /* proto */ static PyObject *__pyx_pf_15View_dot_MemoryView_10memoryview_6nbytes___get__(struct __pyx_memoryview_obj *__pyx_v_self); /* proto */ static PyObject *__pyx_pf_15View_dot_MemoryView_10memoryview_4size___get__(struct __pyx_memoryview_obj *__pyx_v_self); /* proto */ static Py_ssize_t 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"shakemap/c/clib.pyx":52 * * if &lons1[0] == &lons2[0] and &lats1[0] == &lats2[0]: * for y in prange(ny, nogil=True, schedule='guided'): # <<<<<<<<<<<<<< * lon2 = lons2[y] * lat2 = lats2[y] */ { #ifdef WITH_THREAD PyThreadState *_save; Py_UNBLOCK_THREADS __Pyx_FastGIL_Remember(); #endif /*try:*/ { __pyx_t_5 = __pyx_v_ny; if ((1 == 0)) abort(); { #if ((defined(__APPLE__) || defined(__OSX__)) && (defined(__GNUC__) && (__GNUC__ > 2 || (__GNUC__ == 2 && (__GNUC_MINOR__ > 95))))) #undef likely #undef unlikely #define likely(x) (x) #define unlikely(x) (x) #endif __pyx_t_7 = (__pyx_t_5 - 0 + 1 - 1/abs(1)) / 1; if (__pyx_t_7 > 0) { #ifdef _OPENMP #pragma omp parallel private(__pyx_t_10, __pyx_t_11, __pyx_t_12, __pyx_t_2, __pyx_t_3, __pyx_t_8, __pyx_t_9) #endif /* _OPENMP */ { #ifdef _OPENMP #pragma omp for lastprivate(__pyx_v_lat2) lastprivate(__pyx_v_lon2) lastprivate(__pyx_v_x) firstprivate(__pyx_v_y) lastprivate(__pyx_v_y) schedule(guided) #endif /* _OPENMP */ for (__pyx_t_6 = 0; __pyx_t_6 < __pyx_t_7; __pyx_t_6++){ { __pyx_v_y = (Py_ssize_t)(0 + 1 * __pyx_t_6); /* Initialize private variables to invalid values */ __pyx_v_lat2 = ((double)__PYX_NAN()); __pyx_v_lon2 = ((double)__PYX_NAN()); __pyx_v_x = ((Py_ssize_t)0xbad0bad0); /* "shakemap/c/clib.pyx":53 * if &lons1[0] == &lons2[0] and &lats1[0] == &lats2[0]: * for y in prange(ny, nogil=True, schedule='guided'): * lon2 = lons2[y] # <<<<<<<<<<<<<< * lat2 = lats2[y] * for x in range(y+1): */ __pyx_t_2 = __pyx_v_y; __pyx_v_lon2 = (*((double *) ( /* dim=0 */ ((char *) (((double *) __pyx_v_lons2.data) + __pyx_t_2)) ))); /* "shakemap/c/clib.pyx":54 * for y in prange(ny, nogil=True, schedule='guided'): * lon2 = lons2[y] * lat2 = lats2[y] # <<<<<<<<<<<<<< * for x in range(y+1): * result[y, x] = result[x, y] = ( */ __pyx_t_2 = __pyx_v_y; __pyx_v_lat2 = (*((double *) ( /* dim=0 */ ((char *) (((double *) __pyx_v_lats2.data) + __pyx_t_2)) ))); /* "shakemap/c/clib.pyx":55 * lon2 = lons2[y] * lat2 = lats2[y] * for x in range(y+1): # <<<<<<<<<<<<<< * result[y, x] = result[x, y] = ( * EARTH_RADIUS * */ __pyx_t_8 = (__pyx_v_y + 1); __pyx_t_9 = __pyx_t_8; for (__pyx_t_10 = 0; __pyx_t_10 < __pyx_t_9; __pyx_t_10+=1) { __pyx_v_x = __pyx_t_10; /* "shakemap/c/clib.pyx":58 * result[y, x] = result[x, y] = ( * EARTH_RADIUS * * sqrt(((lons1[x] - lon2) * # <<<<<<<<<<<<<< * cos(0.5 * (lats1[x] + lat2)))**2 + * (lats1[x] - lat2)**2)) */ __pyx_t_2 = __pyx_v_x; /* "shakemap/c/clib.pyx":59 * EARTH_RADIUS * * sqrt(((lons1[x] - lon2) * * cos(0.5 * (lats1[x] + lat2)))**2 + # <<<<<<<<<<<<<< * (lats1[x] - lat2)**2)) * else: */ __pyx_t_3 = __pyx_v_x; /* "shakemap/c/clib.pyx":60 * sqrt(((lons1[x] - lon2) * * cos(0.5 * (lats1[x] + lat2)))**2 + * (lats1[x] - lat2)**2)) # <<<<<<<<<<<<<< * else: * for y in prange(ny, nogil=True, schedule=dynamic): */ __pyx_t_11 = __pyx_v_x; /* "shakemap/c/clib.pyx":57 * for x in range(y+1): * result[y, x] = result[x, y] = ( * EARTH_RADIUS * # <<<<<<<<<<<<<< * sqrt(((lons1[x] - lon2) * * cos(0.5 * (lats1[x] + lat2)))**2 + */ __pyx_t_12 = (__pyx_v_EARTH_RADIUS * sqrt((pow((((*((double *) ( /* dim=0 */ ((char *) (((double *) __pyx_v_lons1.data) + __pyx_t_2)) ))) - __pyx_v_lon2) * cos((0.5 * ((*((double *) ( /* dim=0 */ ((char *) (((double *) __pyx_v_lats1.data) + __pyx_t_3)) ))) + __pyx_v_lat2)))), 2.0) + pow(((*((double *) ( /* dim=0 */ ((char *) (((double *) __pyx_v_lats1.data) + __pyx_t_11)) ))) - __pyx_v_lat2), 2.0)))); /* "shakemap/c/clib.pyx":56 * lat2 = lats2[y] * for x in range(y+1): * result[y, x] = result[x, y] = ( # <<<<<<<<<<<<<< * EARTH_RADIUS * * sqrt(((lons1[x] - lon2) * */ __pyx_t_11 = __pyx_v_y; __pyx_t_3 = __pyx_v_x; *((double *) ( /* dim=1 */ ((char *) (((double *) ( /* dim=0 */ (__pyx_v_result.data + __pyx_t_11 * __pyx_v_result.strides[0]) )) + __pyx_t_3)) )) = __pyx_t_12; __pyx_t_3 = __pyx_v_x; __pyx_t_11 = __pyx_v_y; *((double *) ( /* dim=1 */ ((char *) (((double *) ( /* dim=0 */ (__pyx_v_result.data + __pyx_t_3 * __pyx_v_result.strides[0]) )) + __pyx_t_11)) )) = __pyx_t_12; } } } } } } #if ((defined(__APPLE__) || defined(__OSX__)) && (defined(__GNUC__) && (__GNUC__ > 2 || (__GNUC__ == 2 && (__GNUC_MINOR__ > 95))))) #undef likely #undef unlikely #define likely(x) __builtin_expect(!!(x), 1) #define unlikely(x) __builtin_expect(!!(x), 0) #endif } /* "shakemap/c/clib.pyx":52 * * if &lons1[0] == &lons2[0] and &lats1[0] == &lats2[0]: * for y in prange(ny, nogil=True, schedule='guided'): # <<<<<<<<<<<<<< * lon2 = lons2[y] * lat2 = lats2[y] */ /*finally:*/ { /*normal exit:*/{ #ifdef WITH_THREAD __Pyx_FastGIL_Forget(); Py_BLOCK_THREADS #endif goto __pyx_L8; } __pyx_L8:; } } /* "shakemap/c/clib.pyx":51 * cdef Py_ssize_t x, y * * if &lons1[0] == &lons2[0] and &lats1[0] == &lats2[0]: # <<<<<<<<<<<<<< * for y in prange(ny, nogil=True, schedule='guided'): * lon2 = lons2[y] */ goto __pyx_L3; } /* "shakemap/c/clib.pyx":62 * (lats1[x] - lat2)**2)) * else: * for y in prange(ny, nogil=True, schedule=dynamic): # <<<<<<<<<<<<<< * res = &result[y, 0] * lon2 = lons2[y] */ /*else*/ { { #ifdef WITH_THREAD PyThreadState *_save; Py_UNBLOCK_THREADS __Pyx_FastGIL_Remember(); #endif /*try:*/ { __pyx_t_7 = __pyx_v_ny; if ((1 == 0)) abort(); { #if ((defined(__APPLE__) || defined(__OSX__)) && (defined(__GNUC__) && (__GNUC__ > 2 || (__GNUC__ == 2 && (__GNUC_MINOR__ > 95))))) #undef likely #undef unlikely #define likely(x) (x) #define unlikely(x) (x) #endif __pyx_t_5 = (__pyx_t_7 - 0 + 1 - 1/abs(1)) / 1; if (__pyx_t_5 > 0) { #ifdef _OPENMP #pragma omp parallel private(__pyx_t_10, __pyx_t_11, __pyx_t_2, __pyx_t_3, __pyx_t_8, __pyx_t_9) #endif /* _OPENMP */ { #ifdef _OPENMP #pragma omp for lastprivate(__pyx_v_lat2) lastprivate(__pyx_v_lon2) lastprivate(__pyx_v_res) lastprivate(__pyx_v_x) firstprivate(__pyx_v_y) lastprivate(__pyx_v_y) #endif /* _OPENMP */ for (__pyx_t_6 = 0; __pyx_t_6 < __pyx_t_5; __pyx_t_6++){ { __pyx_v_y = (Py_ssize_t)(0 + 1 * __pyx_t_6); /* Initialize private variables to invalid values */ __pyx_v_lat2 = ((double)__PYX_NAN()); __pyx_v_lon2 = ((double)__PYX_NAN()); __pyx_v_res = ((double *)1); __pyx_v_x = ((Py_ssize_t)0xbad0bad0); /* "shakemap/c/clib.pyx":63 * else: * for y in prange(ny, nogil=True, schedule=dynamic): * res = &result[y, 0] # <<<<<<<<<<<<<< * lon2 = lons2[y] * lat2 = lats2[y] */ __pyx_t_11 = __pyx_v_y; __pyx_t_3 = 0; __pyx_v_res = (&(*((double *) ( /* dim=1 */ ((char *) (((double *) ( /* dim=0 */ (__pyx_v_result.data + __pyx_t_11 * __pyx_v_result.strides[0]) )) + __pyx_t_3)) )))); /* "shakemap/c/clib.pyx":64 * for y in prange(ny, nogil=True, schedule=dynamic): * res = &result[y, 0] * lon2 = lons2[y] # <<<<<<<<<<<<<< * lat2 = lats2[y] * for x in range(nx): */ __pyx_t_3 = __pyx_v_y; __pyx_v_lon2 = (*((double *) ( /* dim=0 */ ((char *) (((double *) __pyx_v_lons2.data) + __pyx_t_3)) ))); /* "shakemap/c/clib.pyx":65 * res = &result[y, 0] * lon2 = lons2[y] * lat2 = lats2[y] # <<<<<<<<<<<<<< * for x in range(nx): * res[x] = ( */ __pyx_t_3 = __pyx_v_y; __pyx_v_lat2 = (*((double *) ( /* dim=0 */ ((char 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nogil=True, schedule='guided'): * for x in range(y+1): */ __pyx_t_2 = 0; __pyx_t_3 = 0; __pyx_t_4 = (((&(*((double *) ( /* dim=0 */ ((char *) (((double *) __pyx_v_lons1.data) + __pyx_t_2)) )))) == (&(*((double *) ( /* dim=0 */ ((char *) (((double *) __pyx_v_lons2.data) + __pyx_t_3)) ))))) != 0); if (__pyx_t_4) { } else { __pyx_t_1 = __pyx_t_4; goto __pyx_L4_bool_binop_done; } __pyx_t_3 = 0; __pyx_t_2 = 0; __pyx_t_4 = (((&(*((double *) ( /* dim=0 */ ((char *) (((double *) __pyx_v_lats1.data) + __pyx_t_3)) )))) == (&(*((double *) ( /* dim=0 */ ((char *) (((double *) __pyx_v_lats2.data) + __pyx_t_2)) ))))) != 0); __pyx_t_1 = __pyx_t_4; __pyx_L4_bool_binop_done:; if (__pyx_t_1) { /* "shakemap/c/clib.pyx":88 * * if &lons1[0] == &lons2[0] and &lats1[0] == &lats2[0]: * for y in prange(ny, nogil=True, schedule='guided'): # <<<<<<<<<<<<<< * for x in range(y+1): * result[y, x] = result[x, y] = ( */ { #ifdef WITH_THREAD PyThreadState *_save; Py_UNBLOCK_THREADS __Pyx_FastGIL_Remember(); #endif /*try:*/ { __pyx_t_5 = __pyx_v_ny; if ((1 == 0)) abort(); { #if ((defined(__APPLE__) || defined(__OSX__)) && (defined(__GNUC__) && (__GNUC__ > 2 || (__GNUC__ == 2 && (__GNUC_MINOR__ > 95))))) #undef likely #undef unlikely #define likely(x) (x) #define unlikely(x) (x) #endif __pyx_t_7 = (__pyx_t_5 - 0 + 1 - 1/abs(1)) / 1; if (__pyx_t_7 > 0) { #ifdef _OPENMP #pragma omp parallel private(__pyx_t_10, __pyx_t_11, __pyx_t_12, __pyx_t_13, __pyx_t_14, __pyx_t_15, __pyx_t_2, __pyx_t_3, __pyx_t_8, __pyx_t_9) #endif /* _OPENMP */ { #ifdef _OPENMP #pragma omp for lastprivate(__pyx_v_x) firstprivate(__pyx_v_y) lastprivate(__pyx_v_y) schedule(guided) #endif /* _OPENMP */ for (__pyx_t_6 = 0; __pyx_t_6 < __pyx_t_7; __pyx_t_6++){ { __pyx_v_y = (Py_ssize_t)(0 + 1 * __pyx_t_6); /* Initialize private variables to invalid values */ __pyx_v_x = ((Py_ssize_t)0xbad0bad0); /* "shakemap/c/clib.pyx":89 * if &lons1[0] == &lons2[0] and &lats1[0] == &lats2[0]: * for y in prange(ny, nogil=True, schedule='guided'): * 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__pyx_t_14 = __pyx_v_y; /* "shakemap/c/clib.pyx":91 * for x in range(y+1): * result[y, x] = result[x, y] = ( * diameter * asin(sqrt( # <<<<<<<<<<<<<< * sin((lats1[x] - lats2[y]) / 2.0)**2 + * cos(lats1[x]) * cos(lats2[y]) * */ __pyx_t_15 = (__pyx_v_diameter * asin(sqrt((pow(sin((((*((double *) ( /* dim=0 */ ((char *) (((double *) __pyx_v_lats1.data) + __pyx_t_2)) ))) - (*((double *) ( /* dim=0 */ ((char *) (((double *) __pyx_v_lats2.data) + __pyx_t_3)) )))) / 2.0)), 2.0) + ((cos((*((double *) ( /* dim=0 */ ((char *) (((double *) __pyx_v_lats1.data) + __pyx_t_11)) )))) * cos((*((double *) ( /* dim=0 */ ((char *) (((double *) __pyx_v_lats2.data) + __pyx_t_12)) ))))) * pow(sin((((*((double *) ( /* dim=0 */ ((char *) (((double *) __pyx_v_lons1.data) + __pyx_t_13)) ))) - (*((double *) ( /* dim=0 */ ((char *) (((double *) __pyx_v_lons2.data) + __pyx_t_14)) )))) / 2.0)), 2.0)))))); /* "shakemap/c/clib.pyx":90 * for y in prange(ny, nogil=True, schedule='guided'): * for x in range(y+1): * result[y, x] = result[x, y] = ( # <<<<<<<<<<<<<< * diameter * asin(sqrt( * sin((lats1[x] - lats2[y]) / 2.0)**2 + */ __pyx_t_14 = __pyx_v_y; __pyx_t_13 = __pyx_v_x; *((double *) ( /* dim=1 */ ((char *) (((double *) ( /* dim=0 */ (__pyx_v_result.data + __pyx_t_14 * __pyx_v_result.strides[0]) )) + __pyx_t_13)) )) = __pyx_t_15; __pyx_t_13 = __pyx_v_x; __pyx_t_14 = __pyx_v_y; *((double *) ( /* dim=1 */ ((char *) (((double *) ( /* dim=0 */ (__pyx_v_result.data + __pyx_t_13 * __pyx_v_result.strides[0]) )) + __pyx_t_14)) )) = __pyx_t_15; } } } } } } #if ((defined(__APPLE__) || defined(__OSX__)) && (defined(__GNUC__) && (__GNUC__ > 2 || (__GNUC__ == 2 && (__GNUC_MINOR__ > 95))))) #undef likely #undef unlikely #define likely(x) __builtin_expect(!!(x), 1) #define unlikely(x) __builtin_expect(!!(x), 0) #endif } /* "shakemap/c/clib.pyx":88 * * if &lons1[0] == &lons2[0] and &lats1[0] == &lats2[0]: * for y in prange(ny, nogil=True, schedule='guided'): # <<<<<<<<<<<<<< * for x in range(y+1): * 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__pyx_t_1-=1) { __pyx_v_i = __pyx_t_1; /* "View.MemoryView":1125 * * for i in range(ndim - 1, -1, -1): * if mslice.shape[i] > 1: # <<<<<<<<<<<<<< * c_stride = mslice.strides[i] * break */ __pyx_t_2 = (((__pyx_v_mslice->shape[__pyx_v_i]) > 1) != 0); if (__pyx_t_2) { /* "View.MemoryView":1126 * for i in range(ndim - 1, -1, -1): * if mslice.shape[i] > 1: * c_stride = mslice.strides[i] # <<<<<<<<<<<<<< * break * */ __pyx_v_c_stride = (__pyx_v_mslice->strides[__pyx_v_i]); /* "View.MemoryView":1127 * if mslice.shape[i] > 1: * c_stride = mslice.strides[i] * break # <<<<<<<<<<<<<< * * for i in range(ndim): */ goto __pyx_L4_break; /* "View.MemoryView":1125 * * for i in range(ndim - 1, -1, -1): * if mslice.shape[i] > 1: # <<<<<<<<<<<<<< * c_stride = mslice.strides[i] * break */ } } __pyx_L4_break:; /* "View.MemoryView":1129 * break * * for i in range(ndim): # <<<<<<<<<<<<<< * if mslice.shape[i] > 1: * f_stride = mslice.strides[i] */ __pyx_t_1 = __pyx_v_ndim; __pyx_t_3 = __pyx_t_1; for (__pyx_t_4 = 0; __pyx_t_4 < __pyx_t_3; __pyx_t_4+=1) { __pyx_v_i = __pyx_t_4; /* "View.MemoryView":1130 * * for i in range(ndim): * if mslice.shape[i] > 1: # <<<<<<<<<<<<<< * f_stride = mslice.strides[i] * break */ __pyx_t_2 = (((__pyx_v_mslice->shape[__pyx_v_i]) > 1) != 0); if (__pyx_t_2) { /* "View.MemoryView":1131 * for i in range(ndim): * if mslice.shape[i] > 1: * f_stride = mslice.strides[i] # <<<<<<<<<<<<<< * break * */ __pyx_v_f_stride = (__pyx_v_mslice->strides[__pyx_v_i]); /* "View.MemoryView":1132 * if mslice.shape[i] > 1: * f_stride = mslice.strides[i] * break # <<<<<<<<<<<<<< * * if abs_py_ssize_t(c_stride) <= abs_py_ssize_t(f_stride): */ goto __pyx_L7_break; /* "View.MemoryView":1130 * * for i in range(ndim): * if mslice.shape[i] > 1: # <<<<<<<<<<<<<< * f_stride = mslice.strides[i] * break */ } } __pyx_L7_break:; /* "View.MemoryView":1134 * break * * if abs_py_ssize_t(c_stride) <= abs_py_ssize_t(f_stride): # <<<<<<<<<<<<<< * return 'C' * else: */ __pyx_t_2 = ((abs_py_ssize_t(__pyx_v_c_stride) <= abs_py_ssize_t(__pyx_v_f_stride)) != 0); if (__pyx_t_2) { /* "View.MemoryView":1135 * * if abs_py_ssize_t(c_stride) <= abs_py_ssize_t(f_stride): * return 'C' # <<<<<<<<<<<<<< * else: * return 'F' */ __pyx_r = 'C'; goto __pyx_L0; /* "View.MemoryView":1134 * break * * if abs_py_ssize_t(c_stride) <= abs_py_ssize_t(f_stride): # <<<<<<<<<<<<<< * return 'C' * else: */ } /* "View.MemoryView":1137 * return 'C' * else: * return 'F' # <<<<<<<<<<<<<< * * @cython.cdivision(True) */ /*else*/ { __pyx_r = 'F'; goto __pyx_L0; } /* "View.MemoryView":1116 * * @cname('__pyx_get_best_slice_order') * cdef char get_best_order(__Pyx_memviewslice *mslice, int ndim) nogil: # <<<<<<<<<<<<<< * """ * Figure out the best memory access order for a given slice. */ /* function exit code */ __pyx_L0:; return __pyx_r; } /* "View.MemoryView":1140 * * @cython.cdivision(True) * cdef void _copy_strided_to_strided(char *src_data, Py_ssize_t *src_strides, # <<<<<<<<<<<<<< * char *dst_data, Py_ssize_t *dst_strides, * Py_ssize_t *src_shape, Py_ssize_t *dst_shape, */ static void _copy_strided_to_strided(char *__pyx_v_src_data, Py_ssize_t *__pyx_v_src_strides, char *__pyx_v_dst_data, Py_ssize_t *__pyx_v_dst_strides, Py_ssize_t *__pyx_v_src_shape, Py_ssize_t *__pyx_v_dst_shape, int __pyx_v_ndim, size_t __pyx_v_itemsize) { CYTHON_UNUSED Py_ssize_t __pyx_v_i; CYTHON_UNUSED Py_ssize_t __pyx_v_src_extent; Py_ssize_t __pyx_v_dst_extent; Py_ssize_t __pyx_v_src_stride; Py_ssize_t __pyx_v_dst_stride; int __pyx_t_1; int __pyx_t_2; int __pyx_t_3; Py_ssize_t __pyx_t_4; Py_ssize_t __pyx_t_5; Py_ssize_t __pyx_t_6; /* "View.MemoryView":1147 * * cdef Py_ssize_t i * cdef Py_ssize_t src_extent = src_shape[0] # <<<<<<<<<<<<<< * cdef Py_ssize_t dst_extent = dst_shape[0] * cdef Py_ssize_t src_stride = src_strides[0] */ __pyx_v_src_extent = (__pyx_v_src_shape[0]); /* "View.MemoryView":1148 * cdef Py_ssize_t i * cdef Py_ssize_t src_extent = src_shape[0] * cdef Py_ssize_t dst_extent = dst_shape[0] # <<<<<<<<<<<<<< * cdef Py_ssize_t src_stride = src_strides[0] * cdef Py_ssize_t dst_stride = dst_strides[0] */ __pyx_v_dst_extent = (__pyx_v_dst_shape[0]); /* "View.MemoryView":1149 * cdef Py_ssize_t src_extent = src_shape[0] * cdef Py_ssize_t dst_extent = dst_shape[0] * cdef Py_ssize_t src_stride = src_strides[0] # <<<<<<<<<<<<<< * cdef Py_ssize_t dst_stride = dst_strides[0] * */ __pyx_v_src_stride = (__pyx_v_src_strides[0]); /* "View.MemoryView":1150 * cdef Py_ssize_t dst_extent = dst_shape[0] * cdef Py_ssize_t src_stride = src_strides[0] * cdef Py_ssize_t dst_stride = dst_strides[0] # <<<<<<<<<<<<<< * * if ndim == 1: */ __pyx_v_dst_stride = (__pyx_v_dst_strides[0]); /* "View.MemoryView":1152 * cdef Py_ssize_t dst_stride = dst_strides[0] * * if ndim == 1: # <<<<<<<<<<<<<< * if (src_stride > 0 and dst_stride > 0 and * <size_t> src_stride == itemsize == <size_t> dst_stride): */ __pyx_t_1 = ((__pyx_v_ndim == 1) != 0); if (__pyx_t_1) { /* "View.MemoryView":1153 * * if ndim == 1: * if (src_stride > 0 and dst_stride > 0 and # <<<<<<<<<<<<<< * <size_t> src_stride == itemsize == <size_t> dst_stride): * memcpy(dst_data, src_data, itemsize * dst_extent) */ __pyx_t_2 = ((__pyx_v_src_stride > 0) != 0); if (__pyx_t_2) { } else { __pyx_t_1 = __pyx_t_2; goto __pyx_L5_bool_binop_done; } __pyx_t_2 = ((__pyx_v_dst_stride > 0) != 0); if (__pyx_t_2) { } else { __pyx_t_1 = __pyx_t_2; goto __pyx_L5_bool_binop_done; } /* "View.MemoryView":1154 * if ndim == 1: * if (src_stride > 0 and dst_stride > 0 and * <size_t> src_stride == itemsize == <size_t> dst_stride): # <<<<<<<<<<<<<< * memcpy(dst_data, src_data, itemsize * dst_extent) * else: */ __pyx_t_2 = (((size_t)__pyx_v_src_stride) == __pyx_v_itemsize); if (__pyx_t_2) { __pyx_t_2 = (__pyx_v_itemsize == ((size_t)__pyx_v_dst_stride)); } __pyx_t_3 = (__pyx_t_2 != 0); __pyx_t_1 = __pyx_t_3; __pyx_L5_bool_binop_done:; /* "View.MemoryView":1153 * * if ndim == 1: * if (src_stride > 0 and dst_stride > 0 and # <<<<<<<<<<<<<< * <size_t> src_stride == itemsize == <size_t> dst_stride): * memcpy(dst_data, src_data, itemsize * dst_extent) */ if (__pyx_t_1) { /* "View.MemoryView":1155 * if (src_stride > 0 and dst_stride > 0 and * <size_t> src_stride == itemsize == <size_t> dst_stride): * memcpy(dst_data, src_data, itemsize * dst_extent) # <<<<<<<<<<<<<< * else: * for i in range(dst_extent): */ (void)(memcpy(__pyx_v_dst_data, __pyx_v_src_data, (__pyx_v_itemsize * __pyx_v_dst_extent))); /* "View.MemoryView":1153 * * if ndim == 1: * if (src_stride > 0 and dst_stride > 0 and # <<<<<<<<<<<<<< * <size_t> src_stride == itemsize == <size_t> dst_stride): * memcpy(dst_data, src_data, itemsize * dst_extent) */ goto __pyx_L4; } /* "View.MemoryView":1157 * memcpy(dst_data, src_data, itemsize * dst_extent) * else: * for i in range(dst_extent): # <<<<<<<<<<<<<< * memcpy(dst_data, src_data, itemsize) * src_data += src_stride */ /*else*/ { __pyx_t_4 = __pyx_v_dst_extent; __pyx_t_5 = __pyx_t_4; for (__pyx_t_6 = 0; __pyx_t_6 < 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CYTHON_USE_TP_FINALIZE if (unlikely(PyType_HasFeature(Py_TYPE(o), Py_TPFLAGS_HAVE_FINALIZE) && Py_TYPE(o)->tp_finalize) && (!PyType_IS_GC(Py_TYPE(o)) || !_PyGC_FINALIZED(o))) { if (PyObject_CallFinalizerFromDealloc(o)) return; } #endif { PyObject *etype, *eval, *etb; PyErr_Fetch(&etype, &eval, &etb); __Pyx_SET_REFCNT(o, Py_REFCNT(o) + 1); __pyx_array___dealloc__(o); __Pyx_SET_REFCNT(o, Py_REFCNT(o) - 1); PyErr_Restore(etype, eval, etb); } Py_CLEAR(p->mode); Py_CLEAR(p->_format); (*Py_TYPE(o)->tp_free)(o); } static PyObject *__pyx_sq_item_array(PyObject *o, Py_ssize_t i) { PyObject *r; PyObject *x = PyInt_FromSsize_t(i); if(!x) return 0; r = Py_TYPE(o)->tp_as_mapping->mp_subscript(o, x); Py_DECREF(x); return r; } static int __pyx_mp_ass_subscript_array(PyObject *o, PyObject *i, PyObject *v) { if (v) { return __pyx_array___setitem__(o, i, v); } else { PyErr_Format(PyExc_NotImplementedError, "Subscript deletion not supported by %.200s", Py_TYPE(o)->tp_name); return -1; } } static PyObject *__pyx_tp_getattro_array(PyObject *o, PyObject *n) { PyObject *v = __Pyx_PyObject_GenericGetAttr(o, n); if (!v && PyErr_ExceptionMatches(PyExc_AttributeError)) { PyErr_Clear(); v = __pyx_array___getattr__(o, n); } return v; } static PyObject *__pyx_getprop___pyx_array_memview(PyObject *o, CYTHON_UNUSED void *x) { return __pyx_pw_15View_dot_MemoryView_5array_7memview_1__get__(o); } static PyMethodDef __pyx_methods_array[] = { {"__getattr__", (PyCFunction)__pyx_array___getattr__, METH_O|METH_COEXIST, 0}, {"__reduce_cython__", (PyCFunction)__pyx_pw___pyx_array_1__reduce_cython__, METH_NOARGS, 0}, {"__setstate_cython__", (PyCFunction)__pyx_pw___pyx_array_3__setstate_cython__, METH_O, 0}, {0, 0, 0, 0} }; static struct PyGetSetDef __pyx_getsets_array[] = { {(char *)"memview", __pyx_getprop___pyx_array_memview, 0, (char *)0, 0}, {0, 0, 0, 0, 0} }; static PySequenceMethods __pyx_tp_as_sequence_array = { __pyx_array___len__, /*sq_length*/ 0, /*sq_concat*/ 0, /*sq_repeat*/ __pyx_sq_item_array, 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#endif 0, /*tp_getattr*/ 0, /*tp_setattr*/ #if PY_MAJOR_VERSION < 3 0, /*tp_compare*/ #endif #if PY_MAJOR_VERSION >= 3 0, /*tp_as_async*/ #endif 0, /*tp_repr*/ 0, /*tp_as_number*/ &__pyx_tp_as_sequence_array, /*tp_as_sequence*/ &__pyx_tp_as_mapping_array, /*tp_as_mapping*/ 0, /*tp_hash*/ 0, /*tp_call*/ 0, /*tp_str*/ __pyx_tp_getattro_array, /*tp_getattro*/ 0, /*tp_setattro*/ &__pyx_tp_as_buffer_array, /*tp_as_buffer*/ Py_TPFLAGS_DEFAULT|Py_TPFLAGS_HAVE_VERSION_TAG|Py_TPFLAGS_CHECKTYPES|Py_TPFLAGS_HAVE_NEWBUFFER|Py_TPFLAGS_BASETYPE, /*tp_flags*/ 0, /*tp_doc*/ 0, /*tp_traverse*/ 0, /*tp_clear*/ 0, /*tp_richcompare*/ 0, /*tp_weaklistoffset*/ 0, /*tp_iter*/ 0, /*tp_iternext*/ __pyx_methods_array, /*tp_methods*/ 0, /*tp_members*/ __pyx_getsets_array, /*tp_getset*/ 0, /*tp_base*/ 0, /*tp_dict*/ 0, /*tp_descr_get*/ 0, /*tp_descr_set*/ 0, /*tp_dictoffset*/ 0, /*tp_init*/ 0, /*tp_alloc*/ __pyx_tp_new_array, /*tp_new*/ 0, /*tp_free*/ 0, /*tp_is_gc*/ 0, /*tp_bases*/ 0, /*tp_mro*/ 0, /*tp_cache*/ 0, /*tp_subclasses*/ 0, /*tp_weaklist*/ 0, /*tp_del*/ 0, /*tp_version_tag*/ #if PY_VERSION_HEX >= 0x030400a1 0, /*tp_finalize*/ #endif #if PY_VERSION_HEX >= 0x030800b1 0, /*tp_vectorcall*/ #endif #if PY_VERSION_HEX >= 0x030800b4 && PY_VERSION_HEX < 0x03090000 0, /*tp_print*/ #endif #if PY_VERSION_HEX >= 0x030B00A2 0, /*tp_inline_values_offset*/ #endif }; static PyObject *__pyx_tp_new_Enum(PyTypeObject *t, CYTHON_UNUSED PyObject *a, CYTHON_UNUSED PyObject *k) { struct __pyx_MemviewEnum_obj *p; PyObject *o; if (likely((t->tp_flags & Py_TPFLAGS_IS_ABSTRACT) == 0)) { o = (*t->tp_alloc)(t, 0); } else { o = (PyObject *) PyBaseObject_Type.tp_new(t, __pyx_empty_tuple, 0); } if (unlikely(!o)) return 0; p = ((struct __pyx_MemviewEnum_obj *)o); p->name = Py_None; Py_INCREF(Py_None); return o; } static void __pyx_tp_dealloc_Enum(PyObject *o) { struct __pyx_MemviewEnum_obj *p = (struct __pyx_MemviewEnum_obj *)o; #if CYTHON_USE_TP_FINALIZE if (unlikely(PyType_HasFeature(Py_TYPE(o), Py_TPFLAGS_HAVE_FINALIZE) && Py_TYPE(o)->tp_finalize) && !_PyGC_FINALIZED(o)) { if (PyObject_CallFinalizerFromDealloc(o)) return; } #endif PyObject_GC_UnTrack(o); Py_CLEAR(p->name); (*Py_TYPE(o)->tp_free)(o); } static int __pyx_tp_traverse_Enum(PyObject *o, visitproc v, void *a) { int e; struct __pyx_MemviewEnum_obj *p = (struct __pyx_MemviewEnum_obj *)o; if (p->name) { e = (*v)(p->name, a); if (e) return e; } return 0; } static int __pyx_tp_clear_Enum(PyObject *o) { PyObject* tmp; struct __pyx_MemviewEnum_obj *p = (struct __pyx_MemviewEnum_obj *)o; tmp = ((PyObject*)p->name); p->name = Py_None; Py_INCREF(Py_None); Py_XDECREF(tmp); return 0; } static PyMethodDef __pyx_methods_Enum[] = { {"__reduce_cython__", (PyCFunction)__pyx_pw___pyx_MemviewEnum_1__reduce_cython__, METH_NOARGS, 0}, {"__setstate_cython__", (PyCFunction)__pyx_pw___pyx_MemviewEnum_3__setstate_cython__, METH_O, 0}, {0, 0, 0, 0} }; static PyTypeObject __pyx_type___pyx_MemviewEnum = { PyVarObject_HEAD_INIT(0, 0) "shakemap.c.clib.Enum", /*tp_name*/ sizeof(struct __pyx_MemviewEnum_obj), /*tp_basicsize*/ 0, /*tp_itemsize*/ __pyx_tp_dealloc_Enum, /*tp_dealloc*/ #if PY_VERSION_HEX < 0x030800b4 0, /*tp_print*/ #endif #if PY_VERSION_HEX >= 0x030800b4 0, /*tp_vectorcall_offset*/ #endif 0, /*tp_getattr*/ 0, /*tp_setattr*/ #if PY_MAJOR_VERSION < 3 0, /*tp_compare*/ #endif #if PY_MAJOR_VERSION >= 3 0, /*tp_as_async*/ #endif __pyx_MemviewEnum___repr__, /*tp_repr*/ 0, /*tp_as_number*/ 0, /*tp_as_sequence*/ 0, /*tp_as_mapping*/ 0, /*tp_hash*/ 0, /*tp_call*/ 0, /*tp_str*/ 0, /*tp_getattro*/ 0, /*tp_setattro*/ 0, /*tp_as_buffer*/ Py_TPFLAGS_DEFAULT|Py_TPFLAGS_HAVE_VERSION_TAG|Py_TPFLAGS_CHECKTYPES|Py_TPFLAGS_HAVE_NEWBUFFER|Py_TPFLAGS_BASETYPE|Py_TPFLAGS_HAVE_GC, /*tp_flags*/ 0, /*tp_doc*/ __pyx_tp_traverse_Enum, /*tp_traverse*/ __pyx_tp_clear_Enum, /*tp_clear*/ 0, /*tp_richcompare*/ 0, /*tp_weaklistoffset*/ 0, /*tp_iter*/ 0, /*tp_iternext*/ __pyx_methods_Enum, /*tp_methods*/ 0, /*tp_members*/ 0, /*tp_getset*/ 0, /*tp_base*/ 0, /*tp_dict*/ 0, /*tp_descr_get*/ 0, /*tp_descr_set*/ 0, /*tp_dictoffset*/ __pyx_MemviewEnum___init__, /*tp_init*/ 0, /*tp_alloc*/ __pyx_tp_new_Enum, /*tp_new*/ 0, /*tp_free*/ 0, /*tp_is_gc*/ 0, /*tp_bases*/ 0, /*tp_mro*/ 0, /*tp_cache*/ 0, /*tp_subclasses*/ 0, /*tp_weaklist*/ 0, /*tp_del*/ 0, /*tp_version_tag*/ #if PY_VERSION_HEX >= 0x030400a1 0, /*tp_finalize*/ #endif #if PY_VERSION_HEX >= 0x030800b1 0, /*tp_vectorcall*/ #endif #if PY_VERSION_HEX >= 0x030800b4 && PY_VERSION_HEX < 0x03090000 0, /*tp_print*/ #endif #if PY_VERSION_HEX >= 0x030B00A2 0, /*tp_inline_values_offset*/ #endif }; static struct __pyx_vtabstruct_memoryview __pyx_vtable_memoryview; static PyObject *__pyx_tp_new_memoryview(PyTypeObject *t, PyObject *a, PyObject *k) { struct __pyx_memoryview_obj *p; PyObject *o; if (likely((t->tp_flags & Py_TPFLAGS_IS_ABSTRACT) == 0)) { o = (*t->tp_alloc)(t, 0); } else { o = (PyObject *) PyBaseObject_Type.tp_new(t, __pyx_empty_tuple, 0); } if (unlikely(!o)) return 0; p = ((struct __pyx_memoryview_obj *)o); p->__pyx_vtab = __pyx_vtabptr_memoryview; p->obj = Py_None; Py_INCREF(Py_None); p->_size = Py_None; Py_INCREF(Py_None); p->_array_interface = Py_None; Py_INCREF(Py_None); p->view.obj = NULL; if (unlikely(__pyx_memoryview___cinit__(o, a, k) < 0)) goto bad; return o; bad: Py_DECREF(o); o = 0; return NULL; } static void __pyx_tp_dealloc_memoryview(PyObject *o) { struct __pyx_memoryview_obj *p = (struct __pyx_memoryview_obj *)o; #if CYTHON_USE_TP_FINALIZE if (unlikely(PyType_HasFeature(Py_TYPE(o), Py_TPFLAGS_HAVE_FINALIZE) && Py_TYPE(o)->tp_finalize) && !_PyGC_FINALIZED(o)) { if (PyObject_CallFinalizerFromDealloc(o)) return; } #endif PyObject_GC_UnTrack(o); { PyObject *etype, *eval, *etb; PyErr_Fetch(&etype, &eval, &etb); __Pyx_SET_REFCNT(o, Py_REFCNT(o) + 1); __pyx_memoryview___dealloc__(o); __Pyx_SET_REFCNT(o, Py_REFCNT(o) - 1); PyErr_Restore(etype, eval, etb); } Py_CLEAR(p->obj); Py_CLEAR(p->_size); Py_CLEAR(p->_array_interface); (*Py_TYPE(o)->tp_free)(o); } static int __pyx_tp_traverse_memoryview(PyObject *o, visitproc v, void *a) { int e; struct __pyx_memoryview_obj *p = (struct __pyx_memoryview_obj *)o; if (p->obj) { e = (*v)(p->obj, a); if (e) return e; } if (p->_size) { e = (*v)(p->_size, a); if (e) return e; } if (p->_array_interface) { e = (*v)(p->_array_interface, a); if (e) return e; } if (p->view.obj) { e = (*v)(p->view.obj, a); if (e) return e; } return 0; } static int __pyx_tp_clear_memoryview(PyObject *o) { PyObject* tmp; struct __pyx_memoryview_obj *p = (struct __pyx_memoryview_obj *)o; tmp = ((PyObject*)p->obj); p->obj = Py_None; Py_INCREF(Py_None); Py_XDECREF(tmp); tmp = ((PyObject*)p->_size); p->_size = Py_None; Py_INCREF(Py_None); Py_XDECREF(tmp); tmp = ((PyObject*)p->_array_interface); p->_array_interface = Py_None; Py_INCREF(Py_None); Py_XDECREF(tmp); Py_CLEAR(p->view.obj); return 0; } static PyObject *__pyx_sq_item_memoryview(PyObject *o, Py_ssize_t i) { PyObject *r; PyObject *x = PyInt_FromSsize_t(i); if(!x) return 0; r = Py_TYPE(o)->tp_as_mapping->mp_subscript(o, x); Py_DECREF(x); return r; } static int __pyx_mp_ass_subscript_memoryview(PyObject *o, PyObject *i, PyObject *v) { if (v) { return __pyx_memoryview___setitem__(o, i, v); } else { PyErr_Format(PyExc_NotImplementedError, "Subscript deletion not supported by %.200s", Py_TYPE(o)->tp_name); return -1; } } static PyObject *__pyx_getprop___pyx_memoryview_T(PyObject *o, CYTHON_UNUSED void *x) { return __pyx_pw_15View_dot_MemoryView_10memoryview_1T_1__get__(o); } static PyObject *__pyx_getprop___pyx_memoryview_base(PyObject *o, CYTHON_UNUSED void *x) { return __pyx_pw_15View_dot_MemoryView_10memoryview_4base_1__get__(o); } static PyObject *__pyx_getprop___pyx_memoryview_shape(PyObject *o, CYTHON_UNUSED void *x) { return __pyx_pw_15View_dot_MemoryView_10memoryview_5shape_1__get__(o); } static PyObject *__pyx_getprop___pyx_memoryview_strides(PyObject *o, CYTHON_UNUSED void *x) { return __pyx_pw_15View_dot_MemoryView_10memoryview_7strides_1__get__(o); } static PyObject *__pyx_getprop___pyx_memoryview_suboffsets(PyObject *o, CYTHON_UNUSED void *x) { return __pyx_pw_15View_dot_MemoryView_10memoryview_10suboffsets_1__get__(o); } static PyObject *__pyx_getprop___pyx_memoryview_ndim(PyObject *o, CYTHON_UNUSED void *x) { return __pyx_pw_15View_dot_MemoryView_10memoryview_4ndim_1__get__(o); } static PyObject *__pyx_getprop___pyx_memoryview_itemsize(PyObject *o, CYTHON_UNUSED void *x) { return __pyx_pw_15View_dot_MemoryView_10memoryview_8itemsize_1__get__(o); } static PyObject *__pyx_getprop___pyx_memoryview_nbytes(PyObject *o, CYTHON_UNUSED void *x) { return __pyx_pw_15View_dot_MemoryView_10memoryview_6nbytes_1__get__(o); } static PyObject *__pyx_getprop___pyx_memoryview_size(PyObject *o, CYTHON_UNUSED void *x) { return __pyx_pw_15View_dot_MemoryView_10memoryview_4size_1__get__(o); } static PyMethodDef __pyx_methods_memoryview[] = { {"is_c_contig", (PyCFunction)__pyx_memoryview_is_c_contig, METH_NOARGS, 0}, {"is_f_contig", (PyCFunction)__pyx_memoryview_is_f_contig, METH_NOARGS, 0}, {"copy", (PyCFunction)__pyx_memoryview_copy, METH_NOARGS, 0}, {"copy_fortran", (PyCFunction)__pyx_memoryview_copy_fortran, METH_NOARGS, 0}, {"__reduce_cython__", (PyCFunction)__pyx_pw___pyx_memoryview_1__reduce_cython__, METH_NOARGS, 0}, {"__setstate_cython__", (PyCFunction)__pyx_pw___pyx_memoryview_3__setstate_cython__, METH_O, 0}, {0, 0, 0, 0} }; static struct PyGetSetDef __pyx_getsets_memoryview[] = { {(char *)"T", __pyx_getprop___pyx_memoryview_T, 0, (char *)0, 0}, {(char *)"base", __pyx_getprop___pyx_memoryview_base, 0, (char *)0, 0}, {(char *)"shape", __pyx_getprop___pyx_memoryview_shape, 0, (char *)0, 0}, {(char *)"strides", __pyx_getprop___pyx_memoryview_strides, 0, (char *)0, 0}, {(char *)"suboffsets", __pyx_getprop___pyx_memoryview_suboffsets, 0, (char *)0, 0}, {(char *)"ndim", __pyx_getprop___pyx_memoryview_ndim, 0, (char *)0, 0}, {(char *)"itemsize", __pyx_getprop___pyx_memoryview_itemsize, 0, (char *)0, 0}, {(char *)"nbytes", __pyx_getprop___pyx_memoryview_nbytes, 0, (char *)0, 0}, {(char *)"size", __pyx_getprop___pyx_memoryview_size, 0, (char *)0, 0}, {0, 0, 0, 0, 0} }; static PySequenceMethods __pyx_tp_as_sequence_memoryview = { __pyx_memoryview___len__, /*sq_length*/ 0, /*sq_concat*/ 0, /*sq_repeat*/ __pyx_sq_item_memoryview, /*sq_item*/ 0, /*sq_slice*/ 0, /*sq_ass_item*/ 0, /*sq_ass_slice*/ 0, /*sq_contains*/ 0, /*sq_inplace_concat*/ 0, /*sq_inplace_repeat*/ }; static PyMappingMethods __pyx_tp_as_mapping_memoryview = { __pyx_memoryview___len__, /*mp_length*/ __pyx_memoryview___getitem__, /*mp_subscript*/ __pyx_mp_ass_subscript_memoryview, /*mp_ass_subscript*/ }; static PyBufferProcs __pyx_tp_as_buffer_memoryview = { #if PY_MAJOR_VERSION < 3 0, /*bf_getreadbuffer*/ #endif #if PY_MAJOR_VERSION < 3 0, /*bf_getwritebuffer*/ #endif #if PY_MAJOR_VERSION < 3 0, /*bf_getsegcount*/ #endif #if PY_MAJOR_VERSION < 3 0, /*bf_getcharbuffer*/ #endif __pyx_memoryview_getbuffer, /*bf_getbuffer*/ 0, /*bf_releasebuffer*/ }; static PyTypeObject __pyx_type___pyx_memoryview = { PyVarObject_HEAD_INIT(0, 0) "shakemap.c.clib.memoryview", /*tp_name*/ sizeof(struct __pyx_memoryview_obj), /*tp_basicsize*/ 0, /*tp_itemsize*/ __pyx_tp_dealloc_memoryview, /*tp_dealloc*/ #if PY_VERSION_HEX < 0x030800b4 0, /*tp_print*/ #endif #if PY_VERSION_HEX >= 0x030800b4 0, /*tp_vectorcall_offset*/ #endif 0, /*tp_getattr*/ 0, /*tp_setattr*/ #if PY_MAJOR_VERSION < 3 0, /*tp_compare*/ #endif #if PY_MAJOR_VERSION >= 3 0, /*tp_as_async*/ #endif __pyx_memoryview___repr__, /*tp_repr*/ 0, /*tp_as_number*/ &__pyx_tp_as_sequence_memoryview, /*tp_as_sequence*/ &__pyx_tp_as_mapping_memoryview, /*tp_as_mapping*/ 0, /*tp_hash*/ 0, /*tp_call*/ __pyx_memoryview___str__, /*tp_str*/ 0, /*tp_getattro*/ 0, /*tp_setattro*/ &__pyx_tp_as_buffer_memoryview, /*tp_as_buffer*/ Py_TPFLAGS_DEFAULT|Py_TPFLAGS_HAVE_VERSION_TAG|Py_TPFLAGS_CHECKTYPES|Py_TPFLAGS_HAVE_NEWBUFFER|Py_TPFLAGS_BASETYPE|Py_TPFLAGS_HAVE_GC, /*tp_flags*/ 0, /*tp_doc*/ __pyx_tp_traverse_memoryview, /*tp_traverse*/ __pyx_tp_clear_memoryview, /*tp_clear*/ 0, /*tp_richcompare*/ 0, /*tp_weaklistoffset*/ 0, /*tp_iter*/ 0, /*tp_iternext*/ __pyx_methods_memoryview, /*tp_methods*/ 0, /*tp_members*/ __pyx_getsets_memoryview, /*tp_getset*/ 0, /*tp_base*/ 0, /*tp_dict*/ 0, /*tp_descr_get*/ 0, /*tp_descr_set*/ 0, /*tp_dictoffset*/ 0, /*tp_init*/ 0, /*tp_alloc*/ __pyx_tp_new_memoryview, /*tp_new*/ 0, /*tp_free*/ 0, /*tp_is_gc*/ 0, /*tp_bases*/ 0, /*tp_mro*/ 0, /*tp_cache*/ 0, /*tp_subclasses*/ 0, /*tp_weaklist*/ 0, /*tp_del*/ 0, /*tp_version_tag*/ #if PY_VERSION_HEX >= 0x030400a1 0, /*tp_finalize*/ #endif #if PY_VERSION_HEX >= 0x030800b1 0, /*tp_vectorcall*/ #endif #if PY_VERSION_HEX >= 0x030800b4 && PY_VERSION_HEX < 0x03090000 0, /*tp_print*/ #endif #if PY_VERSION_HEX >= 0x030B00A2 0, 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"" : "s", num_found); } /* RaiseDoubleKeywords */ static void __Pyx_RaiseDoubleKeywordsError( const char* func_name, PyObject* kw_name) { PyErr_Format(PyExc_TypeError, #if PY_MAJOR_VERSION >= 3 "%s() got multiple values for keyword argument '%U'", func_name, kw_name); #else "%s() got multiple values for keyword argument '%s'", func_name, PyString_AsString(kw_name)); #endif } /* ParseKeywords */ static int __Pyx_ParseOptionalKeywords( PyObject *kwds, PyObject **argnames[], PyObject *kwds2, PyObject *values[], Py_ssize_t num_pos_args, const char* function_name) { PyObject *key = 0, *value = 0; Py_ssize_t pos = 0; PyObject*** name; PyObject*** first_kw_arg = argnames + num_pos_args; while (PyDict_Next(kwds, &pos, &key, &value)) { name = first_kw_arg; while (*name && (**name != key)) name++; if (*name) { values[name-argnames] = value; continue; } name = first_kw_arg; #if PY_MAJOR_VERSION < 3 if (likely(PyString_Check(key))) { while (*name) { if ((CYTHON_COMPILING_IN_PYPY || PyString_GET_SIZE(**name) == PyString_GET_SIZE(key)) && _PyString_Eq(**name, key)) { values[name-argnames] = value; break; } name++; } if (*name) continue; else { PyObject*** argname = argnames; while (argname != first_kw_arg) { if ((**argname == key) || ( (CYTHON_COMPILING_IN_PYPY || PyString_GET_SIZE(**argname) == PyString_GET_SIZE(key)) && _PyString_Eq(**argname, key))) { goto arg_passed_twice; } argname++; } } } else #endif if (likely(PyUnicode_Check(key))) { while (*name) { int cmp = (**name == key) ? 0 : #if !CYTHON_COMPILING_IN_PYPY && PY_MAJOR_VERSION >= 3 (__Pyx_PyUnicode_GET_LENGTH(**name) != __Pyx_PyUnicode_GET_LENGTH(key)) ? 1 : #endif PyUnicode_Compare(**name, key); if (cmp < 0 && unlikely(PyErr_Occurred())) goto bad; if (cmp == 0) { values[name-argnames] = value; break; } name++; } if (*name) continue; else { PyObject*** argname = argnames; while (argname != first_kw_arg) { int cmp = (**argname == key) ? 0 : #if !CYTHON_COMPILING_IN_PYPY && PY_MAJOR_VERSION >= 3 (__Pyx_PyUnicode_GET_LENGTH(**argname) != __Pyx_PyUnicode_GET_LENGTH(key)) ? 1 : #endif PyUnicode_Compare(**argname, key); if (cmp < 0 && unlikely(PyErr_Occurred())) goto bad; if (cmp == 0) goto arg_passed_twice; argname++; } } } else goto invalid_keyword_type; if (kwds2) { if (unlikely(PyDict_SetItem(kwds2, key, value))) goto bad; } else { goto invalid_keyword; } } return 0; arg_passed_twice: __Pyx_RaiseDoubleKeywordsError(function_name, key); goto bad; invalid_keyword_type: PyErr_Format(PyExc_TypeError, "%.200s() keywords must be strings", function_name); goto bad; invalid_keyword: PyErr_Format(PyExc_TypeError, #if PY_MAJOR_VERSION < 3 "%.200s() got an unexpected keyword argument '%.200s'", function_name, PyString_AsString(key)); #else "%s() got an unexpected keyword argument '%U'", function_name, key); #endif bad: return -1; } /* MemviewSliceInit */ static int __Pyx_init_memviewslice(struct __pyx_memoryview_obj *memview, int ndim, __Pyx_memviewslice *memviewslice, int memview_is_new_reference) { __Pyx_RefNannyDeclarations int i, retval=-1; Py_buffer *buf = &memview->view; __Pyx_RefNannySetupContext("init_memviewslice", 0); if (unlikely(memviewslice->memview || memviewslice->data)) { PyErr_SetString(PyExc_ValueError, "memviewslice is already initialized!"); goto fail; } if (buf->strides) { for (i = 0; i < ndim; i++) { memviewslice->strides[i] = buf->strides[i]; } } else { Py_ssize_t stride = buf->itemsize; for (i = ndim - 1; i >= 0; i--) { memviewslice->strides[i] = stride; stride *= buf->shape[i]; } } for (i = 0; i < ndim; i++) { memviewslice->shape[i] = buf->shape[i]; if (buf->suboffsets) { memviewslice->suboffsets[i] = buf->suboffsets[i]; } else { memviewslice->suboffsets[i] = -1; } } memviewslice->memview = memview; memviewslice->data = (char *)buf->buf; if (__pyx_add_acquisition_count(memview) == 0 && !memview_is_new_reference) { Py_INCREF(memview); } retval = 0; goto no_fail; fail: memviewslice->memview = 0; memviewslice->data = 0; retval = -1; no_fail: __Pyx_RefNannyFinishContext(); return retval; } #ifndef Py_NO_RETURN #define Py_NO_RETURN #endif static void __pyx_fatalerror(const char *fmt, ...) Py_NO_RETURN { va_list vargs; char msg[200]; #ifdef HAVE_STDARG_PROTOTYPES va_start(vargs, fmt); #else va_start(vargs); #endif vsnprintf(msg, 200, fmt, vargs); va_end(vargs); Py_FatalError(msg); } static CYTHON_INLINE int __pyx_add_acquisition_count_locked(__pyx_atomic_int *acquisition_count, PyThread_type_lock lock) { int result; PyThread_acquire_lock(lock, 1); result = (*acquisition_count)++; PyThread_release_lock(lock); return result; } static CYTHON_INLINE int __pyx_sub_acquisition_count_locked(__pyx_atomic_int *acquisition_count, PyThread_type_lock lock) { int result; PyThread_acquire_lock(lock, 1); result = (*acquisition_count)--; PyThread_release_lock(lock); return result; } static CYTHON_INLINE void __Pyx_INC_MEMVIEW(__Pyx_memviewslice *memslice, int have_gil, int lineno) { int first_time; struct __pyx_memoryview_obj *memview = memslice->memview; if (unlikely(!memview || (PyObject *) memview == Py_None)) return; if (unlikely(__pyx_get_slice_count(memview) < 0)) __pyx_fatalerror("Acquisition count is %d (line %d)", __pyx_get_slice_count(memview), lineno); first_time = __pyx_add_acquisition_count(memview) == 0; if (unlikely(first_time)) { if (have_gil) { Py_INCREF((PyObject *) memview); } else { PyGILState_STATE _gilstate = PyGILState_Ensure(); Py_INCREF((PyObject *) memview); PyGILState_Release(_gilstate); } } } static CYTHON_INLINE void __Pyx_XDEC_MEMVIEW(__Pyx_memviewslice *memslice, int have_gil, int lineno) { int last_time; struct __pyx_memoryview_obj *memview = memslice->memview; if (unlikely(!memview || (PyObject *) memview == Py_None)) { memslice->memview = NULL; return; } if (unlikely(__pyx_get_slice_count(memview) <= 0)) __pyx_fatalerror("Acquisition count is %d (line %d)", __pyx_get_slice_count(memview), lineno); last_time = __pyx_sub_acquisition_count(memview) == 1; memslice->data = NULL; if (unlikely(last_time)) { if (have_gil) { Py_CLEAR(memslice->memview); } else { PyGILState_STATE _gilstate = PyGILState_Ensure(); Py_CLEAR(memslice->memview); PyGILState_Release(_gilstate); } } else { memslice->memview = NULL; } } /* ArgTypeTest */ static int __Pyx__ArgTypeTest(PyObject *obj, PyTypeObject *type, const char *name, int exact) { if (unlikely(!type)) { PyErr_SetString(PyExc_SystemError, "Missing type object"); return 0; } else if (exact) { #if PY_MAJOR_VERSION == 2 if ((type == &PyBaseString_Type) && likely(__Pyx_PyBaseString_CheckExact(obj))) return 1; #endif } else { if (likely(__Pyx_TypeCheck(obj, type))) return 1; } PyErr_Format(PyExc_TypeError, "Argument '%.200s' has incorrect type (expected %.200s, got %.200s)", name, type->tp_name, Py_TYPE(obj)->tp_name); return 0; } /* PyObjectCall */ #if CYTHON_COMPILING_IN_CPYTHON static CYTHON_INLINE PyObject* __Pyx_PyObject_Call(PyObject *func, PyObject *arg, PyObject *kw) { PyObject *result; ternaryfunc call = Py_TYPE(func)->tp_call; if (unlikely(!call)) return PyObject_Call(func, arg, kw); if (unlikely(Py_EnterRecursiveCall((char*)" while calling a Python object"))) return NULL; result = (*call)(func, arg, kw); Py_LeaveRecursiveCall(); if (unlikely(!result) && unlikely(!PyErr_Occurred())) { PyErr_SetString( PyExc_SystemError, "NULL result without error in PyObject_Call"); } return result; } #endif /* PyErrFetchRestore */ #if CYTHON_FAST_THREAD_STATE static CYTHON_INLINE void __Pyx_ErrRestoreInState(PyThreadState *tstate, PyObject *type, PyObject *value, PyObject *tb) { PyObject *tmp_type, *tmp_value, *tmp_tb; tmp_type = tstate->curexc_type; tmp_value = tstate->curexc_value; tmp_tb = tstate->curexc_traceback; tstate->curexc_type = type; tstate->curexc_value = value; tstate->curexc_traceback = tb; Py_XDECREF(tmp_type); Py_XDECREF(tmp_value); Py_XDECREF(tmp_tb); } static CYTHON_INLINE void __Pyx_ErrFetchInState(PyThreadState *tstate, PyObject **type, PyObject **value, PyObject **tb) { *type = tstate->curexc_type; *value = tstate->curexc_value; *tb = tstate->curexc_traceback; tstate->curexc_type = 0; tstate->curexc_value = 0; tstate->curexc_traceback = 0; } #endif /* RaiseException */ #if PY_MAJOR_VERSION < 3 static void __Pyx_Raise(PyObject *type, PyObject *value, PyObject *tb, CYTHON_UNUSED PyObject *cause) { __Pyx_PyThreadState_declare Py_XINCREF(type); if (!value || value == Py_None) value = NULL; else Py_INCREF(value); if (!tb || tb == Py_None) tb = NULL; else { Py_INCREF(tb); if (!PyTraceBack_Check(tb)) { PyErr_SetString(PyExc_TypeError, "raise: arg 3 must be a traceback or None"); goto raise_error; } } if (PyType_Check(type)) { #if CYTHON_COMPILING_IN_PYPY if (!value) { Py_INCREF(Py_None); value = Py_None; } #endif PyErr_NormalizeException(&type, &value, &tb); } else { if (value) { PyErr_SetString(PyExc_TypeError, "instance exception may not have a separate value"); goto raise_error; } value = type; type = (PyObject*) Py_TYPE(type); Py_INCREF(type); if (!PyType_IsSubtype((PyTypeObject *)type, (PyTypeObject *)PyExc_BaseException)) { PyErr_SetString(PyExc_TypeError, "raise: exception class must be a subclass of BaseException"); goto raise_error; } } __Pyx_PyThreadState_assign __Pyx_ErrRestore(type, value, tb); return; raise_error: Py_XDECREF(value); Py_XDECREF(type); Py_XDECREF(tb); return; } #else static void __Pyx_Raise(PyObject *type, PyObject *value, PyObject *tb, PyObject *cause) { PyObject* owned_instance = NULL; if (tb == Py_None) { tb = 0; } else if (tb && !PyTraceBack_Check(tb)) { PyErr_SetString(PyExc_TypeError, "raise: arg 3 must be a traceback or None"); goto bad; } if (value == Py_None) value = 0; if (PyExceptionInstance_Check(type)) { if (value) { PyErr_SetString(PyExc_TypeError, "instance exception may not have a separate value"); goto bad; } value = type; type = (PyObject*) Py_TYPE(value); } else if (PyExceptionClass_Check(type)) { PyObject *instance_class = NULL; if (value && PyExceptionInstance_Check(value)) { instance_class = (PyObject*) Py_TYPE(value); if (instance_class != type) { int is_subclass = PyObject_IsSubclass(instance_class, type); if (!is_subclass) { instance_class = NULL; } else if (unlikely(is_subclass == -1)) { goto bad; } else { type = instance_class; } } } if (!instance_class) { PyObject *args; if (!value) args = PyTuple_New(0); else if (PyTuple_Check(value)) { Py_INCREF(value); args = value; } else args = PyTuple_Pack(1, value); if (!args) goto bad; owned_instance = PyObject_Call(type, args, NULL); Py_DECREF(args); if (!owned_instance) goto bad; value = owned_instance; if (!PyExceptionInstance_Check(value)) { PyErr_Format(PyExc_TypeError, "calling %R should have returned an instance of " "BaseException, not %R", type, Py_TYPE(value)); goto bad; } } } else { PyErr_SetString(PyExc_TypeError, "raise: exception class must be a subclass of BaseException"); goto bad; } if (cause) { PyObject *fixed_cause; if (cause == Py_None) { fixed_cause = NULL; } else if (PyExceptionClass_Check(cause)) { fixed_cause = PyObject_CallObject(cause, NULL); if (fixed_cause == NULL) goto bad; } else if (PyExceptionInstance_Check(cause)) { fixed_cause = cause; Py_INCREF(fixed_cause); } else { PyErr_SetString(PyExc_TypeError, "exception causes must derive from " "BaseException"); goto bad; } PyException_SetCause(value, fixed_cause); } PyErr_SetObject(type, value); if (tb) { #if CYTHON_COMPILING_IN_PYPY PyObject *tmp_type, *tmp_value, *tmp_tb; PyErr_Fetch(&tmp_type, &tmp_value, &tmp_tb); Py_INCREF(tb); PyErr_Restore(tmp_type, tmp_value, tb); Py_XDECREF(tmp_tb); #else PyThreadState *tstate = __Pyx_PyThreadState_Current; PyObject* tmp_tb = tstate->curexc_traceback; if (tb != tmp_tb) { Py_INCREF(tb); tstate->curexc_traceback = tb; Py_XDECREF(tmp_tb); } #endif } bad: Py_XDECREF(owned_instance); return; } #endif /* PyCFunctionFastCall */ #if CYTHON_FAST_PYCCALL static CYTHON_INLINE PyObject * __Pyx_PyCFunction_FastCall(PyObject *func_obj, PyObject **args, Py_ssize_t nargs) { PyCFunctionObject *func = (PyCFunctionObject*)func_obj; PyCFunction meth = PyCFunction_GET_FUNCTION(func); PyObject *self = PyCFunction_GET_SELF(func); int flags = PyCFunction_GET_FLAGS(func); assert(PyCFunction_Check(func)); assert(METH_FASTCALL == (flags & ~(METH_CLASS | METH_STATIC | METH_COEXIST | METH_KEYWORDS | METH_STACKLESS))); assert(nargs >= 0); assert(nargs == 0 || args != NULL); /* _PyCFunction_FastCallDict() must not be called with an exception set, because it may clear it (directly or indirectly) and so the caller loses its exception */ assert(!PyErr_Occurred()); if ((PY_VERSION_HEX < 0x030700A0) || unlikely(flags & METH_KEYWORDS)) { return (*((__Pyx_PyCFunctionFastWithKeywords)(void*)meth)) (self, args, nargs, NULL); } else { return (*((__Pyx_PyCFunctionFast)(void*)meth)) (self, args, nargs); } } #endif /* PyFunctionFastCall */ #if CYTHON_FAST_PYCALL static PyObject* __Pyx_PyFunction_FastCallNoKw(PyCodeObject *co, PyObject **args, Py_ssize_t na, PyObject *globals) { PyFrameObject *f; PyThreadState *tstate = __Pyx_PyThreadState_Current; PyObject **fastlocals; Py_ssize_t i; PyObject *result; assert(globals != NULL); /* XXX Perhaps we should create a specialized PyFrame_New() that doesn't take locals, but does take builtins without sanity checking them. */ assert(tstate != NULL); f = PyFrame_New(tstate, co, globals, NULL); if (f == NULL) { return NULL; } fastlocals = __Pyx_PyFrame_GetLocalsplus(f); for (i = 0; i < na; i++) { Py_INCREF(*args); fastlocals[i] = *args++; } result = PyEval_EvalFrameEx(f,0); ++tstate->recursion_depth; Py_DECREF(f); --tstate->recursion_depth; return result; } #if 1 || PY_VERSION_HEX < 0x030600B1 static PyObject *__Pyx_PyFunction_FastCallDict(PyObject *func, PyObject **args, Py_ssize_t nargs, PyObject *kwargs) { PyCodeObject *co = (PyCodeObject *)PyFunction_GET_CODE(func); PyObject *globals = PyFunction_GET_GLOBALS(func); PyObject *argdefs = PyFunction_GET_DEFAULTS(func); PyObject *closure; #if PY_MAJOR_VERSION >= 3 PyObject *kwdefs; #endif PyObject *kwtuple, **k; PyObject **d; Py_ssize_t nd; Py_ssize_t nk; PyObject *result; assert(kwargs == NULL || PyDict_Check(kwargs)); nk = kwargs ? PyDict_Size(kwargs) : 0; if (Py_EnterRecursiveCall((char*)" while calling a Python object")) { return NULL; } if ( #if PY_MAJOR_VERSION >= 3 co->co_kwonlyargcount == 0 && #endif likely(kwargs == NULL || nk == 0) && co->co_flags == (CO_OPTIMIZED | CO_NEWLOCALS | CO_NOFREE)) { if (argdefs == NULL && co->co_argcount == nargs) { result = __Pyx_PyFunction_FastCallNoKw(co, args, nargs, globals); goto done; } else if (nargs == 0 && argdefs != NULL && co->co_argcount == Py_SIZE(argdefs)) { /* function called with no arguments, but all parameters have a default value: use default values as arguments .*/ args = &PyTuple_GET_ITEM(argdefs, 0); result =__Pyx_PyFunction_FastCallNoKw(co, args, Py_SIZE(argdefs), globals); goto done; } } if (kwargs != NULL) { Py_ssize_t pos, i; kwtuple = PyTuple_New(2 * nk); if (kwtuple == NULL) { result = NULL; goto done; } k = &PyTuple_GET_ITEM(kwtuple, 0); pos = i = 0; while (PyDict_Next(kwargs, &pos, &k[i], &k[i+1])) { Py_INCREF(k[i]); Py_INCREF(k[i+1]); i += 2; } nk = i / 2; } else { kwtuple = NULL; k = NULL; } closure = PyFunction_GET_CLOSURE(func); #if PY_MAJOR_VERSION >= 3 kwdefs = PyFunction_GET_KW_DEFAULTS(func); #endif if (argdefs != NULL) { d = &PyTuple_GET_ITEM(argdefs, 0); nd = Py_SIZE(argdefs); } else { d = NULL; nd = 0; } #if PY_MAJOR_VERSION >= 3 result = PyEval_EvalCodeEx((PyObject*)co, globals, (PyObject *)NULL, args, (int)nargs, k, (int)nk, d, (int)nd, kwdefs, closure); #else result = PyEval_EvalCodeEx(co, globals, (PyObject *)NULL, args, (int)nargs, k, (int)nk, d, (int)nd, closure); #endif Py_XDECREF(kwtuple); done: Py_LeaveRecursiveCall(); return result; } #endif #endif /* PyObjectCall2Args */ static CYTHON_UNUSED PyObject* __Pyx_PyObject_Call2Args(PyObject* function, PyObject* arg1, PyObject* arg2) { PyObject *args, *result = NULL; #if CYTHON_FAST_PYCALL if (PyFunction_Check(function)) { PyObject *args[2] = {arg1, arg2}; return __Pyx_PyFunction_FastCall(function, args, 2); } #endif #if CYTHON_FAST_PYCCALL if (__Pyx_PyFastCFunction_Check(function)) { PyObject *args[2] = {arg1, arg2}; return __Pyx_PyCFunction_FastCall(function, args, 2); } #endif args = PyTuple_New(2); if (unlikely(!args)) goto done; Py_INCREF(arg1); PyTuple_SET_ITEM(args, 0, arg1); Py_INCREF(arg2); PyTuple_SET_ITEM(args, 1, arg2); Py_INCREF(function); result = __Pyx_PyObject_Call(function, args, NULL); Py_DECREF(args); Py_DECREF(function); done: return result; } /* PyObjectCallMethO */ #if CYTHON_COMPILING_IN_CPYTHON static CYTHON_INLINE PyObject* __Pyx_PyObject_CallMethO(PyObject *func, PyObject *arg) { PyObject *self, *result; PyCFunction cfunc; cfunc = PyCFunction_GET_FUNCTION(func); self = PyCFunction_GET_SELF(func); if (unlikely(Py_EnterRecursiveCall((char*)" while calling a Python object"))) return NULL; result = cfunc(self, arg); Py_LeaveRecursiveCall(); if (unlikely(!result) && unlikely(!PyErr_Occurred())) { PyErr_SetString( PyExc_SystemError, "NULL result without error in PyObject_Call"); } return result; } #endif /* PyObjectCallOneArg */ #if CYTHON_COMPILING_IN_CPYTHON static PyObject* __Pyx__PyObject_CallOneArg(PyObject *func, PyObject *arg) { PyObject *result; PyObject *args = PyTuple_New(1); if (unlikely(!args)) return NULL; Py_INCREF(arg); PyTuple_SET_ITEM(args, 0, arg); result = __Pyx_PyObject_Call(func, args, NULL); Py_DECREF(args); return result; } static CYTHON_INLINE PyObject* __Pyx_PyObject_CallOneArg(PyObject *func, PyObject *arg) { #if CYTHON_FAST_PYCALL if (PyFunction_Check(func)) { return __Pyx_PyFunction_FastCall(func, &arg, 1); } #endif if (likely(PyCFunction_Check(func))) { if (likely(PyCFunction_GET_FLAGS(func) & METH_O)) { return __Pyx_PyObject_CallMethO(func, arg); #if CYTHON_FAST_PYCCALL } else if (__Pyx_PyFastCFunction_Check(func)) { return __Pyx_PyCFunction_FastCall(func, &arg, 1); #endif } } return __Pyx__PyObject_CallOneArg(func, arg); } #else static CYTHON_INLINE PyObject* __Pyx_PyObject_CallOneArg(PyObject *func, PyObject *arg) { PyObject *result; PyObject *args = PyTuple_Pack(1, arg); if (unlikely(!args)) return NULL; result = __Pyx_PyObject_Call(func, args, NULL); Py_DECREF(args); return result; } #endif /* BytesEquals */ static CYTHON_INLINE int __Pyx_PyBytes_Equals(PyObject* s1, PyObject* s2, int equals) { #if CYTHON_COMPILING_IN_PYPY return PyObject_RichCompareBool(s1, s2, equals); #else if (s1 == s2) { return (equals == Py_EQ); } else if (PyBytes_CheckExact(s1) & PyBytes_CheckExact(s2)) { const char *ps1, *ps2; Py_ssize_t length = PyBytes_GET_SIZE(s1); if (length != PyBytes_GET_SIZE(s2)) return (equals == Py_NE); ps1 = PyBytes_AS_STRING(s1); ps2 = PyBytes_AS_STRING(s2); if (ps1[0] != ps2[0]) { return (equals == Py_NE); } else if (length == 1) { return (equals == Py_EQ); } else { int result; #if CYTHON_USE_UNICODE_INTERNALS Py_hash_t hash1, hash2; hash1 = ((PyBytesObject*)s1)->ob_shash; hash2 = ((PyBytesObject*)s2)->ob_shash; if (hash1 != hash2 && hash1 != -1 && hash2 != -1) { return (equals == Py_NE); } #endif result = memcmp(ps1, ps2, (size_t)length); return (equals == Py_EQ) ? (result == 0) : (result != 0); } } else if ((s1 == Py_None) & PyBytes_CheckExact(s2)) { return (equals == Py_NE); } else if ((s2 == Py_None) & PyBytes_CheckExact(s1)) { return (equals == Py_NE); } else { int result; PyObject* py_result = PyObject_RichCompare(s1, s2, equals); if (!py_result) return -1; result = __Pyx_PyObject_IsTrue(py_result); Py_DECREF(py_result); return result; } #endif } /* UnicodeEquals */ static CYTHON_INLINE int __Pyx_PyUnicode_Equals(PyObject* s1, PyObject* s2, int equals) { #if CYTHON_COMPILING_IN_PYPY return PyObject_RichCompareBool(s1, s2, equals); #else #if PY_MAJOR_VERSION < 3 PyObject* owned_ref = NULL; #endif int s1_is_unicode, s2_is_unicode; if (s1 == s2) { goto return_eq; } s1_is_unicode = PyUnicode_CheckExact(s1); s2_is_unicode = PyUnicode_CheckExact(s2); #if PY_MAJOR_VERSION < 3 if ((s1_is_unicode & (!s2_is_unicode)) && PyString_CheckExact(s2)) { owned_ref = PyUnicode_FromObject(s2); if (unlikely(!owned_ref)) return -1; s2 = owned_ref; s2_is_unicode = 1; } else if ((s2_is_unicode & (!s1_is_unicode)) && PyString_CheckExact(s1)) { owned_ref = PyUnicode_FromObject(s1); if (unlikely(!owned_ref)) return -1; s1 = owned_ref; s1_is_unicode = 1; } else if (((!s2_is_unicode) & (!s1_is_unicode))) { return __Pyx_PyBytes_Equals(s1, s2, equals); } #endif if (s1_is_unicode & s2_is_unicode) { Py_ssize_t length; int kind; void *data1, *data2; if (unlikely(__Pyx_PyUnicode_READY(s1) < 0) || unlikely(__Pyx_PyUnicode_READY(s2) < 0)) return -1; length = __Pyx_PyUnicode_GET_LENGTH(s1); if (length != __Pyx_PyUnicode_GET_LENGTH(s2)) { goto return_ne; } #if CYTHON_USE_UNICODE_INTERNALS { Py_hash_t hash1, hash2; #if CYTHON_PEP393_ENABLED hash1 = ((PyASCIIObject*)s1)->hash; hash2 = ((PyASCIIObject*)s2)->hash; #else hash1 = ((PyUnicodeObject*)s1)->hash; hash2 = ((PyUnicodeObject*)s2)->hash; #endif if (hash1 != hash2 && hash1 != -1 && hash2 != -1) { goto return_ne; } } #endif kind = __Pyx_PyUnicode_KIND(s1); if (kind != __Pyx_PyUnicode_KIND(s2)) { goto return_ne; } data1 = __Pyx_PyUnicode_DATA(s1); data2 = __Pyx_PyUnicode_DATA(s2); if (__Pyx_PyUnicode_READ(kind, data1, 0) != __Pyx_PyUnicode_READ(kind, data2, 0)) { goto return_ne; } else if (length == 1) { goto return_eq; } else { int result = memcmp(data1, data2, (size_t)(length * kind)); #if PY_MAJOR_VERSION < 3 Py_XDECREF(owned_ref); #endif return (equals == Py_EQ) ? (result == 0) : (result != 0); } } else if ((s1 == Py_None) & s2_is_unicode) { goto return_ne; } else if ((s2 == Py_None) & s1_is_unicode) { goto return_ne; } else { int result; PyObject* py_result = PyObject_RichCompare(s1, s2, equals); #if PY_MAJOR_VERSION < 3 Py_XDECREF(owned_ref); #endif if (!py_result) return -1; result = __Pyx_PyObject_IsTrue(py_result); Py_DECREF(py_result); return result; } return_eq: #if PY_MAJOR_VERSION < 3 Py_XDECREF(owned_ref); #endif return (equals == Py_EQ); return_ne: #if PY_MAJOR_VERSION < 3 Py_XDECREF(owned_ref); #endif return (equals == Py_NE); #endif } /* None */ static CYTHON_INLINE Py_ssize_t __Pyx_div_Py_ssize_t(Py_ssize_t a, Py_ssize_t b) { Py_ssize_t q = a / b; Py_ssize_t r = a - q*b; q -= ((r != 0) & ((r ^ b) < 0)); return q; } /* GetAttr */ static CYTHON_INLINE PyObject *__Pyx_GetAttr(PyObject *o, PyObject *n) { #if CYTHON_USE_TYPE_SLOTS #if PY_MAJOR_VERSION >= 3 if (likely(PyUnicode_Check(n))) #else if (likely(PyString_Check(n))) #endif return __Pyx_PyObject_GetAttrStr(o, n); #endif return PyObject_GetAttr(o, n); } /* GetItemInt */ static PyObject *__Pyx_GetItemInt_Generic(PyObject *o, PyObject* j) { PyObject *r; if (!j) return NULL; r = PyObject_GetItem(o, j); Py_DECREF(j); return r; } static CYTHON_INLINE PyObject *__Pyx_GetItemInt_List_Fast(PyObject *o, Py_ssize_t i, CYTHON_NCP_UNUSED int wraparound, CYTHON_NCP_UNUSED int boundscheck) { #if CYTHON_ASSUME_SAFE_MACROS && !CYTHON_AVOID_BORROWED_REFS Py_ssize_t wrapped_i = i; if (wraparound & unlikely(i < 0)) { wrapped_i += PyList_GET_SIZE(o); } if ((!boundscheck) || likely(__Pyx_is_valid_index(wrapped_i, PyList_GET_SIZE(o)))) { PyObject *r = PyList_GET_ITEM(o, wrapped_i); Py_INCREF(r); return r; } return __Pyx_GetItemInt_Generic(o, PyInt_FromSsize_t(i)); #else return PySequence_GetItem(o, i); #endif } static CYTHON_INLINE PyObject *__Pyx_GetItemInt_Tuple_Fast(PyObject *o, Py_ssize_t i, CYTHON_NCP_UNUSED int wraparound, CYTHON_NCP_UNUSED int boundscheck) { #if CYTHON_ASSUME_SAFE_MACROS && !CYTHON_AVOID_BORROWED_REFS Py_ssize_t wrapped_i = i; if (wraparound & unlikely(i < 0)) { wrapped_i += PyTuple_GET_SIZE(o); } if ((!boundscheck) || likely(__Pyx_is_valid_index(wrapped_i, PyTuple_GET_SIZE(o)))) { PyObject *r = PyTuple_GET_ITEM(o, wrapped_i); Py_INCREF(r); return r; } return __Pyx_GetItemInt_Generic(o, PyInt_FromSsize_t(i)); #else return PySequence_GetItem(o, i); #endif } static CYTHON_INLINE PyObject *__Pyx_GetItemInt_Fast(PyObject *o, Py_ssize_t i, int is_list, CYTHON_NCP_UNUSED int wraparound, CYTHON_NCP_UNUSED int boundscheck) { #if CYTHON_ASSUME_SAFE_MACROS && !CYTHON_AVOID_BORROWED_REFS && CYTHON_USE_TYPE_SLOTS if (is_list || PyList_CheckExact(o)) { Py_ssize_t n = ((!wraparound) | likely(i >= 0)) ? i : i + PyList_GET_SIZE(o); if ((!boundscheck) || (likely(__Pyx_is_valid_index(n, PyList_GET_SIZE(o))))) { PyObject *r = PyList_GET_ITEM(o, n); Py_INCREF(r); return r; } } else if (PyTuple_CheckExact(o)) { Py_ssize_t n = ((!wraparound) | likely(i >= 0)) ? i : i + PyTuple_GET_SIZE(o); if ((!boundscheck) || likely(__Pyx_is_valid_index(n, PyTuple_GET_SIZE(o)))) { PyObject *r = PyTuple_GET_ITEM(o, n); Py_INCREF(r); return r; } } else { PySequenceMethods *m = Py_TYPE(o)->tp_as_sequence; if (likely(m && m->sq_item)) { if (wraparound && unlikely(i < 0) && likely(m->sq_length)) { Py_ssize_t l = m->sq_length(o); if (likely(l >= 0)) { i += l; } else { if (!PyErr_ExceptionMatches(PyExc_OverflowError)) return NULL; PyErr_Clear(); } } return m->sq_item(o, i); } } #else if (is_list || PySequence_Check(o)) { return PySequence_GetItem(o, i); } #endif return __Pyx_GetItemInt_Generic(o, PyInt_FromSsize_t(i)); } /* ObjectGetItem */ #if CYTHON_USE_TYPE_SLOTS static PyObject *__Pyx_PyObject_GetIndex(PyObject *obj, PyObject* index) { PyObject *runerr; Py_ssize_t key_value; PySequenceMethods *m = Py_TYPE(obj)->tp_as_sequence; if (unlikely(!(m && m->sq_item))) { PyErr_Format(PyExc_TypeError, "'%.200s' object is not subscriptable", Py_TYPE(obj)->tp_name); return NULL; } key_value = __Pyx_PyIndex_AsSsize_t(index); if (likely(key_value != -1 || !(runerr = PyErr_Occurred()))) { return __Pyx_GetItemInt_Fast(obj, key_value, 0, 1, 1); } if (PyErr_GivenExceptionMatches(runerr, PyExc_OverflowError)) { PyErr_Clear(); PyErr_Format(PyExc_IndexError, "cannot fit '%.200s' into an index-sized integer", Py_TYPE(index)->tp_name); } return NULL; } static PyObject *__Pyx_PyObject_GetItem(PyObject *obj, PyObject* key) { PyMappingMethods *m = Py_TYPE(obj)->tp_as_mapping; if (likely(m && m->mp_subscript)) { return m->mp_subscript(obj, key); } return __Pyx_PyObject_GetIndex(obj, key); } #endif /* decode_c_string */ static CYTHON_INLINE PyObject* __Pyx_decode_c_string( const char* cstring, Py_ssize_t start, Py_ssize_t stop, const char* encoding, const char* errors, PyObject* (*decode_func)(const char *s, Py_ssize_t size, const char *errors)) { Py_ssize_t length; if (unlikely((start < 0) | (stop < 0))) { size_t slen = strlen(cstring); if (unlikely(slen > (size_t) PY_SSIZE_T_MAX)) { PyErr_SetString(PyExc_OverflowError, "c-string too long to convert to Python"); return NULL; } length = (Py_ssize_t) slen; if (start < 0) { start += length; if (start < 0) start = 0; } if (stop < 0) stop += length; } if (unlikely(stop <= start)) return __Pyx_NewRef(__pyx_empty_unicode); length = stop - start; cstring += start; if (decode_func) { return decode_func(cstring, length, errors); } else { return PyUnicode_Decode(cstring, length, encoding, errors); } } /* PyErrExceptionMatches */ #if CYTHON_FAST_THREAD_STATE static int __Pyx_PyErr_ExceptionMatchesTuple(PyObject *exc_type, PyObject *tuple) { Py_ssize_t i, n; n = PyTuple_GET_SIZE(tuple); #if PY_MAJOR_VERSION >= 3 for (i=0; i<n; i++) { if (exc_type == PyTuple_GET_ITEM(tuple, i)) return 1; } #endif for (i=0; i<n; i++) { if (__Pyx_PyErr_GivenExceptionMatches(exc_type, PyTuple_GET_ITEM(tuple, i))) return 1; } return 0; } static CYTHON_INLINE int __Pyx_PyErr_ExceptionMatchesInState(PyThreadState* tstate, PyObject* err) { PyObject *exc_type = tstate->curexc_type; if (exc_type == err) return 1; if (unlikely(!exc_type)) return 0; if (unlikely(PyTuple_Check(err))) return __Pyx_PyErr_ExceptionMatchesTuple(exc_type, err); return __Pyx_PyErr_GivenExceptionMatches(exc_type, err); } #endif /* GetAttr3 */ static PyObject *__Pyx_GetAttr3Default(PyObject *d) { __Pyx_PyThreadState_declare __Pyx_PyThreadState_assign if (unlikely(!__Pyx_PyErr_ExceptionMatches(PyExc_AttributeError))) return NULL; __Pyx_PyErr_Clear(); Py_INCREF(d); return d; } static CYTHON_INLINE PyObject *__Pyx_GetAttr3(PyObject *o, PyObject *n, PyObject *d) { PyObject *r = __Pyx_GetAttr(o, n); return (likely(r)) ? r : __Pyx_GetAttr3Default(d); } /* PyDictVersioning */ #if CYTHON_USE_DICT_VERSIONS && CYTHON_USE_TYPE_SLOTS static CYTHON_INLINE PY_UINT64_T __Pyx_get_tp_dict_version(PyObject *obj) { PyObject *dict = Py_TYPE(obj)->tp_dict; return likely(dict) ? __PYX_GET_DICT_VERSION(dict) : 0; } static CYTHON_INLINE PY_UINT64_T __Pyx_get_object_dict_version(PyObject *obj) { PyObject **dictptr = NULL; Py_ssize_t offset = Py_TYPE(obj)->tp_dictoffset; if (offset) { #if CYTHON_COMPILING_IN_CPYTHON dictptr = (likely(offset > 0)) ? (PyObject **) ((char *)obj + offset) : _PyObject_GetDictPtr(obj); #else dictptr = _PyObject_GetDictPtr(obj); #endif } return (dictptr && *dictptr) ? __PYX_GET_DICT_VERSION(*dictptr) : 0; } static CYTHON_INLINE int __Pyx_object_dict_version_matches(PyObject* obj, PY_UINT64_T tp_dict_version, PY_UINT64_T obj_dict_version) { PyObject *dict = Py_TYPE(obj)->tp_dict; if (unlikely(!dict) || unlikely(tp_dict_version != __PYX_GET_DICT_VERSION(dict))) return 0; return obj_dict_version == __Pyx_get_object_dict_version(obj); } #endif /* GetModuleGlobalName */ #if CYTHON_USE_DICT_VERSIONS static PyObject *__Pyx__GetModuleGlobalName(PyObject *name, PY_UINT64_T *dict_version, PyObject **dict_cached_value) #else static CYTHON_INLINE PyObject *__Pyx__GetModuleGlobalName(PyObject *name) #endif { PyObject *result; #if !CYTHON_AVOID_BORROWED_REFS #if CYTHON_COMPILING_IN_CPYTHON && PY_VERSION_HEX >= 0x030500A1 result = _PyDict_GetItem_KnownHash(__pyx_d, name, ((PyASCIIObject *) name)->hash); __PYX_UPDATE_DICT_CACHE(__pyx_d, result, *dict_cached_value, *dict_version) if (likely(result)) { return __Pyx_NewRef(result); } else if (unlikely(PyErr_Occurred())) { return NULL; } #else result = PyDict_GetItem(__pyx_d, name); __PYX_UPDATE_DICT_CACHE(__pyx_d, result, *dict_cached_value, *dict_version) if (likely(result)) { return __Pyx_NewRef(result); } #endif #else result = PyObject_GetItem(__pyx_d, name); __PYX_UPDATE_DICT_CACHE(__pyx_d, result, *dict_cached_value, *dict_version) if (likely(result)) { return __Pyx_NewRef(result); } PyErr_Clear(); #endif return __Pyx_GetBuiltinName(name); } /* RaiseTooManyValuesToUnpack */ static CYTHON_INLINE void __Pyx_RaiseTooManyValuesError(Py_ssize_t expected) { PyErr_Format(PyExc_ValueError, "too many values to unpack (expected %" CYTHON_FORMAT_SSIZE_T "d)", expected); } /* RaiseNeedMoreValuesToUnpack */ static CYTHON_INLINE void __Pyx_RaiseNeedMoreValuesError(Py_ssize_t index) { PyErr_Format(PyExc_ValueError, "need more than %" CYTHON_FORMAT_SSIZE_T "d value%.1s to unpack", index, (index == 1) ? "" : "s"); } /* RaiseNoneIterError */ static CYTHON_INLINE void __Pyx_RaiseNoneNotIterableError(void) { PyErr_SetString(PyExc_TypeError, "'NoneType' object is not iterable"); } /* ExtTypeTest */ static CYTHON_INLINE int __Pyx_TypeTest(PyObject *obj, PyTypeObject *type) { if (unlikely(!type)) { PyErr_SetString(PyExc_SystemError, "Missing type object"); return 0; } if (likely(__Pyx_TypeCheck(obj, type))) return 1; PyErr_Format(PyExc_TypeError, "Cannot convert %.200s to %.200s", Py_TYPE(obj)->tp_name, type->tp_name); return 0; } /* GetTopmostException */ #if CYTHON_USE_EXC_INFO_STACK static _PyErr_StackItem * __Pyx_PyErr_GetTopmostException(PyThreadState *tstate) { _PyErr_StackItem *exc_info = tstate->exc_info; while ((exc_info->exc_type == NULL || exc_info->exc_type == Py_None) && exc_info->previous_item != NULL) { exc_info = exc_info->previous_item; } return exc_info; } #endif /* SaveResetException */ #if CYTHON_FAST_THREAD_STATE static CYTHON_INLINE void __Pyx__ExceptionSave(PyThreadState *tstate, PyObject **type, PyObject **value, PyObject **tb) { #if CYTHON_USE_EXC_INFO_STACK _PyErr_StackItem *exc_info = __Pyx_PyErr_GetTopmostException(tstate); *type = exc_info->exc_type; *value = exc_info->exc_value; *tb = exc_info->exc_traceback; #else *type = tstate->exc_type; *value = tstate->exc_value; *tb = tstate->exc_traceback; #endif Py_XINCREF(*type); Py_XINCREF(*value); Py_XINCREF(*tb); } static CYTHON_INLINE void __Pyx__ExceptionReset(PyThreadState *tstate, PyObject *type, PyObject *value, PyObject *tb) { PyObject *tmp_type, *tmp_value, *tmp_tb; #if CYTHON_USE_EXC_INFO_STACK _PyErr_StackItem *exc_info = tstate->exc_info; tmp_type = exc_info->exc_type; tmp_value = exc_info->exc_value; tmp_tb = exc_info->exc_traceback; exc_info->exc_type = type; exc_info->exc_value = value; exc_info->exc_traceback = tb; #else tmp_type = tstate->exc_type; tmp_value = tstate->exc_value; tmp_tb = tstate->exc_traceback; tstate->exc_type = type; tstate->exc_value = value; tstate->exc_traceback = tb; #endif Py_XDECREF(tmp_type); Py_XDECREF(tmp_value); Py_XDECREF(tmp_tb); } #endif /* GetException */ #if CYTHON_FAST_THREAD_STATE static int __Pyx__GetException(PyThreadState *tstate, PyObject **type, PyObject **value, PyObject **tb) #else static int __Pyx_GetException(PyObject **type, PyObject **value, PyObject **tb) #endif { PyObject *local_type, *local_value, *local_tb; #if CYTHON_FAST_THREAD_STATE PyObject *tmp_type, *tmp_value, *tmp_tb; local_type = tstate->curexc_type; local_value = tstate->curexc_value; local_tb = tstate->curexc_traceback; tstate->curexc_type = 0; tstate->curexc_value = 0; tstate->curexc_traceback = 0; #else PyErr_Fetch(&local_type, &local_value, &local_tb); #endif PyErr_NormalizeException(&local_type, &local_value, &local_tb); #if CYTHON_FAST_THREAD_STATE if (unlikely(tstate->curexc_type)) #else if (unlikely(PyErr_Occurred())) #endif goto bad; #if PY_MAJOR_VERSION >= 3 if (local_tb) { if (unlikely(PyException_SetTraceback(local_value, local_tb) < 0)) goto bad; } #endif Py_XINCREF(local_tb); Py_XINCREF(local_type); Py_XINCREF(local_value); *type = local_type; *value = local_value; *tb = local_tb; #if CYTHON_FAST_THREAD_STATE #if CYTHON_USE_EXC_INFO_STACK { _PyErr_StackItem *exc_info = tstate->exc_info; tmp_type = exc_info->exc_type; tmp_value = exc_info->exc_value; tmp_tb = exc_info->exc_traceback; exc_info->exc_type = local_type; exc_info->exc_value = local_value; exc_info->exc_traceback = local_tb; } #else tmp_type = tstate->exc_type; tmp_value = tstate->exc_value; tmp_tb = tstate->exc_traceback; tstate->exc_type = local_type; tstate->exc_value = local_value; tstate->exc_traceback = local_tb; #endif Py_XDECREF(tmp_type); Py_XDECREF(tmp_value); Py_XDECREF(tmp_tb); #else PyErr_SetExcInfo(local_type, local_value, local_tb); #endif return 0; bad: *type = 0; *value = 0; *tb = 0; Py_XDECREF(local_type); Py_XDECREF(local_value); Py_XDECREF(local_tb); return -1; } /* SwapException */ #if CYTHON_FAST_THREAD_STATE static CYTHON_INLINE void __Pyx__ExceptionSwap(PyThreadState *tstate, PyObject **type, PyObject **value, PyObject **tb) { PyObject *tmp_type, *tmp_value, *tmp_tb; #if CYTHON_USE_EXC_INFO_STACK _PyErr_StackItem *exc_info = tstate->exc_info; tmp_type = exc_info->exc_type; tmp_value = exc_info->exc_value; tmp_tb = exc_info->exc_traceback; exc_info->exc_type = *type; exc_info->exc_value = *value; exc_info->exc_traceback = *tb; #else tmp_type = tstate->exc_type; tmp_value = tstate->exc_value; tmp_tb = tstate->exc_traceback; tstate->exc_type = *type; tstate->exc_value = *value; tstate->exc_traceback = *tb; #endif *type = tmp_type; *value = tmp_value; *tb = tmp_tb; } #else static CYTHON_INLINE void __Pyx_ExceptionSwap(PyObject **type, PyObject **value, PyObject **tb) { PyObject *tmp_type, *tmp_value, *tmp_tb; PyErr_GetExcInfo(&tmp_type, &tmp_value, &tmp_tb); PyErr_SetExcInfo(*type, *value, *tb); *type = tmp_type; *value = tmp_value; *tb = tmp_tb; } #endif /* Import */ static PyObject *__Pyx_Import(PyObject *name, PyObject *from_list, int level) { PyObject *empty_list = 0; PyObject *module = 0; PyObject *global_dict = 0; PyObject *empty_dict = 0; PyObject *list; #if PY_MAJOR_VERSION < 3 PyObject *py_import; py_import = __Pyx_PyObject_GetAttrStr(__pyx_b, __pyx_n_s_import); if (!py_import) goto bad; #endif if (from_list) list = from_list; else { empty_list = PyList_New(0); if (!empty_list) goto bad; list = empty_list; } global_dict = PyModule_GetDict(__pyx_m); if (!global_dict) goto bad; empty_dict = PyDict_New(); if (!empty_dict) goto bad; { #if PY_MAJOR_VERSION >= 3 if (level == -1) { if ((1) && (strchr(__Pyx_MODULE_NAME, '.'))) { module = PyImport_ImportModuleLevelObject( name, global_dict, empty_dict, list, 1); if (!module) { if (!PyErr_ExceptionMatches(PyExc_ImportError)) goto bad; PyErr_Clear(); } } level = 0; } #endif if (!module) { #if PY_MAJOR_VERSION < 3 PyObject *py_level = PyInt_FromLong(level); if (!py_level) goto bad; module = PyObject_CallFunctionObjArgs(py_import, name, global_dict, empty_dict, list, py_level, (PyObject *)NULL); Py_DECREF(py_level); #else module = PyImport_ImportModuleLevelObject( name, global_dict, empty_dict, list, level); #endif } } bad: #if PY_MAJOR_VERSION < 3 Py_XDECREF(py_import); #endif Py_XDECREF(empty_list); Py_XDECREF(empty_dict); return module; } /* FastTypeChecks */ #if CYTHON_COMPILING_IN_CPYTHON static int __Pyx_InBases(PyTypeObject *a, PyTypeObject *b) { while (a) { a = a->tp_base; if (a == b) return 1; } return b == &PyBaseObject_Type; } static CYTHON_INLINE int __Pyx_IsSubtype(PyTypeObject *a, PyTypeObject *b) { PyObject *mro; if (a == b) return 1; mro = a->tp_mro; if (likely(mro)) { Py_ssize_t i, n; n = PyTuple_GET_SIZE(mro); for (i = 0; i < n; i++) { if (PyTuple_GET_ITEM(mro, i) == (PyObject *)b) return 1; } return 0; } return __Pyx_InBases(a, b); } #if PY_MAJOR_VERSION == 2 static int __Pyx_inner_PyErr_GivenExceptionMatches2(PyObject *err, PyObject* exc_type1, PyObject* exc_type2) { PyObject *exception, *value, *tb; int res; __Pyx_PyThreadState_declare __Pyx_PyThreadState_assign __Pyx_ErrFetch(&exception, &value, &tb); res = exc_type1 ? PyObject_IsSubclass(err, exc_type1) : 0; if (unlikely(res == -1)) { PyErr_WriteUnraisable(err); res = 0; } if (!res) { res = PyObject_IsSubclass(err, exc_type2); if (unlikely(res == -1)) { PyErr_WriteUnraisable(err); res = 0; } } __Pyx_ErrRestore(exception, value, tb); return res; } #else static CYTHON_INLINE int __Pyx_inner_PyErr_GivenExceptionMatches2(PyObject *err, PyObject* exc_type1, PyObject *exc_type2) { int res = exc_type1 ? __Pyx_IsSubtype((PyTypeObject*)err, (PyTypeObject*)exc_type1) : 0; if (!res) { res = __Pyx_IsSubtype((PyTypeObject*)err, (PyTypeObject*)exc_type2); } return res; } #endif static int __Pyx_PyErr_GivenExceptionMatchesTuple(PyObject *exc_type, PyObject *tuple) { Py_ssize_t i, n; assert(PyExceptionClass_Check(exc_type)); n = PyTuple_GET_SIZE(tuple); #if PY_MAJOR_VERSION >= 3 for (i=0; i<n; i++) { if (exc_type == PyTuple_GET_ITEM(tuple, i)) return 1; } #endif for (i=0; i<n; i++) { PyObject *t = PyTuple_GET_ITEM(tuple, i); #if PY_MAJOR_VERSION < 3 if (likely(exc_type == t)) return 1; #endif if (likely(PyExceptionClass_Check(t))) { if (__Pyx_inner_PyErr_GivenExceptionMatches2(exc_type, NULL, t)) return 1; } else { } } return 0; } static CYTHON_INLINE int __Pyx_PyErr_GivenExceptionMatches(PyObject *err, PyObject* exc_type) { if (likely(err == exc_type)) return 1; if (likely(PyExceptionClass_Check(err))) { if (likely(PyExceptionClass_Check(exc_type))) { return __Pyx_inner_PyErr_GivenExceptionMatches2(err, NULL, exc_type); } else if (likely(PyTuple_Check(exc_type))) { return __Pyx_PyErr_GivenExceptionMatchesTuple(err, exc_type); } else { } } return PyErr_GivenExceptionMatches(err, exc_type); } static CYTHON_INLINE int __Pyx_PyErr_GivenExceptionMatches2(PyObject *err, PyObject *exc_type1, PyObject *exc_type2) { assert(PyExceptionClass_Check(exc_type1)); assert(PyExceptionClass_Check(exc_type2)); if (likely(err == exc_type1 || err == exc_type2)) return 1; if (likely(PyExceptionClass_Check(err))) { return __Pyx_inner_PyErr_GivenExceptionMatches2(err, exc_type1, exc_type2); } return (PyErr_GivenExceptionMatches(err, exc_type1) || PyErr_GivenExceptionMatches(err, exc_type2)); } #endif /* PyIntBinop */ #if !CYTHON_COMPILING_IN_PYPY static PyObject* __Pyx_PyInt_AddObjC(PyObject *op1, PyObject *op2, CYTHON_UNUSED long intval, int inplace, int zerodivision_check) { (void)inplace; (void)zerodivision_check; #if PY_MAJOR_VERSION < 3 if (likely(PyInt_CheckExact(op1))) { const long b = intval; long x; long a = PyInt_AS_LONG(op1); x = (long)((unsigned long)a + b); if (likely((x^a) >= 0 || (x^b) >= 0)) return PyInt_FromLong(x); return PyLong_Type.tp_as_number->nb_add(op1, op2); } #endif #if CYTHON_USE_PYLONG_INTERNALS if (likely(PyLong_CheckExact(op1))) { const long b = intval; long a, x; #ifdef HAVE_LONG_LONG const PY_LONG_LONG llb = intval; PY_LONG_LONG lla, llx; #endif const digit* digits = ((PyLongObject*)op1)->ob_digit; const Py_ssize_t size = Py_SIZE(op1); if (likely(__Pyx_sst_abs(size) <= 1)) { a = likely(size) ? digits[0] : 0; if (size == -1) a = -a; } else { switch (size) { case -2: if (8 * sizeof(long) - 1 > 2 * PyLong_SHIFT) { a = -(long) (((((unsigned long)digits[1]) << PyLong_SHIFT) | (unsigned long)digits[0])); break; #ifdef HAVE_LONG_LONG } else if (8 * sizeof(PY_LONG_LONG) - 1 > 2 * PyLong_SHIFT) { lla = -(PY_LONG_LONG) (((((unsigned PY_LONG_LONG)digits[1]) << PyLong_SHIFT) | (unsigned PY_LONG_LONG)digits[0])); goto long_long; #endif } CYTHON_FALLTHROUGH; case 2: if (8 * sizeof(long) - 1 > 2 * PyLong_SHIFT) { a = (long) (((((unsigned long)digits[1]) << PyLong_SHIFT) | (unsigned long)digits[0])); break; #ifdef HAVE_LONG_LONG } else if (8 * sizeof(PY_LONG_LONG) - 1 > 2 * PyLong_SHIFT) { lla = (PY_LONG_LONG) (((((unsigned PY_LONG_LONG)digits[1]) << PyLong_SHIFT) | (unsigned PY_LONG_LONG)digits[0])); goto long_long; #endif } CYTHON_FALLTHROUGH; case -3: if (8 * sizeof(long) - 1 > 3 * PyLong_SHIFT) { a = -(long) (((((((unsigned long)digits[2]) << PyLong_SHIFT) | (unsigned long)digits[1]) << PyLong_SHIFT) | (unsigned long)digits[0])); break; #ifdef HAVE_LONG_LONG } else if (8 * sizeof(PY_LONG_LONG) - 1 > 3 * PyLong_SHIFT) { lla = -(PY_LONG_LONG) (((((((unsigned PY_LONG_LONG)digits[2]) << PyLong_SHIFT) | (unsigned PY_LONG_LONG)digits[1]) << PyLong_SHIFT) | (unsigned PY_LONG_LONG)digits[0])); goto long_long; #endif } CYTHON_FALLTHROUGH; case 3: if (8 * sizeof(long) - 1 > 3 * PyLong_SHIFT) { a = (long) (((((((unsigned long)digits[2]) << PyLong_SHIFT) | (unsigned long)digits[1]) << PyLong_SHIFT) | (unsigned long)digits[0])); break; #ifdef HAVE_LONG_LONG } else if (8 * sizeof(PY_LONG_LONG) - 1 > 3 * PyLong_SHIFT) { lla = (PY_LONG_LONG) (((((((unsigned PY_LONG_LONG)digits[2]) << PyLong_SHIFT) | (unsigned PY_LONG_LONG)digits[1]) << PyLong_SHIFT) | (unsigned PY_LONG_LONG)digits[0])); goto long_long; #endif } CYTHON_FALLTHROUGH; case -4: if (8 * sizeof(long) - 1 > 4 * PyLong_SHIFT) { a = -(long) (((((((((unsigned long)digits[3]) << PyLong_SHIFT) | (unsigned long)digits[2]) << PyLong_SHIFT) | (unsigned long)digits[1]) << PyLong_SHIFT) | (unsigned long)digits[0])); break; #ifdef HAVE_LONG_LONG } else if (8 * sizeof(PY_LONG_LONG) - 1 > 4 * PyLong_SHIFT) { lla = -(PY_LONG_LONG) (((((((((unsigned PY_LONG_LONG)digits[3]) << PyLong_SHIFT) | (unsigned PY_LONG_LONG)digits[2]) << PyLong_SHIFT) | (unsigned PY_LONG_LONG)digits[1]) << PyLong_SHIFT) | (unsigned PY_LONG_LONG)digits[0])); goto long_long; #endif } CYTHON_FALLTHROUGH; case 4: if (8 * sizeof(long) - 1 > 4 * PyLong_SHIFT) { a = (long) (((((((((unsigned long)digits[3]) << PyLong_SHIFT) | (unsigned long)digits[2]) << PyLong_SHIFT) | (unsigned long)digits[1]) << PyLong_SHIFT) | (unsigned long)digits[0])); break; #ifdef HAVE_LONG_LONG } else if (8 * sizeof(PY_LONG_LONG) - 1 > 4 * PyLong_SHIFT) { lla = (PY_LONG_LONG) (((((((((unsigned PY_LONG_LONG)digits[3]) << PyLong_SHIFT) | (unsigned PY_LONG_LONG)digits[2]) << PyLong_SHIFT) | (unsigned PY_LONG_LONG)digits[1]) << PyLong_SHIFT) | (unsigned PY_LONG_LONG)digits[0])); goto long_long; #endif } CYTHON_FALLTHROUGH; default: return PyLong_Type.tp_as_number->nb_add(op1, op2); } } x = a + b; return PyLong_FromLong(x); #ifdef HAVE_LONG_LONG long_long: llx = lla + llb; return PyLong_FromLongLong(llx); #endif } #endif if (PyFloat_CheckExact(op1)) { const long b = intval; double a = PyFloat_AS_DOUBLE(op1); double result; PyFPE_START_PROTECT("add", return NULL) result = ((double)a) + (double)b; PyFPE_END_PROTECT(result) return PyFloat_FromDouble(result); } return (inplace ? PyNumber_InPlaceAdd : PyNumber_Add)(op1, op2); } #endif /* None */ static CYTHON_INLINE void __Pyx_RaiseUnboundLocalError(const char *varname) { PyErr_Format(PyExc_UnboundLocalError, "local variable '%s' referenced before assignment", varname); } /* None */ static CYTHON_INLINE long __Pyx_div_long(long a, long b) { long q = a / b; long r = a - q*b; q -= ((r != 0) & ((r ^ b) < 0)); return q; } /* ImportFrom */ static PyObject* __Pyx_ImportFrom(PyObject* module, PyObject* name) { PyObject* value = __Pyx_PyObject_GetAttrStr(module, name); if (unlikely(!value) && PyErr_ExceptionMatches(PyExc_AttributeError)) { PyErr_Format(PyExc_ImportError, #if PY_MAJOR_VERSION < 3 "cannot import name %.230s", PyString_AS_STRING(name)); #else "cannot import name %S", name); #endif } return value; } /* HasAttr */ static CYTHON_INLINE int __Pyx_HasAttr(PyObject *o, PyObject *n) { PyObject *r; if (unlikely(!__Pyx_PyBaseString_Check(n))) { PyErr_SetString(PyExc_TypeError, "hasattr(): attribute name must be string"); return -1; } r = __Pyx_GetAttr(o, n); if (unlikely(!r)) { PyErr_Clear(); return 0; } else { Py_DECREF(r); return 1; } } /* PyObject_GenericGetAttrNoDict */ #if CYTHON_USE_TYPE_SLOTS && CYTHON_USE_PYTYPE_LOOKUP && PY_VERSION_HEX < 0x03070000 static PyObject *__Pyx_RaiseGenericGetAttributeError(PyTypeObject *tp, PyObject *attr_name) { PyErr_Format(PyExc_AttributeError, #if PY_MAJOR_VERSION >= 3 "'%.50s' object has no attribute '%U'", tp->tp_name, attr_name); #else "'%.50s' object has no attribute '%.400s'", tp->tp_name, PyString_AS_STRING(attr_name)); #endif return NULL; } static CYTHON_INLINE PyObject* __Pyx_PyObject_GenericGetAttrNoDict(PyObject* obj, PyObject* attr_name) { PyObject *descr; PyTypeObject *tp = Py_TYPE(obj); if (unlikely(!PyString_Check(attr_name))) { return PyObject_GenericGetAttr(obj, attr_name); } assert(!tp->tp_dictoffset); descr = _PyType_Lookup(tp, attr_name); if (unlikely(!descr)) { return __Pyx_RaiseGenericGetAttributeError(tp, attr_name); } Py_INCREF(descr); #if PY_MAJOR_VERSION < 3 if (likely(PyType_HasFeature(Py_TYPE(descr), Py_TPFLAGS_HAVE_CLASS))) #endif { descrgetfunc f = Py_TYPE(descr)->tp_descr_get; if (unlikely(f)) { PyObject *res = f(descr, obj, (PyObject *)tp); Py_DECREF(descr); return res; } } return descr; } #endif /* PyObject_GenericGetAttr */ #if CYTHON_USE_TYPE_SLOTS && CYTHON_USE_PYTYPE_LOOKUP && PY_VERSION_HEX < 0x03070000 static PyObject* __Pyx_PyObject_GenericGetAttr(PyObject* obj, PyObject* attr_name) { if (unlikely(Py_TYPE(obj)->tp_dictoffset)) { return PyObject_GenericGetAttr(obj, attr_name); } return __Pyx_PyObject_GenericGetAttrNoDict(obj, attr_name); } #endif /* SetVTable */ static int __Pyx_SetVtable(PyObject *dict, void *vtable) { #if PY_VERSION_HEX >= 0x02070000 PyObject *ob = PyCapsule_New(vtable, 0, 0); #else PyObject *ob = PyCObject_FromVoidPtr(vtable, 0); #endif if (!ob) goto bad; if (PyDict_SetItem(dict, __pyx_n_s_pyx_vtable, ob) < 0) goto bad; Py_DECREF(ob); return 0; bad: Py_XDECREF(ob); return -1; } /* PyObjectGetAttrStrNoError */ static void __Pyx_PyObject_GetAttrStr_ClearAttributeError(void) { __Pyx_PyThreadState_declare __Pyx_PyThreadState_assign if (likely(__Pyx_PyErr_ExceptionMatches(PyExc_AttributeError))) __Pyx_PyErr_Clear(); } static CYTHON_INLINE PyObject* __Pyx_PyObject_GetAttrStrNoError(PyObject* obj, PyObject* attr_name) { PyObject *result; #if CYTHON_COMPILING_IN_CPYTHON && CYTHON_USE_TYPE_SLOTS && PY_VERSION_HEX >= 0x030700B1 PyTypeObject* tp = Py_TYPE(obj); if (likely(tp->tp_getattro == PyObject_GenericGetAttr)) { return _PyObject_GenericGetAttrWithDict(obj, attr_name, NULL, 1); } #endif result = __Pyx_PyObject_GetAttrStr(obj, attr_name); if (unlikely(!result)) { __Pyx_PyObject_GetAttrStr_ClearAttributeError(); } return result; } /* SetupReduce */ static int __Pyx_setup_reduce_is_named(PyObject* meth, PyObject* name) { int ret; PyObject *name_attr; name_attr = __Pyx_PyObject_GetAttrStr(meth, __pyx_n_s_name_2); if (likely(name_attr)) { ret = PyObject_RichCompareBool(name_attr, name, Py_EQ); } else { ret = -1; } if (unlikely(ret < 0)) { PyErr_Clear(); ret = 0; } Py_XDECREF(name_attr); return ret; } static int __Pyx_setup_reduce(PyObject* type_obj) { int ret = 0; PyObject *object_reduce = NULL; PyObject *object_reduce_ex = NULL; PyObject *reduce = NULL; PyObject *reduce_ex = NULL; PyObject *reduce_cython = NULL; PyObject *setstate = NULL; PyObject *setstate_cython = NULL; #if CYTHON_USE_PYTYPE_LOOKUP if (_PyType_Lookup((PyTypeObject*)type_obj, __pyx_n_s_getstate)) goto __PYX_GOOD; #else if (PyObject_HasAttr(type_obj, __pyx_n_s_getstate)) goto __PYX_GOOD; #endif #if CYTHON_USE_PYTYPE_LOOKUP object_reduce_ex = _PyType_Lookup(&PyBaseObject_Type, __pyx_n_s_reduce_ex); if (!object_reduce_ex) goto __PYX_BAD; #else object_reduce_ex = __Pyx_PyObject_GetAttrStr((PyObject*)&PyBaseObject_Type, __pyx_n_s_reduce_ex); if (!object_reduce_ex) goto __PYX_BAD; #endif reduce_ex = __Pyx_PyObject_GetAttrStr(type_obj, __pyx_n_s_reduce_ex); if (unlikely(!reduce_ex)) goto __PYX_BAD; if (reduce_ex == object_reduce_ex) { #if CYTHON_USE_PYTYPE_LOOKUP object_reduce = _PyType_Lookup(&PyBaseObject_Type, __pyx_n_s_reduce); if (!object_reduce) goto __PYX_BAD; #else object_reduce = __Pyx_PyObject_GetAttrStr((PyObject*)&PyBaseObject_Type, __pyx_n_s_reduce); if (!object_reduce) goto __PYX_BAD; #endif reduce = __Pyx_PyObject_GetAttrStr(type_obj, __pyx_n_s_reduce); if (unlikely(!reduce)) goto __PYX_BAD; if (reduce == object_reduce || __Pyx_setup_reduce_is_named(reduce, __pyx_n_s_reduce_cython)) { reduce_cython = __Pyx_PyObject_GetAttrStrNoError(type_obj, __pyx_n_s_reduce_cython); if (likely(reduce_cython)) { ret = PyDict_SetItem(((PyTypeObject*)type_obj)->tp_dict, __pyx_n_s_reduce, reduce_cython); if (unlikely(ret < 0)) goto __PYX_BAD; ret = PyDict_DelItem(((PyTypeObject*)type_obj)->tp_dict, __pyx_n_s_reduce_cython); if (unlikely(ret < 0)) goto __PYX_BAD; } else if (reduce == object_reduce || PyErr_Occurred()) { goto __PYX_BAD; } setstate = __Pyx_PyObject_GetAttrStr(type_obj, __pyx_n_s_setstate); if (!setstate) PyErr_Clear(); if (!setstate || __Pyx_setup_reduce_is_named(setstate, __pyx_n_s_setstate_cython)) { setstate_cython = __Pyx_PyObject_GetAttrStrNoError(type_obj, __pyx_n_s_setstate_cython); if (likely(setstate_cython)) { ret = PyDict_SetItem(((PyTypeObject*)type_obj)->tp_dict, __pyx_n_s_setstate, setstate_cython); if (unlikely(ret < 0)) goto __PYX_BAD; ret = PyDict_DelItem(((PyTypeObject*)type_obj)->tp_dict, __pyx_n_s_setstate_cython); if (unlikely(ret < 0)) goto __PYX_BAD; } else if (!setstate || PyErr_Occurred()) { goto __PYX_BAD; } } PyType_Modified((PyTypeObject*)type_obj); } } goto __PYX_GOOD; __PYX_BAD: if (!PyErr_Occurred()) PyErr_Format(PyExc_RuntimeError, "Unable to initialize pickling for %s", ((PyTypeObject*)type_obj)->tp_name); ret = -1; __PYX_GOOD: #if !CYTHON_USE_PYTYPE_LOOKUP Py_XDECREF(object_reduce); Py_XDECREF(object_reduce_ex); #endif Py_XDECREF(reduce); Py_XDECREF(reduce_ex); Py_XDECREF(reduce_cython); Py_XDECREF(setstate); Py_XDECREF(setstate_cython); return ret; } /* CLineInTraceback */ #ifndef CYTHON_CLINE_IN_TRACEBACK static int __Pyx_CLineForTraceback(CYTHON_NCP_UNUSED PyThreadState *tstate, int c_line) { PyObject *use_cline; PyObject *ptype, *pvalue, *ptraceback; #if CYTHON_COMPILING_IN_CPYTHON PyObject **cython_runtime_dict; #endif if (unlikely(!__pyx_cython_runtime)) { return c_line; } __Pyx_ErrFetchInState(tstate, &ptype, &pvalue, &ptraceback); #if CYTHON_COMPILING_IN_CPYTHON cython_runtime_dict = _PyObject_GetDictPtr(__pyx_cython_runtime); if (likely(cython_runtime_dict)) { __PYX_PY_DICT_LOOKUP_IF_MODIFIED( use_cline, *cython_runtime_dict, __Pyx_PyDict_GetItemStr(*cython_runtime_dict, __pyx_n_s_cline_in_traceback)) } else #endif { PyObject *use_cline_obj = __Pyx_PyObject_GetAttrStr(__pyx_cython_runtime, __pyx_n_s_cline_in_traceback); if (use_cline_obj) { use_cline = PyObject_Not(use_cline_obj) ? Py_False : Py_True; Py_DECREF(use_cline_obj); } else { PyErr_Clear(); use_cline = NULL; } } if (!use_cline) { c_line = 0; (void) PyObject_SetAttr(__pyx_cython_runtime, __pyx_n_s_cline_in_traceback, Py_False); } else if (use_cline == Py_False || (use_cline != Py_True && PyObject_Not(use_cline) != 0)) { c_line = 0; } __Pyx_ErrRestoreInState(tstate, ptype, pvalue, ptraceback); return c_line; } #endif /* CodeObjectCache */ static int __pyx_bisect_code_objects(__Pyx_CodeObjectCacheEntry* entries, int count, int code_line) { int start = 0, mid = 0, end = count - 1; if (end >= 0 && code_line > entries[end].code_line) { return count; } while (start < end) { mid = start + (end - start) / 2; if (code_line < entries[mid].code_line) { end = mid; } else if (code_line > entries[mid].code_line) { start = mid + 1; } else { return mid; } } if (code_line <= entries[mid].code_line) { return mid; } else { return mid + 1; } } static PyCodeObject *__pyx_find_code_object(int code_line) { PyCodeObject* code_object; int pos; if (unlikely(!code_line) || unlikely(!__pyx_code_cache.entries)) { return NULL; } pos = __pyx_bisect_code_objects(__pyx_code_cache.entries, __pyx_code_cache.count, code_line); if (unlikely(pos >= __pyx_code_cache.count) || unlikely(__pyx_code_cache.entries[pos].code_line != code_line)) { return NULL; } code_object = __pyx_code_cache.entries[pos].code_object; Py_INCREF(code_object); return code_object; } static void __pyx_insert_code_object(int code_line, PyCodeObject* code_object) { int pos, i; __Pyx_CodeObjectCacheEntry* entries = __pyx_code_cache.entries; if (unlikely(!code_line)) { return; } if (unlikely(!entries)) { entries = (__Pyx_CodeObjectCacheEntry*)PyMem_Malloc(64*sizeof(__Pyx_CodeObjectCacheEntry)); if (likely(entries)) { __pyx_code_cache.entries = entries; __pyx_code_cache.max_count = 64; __pyx_code_cache.count = 1; entries[0].code_line = code_line; entries[0].code_object = code_object; Py_INCREF(code_object); } return; } pos = __pyx_bisect_code_objects(__pyx_code_cache.entries, __pyx_code_cache.count, code_line); if ((pos < __pyx_code_cache.count) && unlikely(__pyx_code_cache.entries[pos].code_line == code_line)) { PyCodeObject* tmp = entries[pos].code_object; entries[pos].code_object = code_object; Py_DECREF(tmp); return; } if (__pyx_code_cache.count == __pyx_code_cache.max_count) { int new_max = __pyx_code_cache.max_count + 64; entries = (__Pyx_CodeObjectCacheEntry*)PyMem_Realloc( __pyx_code_cache.entries, ((size_t)new_max) * sizeof(__Pyx_CodeObjectCacheEntry)); if (unlikely(!entries)) { return; } __pyx_code_cache.entries = entries; __pyx_code_cache.max_count = new_max; } for (i=__pyx_code_cache.count; i>pos; i--) { entries[i] = entries[i-1]; } entries[pos].code_line = code_line; entries[pos].code_object = code_object; __pyx_code_cache.count++; Py_INCREF(code_object); } /* AddTraceback */ #include "compile.h" #include "frameobject.h" #include "traceback.h" static PyCodeObject* __Pyx_CreateCodeObjectForTraceback( const char *funcname, int c_line, int py_line, const char *filename) { PyCodeObject *py_code = NULL; PyObject *py_funcname = NULL; #if PY_MAJOR_VERSION < 3 PyObject *py_srcfile = NULL; py_srcfile = PyString_FromString(filename); if (!py_srcfile) goto bad; #endif if (c_line) { #if PY_MAJOR_VERSION < 3 py_funcname = PyString_FromFormat( "%s (%s:%d)", funcname, __pyx_cfilenm, c_line); if (!py_funcname) goto bad; #else py_funcname = PyUnicode_FromFormat( "%s (%s:%d)", funcname, __pyx_cfilenm, c_line); if (!py_funcname) goto bad; funcname = PyUnicode_AsUTF8(py_funcname); if (!funcname) goto bad; #endif } else { #if PY_MAJOR_VERSION < 3 py_funcname = PyString_FromString(funcname); if (!py_funcname) goto bad; #endif } #if PY_MAJOR_VERSION < 3 py_code = __Pyx_PyCode_New( 0, 0, 0, 0, 0, __pyx_empty_bytes, /*PyObject *code,*/ __pyx_empty_tuple, /*PyObject *consts,*/ __pyx_empty_tuple, /*PyObject *names,*/ __pyx_empty_tuple, /*PyObject *varnames,*/ __pyx_empty_tuple, /*PyObject *freevars,*/ __pyx_empty_tuple, /*PyObject *cellvars,*/ py_srcfile, /*PyObject *filename,*/ py_funcname, /*PyObject *name,*/ py_line, __pyx_empty_bytes /*PyObject *lnotab*/ ); Py_DECREF(py_srcfile); #else py_code = PyCode_NewEmpty(filename, funcname, py_line); #endif Py_XDECREF(py_funcname); // XDECREF since it's only set on Py3 if cline return py_code; bad: Py_XDECREF(py_funcname); #if PY_MAJOR_VERSION < 3 Py_XDECREF(py_srcfile); #endif return NULL; } static void __Pyx_AddTraceback(const char *funcname, int c_line, int py_line, const char *filename) { PyCodeObject *py_code = 0; PyFrameObject *py_frame = 0; PyThreadState *tstate = __Pyx_PyThreadState_Current; if (c_line) { c_line = __Pyx_CLineForTraceback(tstate, c_line); } py_code = __pyx_find_code_object(c_line ? -c_line : py_line); if (!py_code) { py_code = __Pyx_CreateCodeObjectForTraceback( funcname, c_line, py_line, filename); if (!py_code) goto bad; __pyx_insert_code_object(c_line ? -c_line : py_line, py_code); } py_frame = PyFrame_New( tstate, /*PyThreadState *tstate,*/ py_code, /*PyCodeObject *code,*/ __pyx_d, /*PyObject *globals,*/ 0 /*PyObject *locals*/ ); if (!py_frame) goto bad; __Pyx_PyFrame_SetLineNumber(py_frame, py_line); PyTraceBack_Here(py_frame); bad: Py_XDECREF(py_code); Py_XDECREF(py_frame); } #if PY_MAJOR_VERSION < 3 static int __Pyx_GetBuffer(PyObject *obj, Py_buffer *view, int flags) { if (PyObject_CheckBuffer(obj)) return PyObject_GetBuffer(obj, view, flags); if (__Pyx_TypeCheck(obj, __pyx_array_type)) return __pyx_array_getbuffer(obj, view, flags); if (__Pyx_TypeCheck(obj, __pyx_memoryview_type)) return __pyx_memoryview_getbuffer(obj, view, flags); PyErr_Format(PyExc_TypeError, "'%.200s' does not have the buffer interface", Py_TYPE(obj)->tp_name); return -1; } static void __Pyx_ReleaseBuffer(Py_buffer *view) { PyObject *obj = view->obj; if (!obj) return; if (PyObject_CheckBuffer(obj)) { PyBuffer_Release(view); return; } if ((0)) {} view->obj = NULL; Py_DECREF(obj); } #endif /* MemviewSliceIsContig */ static int __pyx_memviewslice_is_contig(const __Pyx_memviewslice mvs, char order, int ndim) { int i, index, step, start; Py_ssize_t itemsize = mvs.memview->view.itemsize; if (order == 'F') { step = 1; start = 0; } else { step = -1; start = ndim - 1; } for (i = 0; i < ndim; i++) { index = start + step * i; if (mvs.suboffsets[index] >= 0 || mvs.strides[index] != itemsize) return 0; itemsize *= mvs.shape[index]; } return 1; } /* OverlappingSlices */ static void __pyx_get_array_memory_extents(__Pyx_memviewslice *slice, void **out_start, void **out_end, int ndim, size_t itemsize) { char *start, *end; int i; start = end = slice->data; for (i = 0; i < ndim; i++) { Py_ssize_t stride = slice->strides[i]; Py_ssize_t extent = slice->shape[i]; if (extent == 0) { *out_start = *out_end = start; return; } else { if (stride > 0) end += stride * (extent - 1); else start += stride * (extent - 1); } } *out_start = start; *out_end = end + itemsize; } static int __pyx_slices_overlap(__Pyx_memviewslice *slice1, __Pyx_memviewslice *slice2, int ndim, size_t itemsize) { void *start1, *end1, *start2, *end2; __pyx_get_array_memory_extents(slice1, &start1, &end1, ndim, itemsize); __pyx_get_array_memory_extents(slice2, &start2, &end2, ndim, itemsize); return (start1 < end2) && (start2 < end1); } /* Capsule */ static CYTHON_INLINE PyObject * __pyx_capsule_create(void *p, CYTHON_UNUSED const char *sig) { PyObject *cobj; #if PY_VERSION_HEX >= 0x02070000 cobj = PyCapsule_New(p, sig, NULL); #else cobj = PyCObject_FromVoidPtr(p, NULL); #endif return cobj; } /* IsLittleEndian */ static CYTHON_INLINE int __Pyx_Is_Little_Endian(void) { union { uint32_t u32; uint8_t u8[4]; } S; S.u32 = 0x01020304; return S.u8[0] == 4; } /* BufferFormatCheck */ static void __Pyx_BufFmt_Init(__Pyx_BufFmt_Context* ctx, __Pyx_BufFmt_StackElem* stack, __Pyx_TypeInfo* type) { stack[0].field = &ctx->root; stack[0].parent_offset = 0; ctx->root.type = type; ctx->root.name = "buffer dtype"; ctx->root.offset = 0; ctx->head = stack; ctx->head->field = &ctx->root; ctx->fmt_offset = 0; ctx->head->parent_offset = 0; ctx->new_packmode = '@'; ctx->enc_packmode = '@'; ctx->new_count = 1; ctx->enc_count = 0; ctx->enc_type = 0; ctx->is_complex = 0; ctx->is_valid_array = 0; ctx->struct_alignment = 0; while (type->typegroup == 'S') { ++ctx->head; ctx->head->field = type->fields; ctx->head->parent_offset = 0; type = type->fields->type; } } static int __Pyx_BufFmt_ParseNumber(const char** ts) { int count; const char* t = *ts; if (*t < '0' || *t > '9') { return -1; } else { count = *t++ - '0'; while (*t >= '0' && *t <= '9') { count *= 10; count += *t++ - '0'; } } *ts = t; return count; } static int __Pyx_BufFmt_ExpectNumber(const char **ts) { int number = __Pyx_BufFmt_ParseNumber(ts); if (number == -1) PyErr_Format(PyExc_ValueError,\ "Does not understand character buffer dtype format string ('%c')", **ts); return number; } static void __Pyx_BufFmt_RaiseUnexpectedChar(char ch) { PyErr_Format(PyExc_ValueError, "Unexpected format string character: '%c'", ch); } static const char* __Pyx_BufFmt_DescribeTypeChar(char ch, int is_complex) { switch (ch) { case '?': return "'bool'"; case 'c': return "'char'"; case 'b': return "'signed char'"; case 'B': return "'unsigned char'"; case 'h': return "'short'"; case 'H': return "'unsigned short'"; case 'i': return "'int'"; case 'I': return "'unsigned int'"; case 'l': return "'long'"; case 'L': return "'unsigned long'"; case 'q': return "'long long'"; case 'Q': return "'unsigned long long'"; case 'f': return (is_complex ? "'complex float'" : "'float'"); case 'd': return (is_complex ? "'complex double'" : "'double'"); case 'g': return (is_complex ? "'complex long double'" : "'long double'"); case 'T': return "a struct"; case 'O': return "Python object"; case 'P': return "a pointer"; case 's': case 'p': return "a string"; case 0: return "end"; default: return "unparseable format string"; } } static size_t __Pyx_BufFmt_TypeCharToStandardSize(char ch, int is_complex) { switch (ch) { case '?': case 'c': case 'b': case 'B': case 's': case 'p': return 1; case 'h': case 'H': return 2; case 'i': case 'I': case 'l': case 'L': return 4; case 'q': case 'Q': return 8; case 'f': return (is_complex ? 8 : 4); case 'd': return (is_complex ? 16 : 8); case 'g': { PyErr_SetString(PyExc_ValueError, "Python does not define a standard format string size for long double ('g').."); return 0; } case 'O': case 'P': return sizeof(void*); default: __Pyx_BufFmt_RaiseUnexpectedChar(ch); return 0; } } static size_t __Pyx_BufFmt_TypeCharToNativeSize(char ch, int is_complex) { switch (ch) { case '?': case 'c': case 'b': case 'B': case 's': case 'p': return 1; case 'h': case 'H': return sizeof(short); case 'i': case 'I': return sizeof(int); case 'l': case 'L': return sizeof(long); #ifdef HAVE_LONG_LONG case 'q': case 'Q': return sizeof(PY_LONG_LONG); #endif case 'f': return sizeof(float) * (is_complex ? 2 : 1); case 'd': return sizeof(double) * (is_complex ? 2 : 1); case 'g': return sizeof(long double) * (is_complex ? 2 : 1); case 'O': case 'P': return sizeof(void*); default: { __Pyx_BufFmt_RaiseUnexpectedChar(ch); return 0; } } } typedef struct { char c; short x; } __Pyx_st_short; typedef struct { char c; int x; } __Pyx_st_int; typedef struct { char c; long x; } __Pyx_st_long; typedef struct { char c; float x; } __Pyx_st_float; typedef struct { char c; double x; } __Pyx_st_double; typedef struct { char c; long double x; } __Pyx_st_longdouble; typedef struct { char c; void *x; } __Pyx_st_void_p; #ifdef HAVE_LONG_LONG typedef struct { char c; PY_LONG_LONG x; } __Pyx_st_longlong; #endif static size_t __Pyx_BufFmt_TypeCharToAlignment(char ch, CYTHON_UNUSED int is_complex) { switch (ch) { case '?': case 'c': case 'b': case 'B': case 's': case 'p': return 1; case 'h': case 'H': return sizeof(__Pyx_st_short) - sizeof(short); case 'i': case 'I': return sizeof(__Pyx_st_int) - sizeof(int); case 'l': case 'L': return sizeof(__Pyx_st_long) - sizeof(long); #ifdef HAVE_LONG_LONG case 'q': case 'Q': return sizeof(__Pyx_st_longlong) - sizeof(PY_LONG_LONG); #endif case 'f': return sizeof(__Pyx_st_float) - sizeof(float); case 'd': return sizeof(__Pyx_st_double) - sizeof(double); case 'g': return sizeof(__Pyx_st_longdouble) - sizeof(long double); case 'P': case 'O': return sizeof(__Pyx_st_void_p) - sizeof(void*); default: __Pyx_BufFmt_RaiseUnexpectedChar(ch); return 0; } } /* These are for computing the padding at the end of the struct to align on the first member of the struct. This will probably the same as above, but we don't have any guarantees. */ typedef struct { short x; char c; } __Pyx_pad_short; typedef struct { int x; char c; } __Pyx_pad_int; typedef struct { long x; char c; } __Pyx_pad_long; typedef struct { float x; char c; } __Pyx_pad_float; typedef struct { double x; char c; } __Pyx_pad_double; typedef struct { long double x; char c; } __Pyx_pad_longdouble; typedef struct { void *x; char c; } __Pyx_pad_void_p; #ifdef HAVE_LONG_LONG typedef struct { PY_LONG_LONG x; char c; } __Pyx_pad_longlong; #endif static size_t __Pyx_BufFmt_TypeCharToPadding(char ch, CYTHON_UNUSED int is_complex) { switch (ch) { case '?': case 'c': case 'b': case 'B': case 's': case 'p': return 1; case 'h': case 'H': return sizeof(__Pyx_pad_short) - sizeof(short); case 'i': case 'I': return sizeof(__Pyx_pad_int) - sizeof(int); case 'l': case 'L': return sizeof(__Pyx_pad_long) - sizeof(long); #ifdef HAVE_LONG_LONG case 'q': case 'Q': return sizeof(__Pyx_pad_longlong) - sizeof(PY_LONG_LONG); #endif case 'f': return sizeof(__Pyx_pad_float) - sizeof(float); case 'd': return sizeof(__Pyx_pad_double) - sizeof(double); case 'g': return sizeof(__Pyx_pad_longdouble) - sizeof(long double); case 'P': case 'O': return sizeof(__Pyx_pad_void_p) - sizeof(void*); default: __Pyx_BufFmt_RaiseUnexpectedChar(ch); return 0; } } static char __Pyx_BufFmt_TypeCharToGroup(char ch, int is_complex) { switch (ch) { case 'c': return 'H'; case 'b': case 'h': case 'i': case 'l': case 'q': case 's': case 'p': return 'I'; case '?': case 'B': case 'H': case 'I': case 'L': case 'Q': return 'U'; case 'f': case 'd': case 'g': return (is_complex ? 'C' : 'R'); case 'O': return 'O'; case 'P': return 'P'; default: { __Pyx_BufFmt_RaiseUnexpectedChar(ch); return 0; } } } static void __Pyx_BufFmt_RaiseExpected(__Pyx_BufFmt_Context* ctx) { if (ctx->head == NULL || ctx->head->field == &ctx->root) { const char* expected; const char* quote; if (ctx->head == NULL) { expected = "end"; quote = ""; } else { expected = ctx->head->field->type->name; quote = "'"; } PyErr_Format(PyExc_ValueError, "Buffer dtype mismatch, expected %s%s%s but got %s", quote, expected, quote, __Pyx_BufFmt_DescribeTypeChar(ctx->enc_type, ctx->is_complex)); } else { __Pyx_StructField* field = ctx->head->field; __Pyx_StructField* parent = (ctx->head - 1)->field; PyErr_Format(PyExc_ValueError, "Buffer dtype mismatch, expected '%s' but got %s in '%s.%s'", field->type->name, __Pyx_BufFmt_DescribeTypeChar(ctx->enc_type, ctx->is_complex), parent->type->name, field->name); } } static int __Pyx_BufFmt_ProcessTypeChunk(__Pyx_BufFmt_Context* ctx) { char group; size_t size, offset, arraysize = 1; if (ctx->enc_type == 0) return 0; if (ctx->head->field->type->arraysize[0]) { int i, ndim = 0; if (ctx->enc_type == 's' || ctx->enc_type == 'p') { ctx->is_valid_array = ctx->head->field->type->ndim == 1; ndim = 1; if (ctx->enc_count != ctx->head->field->type->arraysize[0]) { PyErr_Format(PyExc_ValueError, "Expected a dimension of size %zu, got %zu", ctx->head->field->type->arraysize[0], ctx->enc_count); return -1; } } if (!ctx->is_valid_array) { PyErr_Format(PyExc_ValueError, "Expected %d dimensions, got %d", ctx->head->field->type->ndim, ndim); return -1; } for (i = 0; i < ctx->head->field->type->ndim; i++) { arraysize *= ctx->head->field->type->arraysize[i]; } ctx->is_valid_array = 0; ctx->enc_count = 1; } group = __Pyx_BufFmt_TypeCharToGroup(ctx->enc_type, ctx->is_complex); do { __Pyx_StructField* field = ctx->head->field; __Pyx_TypeInfo* type = field->type; if (ctx->enc_packmode == '@' || ctx->enc_packmode == '^') { size = __Pyx_BufFmt_TypeCharToNativeSize(ctx->enc_type, ctx->is_complex); } else { size = __Pyx_BufFmt_TypeCharToStandardSize(ctx->enc_type, ctx->is_complex); } if (ctx->enc_packmode == '@') { size_t align_at = __Pyx_BufFmt_TypeCharToAlignment(ctx->enc_type, ctx->is_complex); size_t align_mod_offset; if (align_at == 0) return -1; align_mod_offset = ctx->fmt_offset % align_at; if (align_mod_offset > 0) ctx->fmt_offset += align_at - align_mod_offset; if (ctx->struct_alignment == 0) ctx->struct_alignment = __Pyx_BufFmt_TypeCharToPadding(ctx->enc_type, ctx->is_complex); } if (type->size != size || type->typegroup != group) { if (type->typegroup == 'C' && type->fields != NULL) { size_t parent_offset = ctx->head->parent_offset + field->offset; ++ctx->head; ctx->head->field = type->fields; ctx->head->parent_offset = parent_offset; continue; } if ((type->typegroup == 'H' || group == 'H') && type->size == size) { } else { __Pyx_BufFmt_RaiseExpected(ctx); return -1; } } offset = ctx->head->parent_offset + field->offset; if (ctx->fmt_offset != offset) { PyErr_Format(PyExc_ValueError, "Buffer dtype mismatch; next field is at offset %" CYTHON_FORMAT_SSIZE_T "d but %" CYTHON_FORMAT_SSIZE_T "d expected", (Py_ssize_t)ctx->fmt_offset, (Py_ssize_t)offset); return -1; } ctx->fmt_offset += size; if (arraysize) ctx->fmt_offset += (arraysize - 1) * size; --ctx->enc_count; while (1) { if (field == &ctx->root) { ctx->head = NULL; if (ctx->enc_count != 0) { __Pyx_BufFmt_RaiseExpected(ctx); return -1; } break; } ctx->head->field = ++field; if (field->type == NULL) { --ctx->head; field = ctx->head->field; continue; } else if (field->type->typegroup == 'S') { size_t parent_offset = ctx->head->parent_offset + field->offset; if (field->type->fields->type == NULL) continue; field = field->type->fields; ++ctx->head; ctx->head->field = field; ctx->head->parent_offset = parent_offset; break; } else { break; } } } while (ctx->enc_count); ctx->enc_type = 0; ctx->is_complex = 0; return 0; } static PyObject * __pyx_buffmt_parse_array(__Pyx_BufFmt_Context* ctx, const char** tsp) { const char *ts = *tsp; int i = 0, number, ndim; ++ts; if (ctx->new_count != 1) { PyErr_SetString(PyExc_ValueError, "Cannot handle repeated arrays in format string"); return NULL; } if (__Pyx_BufFmt_ProcessTypeChunk(ctx) == -1) return NULL; ndim = ctx->head->field->type->ndim; while (*ts && *ts != ')') { switch (*ts) { case ' ': case '\f': case '\r': case '\n': case '\t': case '\v': continue; default: break; } number = __Pyx_BufFmt_ExpectNumber(&ts); if (number == -1) return NULL; if (i < ndim && (size_t) number != ctx->head->field->type->arraysize[i]) return PyErr_Format(PyExc_ValueError, "Expected a dimension of size %zu, got %d", ctx->head->field->type->arraysize[i], number); if (*ts != ',' && *ts != ')') return PyErr_Format(PyExc_ValueError, "Expected a comma in format string, got '%c'", *ts); if (*ts == ',') ts++; i++; } if (i != ndim) return PyErr_Format(PyExc_ValueError, "Expected %d dimension(s), got %d", ctx->head->field->type->ndim, i); if (!*ts) { PyErr_SetString(PyExc_ValueError, "Unexpected end of format string, expected ')'"); return NULL; } ctx->is_valid_array = 1; ctx->new_count = 1; *tsp = ++ts; return Py_None; } static const char* __Pyx_BufFmt_CheckString(__Pyx_BufFmt_Context* ctx, const char* ts) { int got_Z = 0; while (1) { switch(*ts) { case 0: if (ctx->enc_type != 0 && ctx->head == NULL) { __Pyx_BufFmt_RaiseExpected(ctx); return NULL; } if (__Pyx_BufFmt_ProcessTypeChunk(ctx) == -1) return NULL; if (ctx->head != NULL) { __Pyx_BufFmt_RaiseExpected(ctx); return NULL; } return ts; case ' ': case '\r': case '\n': ++ts; break; case '<': if (!__Pyx_Is_Little_Endian()) { PyErr_SetString(PyExc_ValueError, "Little-endian buffer not supported on big-endian compiler"); return NULL; } ctx->new_packmode = '='; ++ts; break; case '>': case '!': if (__Pyx_Is_Little_Endian()) { PyErr_SetString(PyExc_ValueError, "Big-endian buffer not supported on little-endian compiler"); return NULL; } ctx->new_packmode = '='; ++ts; break; case '=': case '@': case '^': ctx->new_packmode = *ts++; break; case 'T': { const char* ts_after_sub; size_t i, struct_count = ctx->new_count; size_t struct_alignment = ctx->struct_alignment; ctx->new_count = 1; ++ts; if (*ts != '{') { PyErr_SetString(PyExc_ValueError, "Buffer acquisition: Expected '{' after 'T'"); return NULL; } if (__Pyx_BufFmt_ProcessTypeChunk(ctx) == -1) return NULL; ctx->enc_type = 0; ctx->enc_count = 0; ctx->struct_alignment = 0; ++ts; ts_after_sub = ts; for (i = 0; i != struct_count; ++i) { ts_after_sub = __Pyx_BufFmt_CheckString(ctx, ts); if (!ts_after_sub) return NULL; } ts = ts_after_sub; if (struct_alignment) ctx->struct_alignment = struct_alignment; } break; case '}': { size_t alignment = ctx->struct_alignment; ++ts; if (__Pyx_BufFmt_ProcessTypeChunk(ctx) == -1) return NULL; ctx->enc_type = 0; if (alignment && ctx->fmt_offset % alignment) { ctx->fmt_offset += alignment - (ctx->fmt_offset % alignment); } } return ts; case 'x': if (__Pyx_BufFmt_ProcessTypeChunk(ctx) == -1) return NULL; ctx->fmt_offset += ctx->new_count; ctx->new_count = 1; ctx->enc_count = 0; ctx->enc_type = 0; ctx->enc_packmode = ctx->new_packmode; ++ts; break; case 'Z': got_Z = 1; ++ts; if (*ts != 'f' && *ts != 'd' && *ts != 'g') { __Pyx_BufFmt_RaiseUnexpectedChar('Z'); return NULL; } CYTHON_FALLTHROUGH; case '?': case 'c': case 'b': case 'B': case 'h': case 'H': case 'i': case 'I': case 'l': case 'L': case 'q': case 'Q': case 'f': case 'd': case 'g': case 'O': case 'p': if ((ctx->enc_type == *ts) && (got_Z == ctx->is_complex) && (ctx->enc_packmode == ctx->new_packmode) && (!ctx->is_valid_array)) { ctx->enc_count += ctx->new_count; ctx->new_count = 1; got_Z = 0; ++ts; break; } CYTHON_FALLTHROUGH; case 's': if (__Pyx_BufFmt_ProcessTypeChunk(ctx) == -1) return NULL; ctx->enc_count = ctx->new_count; ctx->enc_packmode = ctx->new_packmode; ctx->enc_type = *ts; ctx->is_complex = got_Z; ++ts; ctx->new_count = 1; got_Z = 0; break; case ':': ++ts; while(*ts != ':') ++ts; ++ts; break; case '(': if (!__pyx_buffmt_parse_array(ctx, &ts)) return NULL; break; default: { int number = __Pyx_BufFmt_ExpectNumber(&ts); if (number == -1) return NULL; ctx->new_count = (size_t)number; } } } } /* TypeInfoCompare */ static int __pyx_typeinfo_cmp(__Pyx_TypeInfo *a, __Pyx_TypeInfo *b) { int i; if (!a || !b) return 0; if (a == b) return 1; if (a->size != b->size || a->typegroup != b->typegroup || a->is_unsigned != b->is_unsigned || a->ndim != b->ndim) { if (a->typegroup == 'H' || b->typegroup == 'H') { return a->size == b->size; } else { return 0; } } if (a->ndim) { for (i = 0; i < a->ndim; i++) if (a->arraysize[i] != b->arraysize[i]) return 0; } if (a->typegroup == 'S') { if (a->flags != b->flags) return 0; if (a->fields || b->fields) { if (!(a->fields && b->fields)) return 0; for (i = 0; a->fields[i].type && b->fields[i].type; i++) { __Pyx_StructField *field_a = a->fields + i; __Pyx_StructField *field_b = b->fields + i; if (field_a->offset != field_b->offset || !__pyx_typeinfo_cmp(field_a->type, field_b->type)) return 0; } return !a->fields[i].type && !b->fields[i].type; } } return 1; } /* MemviewSliceValidateAndInit */ static int __pyx_check_strides(Py_buffer *buf, int dim, int ndim, int spec) { if (buf->shape[dim] <= 1) return 1; if (buf->strides) { if (spec & __Pyx_MEMVIEW_CONTIG) { if (spec & (__Pyx_MEMVIEW_PTR|__Pyx_MEMVIEW_FULL)) { if (unlikely(buf->strides[dim] != sizeof(void *))) { PyErr_Format(PyExc_ValueError, "Buffer is not indirectly contiguous " "in dimension %d.", dim); goto fail; } } else if (unlikely(buf->strides[dim] != buf->itemsize)) { PyErr_SetString(PyExc_ValueError, "Buffer and memoryview are not contiguous " "in the same dimension."); goto fail; } } if (spec & __Pyx_MEMVIEW_FOLLOW) { Py_ssize_t stride = buf->strides[dim]; if (stride < 0) stride = -stride; if (unlikely(stride < buf->itemsize)) { PyErr_SetString(PyExc_ValueError, "Buffer and memoryview are not contiguous " "in the same dimension."); goto fail; } } } else { if (unlikely(spec & __Pyx_MEMVIEW_CONTIG && dim != ndim - 1)) { PyErr_Format(PyExc_ValueError, "C-contiguous buffer is not contiguous in " "dimension %d", dim); goto fail; } else if (unlikely(spec & (__Pyx_MEMVIEW_PTR))) { PyErr_Format(PyExc_ValueError, "C-contiguous buffer is not indirect in " "dimension %d", dim); goto fail; } else if (unlikely(buf->suboffsets)) { PyErr_SetString(PyExc_ValueError, "Buffer exposes suboffsets but no strides"); goto fail; } } return 1; fail: return 0; } static int __pyx_check_suboffsets(Py_buffer *buf, int dim, CYTHON_UNUSED int ndim, int spec) { if (spec & __Pyx_MEMVIEW_DIRECT) { if (unlikely(buf->suboffsets && buf->suboffsets[dim] >= 0)) { PyErr_Format(PyExc_ValueError, "Buffer not compatible with direct access " "in dimension %d.", dim); goto fail; } } if (spec & __Pyx_MEMVIEW_PTR) { if (unlikely(!buf->suboffsets || (buf->suboffsets[dim] < 0))) { PyErr_Format(PyExc_ValueError, "Buffer is not indirectly accessible " "in dimension %d.", dim); goto fail; } } return 1; fail: return 0; } static int __pyx_verify_contig(Py_buffer *buf, int ndim, int c_or_f_flag) { int i; if (c_or_f_flag & __Pyx_IS_F_CONTIG) { Py_ssize_t stride = 1; for (i = 0; i < ndim; i++) { if (unlikely(stride * buf->itemsize != buf->strides[i] && buf->shape[i] > 1)) { PyErr_SetString(PyExc_ValueError, "Buffer not fortran contiguous."); goto fail; } stride = stride * buf->shape[i]; } } else if (c_or_f_flag & __Pyx_IS_C_CONTIG) { Py_ssize_t stride = 1; for (i = ndim - 1; i >- 1; i--) { if (unlikely(stride * buf->itemsize != buf->strides[i] && buf->shape[i] > 1)) { PyErr_SetString(PyExc_ValueError, "Buffer not C contiguous."); goto fail; } stride = stride * buf->shape[i]; } } return 1; fail: return 0; } static int __Pyx_ValidateAndInit_memviewslice( int *axes_specs, int c_or_f_flag, int buf_flags, int ndim, __Pyx_TypeInfo *dtype, __Pyx_BufFmt_StackElem stack[], __Pyx_memviewslice *memviewslice, PyObject *original_obj) { struct __pyx_memoryview_obj *memview, *new_memview; __Pyx_RefNannyDeclarations Py_buffer *buf; int i, spec = 0, retval = -1; __Pyx_BufFmt_Context ctx; int from_memoryview = __pyx_memoryview_check(original_obj); __Pyx_RefNannySetupContext("ValidateAndInit_memviewslice", 0); if (from_memoryview && __pyx_typeinfo_cmp(dtype, ((struct __pyx_memoryview_obj *) original_obj)->typeinfo)) { memview = (struct __pyx_memoryview_obj *) original_obj; new_memview = NULL; } else { memview = (struct __pyx_memoryview_obj *) __pyx_memoryview_new( original_obj, buf_flags, 0, dtype); new_memview = memview; if (unlikely(!memview)) goto fail; } buf = &memview->view; if (unlikely(buf->ndim != ndim)) { PyErr_Format(PyExc_ValueError, "Buffer has wrong number of dimensions (expected %d, got %d)", ndim, buf->ndim); goto fail; } if (new_memview) { __Pyx_BufFmt_Init(&ctx, stack, dtype); if (unlikely(!__Pyx_BufFmt_CheckString(&ctx, buf->format))) goto fail; } if (unlikely((unsigned) buf->itemsize != dtype->size)) { PyErr_Format(PyExc_ValueError, "Item size of buffer (%" CYTHON_FORMAT_SSIZE_T "u byte%s) " "does not match size of '%s' (%" CYTHON_FORMAT_SSIZE_T "u byte%s)", buf->itemsize, (buf->itemsize > 1) ? "s" : "", dtype->name, dtype->size, (dtype->size > 1) ? "s" : ""); goto fail; } if (buf->len > 0) { for (i = 0; i < ndim; i++) { spec = axes_specs[i]; if (unlikely(!__pyx_check_strides(buf, i, ndim, spec))) goto fail; if (unlikely(!__pyx_check_suboffsets(buf, i, ndim, spec))) goto fail; } if (unlikely(buf->strides && !__pyx_verify_contig(buf, ndim, c_or_f_flag))) goto fail; } if (unlikely(__Pyx_init_memviewslice(memview, ndim, memviewslice, new_memview != NULL) == -1)) { goto fail; } retval = 0; goto no_fail; fail: Py_XDECREF(new_memview); retval = -1; no_fail: __Pyx_RefNannyFinishContext(); return retval; } /* ObjectToMemviewSlice */ static CYTHON_INLINE __Pyx_memviewslice __Pyx_PyObject_to_MemoryviewSlice_d_dc_double(PyObject *obj, int writable_flag) { __Pyx_memviewslice result = { 0, 0, { 0 }, { 0 }, { 0 } }; __Pyx_BufFmt_StackElem stack[1]; int axes_specs[] = { (__Pyx_MEMVIEW_DIRECT | __Pyx_MEMVIEW_FOLLOW), (__Pyx_MEMVIEW_DIRECT | __Pyx_MEMVIEW_CONTIG) }; int retcode; if (obj == Py_None) { result.memview = (struct __pyx_memoryview_obj *) Py_None; return result; } retcode = __Pyx_ValidateAndInit_memviewslice(axes_specs, __Pyx_IS_C_CONTIG, (PyBUF_C_CONTIGUOUS | PyBUF_FORMAT) | writable_flag, 2, &__Pyx_TypeInfo_double, stack, &result, obj); if (unlikely(retcode == -1)) goto __pyx_fail; return result; __pyx_fail: result.memview = NULL; result.data = NULL; return result; } /* ObjectToMemviewSlice */ static CYTHON_INLINE __Pyx_memviewslice __Pyx_PyObject_to_MemoryviewSlice_ds_double(PyObject *obj, int writable_flag) { __Pyx_memviewslice result = { 0, 0, { 0 }, { 0 }, { 0 } }; __Pyx_BufFmt_StackElem stack[1]; int axes_specs[] = { (__Pyx_MEMVIEW_DIRECT | __Pyx_MEMVIEW_STRIDED) }; int retcode; if (obj == Py_None) { result.memview = (struct __pyx_memoryview_obj *) Py_None; return result; } retcode = __Pyx_ValidateAndInit_memviewslice(axes_specs, 0, PyBUF_RECORDS_RO | writable_flag, 1, &__Pyx_TypeInfo_double, stack, &result, obj); if (unlikely(retcode == -1)) goto __pyx_fail; return result; __pyx_fail: result.memview = NULL; result.data = NULL; return result; } /* ObjectToMemviewSlice */ static CYTHON_INLINE __Pyx_memviewslice __Pyx_PyObject_to_MemoryviewSlice_dc_double(PyObject *obj, int writable_flag) { __Pyx_memviewslice result = { 0, 0, { 0 }, { 0 }, { 0 } }; __Pyx_BufFmt_StackElem stack[1]; int axes_specs[] = { (__Pyx_MEMVIEW_DIRECT | __Pyx_MEMVIEW_CONTIG) }; int retcode; if (obj == Py_None) { result.memview = (struct __pyx_memoryview_obj *) Py_None; return result; } retcode = __Pyx_ValidateAndInit_memviewslice(axes_specs, __Pyx_IS_C_CONTIG, (PyBUF_C_CONTIGUOUS | PyBUF_FORMAT) | writable_flag, 1, &__Pyx_TypeInfo_double, stack, &result, obj); if (unlikely(retcode == -1)) goto __pyx_fail; return result; __pyx_fail: result.memview = NULL; result.data = NULL; return result; } /* ObjectToMemviewSlice */ static CYTHON_INLINE __Pyx_memviewslice __Pyx_PyObject_to_MemoryviewSlice_d_dc_long(PyObject *obj, int writable_flag) { __Pyx_memviewslice result = { 0, 0, { 0 }, { 0 }, { 0 } }; __Pyx_BufFmt_StackElem stack[1]; int axes_specs[] = { (__Pyx_MEMVIEW_DIRECT | __Pyx_MEMVIEW_FOLLOW), (__Pyx_MEMVIEW_DIRECT | __Pyx_MEMVIEW_CONTIG) }; int retcode; if (obj == Py_None) { result.memview = (struct __pyx_memoryview_obj *) Py_None; return result; } retcode = __Pyx_ValidateAndInit_memviewslice(axes_specs, __Pyx_IS_C_CONTIG, (PyBUF_C_CONTIGUOUS | PyBUF_FORMAT) | writable_flag, 2, &__Pyx_TypeInfo_long, stack, &result, obj); if (unlikely(retcode == -1)) goto __pyx_fail; return result; __pyx_fail: result.memview = NULL; result.data = NULL; return result; } /* CIntFromPyVerify */ #define __PYX_VERIFY_RETURN_INT(target_type, func_type, func_value)\ __PYX__VERIFY_RETURN_INT(target_type, func_type, func_value, 0) #define __PYX_VERIFY_RETURN_INT_EXC(target_type, func_type, func_value)\ __PYX__VERIFY_RETURN_INT(target_type, func_type, func_value, 1) #define __PYX__VERIFY_RETURN_INT(target_type, func_type, func_value, exc)\ {\ func_type value = func_value;\ if (sizeof(target_type) < sizeof(func_type)) {\ if (unlikely(value != (func_type) (target_type) value)) {\ func_type zero = 0;\ if (exc && unlikely(value == (func_type)-1 && PyErr_Occurred()))\ return (target_type) -1;\ if (is_unsigned && unlikely(value < zero))\ goto raise_neg_overflow;\ else\ goto raise_overflow;\ }\ }\ return (target_type) value;\ } /* MemviewDtypeToObject */ static CYTHON_INLINE PyObject *__pyx_memview_get_double(const char *itemp) { return (PyObject *) PyFloat_FromDouble(*(double *) itemp); } static CYTHON_INLINE int __pyx_memview_set_double(const char *itemp, PyObject *obj) { double value = __pyx_PyFloat_AsDouble(obj); if ((value == (double)-1) && PyErr_Occurred()) return 0; *(double *) itemp = value; return 1; } /* MemviewSliceCopyTemplate */ static __Pyx_memviewslice __pyx_memoryview_copy_new_contig(const __Pyx_memviewslice *from_mvs, const char *mode, int ndim, size_t sizeof_dtype, int contig_flag, int dtype_is_object) { __Pyx_RefNannyDeclarations int i; __Pyx_memviewslice new_mvs = { 0, 0, { 0 }, { 0 }, { 0 } }; struct __pyx_memoryview_obj *from_memview = from_mvs->memview; Py_buffer *buf = &from_memview->view; PyObject *shape_tuple = NULL; PyObject *temp_int = NULL; struct __pyx_array_obj *array_obj = NULL; struct __pyx_memoryview_obj *memview_obj = NULL; __Pyx_RefNannySetupContext("__pyx_memoryview_copy_new_contig", 0); for (i = 0; i < ndim; i++) { if (unlikely(from_mvs->suboffsets[i] >= 0)) { PyErr_Format(PyExc_ValueError, "Cannot copy memoryview slice with " "indirect dimensions (axis %d)", i); goto fail; } } shape_tuple = PyTuple_New(ndim); if (unlikely(!shape_tuple)) { goto fail; } __Pyx_GOTREF(shape_tuple); for(i = 0; i < ndim; i++) { temp_int = PyInt_FromSsize_t(from_mvs->shape[i]); if(unlikely(!temp_int)) { goto fail; } else { PyTuple_SET_ITEM(shape_tuple, i, temp_int); temp_int = NULL; } } array_obj = __pyx_array_new(shape_tuple, sizeof_dtype, buf->format, (char *) mode, NULL); if (unlikely(!array_obj)) { goto fail; } __Pyx_GOTREF(array_obj); memview_obj = (struct __pyx_memoryview_obj *) __pyx_memoryview_new( (PyObject *) array_obj, contig_flag, dtype_is_object, from_mvs->memview->typeinfo); if (unlikely(!memview_obj)) goto fail; if (unlikely(__Pyx_init_memviewslice(memview_obj, ndim, &new_mvs, 1) < 0)) goto fail; if (unlikely(__pyx_memoryview_copy_contents(*from_mvs, new_mvs, ndim, ndim, dtype_is_object) < 0)) goto fail; goto no_fail; fail: __Pyx_XDECREF(new_mvs.memview); new_mvs.memview = NULL; new_mvs.data = NULL; no_fail: __Pyx_XDECREF(shape_tuple); __Pyx_XDECREF(temp_int); __Pyx_XDECREF(array_obj); __Pyx_RefNannyFinishContext(); return new_mvs; } /* CIntFromPy */ static CYTHON_INLINE long __Pyx_PyInt_As_long(PyObject *x) { #ifdef __Pyx_HAS_GCC_DIAGNOSTIC #pragma GCC diagnostic push #pragma GCC diagnostic ignored "-Wconversion" #endif const long neg_one = (long) -1, const_zero = (long) 0; #ifdef __Pyx_HAS_GCC_DIAGNOSTIC #pragma GCC diagnostic pop #endif const int is_unsigned = neg_one > const_zero; #if PY_MAJOR_VERSION < 3 if (likely(PyInt_Check(x))) { if (sizeof(long) < sizeof(long)) { __PYX_VERIFY_RETURN_INT(long, long, PyInt_AS_LONG(x)) } else { long val = PyInt_AS_LONG(x); if (is_unsigned && unlikely(val < 0)) { goto raise_neg_overflow; } return (long) val; } } else #endif if (likely(PyLong_Check(x))) { if (is_unsigned) { #if CYTHON_USE_PYLONG_INTERNALS const digit* digits = ((PyLongObject*)x)->ob_digit; switch (Py_SIZE(x)) { case 0: return (long) 0; case 1: __PYX_VERIFY_RETURN_INT(long, digit, digits[0]) case 2: if (8 * sizeof(long) > 1 * PyLong_SHIFT) { if (8 * sizeof(unsigned long) > 2 * PyLong_SHIFT) { __PYX_VERIFY_RETURN_INT(long, unsigned long, (((((unsigned long)digits[1]) << PyLong_SHIFT) | (unsigned long)digits[0]))) } else if (8 * sizeof(long) >= 2 * PyLong_SHIFT) { return (long) (((((long)digits[1]) << PyLong_SHIFT) | (long)digits[0])); } } break; case 3: if (8 * sizeof(long) > 2 * PyLong_SHIFT) { if (8 * sizeof(unsigned long) > 3 * PyLong_SHIFT) { __PYX_VERIFY_RETURN_INT(long, unsigned long, (((((((unsigned long)digits[2]) << PyLong_SHIFT) | (unsigned long)digits[1]) << PyLong_SHIFT) | (unsigned long)digits[0]))) } else if (8 * sizeof(long) >= 3 * PyLong_SHIFT) { return (long) (((((((long)digits[2]) << PyLong_SHIFT) | (long)digits[1]) << PyLong_SHIFT) | (long)digits[0])); } } break; case 4: if (8 * sizeof(long) > 3 * PyLong_SHIFT) { if (8 * sizeof(unsigned long) > 4 * PyLong_SHIFT) { __PYX_VERIFY_RETURN_INT(long, unsigned long, (((((((((unsigned long)digits[3]) << PyLong_SHIFT) | (unsigned long)digits[2]) << PyLong_SHIFT) | (unsigned long)digits[1]) << PyLong_SHIFT) | (unsigned long)digits[0]))) } else if (8 * sizeof(long) >= 4 * PyLong_SHIFT) { return (long) (((((((((long)digits[3]) << PyLong_SHIFT) | (long)digits[2]) << PyLong_SHIFT) | (long)digits[1]) << PyLong_SHIFT) | (long)digits[0])); } } break; } #endif #if CYTHON_COMPILING_IN_CPYTHON if (unlikely(Py_SIZE(x) < 0)) { goto raise_neg_overflow; } #else { int result = PyObject_RichCompareBool(x, Py_False, Py_LT); if (unlikely(result < 0)) return (long) -1; if (unlikely(result == 1)) goto raise_neg_overflow; } #endif if (sizeof(long) <= sizeof(unsigned long)) { __PYX_VERIFY_RETURN_INT_EXC(long, unsigned long, PyLong_AsUnsignedLong(x)) #ifdef HAVE_LONG_LONG } else if (sizeof(long) <= sizeof(unsigned PY_LONG_LONG)) { __PYX_VERIFY_RETURN_INT_EXC(long, unsigned PY_LONG_LONG, PyLong_AsUnsignedLongLong(x)) #endif } } else { #if CYTHON_USE_PYLONG_INTERNALS const digit* digits = ((PyLongObject*)x)->ob_digit; switch (Py_SIZE(x)) { case 0: return (long) 0; case -1: __PYX_VERIFY_RETURN_INT(long, sdigit, (sdigit) (-(sdigit)digits[0])) case 1: __PYX_VERIFY_RETURN_INT(long, digit, +digits[0]) case -2: if (8 * sizeof(long) - 1 > 1 * PyLong_SHIFT) { if (8 * sizeof(unsigned long) > 2 * PyLong_SHIFT) { __PYX_VERIFY_RETURN_INT(long, long, -(long) (((((unsigned long)digits[1]) << PyLong_SHIFT) | (unsigned long)digits[0]))) } else if (8 * sizeof(long) - 1 > 2 * PyLong_SHIFT) { return (long) (((long)-1)*(((((long)digits[1]) << PyLong_SHIFT) | (long)digits[0]))); } } break; case 2: if (8 * sizeof(long) > 1 * PyLong_SHIFT) { if (8 * sizeof(unsigned long) > 2 * PyLong_SHIFT) { __PYX_VERIFY_RETURN_INT(long, unsigned long, (((((unsigned long)digits[1]) << PyLong_SHIFT) | (unsigned long)digits[0]))) } else if (8 * sizeof(long) - 1 > 2 * PyLong_SHIFT) { return (long) ((((((long)digits[1]) << PyLong_SHIFT) | (long)digits[0]))); } } break; case -3: if (8 * sizeof(long) - 1 > 2 * PyLong_SHIFT) { if (8 * sizeof(unsigned long) > 3 * PyLong_SHIFT) { __PYX_VERIFY_RETURN_INT(long, long, -(long) (((((((unsigned long)digits[2]) << PyLong_SHIFT) | (unsigned long)digits[1]) << PyLong_SHIFT) | (unsigned long)digits[0]))) } else if (8 * sizeof(long) - 1 > 3 * PyLong_SHIFT) { return (long) (((long)-1)*(((((((long)digits[2]) << PyLong_SHIFT) | (long)digits[1]) << PyLong_SHIFT) | (long)digits[0]))); } } break; case 3: if (8 * sizeof(long) > 2 * PyLong_SHIFT) { if (8 * sizeof(unsigned long) > 3 * PyLong_SHIFT) { __PYX_VERIFY_RETURN_INT(long, unsigned long, (((((((unsigned long)digits[2]) << PyLong_SHIFT) | (unsigned long)digits[1]) << PyLong_SHIFT) | (unsigned long)digits[0]))) } else if (8 * sizeof(long) - 1 > 3 * PyLong_SHIFT) { return (long) ((((((((long)digits[2]) << PyLong_SHIFT) | (long)digits[1]) << PyLong_SHIFT) | (long)digits[0]))); } } break; case -4: if (8 * sizeof(long) - 1 > 3 * PyLong_SHIFT) { if (8 * sizeof(unsigned long) > 4 * PyLong_SHIFT) { __PYX_VERIFY_RETURN_INT(long, long, -(long) (((((((((unsigned long)digits[3]) << PyLong_SHIFT) | (unsigned long)digits[2]) << PyLong_SHIFT) | (unsigned long)digits[1]) << PyLong_SHIFT) | (unsigned long)digits[0]))) } else if (8 * sizeof(long) - 1 > 4 * PyLong_SHIFT) { return (long) (((long)-1)*(((((((((long)digits[3]) << PyLong_SHIFT) | (long)digits[2]) << PyLong_SHIFT) | (long)digits[1]) << PyLong_SHIFT) | (long)digits[0]))); } } break; case 4: if (8 * sizeof(long) > 3 * PyLong_SHIFT) { if (8 * sizeof(unsigned long) > 4 * PyLong_SHIFT) { __PYX_VERIFY_RETURN_INT(long, unsigned long, (((((((((unsigned long)digits[3]) << PyLong_SHIFT) | (unsigned long)digits[2]) << PyLong_SHIFT) | (unsigned long)digits[1]) << PyLong_SHIFT) | (unsigned long)digits[0]))) } else if (8 * sizeof(long) - 1 > 4 * PyLong_SHIFT) { return (long) ((((((((((long)digits[3]) << PyLong_SHIFT) | (long)digits[2]) << PyLong_SHIFT) | (long)digits[1]) << PyLong_SHIFT) | (long)digits[0]))); } } break; } #endif if (sizeof(long) <= sizeof(long)) { __PYX_VERIFY_RETURN_INT_EXC(long, long, PyLong_AsLong(x)) #ifdef HAVE_LONG_LONG } else if (sizeof(long) <= sizeof(PY_LONG_LONG)) { __PYX_VERIFY_RETURN_INT_EXC(long, PY_LONG_LONG, PyLong_AsLongLong(x)) #endif } } { #if CYTHON_COMPILING_IN_PYPY && !defined(_PyLong_AsByteArray) PyErr_SetString(PyExc_RuntimeError, "_PyLong_AsByteArray() not available in PyPy, cannot convert large numbers"); #else long val; PyObject *v = __Pyx_PyNumber_IntOrLong(x); #if PY_MAJOR_VERSION < 3 if (likely(v) && !PyLong_Check(v)) { PyObject *tmp = v; v = PyNumber_Long(tmp); Py_DECREF(tmp); } #endif if (likely(v)) { int one = 1; int is_little = (int)*(unsigned char *)&one; unsigned char *bytes = (unsigned char *)&val; int ret = _PyLong_AsByteArray((PyLongObject *)v, bytes, sizeof(val), is_little, !is_unsigned); Py_DECREF(v); if (likely(!ret)) return val; } #endif return (long) -1; } } else { long val; PyObject *tmp = __Pyx_PyNumber_IntOrLong(x); if (!tmp) return (long) -1; val = __Pyx_PyInt_As_long(tmp); Py_DECREF(tmp); return val; } raise_overflow: PyErr_SetString(PyExc_OverflowError, "value too large to convert to long"); return (long) -1; raise_neg_overflow: PyErr_SetString(PyExc_OverflowError, "can't convert negative value to long"); return (long) -1; } /* CIntFromPy */ static CYTHON_INLINE int __Pyx_PyInt_As_int(PyObject *x) { #ifdef __Pyx_HAS_GCC_DIAGNOSTIC #pragma GCC diagnostic push #pragma GCC diagnostic ignored "-Wconversion" #endif const int neg_one = (int) -1, const_zero = (int) 0; #ifdef __Pyx_HAS_GCC_DIAGNOSTIC #pragma GCC diagnostic pop #endif const int is_unsigned = neg_one > const_zero; #if PY_MAJOR_VERSION < 3 if (likely(PyInt_Check(x))) { if (sizeof(int) < sizeof(long)) { __PYX_VERIFY_RETURN_INT(int, long, PyInt_AS_LONG(x)) } else { long val = PyInt_AS_LONG(x); if (is_unsigned && unlikely(val < 0)) { goto raise_neg_overflow; } return (int) val; } } else #endif if (likely(PyLong_Check(x))) { if (is_unsigned) { #if CYTHON_USE_PYLONG_INTERNALS const digit* digits = ((PyLongObject*)x)->ob_digit; switch (Py_SIZE(x)) { case 0: return (int) 0; case 1: __PYX_VERIFY_RETURN_INT(int, digit, digits[0]) case 2: if (8 * sizeof(int) > 1 * PyLong_SHIFT) { if (8 * sizeof(unsigned long) > 2 * PyLong_SHIFT) { __PYX_VERIFY_RETURN_INT(int, unsigned long, (((((unsigned long)digits[1]) << PyLong_SHIFT) | (unsigned long)digits[0]))) } else if (8 * sizeof(int) >= 2 * PyLong_SHIFT) { return (int) (((((int)digits[1]) << PyLong_SHIFT) | (int)digits[0])); } } break; case 3: if (8 * sizeof(int) > 2 * PyLong_SHIFT) { if (8 * sizeof(unsigned long) > 3 * PyLong_SHIFT) { __PYX_VERIFY_RETURN_INT(int, unsigned long, (((((((unsigned long)digits[2]) << PyLong_SHIFT) | (unsigned long)digits[1]) << PyLong_SHIFT) | (unsigned long)digits[0]))) } else if (8 * sizeof(int) >= 3 * PyLong_SHIFT) { return (int) (((((((int)digits[2]) << PyLong_SHIFT) | (int)digits[1]) << PyLong_SHIFT) | (int)digits[0])); } } break; case 4: if (8 * sizeof(int) > 3 * PyLong_SHIFT) { if (8 * sizeof(unsigned long) > 4 * PyLong_SHIFT) { __PYX_VERIFY_RETURN_INT(int, unsigned long, (((((((((unsigned long)digits[3]) << PyLong_SHIFT) | (unsigned long)digits[2]) << PyLong_SHIFT) | (unsigned long)digits[1]) << PyLong_SHIFT) | (unsigned long)digits[0]))) } else if (8 * sizeof(int) >= 4 * PyLong_SHIFT) { return (int) (((((((((int)digits[3]) << PyLong_SHIFT) | (int)digits[2]) << PyLong_SHIFT) | (int)digits[1]) << PyLong_SHIFT) | (int)digits[0])); } } break; } #endif #if CYTHON_COMPILING_IN_CPYTHON if (unlikely(Py_SIZE(x) < 0)) { goto raise_neg_overflow; } #else { int result = PyObject_RichCompareBool(x, Py_False, Py_LT); if (unlikely(result < 0)) return (int) -1; if (unlikely(result == 1)) goto raise_neg_overflow; } #endif if (sizeof(int) <= sizeof(unsigned long)) { __PYX_VERIFY_RETURN_INT_EXC(int, unsigned long, PyLong_AsUnsignedLong(x)) #ifdef HAVE_LONG_LONG } else if (sizeof(int) <= sizeof(unsigned PY_LONG_LONG)) { __PYX_VERIFY_RETURN_INT_EXC(int, unsigned PY_LONG_LONG, PyLong_AsUnsignedLongLong(x)) #endif } } else { #if CYTHON_USE_PYLONG_INTERNALS const digit* digits = ((PyLongObject*)x)->ob_digit; switch (Py_SIZE(x)) { case 0: return (int) 0; case -1: __PYX_VERIFY_RETURN_INT(int, sdigit, (sdigit) (-(sdigit)digits[0])) case 1: __PYX_VERIFY_RETURN_INT(int, digit, +digits[0]) case -2: if (8 * sizeof(int) - 1 > 1 * PyLong_SHIFT) { if (8 * sizeof(unsigned long) > 2 * PyLong_SHIFT) { __PYX_VERIFY_RETURN_INT(int, long, -(long) (((((unsigned long)digits[1]) << PyLong_SHIFT) | (unsigned long)digits[0]))) } else if (8 * sizeof(int) - 1 > 2 * PyLong_SHIFT) { return (int) (((int)-1)*(((((int)digits[1]) << PyLong_SHIFT) | (int)digits[0]))); } } break; case 2: if (8 * sizeof(int) > 1 * PyLong_SHIFT) { if (8 * sizeof(unsigned long) > 2 * PyLong_SHIFT) { __PYX_VERIFY_RETURN_INT(int, unsigned long, (((((unsigned long)digits[1]) << PyLong_SHIFT) | (unsigned long)digits[0]))) } else if (8 * sizeof(int) - 1 > 2 * PyLong_SHIFT) { return (int) ((((((int)digits[1]) << PyLong_SHIFT) | (int)digits[0]))); } } break; case -3: if (8 * sizeof(int) - 1 > 2 * PyLong_SHIFT) { if (8 * sizeof(unsigned long) > 3 * PyLong_SHIFT) { __PYX_VERIFY_RETURN_INT(int, long, -(long) (((((((unsigned long)digits[2]) << PyLong_SHIFT) | (unsigned long)digits[1]) << PyLong_SHIFT) | (unsigned long)digits[0]))) } else if (8 * sizeof(int) - 1 > 3 * PyLong_SHIFT) { return (int) (((int)-1)*(((((((int)digits[2]) << PyLong_SHIFT) | (int)digits[1]) << PyLong_SHIFT) | (int)digits[0]))); } } break; case 3: if (8 * sizeof(int) > 2 * PyLong_SHIFT) { if (8 * sizeof(unsigned long) > 3 * PyLong_SHIFT) { __PYX_VERIFY_RETURN_INT(int, unsigned long, (((((((unsigned long)digits[2]) << PyLong_SHIFT) | (unsigned long)digits[1]) << PyLong_SHIFT) | (unsigned long)digits[0]))) } else if (8 * sizeof(int) - 1 > 3 * PyLong_SHIFT) { return (int) ((((((((int)digits[2]) << PyLong_SHIFT) | (int)digits[1]) << PyLong_SHIFT) | (int)digits[0]))); } } break; case -4: if (8 * sizeof(int) - 1 > 3 * PyLong_SHIFT) { if (8 * sizeof(unsigned long) > 4 * PyLong_SHIFT) { __PYX_VERIFY_RETURN_INT(int, long, -(long) (((((((((unsigned long)digits[3]) << PyLong_SHIFT) | (unsigned long)digits[2]) << PyLong_SHIFT) | (unsigned long)digits[1]) << PyLong_SHIFT) | (unsigned long)digits[0]))) } else if (8 * sizeof(int) - 1 > 4 * PyLong_SHIFT) { return (int) (((int)-1)*(((((((((int)digits[3]) << PyLong_SHIFT) | (int)digits[2]) << PyLong_SHIFT) | (int)digits[1]) << PyLong_SHIFT) | (int)digits[0]))); } } break; case 4: if (8 * sizeof(int) > 3 * PyLong_SHIFT) { if (8 * sizeof(unsigned long) > 4 * PyLong_SHIFT) { __PYX_VERIFY_RETURN_INT(int, unsigned long, (((((((((unsigned long)digits[3]) << PyLong_SHIFT) | (unsigned long)digits[2]) << PyLong_SHIFT) | (unsigned long)digits[1]) << PyLong_SHIFT) | (unsigned long)digits[0]))) } else if (8 * sizeof(int) - 1 > 4 * PyLong_SHIFT) { return (int) ((((((((((int)digits[3]) << PyLong_SHIFT) | (int)digits[2]) << PyLong_SHIFT) | (int)digits[1]) << PyLong_SHIFT) | (int)digits[0]))); } } break; } #endif if (sizeof(int) <= sizeof(long)) { __PYX_VERIFY_RETURN_INT_EXC(int, long, PyLong_AsLong(x)) #ifdef HAVE_LONG_LONG } else if (sizeof(int) <= sizeof(PY_LONG_LONG)) { __PYX_VERIFY_RETURN_INT_EXC(int, PY_LONG_LONG, PyLong_AsLongLong(x)) #endif } } { #if CYTHON_COMPILING_IN_PYPY && !defined(_PyLong_AsByteArray) PyErr_SetString(PyExc_RuntimeError, "_PyLong_AsByteArray() not available in PyPy, cannot convert large numbers"); #else int val; PyObject *v = __Pyx_PyNumber_IntOrLong(x); #if PY_MAJOR_VERSION < 3 if (likely(v) && !PyLong_Check(v)) { PyObject *tmp = v; v = PyNumber_Long(tmp); Py_DECREF(tmp); } #endif if (likely(v)) { int one = 1; int is_little = (int)*(unsigned char *)&one; unsigned char *bytes = (unsigned char *)&val; int ret = _PyLong_AsByteArray((PyLongObject *)v, bytes, sizeof(val), is_little, !is_unsigned); Py_DECREF(v); if (likely(!ret)) return val; } #endif return (int) -1; } } else { int val; PyObject *tmp = __Pyx_PyNumber_IntOrLong(x); if (!tmp) return (int) -1; val = __Pyx_PyInt_As_int(tmp); Py_DECREF(tmp); return val; } raise_overflow: PyErr_SetString(PyExc_OverflowError, "value too large to convert to int"); return (int) -1; raise_neg_overflow: PyErr_SetString(PyExc_OverflowError, "can't convert negative value to int"); return (int) -1; } /* CIntToPy */ static CYTHON_INLINE PyObject* __Pyx_PyInt_From_int(int value) { #ifdef __Pyx_HAS_GCC_DIAGNOSTIC #pragma GCC diagnostic push #pragma GCC diagnostic ignored "-Wconversion" #endif const int neg_one = (int) -1, const_zero = (int) 0; #ifdef __Pyx_HAS_GCC_DIAGNOSTIC #pragma GCC diagnostic pop #endif const int is_unsigned = neg_one > const_zero; if (is_unsigned) { if (sizeof(int) < sizeof(long)) { return PyInt_FromLong((long) value); } else if (sizeof(int) <= sizeof(unsigned long)) { return PyLong_FromUnsignedLong((unsigned long) value); #ifdef HAVE_LONG_LONG } else if (sizeof(int) <= sizeof(unsigned PY_LONG_LONG)) { return PyLong_FromUnsignedLongLong((unsigned PY_LONG_LONG) value); #endif } } else { if (sizeof(int) <= sizeof(long)) { return PyInt_FromLong((long) value); #ifdef HAVE_LONG_LONG } else if (sizeof(int) <= sizeof(PY_LONG_LONG)) { return PyLong_FromLongLong((PY_LONG_LONG) value); #endif } } { int one = 1; int little = (int)*(unsigned char *)&one; unsigned char *bytes = (unsigned char *)&value; return _PyLong_FromByteArray(bytes, sizeof(int), little, !is_unsigned); } } /* CIntToPy */ static CYTHON_INLINE PyObject* __Pyx_PyInt_From_long(long value) { #ifdef __Pyx_HAS_GCC_DIAGNOSTIC #pragma GCC diagnostic push #pragma GCC diagnostic ignored "-Wconversion" #endif const long neg_one = (long) -1, const_zero = (long) 0; #ifdef __Pyx_HAS_GCC_DIAGNOSTIC #pragma GCC diagnostic pop #endif const int is_unsigned = neg_one > const_zero; if (is_unsigned) { if (sizeof(long) < sizeof(long)) { return PyInt_FromLong((long) value); } else if (sizeof(long) <= sizeof(unsigned long)) { return PyLong_FromUnsignedLong((unsigned long) value); #ifdef HAVE_LONG_LONG } else if (sizeof(long) <= sizeof(unsigned PY_LONG_LONG)) { return PyLong_FromUnsignedLongLong((unsigned PY_LONG_LONG) value); #endif } } else { if (sizeof(long) <= sizeof(long)) { return PyInt_FromLong((long) value); #ifdef HAVE_LONG_LONG } else if (sizeof(long) <= sizeof(PY_LONG_LONG)) { return PyLong_FromLongLong((PY_LONG_LONG) value); #endif } } { int one = 1; int little = (int)*(unsigned char *)&one; unsigned char *bytes = (unsigned char *)&value; return _PyLong_FromByteArray(bytes, sizeof(long), little, !is_unsigned); } } /* CIntFromPy */ static CYTHON_INLINE char __Pyx_PyInt_As_char(PyObject *x) { #ifdef __Pyx_HAS_GCC_DIAGNOSTIC #pragma GCC diagnostic push #pragma GCC diagnostic ignored "-Wconversion" #endif const char neg_one = (char) -1, const_zero = (char) 0; #ifdef __Pyx_HAS_GCC_DIAGNOSTIC #pragma GCC diagnostic pop #endif const int is_unsigned = neg_one > const_zero; #if PY_MAJOR_VERSION < 3 if (likely(PyInt_Check(x))) { if (sizeof(char) < sizeof(long)) { __PYX_VERIFY_RETURN_INT(char, long, PyInt_AS_LONG(x)) } else { long val = PyInt_AS_LONG(x); if (is_unsigned && unlikely(val < 0)) { goto raise_neg_overflow; } return (char) val; } } else #endif if (likely(PyLong_Check(x))) { if (is_unsigned) { #if CYTHON_USE_PYLONG_INTERNALS const digit* digits = ((PyLongObject*)x)->ob_digit; switch (Py_SIZE(x)) { case 0: return (char) 0; case 1: __PYX_VERIFY_RETURN_INT(char, digit, digits[0]) case 2: if (8 * sizeof(char) > 1 * PyLong_SHIFT) { if (8 * sizeof(unsigned long) > 2 * PyLong_SHIFT) { __PYX_VERIFY_RETURN_INT(char, unsigned long, (((((unsigned long)digits[1]) << PyLong_SHIFT) | (unsigned long)digits[0]))) } else if (8 * sizeof(char) >= 2 * PyLong_SHIFT) { return (char) (((((char)digits[1]) << PyLong_SHIFT) | (char)digits[0])); } } break; case 3: if (8 * sizeof(char) > 2 * PyLong_SHIFT) { if (8 * sizeof(unsigned long) > 3 * PyLong_SHIFT) { __PYX_VERIFY_RETURN_INT(char, unsigned long, (((((((unsigned long)digits[2]) << PyLong_SHIFT) | (unsigned long)digits[1]) << PyLong_SHIFT) | (unsigned long)digits[0]))) } else if (8 * sizeof(char) >= 3 * PyLong_SHIFT) { return (char) (((((((char)digits[2]) << PyLong_SHIFT) | (char)digits[1]) << PyLong_SHIFT) | (char)digits[0])); } } break; case 4: if (8 * sizeof(char) > 3 * PyLong_SHIFT) { if (8 * sizeof(unsigned long) > 4 * PyLong_SHIFT) { __PYX_VERIFY_RETURN_INT(char, unsigned long, (((((((((unsigned long)digits[3]) << PyLong_SHIFT) | (unsigned long)digits[2]) << PyLong_SHIFT) | (unsigned long)digits[1]) << PyLong_SHIFT) | (unsigned long)digits[0]))) } else if (8 * sizeof(char) >= 4 * PyLong_SHIFT) { return (char) (((((((((char)digits[3]) << PyLong_SHIFT) | (char)digits[2]) << PyLong_SHIFT) | (char)digits[1]) << PyLong_SHIFT) | (char)digits[0])); } } break; } #endif #if CYTHON_COMPILING_IN_CPYTHON if (unlikely(Py_SIZE(x) < 0)) { goto raise_neg_overflow; } #else { int result = PyObject_RichCompareBool(x, Py_False, Py_LT); if (unlikely(result < 0)) return (char) -1; if (unlikely(result == 1)) goto raise_neg_overflow; } #endif if (sizeof(char) <= sizeof(unsigned long)) { __PYX_VERIFY_RETURN_INT_EXC(char, unsigned long, PyLong_AsUnsignedLong(x)) #ifdef HAVE_LONG_LONG } else if (sizeof(char) <= sizeof(unsigned PY_LONG_LONG)) { __PYX_VERIFY_RETURN_INT_EXC(char, unsigned PY_LONG_LONG, PyLong_AsUnsignedLongLong(x)) #endif } } else { #if CYTHON_USE_PYLONG_INTERNALS const digit* digits = ((PyLongObject*)x)->ob_digit; switch (Py_SIZE(x)) { case 0: return (char) 0; case -1: __PYX_VERIFY_RETURN_INT(char, sdigit, (sdigit) (-(sdigit)digits[0])) case 1: __PYX_VERIFY_RETURN_INT(char, digit, +digits[0]) case -2: if (8 * sizeof(char) - 1 > 1 * PyLong_SHIFT) { if (8 * sizeof(unsigned long) > 2 * PyLong_SHIFT) { __PYX_VERIFY_RETURN_INT(char, long, -(long) (((((unsigned long)digits[1]) << PyLong_SHIFT) | (unsigned long)digits[0]))) } else if (8 * sizeof(char) - 1 > 2 * PyLong_SHIFT) { return (char) (((char)-1)*(((((char)digits[1]) << PyLong_SHIFT) | (char)digits[0]))); } } break; case 2: if (8 * sizeof(char) > 1 * PyLong_SHIFT) { if (8 * sizeof(unsigned long) > 2 * PyLong_SHIFT) { __PYX_VERIFY_RETURN_INT(char, unsigned long, (((((unsigned long)digits[1]) << PyLong_SHIFT) | (unsigned long)digits[0]))) } else if (8 * sizeof(char) - 1 > 2 * PyLong_SHIFT) { return (char) ((((((char)digits[1]) << PyLong_SHIFT) | (char)digits[0]))); } } break; case -3: if (8 * sizeof(char) - 1 > 2 * PyLong_SHIFT) { if (8 * sizeof(unsigned long) > 3 * PyLong_SHIFT) { __PYX_VERIFY_RETURN_INT(char, long, -(long) (((((((unsigned long)digits[2]) << PyLong_SHIFT) | (unsigned long)digits[1]) << PyLong_SHIFT) | (unsigned long)digits[0]))) } else if (8 * sizeof(char) - 1 > 3 * PyLong_SHIFT) { return (char) (((char)-1)*(((((((char)digits[2]) << PyLong_SHIFT) | (char)digits[1]) << PyLong_SHIFT) | (char)digits[0]))); } } break; case 3: if (8 * sizeof(char) > 2 * PyLong_SHIFT) { if (8 * sizeof(unsigned long) > 3 * PyLong_SHIFT) { __PYX_VERIFY_RETURN_INT(char, unsigned long, (((((((unsigned long)digits[2]) << PyLong_SHIFT) | (unsigned long)digits[1]) << PyLong_SHIFT) | (unsigned long)digits[0]))) } else if (8 * sizeof(char) - 1 > 3 * PyLong_SHIFT) { return (char) ((((((((char)digits[2]) << PyLong_SHIFT) | (char)digits[1]) << PyLong_SHIFT) | (char)digits[0]))); } } break; case -4: if (8 * sizeof(char) - 1 > 3 * PyLong_SHIFT) { if (8 * sizeof(unsigned long) > 4 * PyLong_SHIFT) { __PYX_VERIFY_RETURN_INT(char, long, -(long) (((((((((unsigned long)digits[3]) << PyLong_SHIFT) | (unsigned long)digits[2]) << PyLong_SHIFT) | (unsigned long)digits[1]) << PyLong_SHIFT) | (unsigned long)digits[0]))) } else if (8 * sizeof(char) - 1 > 4 * PyLong_SHIFT) { return (char) (((char)-1)*(((((((((char)digits[3]) << PyLong_SHIFT) | (char)digits[2]) << PyLong_SHIFT) | (char)digits[1]) << PyLong_SHIFT) | (char)digits[0]))); } } break; case 4: if (8 * sizeof(char) > 3 * PyLong_SHIFT) { if (8 * sizeof(unsigned long) > 4 * PyLong_SHIFT) { __PYX_VERIFY_RETURN_INT(char, unsigned long, (((((((((unsigned long)digits[3]) << PyLong_SHIFT) | (unsigned long)digits[2]) << PyLong_SHIFT) | (unsigned long)digits[1]) << PyLong_SHIFT) | (unsigned long)digits[0]))) } else if (8 * sizeof(char) - 1 > 4 * PyLong_SHIFT) { return (char) ((((((((((char)digits[3]) << PyLong_SHIFT) | (char)digits[2]) << PyLong_SHIFT) | (char)digits[1]) << PyLong_SHIFT) | (char)digits[0]))); } } break; } #endif if (sizeof(char) <= sizeof(long)) { __PYX_VERIFY_RETURN_INT_EXC(char, long, PyLong_AsLong(x)) #ifdef HAVE_LONG_LONG } else if (sizeof(char) <= sizeof(PY_LONG_LONG)) { __PYX_VERIFY_RETURN_INT_EXC(char, PY_LONG_LONG, PyLong_AsLongLong(x)) #endif } } { #if CYTHON_COMPILING_IN_PYPY && !defined(_PyLong_AsByteArray) PyErr_SetString(PyExc_RuntimeError, "_PyLong_AsByteArray() not available in PyPy, cannot convert large numbers"); #else char val; PyObject *v = __Pyx_PyNumber_IntOrLong(x); #if PY_MAJOR_VERSION < 3 if (likely(v) && !PyLong_Check(v)) { PyObject *tmp = v; v = PyNumber_Long(tmp); Py_DECREF(tmp); } #endif if (likely(v)) { int one = 1; int is_little = (int)*(unsigned char *)&one; unsigned char *bytes = (unsigned char *)&val; int ret = _PyLong_AsByteArray((PyLongObject *)v, bytes, sizeof(val), is_little, !is_unsigned); Py_DECREF(v); if (likely(!ret)) return val; } #endif return (char) -1; } } else { char val; PyObject *tmp = __Pyx_PyNumber_IntOrLong(x); if (!tmp) return (char) -1; val = __Pyx_PyInt_As_char(tmp); Py_DECREF(tmp); return val; } raise_overflow: PyErr_SetString(PyExc_OverflowError, "value too large to convert to char"); return (char) -1; raise_neg_overflow: PyErr_SetString(PyExc_OverflowError, "can't convert negative value to char"); return (char) -1; } /* CheckBinaryVersion */ static int __Pyx_check_binary_version(void) { char ctversion[4], rtversion[4]; PyOS_snprintf(ctversion, 4, "%d.%d", PY_MAJOR_VERSION, PY_MINOR_VERSION); PyOS_snprintf(rtversion, 4, "%s", Py_GetVersion()); if (ctversion[0] != rtversion[0] || ctversion[2] != rtversion[2]) { char message[200]; PyOS_snprintf(message, sizeof(message), "compiletime version %s of module '%.100s' " "does not match runtime version %s", ctversion, __Pyx_MODULE_NAME, rtversion); return PyErr_WarnEx(NULL, message, 1); } return 0; } /* InitStrings */ static int __Pyx_InitStrings(__Pyx_StringTabEntry *t) { while (t->p) { #if PY_MAJOR_VERSION < 3 if (t->is_unicode) { *t->p = PyUnicode_DecodeUTF8(t->s, t->n - 1, NULL); } else if (t->intern) { *t->p = PyString_InternFromString(t->s); } else { *t->p = PyString_FromStringAndSize(t->s, t->n - 1); } #else if (t->is_unicode | t->is_str) { if (t->intern) { *t->p = PyUnicode_InternFromString(t->s); } else if (t->encoding) { *t->p = PyUnicode_Decode(t->s, t->n - 1, t->encoding, NULL); } else { *t->p = PyUnicode_FromStringAndSize(t->s, t->n - 1); } } else { *t->p = PyBytes_FromStringAndSize(t->s, t->n - 1); } #endif if (!*t->p) return -1; if (PyObject_Hash(*t->p) == -1) return -1; ++t; } return 0; } static CYTHON_INLINE PyObject* __Pyx_PyUnicode_FromString(const char* c_str) { return __Pyx_PyUnicode_FromStringAndSize(c_str, (Py_ssize_t)strlen(c_str)); } static CYTHON_INLINE const char* __Pyx_PyObject_AsString(PyObject* o) { Py_ssize_t ignore; return __Pyx_PyObject_AsStringAndSize(o, &ignore); } #if __PYX_DEFAULT_STRING_ENCODING_IS_ASCII || __PYX_DEFAULT_STRING_ENCODING_IS_DEFAULT #if !CYTHON_PEP393_ENABLED static const char* __Pyx_PyUnicode_AsStringAndSize(PyObject* o, Py_ssize_t *length) { char* defenc_c; PyObject* defenc = _PyUnicode_AsDefaultEncodedString(o, NULL); if (!defenc) return NULL; defenc_c = PyBytes_AS_STRING(defenc); #if __PYX_DEFAULT_STRING_ENCODING_IS_ASCII { char* end = defenc_c + PyBytes_GET_SIZE(defenc); char* c; for (c = defenc_c; c < end; c++) { if ((unsigned char) (*c) >= 128) { PyUnicode_AsASCIIString(o); return NULL; } } } #endif *length = PyBytes_GET_SIZE(defenc); return defenc_c; } #else static CYTHON_INLINE const char* __Pyx_PyUnicode_AsStringAndSize(PyObject* o, Py_ssize_t *length) { if (unlikely(__Pyx_PyUnicode_READY(o) == -1)) return NULL; #if __PYX_DEFAULT_STRING_ENCODING_IS_ASCII if (likely(PyUnicode_IS_ASCII(o))) { *length = PyUnicode_GET_LENGTH(o); return PyUnicode_AsUTF8(o); } else { PyUnicode_AsASCIIString(o); return NULL; } #else return PyUnicode_AsUTF8AndSize(o, length); #endif } #endif #endif static CYTHON_INLINE const char* __Pyx_PyObject_AsStringAndSize(PyObject* o, Py_ssize_t *length) { #if __PYX_DEFAULT_STRING_ENCODING_IS_ASCII || __PYX_DEFAULT_STRING_ENCODING_IS_DEFAULT if ( #if PY_MAJOR_VERSION < 3 && __PYX_DEFAULT_STRING_ENCODING_IS_ASCII __Pyx_sys_getdefaultencoding_not_ascii && #endif PyUnicode_Check(o)) { return __Pyx_PyUnicode_AsStringAndSize(o, length); } else #endif #if (!CYTHON_COMPILING_IN_PYPY) || (defined(PyByteArray_AS_STRING) && defined(PyByteArray_GET_SIZE)) if (PyByteArray_Check(o)) { *length = PyByteArray_GET_SIZE(o); return PyByteArray_AS_STRING(o); } else #endif { char* result; int r = PyBytes_AsStringAndSize(o, &result, length); if (unlikely(r < 0)) { return NULL; } else { return result; } } } static CYTHON_INLINE int __Pyx_PyObject_IsTrue(PyObject* x) { int is_true = x == Py_True; if (is_true | (x == Py_False) | (x == Py_None)) return is_true; else return PyObject_IsTrue(x); } static CYTHON_INLINE int __Pyx_PyObject_IsTrueAndDecref(PyObject* x) { int retval; if (unlikely(!x)) return -1; retval = __Pyx_PyObject_IsTrue(x); Py_DECREF(x); return retval; } static PyObject* __Pyx_PyNumber_IntOrLongWrongResultType(PyObject* result, const char* type_name) { #if PY_MAJOR_VERSION >= 3 if (PyLong_Check(result)) { if (PyErr_WarnFormat(PyExc_DeprecationWarning, 1, "__int__ returned non-int (type %.200s). " "The ability to return an instance of a strict subclass of int " "is deprecated, and may be removed in a future version of Python.", Py_TYPE(result)->tp_name)) { Py_DECREF(result); return NULL; } return result; } #endif PyErr_Format(PyExc_TypeError, "__%.4s__ returned non-%.4s (type %.200s)", type_name, type_name, Py_TYPE(result)->tp_name); Py_DECREF(result); return NULL; } static CYTHON_INLINE PyObject* __Pyx_PyNumber_IntOrLong(PyObject* x) { #if CYTHON_USE_TYPE_SLOTS PyNumberMethods *m; #endif const char *name = NULL; PyObject *res = NULL; #if PY_MAJOR_VERSION < 3 if (likely(PyInt_Check(x) || PyLong_Check(x))) #else if (likely(PyLong_Check(x))) #endif return __Pyx_NewRef(x); #if CYTHON_USE_TYPE_SLOTS m = Py_TYPE(x)->tp_as_number; #if PY_MAJOR_VERSION < 3 if (m && m->nb_int) { name = "int"; res = m->nb_int(x); } else if (m && m->nb_long) { name = "long"; res = m->nb_long(x); } #else if (likely(m && m->nb_int)) { name = "int"; res = m->nb_int(x); } #endif #else if (!PyBytes_CheckExact(x) && !PyUnicode_CheckExact(x)) { res = PyNumber_Int(x); } #endif if (likely(res)) { #if PY_MAJOR_VERSION < 3 if (unlikely(!PyInt_Check(res) && !PyLong_Check(res))) { #else if (unlikely(!PyLong_CheckExact(res))) { #endif return __Pyx_PyNumber_IntOrLongWrongResultType(res, name); } } else if (!PyErr_Occurred()) { PyErr_SetString(PyExc_TypeError, "an integer is required"); } return res; } static CYTHON_INLINE Py_ssize_t __Pyx_PyIndex_AsSsize_t(PyObject* b) { Py_ssize_t ival; PyObject *x; #if PY_MAJOR_VERSION < 3 if (likely(PyInt_CheckExact(b))) { if (sizeof(Py_ssize_t) >= sizeof(long)) return PyInt_AS_LONG(b); else return PyInt_AsSsize_t(b); } #endif if (likely(PyLong_CheckExact(b))) { #if CYTHON_USE_PYLONG_INTERNALS const digit* digits = ((PyLongObject*)b)->ob_digit; const Py_ssize_t size = Py_SIZE(b); if (likely(__Pyx_sst_abs(size) <= 1)) { ival = likely(size) ? digits[0] : 0; if (size == -1) ival = -ival; return ival; } else { switch (size) { case 2: if (8 * sizeof(Py_ssize_t) > 2 * PyLong_SHIFT) { return (Py_ssize_t) (((((size_t)digits[1]) << PyLong_SHIFT) | (size_t)digits[0])); } break; case -2: if (8 * sizeof(Py_ssize_t) > 2 * PyLong_SHIFT) { return -(Py_ssize_t) (((((size_t)digits[1]) << PyLong_SHIFT) | (size_t)digits[0])); } break; case 3: if (8 * sizeof(Py_ssize_t) > 3 * PyLong_SHIFT) { return (Py_ssize_t) (((((((size_t)digits[2]) << PyLong_SHIFT) | (size_t)digits[1]) << PyLong_SHIFT) | (size_t)digits[0])); } break; case -3: if (8 * sizeof(Py_ssize_t) > 3 * PyLong_SHIFT) { return -(Py_ssize_t) (((((((size_t)digits[2]) << PyLong_SHIFT) | (size_t)digits[1]) << PyLong_SHIFT) | (size_t)digits[0])); } break; case 4: if (8 * sizeof(Py_ssize_t) > 4 * PyLong_SHIFT) { return (Py_ssize_t) (((((((((size_t)digits[3]) << PyLong_SHIFT) | (size_t)digits[2]) << PyLong_SHIFT) | (size_t)digits[1]) << PyLong_SHIFT) | (size_t)digits[0])); } break; case -4: if (8 * sizeof(Py_ssize_t) > 4 * PyLong_SHIFT) { return -(Py_ssize_t) (((((((((size_t)digits[3]) << PyLong_SHIFT) | (size_t)digits[2]) << PyLong_SHIFT) | (size_t)digits[1]) << PyLong_SHIFT) | (size_t)digits[0])); } break; } } #endif return PyLong_AsSsize_t(b); } x = PyNumber_Index(b); if (!x) return -1; ival = PyInt_AsSsize_t(x); Py_DECREF(x); return ival; } static CYTHON_INLINE Py_hash_t __Pyx_PyIndex_AsHash_t(PyObject* o) { if (sizeof(Py_hash_t) == sizeof(Py_ssize_t)) { return (Py_hash_t) __Pyx_PyIndex_AsSsize_t(o); #if PY_MAJOR_VERSION < 3 } else if (likely(PyInt_CheckExact(o))) { return PyInt_AS_LONG(o); #endif } else { Py_ssize_t ival; PyObject *x; x = PyNumber_Index(o); if (!x) return -1; ival = PyInt_AsLong(x); Py_DECREF(x); return ival; } } static CYTHON_INLINE PyObject * __Pyx_PyBool_FromLong(long b) { return b ? __Pyx_NewRef(Py_True) : __Pyx_NewRef(Py_False); } static CYTHON_INLINE PyObject * __Pyx_PyInt_FromSize_t(size_t ival) { return PyInt_FromSize_t(ival); } #endif /* Py_PYTHON_H */

GB_unaryop__identity_int16_uint64.c

//------------------------------------------------------------------------------ // GB_unaryop: hard-coded functions for each built-in unary operator //------------------------------------------------------------------------------ // SuiteSparse:GraphBLAS, Timothy A. Davis, (c) 2017-2020, All Rights Reserved. // http://suitesparse.com See GraphBLAS/Doc/License.txt for license. //------------------------------------------------------------------------------ // If this file is in the Generated/ folder, do not edit it (auto-generated). #include "GB.h" #ifndef GBCOMPACT #include "GB_control.h" #include "GB_iterator.h" #include "GB_unaryop__include.h" // C=unop(A) is defined by the following types and operators: // op(A) function: GB_unop__identity_int16_uint64 // op(A') function: GB_tran__identity_int16_uint64 // C type: int16_t // A type: uint64_t // cast: int16_t cij = (int16_t) aij // unaryop: cij = aij #define GB_ATYPE \ uint64_t #define GB_CTYPE \ int16_t // aij = Ax [pA] #define GB_GETA(aij,Ax,pA) \ uint64_t aij = Ax [pA] #define GB_CX(p) Cx [p] // unary operator #define GB_OP(z, x) \ z = x ; // casting #define GB_CASTING(z, aij) \ int16_t z = (int16_t) aij ; // cij = op (cast (aij)) #define GB_CAST_OP(pC,pA) \ { \ /* aij = Ax [pA] */ \ GB_GETA (aij, Ax, pA) ; \ /* Cx [pC] = op (cast (aij)) */ \ GB_CASTING (z, aij) ; \ GB_OP (GB_CX (pC), z) ; \ } // disable this operator and use the generic case if these conditions hold #define GB_DISABLE \ (GxB_NO_IDENTITY || GxB_NO_INT16 || GxB_NO_UINT64) //------------------------------------------------------------------------------ // Cx = op (cast (Ax)): apply a unary operator //------------------------------------------------------------------------------ GrB_Info GB_unop__identity_int16_uint64 ( int16_t *Cx, // Cx and Ax may be aliased uint64_t *Ax, int64_t anz, int nthreads ) { #if GB_DISABLE return (GrB_NO_VALUE) ; #else int64_t p ; #pragma omp parallel for num_threads(nthreads) schedule(static) for (p = 0 ; p < anz ; p++) { GB_CAST_OP (p, p) ; } return (GrB_SUCCESS) ; #endif } //------------------------------------------------------------------------------ // C = op (cast (A')): transpose, typecast, and apply a unary operator //------------------------------------------------------------------------------ GrB_Info GB_tran__identity_int16_uint64 ( GrB_Matrix C, const GrB_Matrix A, int64_t *GB_RESTRICT *Rowcounts, GBI_single_iterator Iter, const int64_t *GB_RESTRICT A_slice, int naslice ) { #if GB_DISABLE return (GrB_NO_VALUE) ; #else #define GB_PHASE_2_OF_2 #include "GB_unaryop_transpose.c" return (GrB_SUCCESS) ; #endif } #endif

3d25pt.lbpar.c

#include <omp.h> #include <math.h> #define ceild(n,d) ceil(((double)(n))/((double)(d))) #define floord(n,d) floor(((double)(n))/((double)(d))) #define max(x,y) ((x) > (y)? (x) : (y)) #define min(x,y) ((x) < (y)? (x) : (y)) /* * Order-2, 3D 25 point stencil * Adapted from PLUTO and Pochoir test bench * * Tareq Malas */ #include <stdio.h> #include <stdlib.h> #include <sys/time.h> #ifdef LIKWID_PERFMON #include <likwid.h> #endif #include "print_utils.h" #define TESTS 2 #define MAX(a,b) ((a) > (b) ? a : b) #define MIN(a,b) ((a) < (b) ? a : b) #ifndef min #define min(x,y) ((x) < (y)? (x) : (y)) #endif /* Subtract the `struct timeval' values X and Y, * storing the result in RESULT. * * Return 1 if the difference is negative, otherwise 0. */ int timeval_subtract(struct timeval *result, struct timeval *x, struct timeval *y) { /* Perform the carry for the later subtraction by updating y. */ if (x->tv_usec < y->tv_usec) { int nsec = (y->tv_usec - x->tv_usec) / 1000000 + 1; y->tv_usec -= 1000000 * nsec; y->tv_sec += nsec; } if (x->tv_usec - y->tv_usec > 1000000) { int nsec = (x->tv_usec - y->tv_usec) / 1000000; y->tv_usec += 1000000 * nsec; y->tv_sec -= nsec; } /* Compute the time remaining to wait. * tv_usec is certainly positive. */ result->tv_sec = x->tv_sec - y->tv_sec; result->tv_usec = x->tv_usec - y->tv_usec; /* Return 1 if result is negative. */ return x->tv_sec < y->tv_sec; } int main(int argc, char *argv[]) { int t, i, j, k, test; int Nx, Ny, Nz, Nt; if (argc > 3) { Nx = atoi(argv[1])+8; Ny = atoi(argv[2])+8; Nz = atoi(argv[3])+8; } if (argc > 4) Nt = atoi(argv[4]); double ****A = (double ****) malloc(sizeof(double***)*2); double ***roc2 = (double ***) malloc(sizeof(double**)); A[0] = (double ***) malloc(sizeof(double**)*Nz); A[1] = (double ***) malloc(sizeof(double**)*Nz); roc2 = (double ***) malloc(sizeof(double**)*Nz); for(i=0; i<Nz; i++){ A[0][i] = (double**) malloc(sizeof(double*)*Ny); A[1][i] = (double**) malloc(sizeof(double*)*Ny); roc2[i] = (double**) malloc(sizeof(double*)*Ny); for(j=0;j<Ny;j++){ A[0][i][j] = (double*) malloc(sizeof(double)*Nx); A[1][i][j] = (double*) malloc(sizeof(double)*Nx); roc2[i][j] = (double*) malloc(sizeof(double)*Nx); } } // tile size information, including extra element to decide the list length int *tile_size = (int*) malloc(sizeof(int)); tile_size[0] = -1; // The list is modified here before source-to-source transformations tile_size = (int*) realloc((void *)tile_size, sizeof(int)*5); tile_size[0] = 8; tile_size[1] = 8; tile_size[2] = 16; tile_size[3] = 1024; tile_size[4] = -1; // for timekeeping int ts_return = -1; struct timeval start, end, result; double tdiff = 0.0, min_tdiff=1.e100; const int BASE = 1024; // initialize variables // srand(42); for (i = 1; i < Nz; i++) { for (j = 1; j < Ny; j++) { for (k = 1; k < Nx; k++) { A[0][i][j][k] = 1.0 * (rand() % BASE); roc2[i][j][k] = 2.0 * (rand() % BASE); } } } #ifdef LIKWID_PERFMON LIKWID_MARKER_INIT; #pragma omp parallel { LIKWID_MARKER_THREADINIT; #pragma omp barrier LIKWID_MARKER_START("calc"); } #endif int num_threads = 1; #if defined(_OPENMP) num_threads = omp_get_max_threads(); #endif const double coef0 = -0.28472; const double coef1 = 0.16000; const double coef2 = -0.02000; const double coef3 = 0.00254; const double coef4 = -0.00018; for(test=0; test<TESTS; test++){ gettimeofday(&start, 0); // serial execution - Addition: 6 && Multiplication: 2 /* Copyright (C) 1991-2014 Free Software Foundation, Inc. This file is part of the GNU C Library. The GNU C Library is free software; you can redistribute it and/or modify it under the terms of the GNU Lesser General Public License as published by the Free Software Foundation; either version 2.1 of the License, or (at your option) any later version. The GNU C Library is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU Lesser General Public License for more details. You should have received a copy of the GNU Lesser General Public License along with the GNU C Library; if not, see <http://www.gnu.org/licenses/>. */ /* This header is separate from features.h so that the compiler can include it implicitly at the start of every compilation. It must not itself include <features.h> or any other header that includes <features.h> because the implicit include comes before any feature test macros that may be defined in a source file before it first explicitly includes a system header. GCC knows the name of this header in order to preinclude it. */ /* glibc's intent is to support the IEC 559 math functionality, real and complex. If the GCC (4.9 and later) predefined macros specifying compiler intent are available, use them to determine whether the overall intent is to support these features; otherwise, presume an older compiler has intent to support these features and define these macros by default. */ /* wchar_t uses ISO/IEC 10646 (2nd ed., published 2011-03-15) / Unicode 6.0. */ /* We do not support C11 <threads.h>. */ int t1, t2, t3, t4, t5, t6, t7, t8; int lb, ub, lbp, ubp, lb2, ub2; register int lbv, ubv; /* Start of CLooG code */ if ((Nt >= 1) && (Nx >= 9) && (Ny >= 9) && (Nz >= 9)) { for (t1=-1;t1<=Nt-1;t1++) { lbp=ceild(t1+1,2); ubp=min(floord(4*Nt+Nz-9,8),floord(4*t1+Nz-2,8)); #pragma omp parallel for private(lbv,ubv,t3,t4,t5,t6,t7,t8) for (t2=lbp;t2<=ubp;t2++) { for (t3=max(ceild(t1-2,4),ceild(8*t2-Nz-3,16));t3<=min(floord(4*Nt+Ny-9,16),floord(4*t1+Ny-1,16));t3++) { for (t4=max(max(ceild(t1-254,256),ceild(8*t2-Nz-1011,1024)),ceild(16*t3-Ny-1011,1024));t4<=min(min(floord(4*Nt+Nx-9,1024),floord(4*t1+Nx-1,1024)),floord(16*t3+Nx+3,1024));t4++) { for (t5=max(max(max(max(0,ceild(8*t2-Nz+5,4)),ceild(16*t3-Ny+5,4)),ceild(1024*t4-Nx+5,4)),t1);t5<=min(min(min(Nt-1,t1+1),4*t3+2),256*t4+254);t5++) { for (t6=max(max(8*t2,4*t5+4),-8*t1+8*t2+8*t5-7);t6<=min(min(8*t2+7,-8*t1+8*t2+8*t5),4*t5+Nz-5);t6++) { for (t7=max(16*t3,4*t5+4);t7<=min(16*t3+15,4*t5+Ny-5);t7++) { lbv=max(1024*t4,4*t5+4); ubv=min(1024*t4+1023,4*t5+Nx-5); #pragma ivdep #pragma vector always for (t8=lbv;t8<=ubv;t8++) { A[( t5 + 1) % 2][ (-4*t5+t6)][ (-4*t5+t7)][ (-4*t5+t8)] = (((2.0 * A[ t5 % 2][ (-4*t5+t6)][ (-4*t5+t7)][ (-4*t5+t8)]) - A[( t5 + 1) % 2][ (-4*t5+t6)][ (-4*t5+t7)][ (-4*t5+t8)]) + (roc2[ (-4*t5+t6)][ (-4*t5+t7)][ (-4*t5+t8)] * (((((coef0 * A[ t5 % 2][ (-4*t5+t6)][ (-4*t5+t7)][ (-4*t5+t8)]) + (coef1 * (((((A[ t5 % 2][ (-4*t5+t6) - 1][ (-4*t5+t7)][ (-4*t5+t8)] + A[ t5 % 2][ (-4*t5+t6) + 1][ (-4*t5+t7)][ (-4*t5+t8)]) + A[ t5 % 2][ (-4*t5+t6)][ (-4*t5+t7) - 1][ (-4*t5+t8)]) + A[ t5 % 2][ (-4*t5+t6)][ (-4*t5+t7) + 1][ (-4*t5+t8)]) + A[ t5 % 2][ (-4*t5+t6)][ (-4*t5+t7)][ (-4*t5+t8) - 1]) + A[ t5 % 2][ (-4*t5+t6)][ (-4*t5+t7)][ (-4*t5+t8) + 1]))) + (coef2 * (((((A[ t5 % 2][ (-4*t5+t6) - 2][ (-4*t5+t7)][ (-4*t5+t8)] + A[ t5 % 2][ (-4*t5+t6) + 2][ (-4*t5+t7)][ (-4*t5+t8)]) + A[ t5 % 2][ (-4*t5+t6)][ (-4*t5+t7) - 2][ (-4*t5+t8)]) + A[ t5 % 2][ (-4*t5+t6)][ (-4*t5+t7) + 2][ (-4*t5+t8)]) + A[ t5 % 2][ (-4*t5+t6)][ (-4*t5+t7)][ (-4*t5+t8) - 2]) + A[ t5 % 2][ (-4*t5+t6)][ (-4*t5+t7)][ (-4*t5+t8) + 2]))) + (coef3 * (((((A[ t5 % 2][ (-4*t5+t6) - 3][ (-4*t5+t7)][ (-4*t5+t8)] + A[ t5 % 2][ (-4*t5+t6) + 3][ (-4*t5+t7)][ (-4*t5+t8)]) + A[ t5 % 2][ (-4*t5+t6)][ (-4*t5+t7) - 3][ (-4*t5+t8)]) + A[ t5 % 2][ (-4*t5+t6)][ (-4*t5+t7) + 3][ (-4*t5+t8)]) + A[ t5 % 2][ (-4*t5+t6)][ (-4*t5+t7)][ (-4*t5+t8) - 3]) + A[ t5 % 2][ (-4*t5+t6)][ (-4*t5+t7)][ (-4*t5+t8) + 3]))) + (coef4 * (((((A[ t5 % 2][ (-4*t5+t6) - 4][ (-4*t5+t7)][ (-4*t5+t8)] + A[ t5 % 2][ (-4*t5+t6) + 4][ (-4*t5+t7)][ (-4*t5+t8)]) + A[ t5 % 2][ (-4*t5+t6)][ (-4*t5+t7) - 4][ (-4*t5+t8)]) + A[ t5 % 2][ (-4*t5+t6)][ (-4*t5+t7) + 4][ (-4*t5+t8)]) + A[ t5 % 2][ (-4*t5+t6)][ (-4*t5+t7)][ (-4*t5+t8) - 4]) + A[ t5 % 2][ (-4*t5+t6)][ (-4*t5+t7)][ (-4*t5+t8) + 4])))));; } } } } } } } } } /* End of CLooG code */ gettimeofday(&end, 0); ts_return = timeval_subtract(&result, &end, &start); tdiff = (double) (result.tv_sec + result.tv_usec * 1.0e-6); min_tdiff = MIN(min_tdiff, tdiff); printf("Rank 0 TEST# %d time: %f\n", test, tdiff); } PRINT_RESULTS(4, "constant") #ifdef LIKWID_PERFMON #pragma omp parallel { LIKWID_MARKER_STOP("calc"); } LIKWID_MARKER_CLOSE; #endif // Free allocated arrays for(i=0; i<Nz; i++){ for(j=0;j<Ny;j++){ free(A[0][i][j]); free(A[1][i][j]); free(roc2[i][j]); } free(A[0][i]); free(A[1][i]); free(roc2[i]); } free(A[0]); free(A[1]); free(roc2); return 0; }

3d7pt_var.c

/* * Order-1, 3D 7 point stencil with variable coefficients * Adapted from PLUTO and Pochoir test bench * * Tareq Malas */ #include <stdio.h> #include <stdlib.h> #include <sys/time.h> #ifdef LIKWID_PERFMON #include <likwid.h> #endif #include "print_utils.h" #define TESTS 2 #define MAX(a,b) ((a) > (b) ? a : b) #define MIN(a,b) ((a) < (b) ? a : b) /* Subtract the `struct timeval' values X and Y, * storing the result in RESULT. * * Return 1 if the difference is negative, otherwise 0. */ int timeval_subtract(struct timeval *result, struct timeval *x, struct timeval *y) { /* Perform the carry for the later subtraction by updating y. */ if (x->tv_usec < y->tv_usec) { int nsec = (y->tv_usec - x->tv_usec) / 1000000 + 1; y->tv_usec -= 1000000 * nsec; y->tv_sec += nsec; } if (x->tv_usec - y->tv_usec > 1000000) { int nsec = (x->tv_usec - y->tv_usec) / 1000000; y->tv_usec += 1000000 * nsec; y->tv_sec -= nsec; } /* Compute the time remaining to wait. * tv_usec is certainly positive. */ result->tv_sec = x->tv_sec - y->tv_sec; result->tv_usec = x->tv_usec - y->tv_usec; /* Return 1 if result is negative. */ return x->tv_sec < y->tv_sec; } int main(int argc, char *argv[]) { int t, i, j, k, m, test; int Nx, Ny, Nz, Nt; if (argc > 3) { Nx = atoi(argv[1])+2; Ny = atoi(argv[2])+2; Nz = atoi(argv[3])+2; } if (argc > 4) Nt = atoi(argv[4]); // allocate the arrays double ****A = (double ****) malloc(sizeof(double***)*2); for(m=0; m<2;m++){ A[m] = (double ***) malloc(sizeof(double**)*Nz); for(i=0; i<Nz; i++){ A[m][i] = (double**) malloc(sizeof(double*)*Ny); for(j=0;j<Ny;j++){ A[m][i][j] = (double*) malloc(sizeof(double)*Nx); } } } double ****coef = (double ****) malloc(sizeof(double***)*7); for(m=0; m<7;m++){ coef[m] = (double ***) malloc(sizeof(double**)*Nz); for(i=0; i<Nz; i++){ coef[m][i] = (double**) malloc(sizeof(double*)*Ny); for(j=0;j<Ny;j++){ coef[m][i][j] = (double*) malloc(sizeof(double)*Nx); } } } // tile size information, including extra element to decide the list length int *tile_size = (int*) malloc(sizeof(int)); tile_size[0] = -1; // The list is modified here before source-to-source transformations tile_size = (int*) realloc((void *)tile_size, sizeof(int)*5); tile_size[0] = 16; tile_size[1] = 16; tile_size[2] = 16; tile_size[3] = 512; tile_size[4] = -1; // for timekeeping int ts_return = -1; struct timeval start, end, result; double tdiff = 0.0, min_tdiff=1.e100; const int BASE = 1024; // initialize variables // srand(42); for (i = 1; i < Nz; i++) { for (j = 1; j < Ny; j++) { for (k = 1; k < Nx; k++) { A[0][i][j][k] = 1.0 * (rand() % BASE); } } } for (m=0; m<7; m++) { for (i=1; i<Nz; i++) { for (j=1; j<Ny; j++) { for (k=1; k<Nx; k++) { coef[m][i][j][k] = 1.0 * (rand() % BASE); } } } } #ifdef LIKWID_PERFMON LIKWID_MARKER_INIT; #pragma omp parallel { LIKWID_MARKER_THREADINIT; #pragma omp barrier LIKWID_MARKER_START("calc"); } #endif int num_threads = 1; #if defined(_OPENMP) num_threads = omp_get_max_threads(); #endif for(test=0; test<TESTS; test++){ gettimeofday(&start, 0); // serial execution - Addition: 6 && Multiplication: 2 #pragma scop for (t = 0; t < Nt-1; t++) { for (i = 1; i < Nz-1; i++) { for (j = 1; j < Ny-1; j++) { for (k = 1; k < Nx-1; k++) { A[(t+1)%2][i][j][k] = coef[0][i][j][k] * A[t%2][i ][j ][k ] + coef[1][i][j][k] * A[t%2][i-1][j ][k ] + coef[2][i][j][k] * A[t%2][i ][j-1][k ] + coef[3][i][j][k] * A[t%2][i ][j ][k-1] + coef[4][i][j][k] * A[t%2][i+1][j ][k ] + coef[5][i][j][k] * A[t%2][i ][j+1][k ] + coef[6][i][j][k] * A[t%2][i ][j ][k+1]; } } } } #pragma endscop gettimeofday(&end, 0); ts_return = timeval_subtract(&result, &end, &start); tdiff = (double) (result.tv_sec + result.tv_usec * 1.0e-6); min_tdiff = min(min_tdiff, tdiff); printf("Rank 0 TEST# %d time: %f\n", test, tdiff); } PRINT_RESULTS(1, "variable no-symmetry") #ifdef LIKWID_PERFMON #pragma omp parallel { LIKWID_MARKER_STOP("calc"); } LIKWID_MARKER_CLOSE; #endif // Free allocated arrays for(i=0; i<Nz; i++){ for(j=0;j<Ny;j++){ free(A[0][i][j]); free(A[1][i][j]); } free(A[0][i]); free(A[1][i]); } free(A[0]); free(A[1]); for(m=0; m<7;m++){ for(i=0; i<Nz; i++){ for(j=0;j<Ny;j++){ free(coef[m][i][j]); } free(coef[m][i]); } free(coef[m]); } return 0; }

for.c

#include <omp.h> #include <stdio.h> #define CHUNKSIZE 10 #define N 100 main () { int i, chunk; float a[N], b[N], c[N]; /* Some initializations */ for (i=0; i < N; i++) a[i] = b[i] = i * 1.0; chunk = CHUNKSIZE; #pragma omp parallel shared(a,b,c,chunk) private(i) { #pragma omp for schedule(dynamic,chunk) for (i=0; i < N; i++) c[i] = a[i] + b[i]; } /* end of parallel section */ for (i=0; i<N; i++) printf("c[%d] = %3.1f\n", i, c[i]); }

master.c

// OpenMP Master Example #include <omp.h> #include <stdio.h> #include <stdlib.h> int main( int argc, char** argv ) { int num_threads = 0; // Number of Threads int thread_id = 0; // ID Number of Running Thread #pragma omp parallel private( num_threads, thread_id ) { // Get the Thread Number thread_id = omp_get_thread_num( ); printf( "Hello World from Thread %d\n", thread_id ); // Have Master Print Total Number of Threads Used #pragma omp master { num_threads = omp_get_num_threads( ); printf( "Number of Threads = %d\n", num_threads ); } } return 0; } // End master.c - EWG SDG

merge_tasks_unnested.c

#include <stdlib.h> #include <stdio.h> #include <string.h> #include <omp.h> /* OpenMP Parallel Mergesort - STasking * * @author: ANDREW VAILLANCOURT * 2019 */ void merge(int a[], int size, int temp[]); void insertion_sort(int a[], int size); void mergesort_serial(int a[], int size, int temp[], int thresh); void mergesort_parallel_omp(int a[], int size, int temp[], int threads, int thresh); void run_omp(int a[], int size, int temp[], int threads, int thresh); void par_mergesort (int a[], int size, int temp[], int threads, int thresh); int main(int argc, char *argv[]) { if (argc != 4) { printf("Usage: %s array_size threshold num_threads\n", argv[0]); return 1; } int size = atoi(argv[1]); // Array size int thresh = atoi(argv[2]); // point at which sort switches to insertion int threads = atoi(argv[3]); // Requested number of threads double start, end; // Check nested parallelism availability omp_set_nested(1); if (omp_get_nested() != 1) { puts("Warning: Nested parallelism desired but unavailable"); } // Check processors and threads int processors = omp_get_num_procs(); // Available processors if (threads > processors) { printf("Warning: %d threads requested, will run_omp on %d processors available\n",threads, processors); omp_set_num_threads(threads); } int max_threads = omp_get_max_threads(); // Max available threads if (threads > max_threads) // Requested threads are more than max available { printf("Error: Cannot use %d threads, only %d threads available\n", threads, max_threads); return 1; } // Array allocation int *a = malloc(sizeof(int) * size); int *temp = malloc(sizeof(int) * size); if (a == NULL || temp == NULL) { printf("Error: Could not allocate array of size %d\n", size); return 1; } // array initialization int i; srand(314159); for (i = 0; i < size; i++) { a[i] = rand() % size; } // run sort and get time start = omp_get_wtime(); run_omp(a, size, temp, threads, thresh); end = omp_get_wtime(); printf("%.4f\n", end - start); // check sorted for (i = 1; i < size; i++) { if (!(a[i - 1] <= a[i])) { printf("Error: final array not sorted => a[%d]=%d > a[%d]=%d\n", i - 1, a[i - 1], i, a[i]); return 1; } } return 0; } void run_omp(int a[], int size, int temp[], int threads, int thresh) { //omp_set_nested(1); // Enable nested parallelism, if available par_mergesort(a, size, temp, threads, thresh); } // OpenMP merge sort with given number of threads void mergesort_parallel_omp(int a[], int size, int temp[], int threads, int thresh) { if (threads == 1) { mergesort_serial(a, size, temp, thresh); } else if (threads > 1) { #pragma omp task { mergesort_parallel_omp(a, size / 2, temp, threads / 2, thresh); } #pragma omp task { mergesort_parallel_omp(a + size / 2, size - size / 2, temp + size / 2, threads - threads / 2, thresh); } #pragma omp taskwait { merge(a, size, temp); } } else { printf("Error: %d threads\n", threads); return; } } void par_mergesort (int a[], int size, int temp[], int threads, int thresh) { #pragma omp parallel { #pragma omp single nowait mergesort_parallel_omp (a, size, temp, threads, thresh); } } // only called if num_threads = 1 void mergesort_serial(int a[], int size, int temp[], int thresh) { // Switch to insertion sort for small arrays if (size <= thresh) { insertion_sort(a, size); return; } mergesort_serial(a, size / 2, temp, thresh); mergesort_serial(a + size / 2, size - size / 2, temp, thresh); merge(a, size, temp); } void merge(int a[], int size, int temp[]) { int i1 = 0; int i2 = size / 2; int tempi = 0; while (i1 < size / 2 && i2 < size) { if (a[i1] < a[i2]) { temp[tempi] = a[i1]; i1++; } else { temp[tempi] = a[i2]; i2++; } tempi++; } while (i1 < size / 2) { temp[tempi] = a[i1]; i1++; tempi++; } while (i2 < size) { temp[tempi] = a[i2]; i2++; tempi++; } // Copy sorted temp array into main array, a memcpy(a, temp, size * sizeof(int)); } void insertion_sort(int a[], int size) { int i; for (i = 0; i < size; i++) { int j, v = a[i]; for (j = i - 1; j >= 0; j--) { if (a[j] <= v) break; a[j + 1] = a[j]; } a[j + 1] = v; } }

utils.h

/* * Licensed to the Apache Software Foundation (ASF) under one * or more contributor license agreements. See the NOTICE file * distributed with this work for additional information * regarding copyright ownership. The ASF licenses this file * to you under the Apache License, Version 2.0 (the * "License"); you may not use this file except in compliance * with the License. You may obtain a copy of the License at * * http://www.apache.org/licenses/LICENSE-2.0 * * Unless required by applicable law or agreed to in writing, * software distributed under the License is distributed on an * "AS IS" BASIS, WITHOUT WARRANTIES OR CONDITIONS OF ANY * KIND, either express or implied. See the License for the * specific language governing permissions and limitations * under the License. */ /*! * Copyright (c) 2015 by Contributors * \file utils.h * \brief Basic utilility functions. */ #ifndef MXNET_COMMON_UTILS_H_ #define MXNET_COMMON_UTILS_H_ #include <dmlc/logging.h> #include <dmlc/omp.h> #include <nnvm/graph.h> #include <mxnet/engine.h> #include <mxnet/ndarray.h> #include <mxnet/op_attr_types.h> #include <mxnet/graph_attr_types.h> #include <nnvm/graph_attr_types.h> #include <memory> #include <vector> #include <type_traits> #include <utility> #include <random> #include <string> #include <thread> #include <algorithm> #include <functional> #include <limits> #include "../operator/mxnet_op.h" #if MXNET_USE_MKLDNN == 1 #include "../operator/nn/mkldnn/mkldnn_base-inl.h" #endif #if defined(_WIN32) || defined(_WIN64) || defined(__WINDOWS__) #include <windows.h> #else #include <unistd.h> #endif namespace mxnet { namespace common { #if defined(_WIN32) || defined(_WIN64) || defined(__WINDOWS__) inline size_t current_process_id() { return ::GetCurrentProcessId(); } #else inline size_t current_process_id() { return getpid(); } #endif /*! * \brief IndPtr should be non-negative, in non-decreasing order, start with 0 * and end with value equal with size of indices. */ struct csr_indptr_check { template<typename DType, typename IType> MSHADOW_XINLINE static void Map(int i, DType* out, const IType* indptr, const nnvm::dim_t end, const nnvm::dim_t idx_size) { if (indptr[i+1] < 0 || indptr[i+1] < indptr[i] || (i == 0 && indptr[i] != 0) || (i == end - 1 && indptr[end] != idx_size)) *out = kCSRIndPtrErr; } }; /*! * \brief Indices should be non-negative, less than the number of columns * and in ascending order per row. */ struct csr_idx_check { template<typename DType, typename IType, typename RType> MSHADOW_XINLINE static void Map(int i, DType* out, const IType* idx, const RType* indptr, const nnvm::dim_t ncols) { for (RType j = indptr[i]; j < indptr[i+1]; j++) { if (idx[j] >= ncols || idx[j] < 0 || (j < indptr[i+1] - 1 && idx[j] >= idx[j+1])) { *out = kCSRIdxErr; break; } } } }; /*! * \brief Indices of RSPNDArray should be non-negative, * less than the size of first dimension and in ascending order */ struct rsp_idx_check { template<typename DType, typename IType> MSHADOW_XINLINE static void Map(int i, DType* out, const IType* idx, const nnvm::dim_t end, const nnvm::dim_t nrows) { if ((i < end && idx[i+1] <= idx[i]) || idx[i] < 0 || idx[i] >= nrows) *out = kRSPIdxErr; } }; template<typename xpu> void CheckFormatWrapper(const RunContext &rctx, const NDArray &input, const TBlob &err_cpu, const bool full_check); /*! * \brief Check the validity of CSRNDArray. * \param rctx Execution context. * \param input Input NDArray of CSRStorage. * \param err_cpu Error number on cpu. * \param full_check If true, rigorous check, O(N) operations, * otherwise basic check, O(1) operations. */ template<typename xpu> void CheckFormatCSRImpl(const RunContext &rctx, const NDArray &input, const TBlob &err_cpu, const bool full_check) { using namespace op::mxnet_op; CHECK_EQ(input.storage_type(), kCSRStorage) << "CheckFormatCSRImpl is for CSRNDArray"; const mxnet::TShape shape = input.shape(); const mxnet::TShape idx_shape = input.aux_shape(csr::kIdx); const mxnet::TShape indptr_shape = input.aux_shape(csr::kIndPtr); const mxnet::TShape storage_shape = input.storage_shape(); if ((shape.ndim() != 2) || (idx_shape.ndim() != 1 || indptr_shape.ndim() != 1 || storage_shape.ndim() != 1) || (indptr_shape[0] != shape[0] + 1) || (idx_shape[0] != storage_shape[0])) { MSHADOW_TYPE_SWITCH(err_cpu.type_flag_, DType, { DType* err = err_cpu.dptr<DType>(); *err = kCSRShapeErr; }); return; } if (full_check) { MSHADOW_TYPE_SWITCH(err_cpu.type_flag_, DType, { MSHADOW_IDX_TYPE_SWITCH(input.aux_type(csr::kIndPtr), RType, { MSHADOW_IDX_TYPE_SWITCH(input.aux_type(csr::kIdx), IType, { mshadow::Stream<xpu> *s = rctx.get_stream<xpu>(); NDArray ret_xpu = NDArray(mshadow::Shape1(1), rctx.get_ctx(), false, err_cpu.type_flag_); TBlob val_xpu = ret_xpu.data(); Kernel<set_to_int<kNormalErr>, xpu>::Launch(s, val_xpu.Size(), val_xpu.dptr<DType>()); Kernel<csr_indptr_check, xpu>::Launch(s, indptr_shape[0] - 1, val_xpu.dptr<DType>(), input.aux_data(csr::kIndPtr).dptr<RType>(), indptr_shape[0] - 1, idx_shape[0]); // no need to check indices if indices are empty if (idx_shape[0] != 0) { Kernel<csr_idx_check, xpu>::Launch(s, indptr_shape[0] - 1, val_xpu.dptr<DType>(), input.aux_data(csr::kIdx).dptr<IType>(), input.aux_data(csr::kIndPtr).dptr<RType>(), shape[1]); } mshadow::Copy(err_cpu.get<cpu, 1, DType>(), val_xpu.get<xpu, 1, DType>(s), s); }); }); }); } } /*! * \brief Check the validity of RowSparseNDArray. * \param rctx Execution context. * \param input Input NDArray of RowSparseStorage. * \param err_cpu Error number on cpu. * \param full_check If true, rigorous check, O(N) operations, * otherwise basic check, O(1) operations. */ template<typename xpu> void CheckFormatRSPImpl(const RunContext &rctx, const NDArray &input, const TBlob &err_cpu, const bool full_check) { using namespace op::mxnet_op; CHECK_EQ(input.storage_type(), kRowSparseStorage) << "CheckFormatRSPImpl is for RSPNDArray"; const mxnet::TShape idx_shape = input.aux_shape(rowsparse::kIdx); if (idx_shape[0] != input.storage_shape()[0]) { MSHADOW_TYPE_SWITCH(err_cpu.type_flag_, DType, { DType* err = err_cpu.dptr<DType>(); *err = kRSPShapeErr; }); return; } if (idx_shape[0] == 0) { return; } if (full_check) { MSHADOW_TYPE_SWITCH(err_cpu.type_flag_, DType, { MSHADOW_IDX_TYPE_SWITCH(input.aux_type(rowsparse::kIdx), IType, { mshadow::Stream<xpu> *s = rctx.get_stream<xpu>(); NDArray ret_xpu = NDArray(mshadow::Shape1(1), rctx.get_ctx(), false, err_cpu.type_flag_); TBlob val_xpu = ret_xpu.data(); Kernel<set_to_int<kNormalErr>, xpu>::Launch(s, val_xpu.Size(), val_xpu.dptr<DType>()); Kernel<rsp_idx_check, xpu>::Launch(s, idx_shape[0], val_xpu.dptr<DType>(), input.aux_data(rowsparse::kIdx).dptr<IType>(), idx_shape[0] - 1, input.shape()[0]); mshadow::Copy(err_cpu.get<cpu, 1, DType>(), val_xpu.get<xpu, 1, DType>(s), s); }); }); } } template<typename xpu> void CheckFormatImpl(const RunContext &rctx, const NDArray &input, const TBlob &err_cpu, const bool full_check) { int stype = input.storage_type(); if (stype == kCSRStorage) { CheckFormatCSRImpl<xpu>(rctx, input, err_cpu, full_check); } else if (stype == kRowSparseStorage) { CheckFormatRSPImpl<xpu>(rctx, input, err_cpu, full_check); } else if (stype == kDefaultStorage) { // no-op for default storage } else { LOG(FATAL) << "Unknown storage type " << stype; } } /*! \brief Pick rows specified by user input index array from a row sparse ndarray * and save them in the output sparse ndarray. */ template<typename xpu> void SparseRetainOpForwardRspWrapper(mshadow::Stream<xpu> *s, const NDArray& input_nd, const TBlob& idx_data, const OpReqType req, NDArray* output_nd); /* \brief Casts tensor storage type to the new type. */ template<typename xpu> void CastStorageDispatch(const OpContext& ctx, const NDArray& input, const NDArray& output); /*! \brief returns true if all storage types in `vstorage` are the same as target `stype`. * false is returned for empty inputs. */ inline bool ContainsOnlyStorage(const StorageTypeVector& vstorage, const NDArrayStorageType stype) { if (!vstorage.empty()) { for (const auto& i : vstorage) { if (i != stype) return false; } return true; } return false; } /*! \brief returns true if all storage types in `vstorage` are the same as target `stype1` * or `stype2'. Sets boolean if both found. * false is returned for empty inputs. */ inline bool ContainsOnlyStorage(const StorageTypeVector& vstorage, const NDArrayStorageType stype1, const NDArrayStorageType stype2, bool *has_both) { if (has_both) { *has_both = false; } if (!vstorage.empty()) { uint8_t has = 0; for (const auto i : vstorage) { if (i == stype1) { has |= 1; } else if (i == stype2) { has |= 2; } else { return false; } } if (has_both) { *has_both = has == 3; } return true; } return false; } /*! \brief returns true if the storage types of arrays in `ndarrays` * are the same as target `stype`. false is returned for empty inputs. */ inline bool ContainsOnlyStorage(const std::vector<NDArray>& ndarrays, const NDArrayStorageType stype) { if (!ndarrays.empty()) { for (const auto& nd : ndarrays) { if (nd.storage_type() != stype) { return false; } } return true; } return false; } /*! \brief returns true if the storage types of arrays in `ndarrays` * are the same as targets `stype1` or `stype2`. false is returned for empty inputs. */ inline bool ContainsOnlyStorage(const std::vector<NDArray>& ndarrays, const NDArrayStorageType stype1, const NDArrayStorageType stype2, bool *has_both) { if (has_both) { *has_both = false; } if (!ndarrays.empty()) { uint8_t has = 0; for (const auto& nd : ndarrays) { const NDArrayStorageType stype = nd.storage_type(); if (stype == stype1) { has |= 1; } else if (stype == stype2) { has |= 2; } else { return false; } } if (has_both) { *has_both = has == 3; } return true; } return false; } /*! \brief returns true if storage type of any array in `ndarrays` * is the same as the target `stype`. false is returned for empty inputs. */ inline bool ContainsStorageType(const std::vector<NDArray>& ndarrays, const NDArrayStorageType stype) { if (!ndarrays.empty()) { for (const auto& nd : ndarrays) { if (nd.storage_type() == stype) { return true; } } } return false; } /*! \brief returns true if any storage type `ndstype` in `ndstypes` * is the same as the target `stype`. false is returned for empty inputs. */ inline bool ContainsStorageType(const std::vector<int>& ndstypes, const NDArrayStorageType stype) { if (!ndstypes.empty()) { for (const auto& ndstype : ndstypes) { if (ndstype == stype) { return true; } } } return false; } /*! \brief get string representation of dispatch_mode */ inline std::string dispatch_mode_string(const DispatchMode x) { switch (x) { case DispatchMode::kFCompute: return "fcompute"; case DispatchMode::kFComputeEx: return "fcompute_ex"; case DispatchMode::kFComputeFallback: return "fcompute_fallback"; case DispatchMode::kVariable: return "variable"; case DispatchMode::kUndefined: return "undefined"; } return "unknown"; } /*! \brief get string representation of storage_type */ inline std::string stype_string(const int x) { switch (x) { case kDefaultStorage: return "default"; case kCSRStorage: return "csr"; case kRowSparseStorage: return "row_sparse"; } return "unknown"; } /*! \brief get string representation of device type */ inline std::string dev_type_string(const int dev_type) { switch (dev_type) { case Context::kCPU: return "cpu"; case Context::kGPU: return "gpu"; case Context::kCPUPinned: return "cpu_pinned"; case Context::kCPUShared: return "cpu_shared"; } return "unknown"; } /*! \brief get string representation of the operator stypes */ inline std::string operator_stype_string(const nnvm::NodeAttrs& attrs, const int dev_mask, const std::vector<int>& in_attrs, const std::vector<int>& out_attrs) { std::ostringstream os; os << "operator = " << attrs.op->name << "\ninput storage types = ["; for (const int attr : in_attrs) { os << stype_string(attr) << ", "; } os << "]\n" << "output storage types = ["; for (const int attr : out_attrs) { os << stype_string(attr) << ", "; } os << "]\n" << "params = {"; for (auto kv : attrs.dict) { os << "\"" << kv.first << "\" : " << kv.second << ", "; } os << "}\n" << "context.dev_mask = " << dev_type_string(dev_mask); return os.str(); } /*! \brief get string representation of the operator */ inline std::string operator_string(const nnvm::NodeAttrs& attrs, const OpContext& ctx, const std::vector<NDArray>& inputs, const std::vector<OpReqType>& req, const std::vector<NDArray>& outputs) { std::string result = ""; std::vector<int> in_stypes; std::vector<int> out_stypes; in_stypes.reserve(inputs.size()); out_stypes.reserve(outputs.size()); auto xform = [](const NDArray arr) -> int { return arr.storage_type(); }; std::transform(inputs.begin(), inputs.end(), std::back_inserter(in_stypes), xform); std::transform(outputs.begin(), outputs.end(), std::back_inserter(out_stypes), xform); result += operator_stype_string(attrs, ctx.run_ctx.ctx.dev_mask(), in_stypes, out_stypes); return result; } /*! \brief log message once. Intended for storage fallback warning messages. */ inline void LogOnce(const std::string& message) { typedef dmlc::ThreadLocalStore<std::unordered_set<std::string>> LogStore; auto log_store = LogStore::Get(); if (log_store->find(message) == log_store->end()) { LOG(INFO) << message; log_store->insert(message); } } /*! \brief log storage fallback event */ inline void LogStorageFallback(const nnvm::NodeAttrs& attrs, const int dev_mask, const std::vector<int>* in_attrs, const std::vector<int>* out_attrs) { static bool log = dmlc::GetEnv("MXNET_STORAGE_FALLBACK_LOG_VERBOSE", true); if (!log) return; const std::string op_str = operator_stype_string(attrs, dev_mask, *in_attrs, *out_attrs); std::ostringstream os; const char* warning = "\nThe operator with default storage type will be dispatched " "for execution. You're seeing this warning message because the operator above is unable " "to process the given ndarrays with specified storage types, context and parameter. " "Temporary dense ndarrays are generated in order to execute the operator. " "This does not affect the correctness of the programme. " "You can set environment variable MXNET_STORAGE_FALLBACK_LOG_VERBOSE to " "0 to suppress this warning."; os << "\nStorage type fallback detected:\n" << op_str << warning; LogOnce(os.str()); #if MXNET_USE_MKLDNN == 1 if (!MKLDNNEnvSet()) common::LogOnce("MXNET_MKLDNN_ENABLED flag is off. " "You can re-enable by setting MXNET_MKLDNN_ENABLED=1"); if (GetMKLDNNCacheSize() != -1) common::LogOnce("MXNET_MKLDNN_CACHE_NUM is set." "Should only be set if " "your model has variable input shapes, " "as cache size may grow unbounded"); #endif } // heuristic to dermine number of threads per GPU inline int GetNumThreadsPerGPU() { // This is resource efficient option. return dmlc::GetEnv("MXNET_GPU_WORKER_NTHREADS", 2); } // heuristic to get number of matching colors. // this decides how much parallelism we can get in each GPU. inline int GetExecNumMatchColor() { // This is resource efficient option. int num_match_color = dmlc::GetEnv("MXNET_EXEC_NUM_TEMP", 1); return std::min(num_match_color, GetNumThreadsPerGPU()); } template<typename T, typename V> V ParallelAccumulate(const T* a, const int n, V start) { V sum = start; #pragma omp parallel for reduction(+:sum) for (int i = 0; i < n; ++i) { sum += a[i]; } return sum; } /*! * \brief * Helper function for ParallelSort. * DO NOT call this function directly. * Use the interface ParallelSort instead. * Ref: https://github.com/dmlc/difacto/blob/master/src/common/parallel_sort.h */ template<typename RandomIt, typename Compare> void ParallelSortHelper(RandomIt first, size_t len, size_t grainsize, const Compare& comp) { if (len < grainsize) { std::sort(first, first+len, comp); } else { std::thread thr(ParallelSortHelper<RandomIt, Compare>, first, len/2, grainsize, comp); ParallelSortHelper(first+len/2, len - len/2, grainsize, comp); thr.join(); std::inplace_merge(first, first+len/2, first+len, comp); } } /*! * \brief * Sort the elements in the range [first, last) into the ascending order defined by * the comparator comp. * If the length of the range [first, last) is greater than a certain threshold, * the range will be recursively divided into two and assign two threads * to sort each half range. * Ref: https://github.com/dmlc/difacto/blob/master/src/common/parallel_sort.h */ template<typename RandomIt, typename Compare> void ParallelSort(RandomIt first, RandomIt last, size_t num_threads, Compare comp) { const auto num = std::distance(first, last); size_t grainsize = std::max(num / num_threads + 5, static_cast<size_t>(1024*16)); ParallelSortHelper(first, num, grainsize, comp); } /*! * \brief * Sort the elements in the range [first, last) into ascending order. * The elements are compared using the default < operator. * If the length of the range [first, last) is greater than a certain threshold, * the range will be recursively divided into two and assign two threads * to sort each half range. * Ref: https://github.com/dmlc/difacto/blob/master/src/common/parallel_sort.h */ template<typename RandomIt> void ParallelSort(RandomIt first, RandomIt last, size_t num_threads) { ParallelSort(first, last, num_threads, std::less<typename std::iterator_traits<RandomIt>::value_type>()); } /*! * \brief Random Engine */ typedef std::mt19937 RANDOM_ENGINE; /*! * \brief Helper functions. */ namespace helper { /*! * \brief Helper for non-array type `T`. */ template <class T> struct UniqueIf { /*! * \brief Type of `T`. */ using SingleObject = std::unique_ptr<T>; }; /*! * \brief Helper for an array of unknown bound `T`. */ template <class T> struct UniqueIf<T[]> { /*! * \brief Type of `T`. */ using UnknownBound = std::unique_ptr<T[]>; }; /*! * \brief Helper for an array of known bound `T`. */ template <class T, size_t kSize> struct UniqueIf<T[kSize]> { /*! * \brief Type of `T`. */ using KnownBound = void; }; } // namespace helper /*! * \brief Constructs an object of type `T` and wraps it in a * `std``::``unique_ptr`. * \param args List of arguments with which an instance of `T` will be * constructed. * \return `std``::``unique_ptr` of an instance of type `T`. * * Constructs a non-array type `T`. The arguments `args` are passed to the * constructor of `T`. The function does not participate in the overload * resolution if `T` is an array type. */ template <class T, class... Args> typename helper::UniqueIf<T>::SingleObject MakeUnique(Args&&... args) { return std::unique_ptr<T>(new T(std::forward<Args>(args)...)); } /*! * \brief Constructs an object of type `T` and wraps it in a * `std``::``unique_ptr`. * \param n The size of the array to construct. * \return `std``::``unique_ptr` of an instance of type `T`. * * Constructs an array of unknown bound `T`. The function does not participate * in the overload resolution unless `T` is an array of unknown bound. */ template <class T> typename helper::UniqueIf<T>::UnknownBound MakeUnique(size_t n) { using U = typename std::remove_extent<T>::type; return std::unique_ptr<T>(new U[n]{}); } /*! * \brief Constructs an object of type `T` and wraps it in a * `std``::``unique_ptr`. * \param args List of arguments with which an instance of `T` will be * constructed. * * Constructs an arrays of known bound is disallowed. */ template <class T, class... Args> typename helper::UniqueIf<T>::KnownBound MakeUnique(Args&&... args) = delete; template<typename FCompType> FCompType GetFCompute(const nnvm::Op* op, const std::string& name, const Context& ctx) { static auto& fcompute_cpu = nnvm::Op::GetAttr<FCompType>(name + "<cpu>"); static auto& fcompute_gpu = nnvm::Op::GetAttr<FCompType>(name + "<gpu>"); if (ctx.dev_mask() == cpu::kDevMask) { return fcompute_cpu.get(op, nullptr); } else if (ctx.dev_mask() == gpu::kDevMask) { return fcompute_gpu.get(op, nullptr); } else { LOG(FATAL) << "Unknown device mask " << ctx.dev_mask(); return nullptr; } } /*! * \brief Return the max integer value representable in the type `T` without loss of precision. */ template <typename T> constexpr size_t MaxIntegerValue() { return std::is_integral<T>::value ? std::numeric_limits<T>::max(): size_t(2) << (std::numeric_limits<T>::digits - 1); } template <> constexpr size_t MaxIntegerValue<mshadow::half::half_t>() { return size_t(2) << 10; } MSHADOW_XINLINE int ilog2ul(size_t a) { int k = 1; while (a >>= 1) ++k; return k; } MSHADOW_XINLINE int ilog2ui(unsigned int a) { int k = 1; while (a >>= 1) ++k; return k; } /*! * \brief Return an NDArray of all zeros. */ inline NDArray InitZeros(const NDArrayStorageType stype, const mxnet::TShape &shape, const Context &ctx, const int dtype) { // NDArray with default storage if (stype == kDefaultStorage) { NDArray ret(shape, ctx, false, dtype); ret = 0; return ret; } // NDArray with non-default storage. Storage allocation is always delayed. return NDArray(stype, shape, ctx, true, dtype); } /*! * \brief Helper to add a NDArray of zeros to a std::vector. */ inline void EmplaceBackZeros(const NDArrayStorageType stype, const mxnet::TShape &shape, const Context &ctx, const int dtype, std::vector<NDArray> *vec) { // NDArray with default storage if (stype == kDefaultStorage) { vec->emplace_back(shape, ctx, false, dtype); vec->back() = 0; } else { // NDArray with non-default storage. Storage allocation is always delayed. vec->emplace_back(stype, shape, ctx, true, dtype); } } /*! * \brief parallelize copy by OpenMP. */ template<typename DType> inline void ParallelCopy(DType* dst, const DType* src, index_t size) { static index_t copy_block_size = dmlc::GetEnv("MXNET_CPU_PARALLEL_COPY_SIZE", 200000); if (size >= copy_block_size) { #pragma omp parallel for num_threads(engine::OpenMP::Get()->GetRecommendedOMPThreadCount()) for (index_t i = 0; i < size; ++i) { dst[i] = src[i]; } } else { std::memcpy(dst, src, sizeof(DType) * size); } } /*! * \brief If numpy compatibility is turned off (default), the shapes passed in * by users follow the legacy shape definition: * 1. 0 ndim means the shape is completely unknown. * 2. 0 dim size means the dim size is unknown. * We need to convert those shapes to use the numpy shape definition: * 1. 0 ndim means it's a scalar tensor. * 2. -1 ndim means the shape is unknown. * 3. 0 dim size means no elements in that dimension. * 4. -1 dim size means the dimension's size is unknown. * so that operator's infer shape function can work in backend. * \param shape to be converted. * Note: It is possible that the shape to be converted is already * numpy compatible. For example, when a subgraph operator's infer * shape function is called from the infer shape pass of the whole * graph, its input/output shapes have been converted to numpy * compatible shapes. */ inline void ConvertToNumpyShape(mxnet::TShape* shape) { if (shape->ndim() == 0) { // legacy shape ndim = 0 means unknown *shape = mxnet::TShape(); // unknown shape ndim = -1 } else { for (int j = 0; j < shape->ndim(); ++j) { if ((*shape)[j] == 0) { // legacy shape dim_size = 0 means unknown (*shape)[j] = -1; // unknown dim size = -1 } } } } inline void ConvertToNumpyShape(mxnet::ShapeVector* shapes) { for (size_t i = 0; i < shapes->size(); ++i) { ConvertToNumpyShape(&(shapes->at(i))); } } /*! * \brief This is function is used to convert shapes returned by * the infer shape functions/pass to the legacy shape definition. */ inline void ConvertToLegacyShape(mxnet::TShape* shape) { if (!mxnet::ndim_is_known(*shape)) { *shape = mxnet::TShape(0, -1); } else { for (int j = 0; j < shape->ndim(); ++j) { if (!mxnet::dim_size_is_known(*shape, j)) { (*shape)[j] = 0; } } } } inline void ConvertToLegacyShape(mxnet::ShapeVector* shapes) { for (size_t i = 0; i < shapes->size(); ++i) { ConvertToLegacyShape(&(shapes->at(i))); } } } // namespace common } // namespace mxnet #endif // MXNET_COMMON_UTILS_H_

DRB011-minusminus-orig-yes.c

/* Copyright (C) 1991-2018 Free Software Foundation, Inc. This file is part of the GNU C Library. The GNU C Library is free software; you can redistribute it andor modify it under the terms of the GNU Lesser General Public License as published by the Free Software Foundation; either version 2.1 of the License, or (at your option) any later version. The GNU C Library is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU Lesser General Public License for more details. You should have received a copy of the GNU Lesser General Public License along with the GNU C Library; if not, see <http:www.gnu.org/licenses/>. */ /* This header is separate from features.h so that the compiler can include it implicitly at the start of every compilation. It must not itself include <features.h> or any other header that includes <features.h> because the implicit include comes before any feature test macros that may be defined in a source file before it first explicitly includes a system header. GCC knows the name of this header in order to preinclude it. */ /* glibc's intent is to support the IEC 559 math functionality, real and complex. If the GCC (4.9 and later) predefined macros specifying compiler intent are available, use them to determine whether the overall intent is to support these features; otherwise, presume an older compiler has intent to support these features and define these macros by default. */ /* wchar_t uses Unicode 10.0.0. Version 10.0 of the Unicode Standard is synchronized with ISOIEC 10646:2017, fifth edition, plus the following additions from Amendment 1 to the fifth edition: - 56 emoji characters - 285 hentaigana - 3 additional Zanabazar Square characters */ /* Copyright (c) 2017, Lawrence Livermore National Security, LLC. Produced at the Lawrence Livermore National Laboratory Written by Chunhua Liao, Pei-Hung Lin, Joshua Asplund, Markus Schordan, and Ian Karlin (email: liao6@llnl.gov, lin32@llnl.gov, asplund1@llnl.gov, schordan1@llnl.gov, karlin1@llnl.gov) LLNL-CODE-732144 All rights reserved. This file is part of DataRaceBench. For details, see https:github.comLLNL/dataracebench. Please also see the LICENSE file for our additional BSD notice. Redistribution and use in source and binary forms, with or without modification, are permitted provided that the following conditions are met: * Redistributions of source code must retain the above copyright notice, this list of conditions and the disclaimer below. * Redistributions in binary form must reproduce the above copyright notice, this list of conditions and the disclaimer (as noted below) in the documentation and/or other materials provided with the distribution. * Neither the name of the LLNS/LLNL nor the names of its contributors may be used to endorse or promote products derived from this software without specific prior written permission. THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL LAWRENCE LIVERMORE NATIONAL SECURITY, LLC, THE U.S. DEPARTMENT OF ENERGY OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE. */ /* The -- operation on numNodes2 is not protected, causing data race. Data race pair: numNodes2@74:7 vs. numNodes2@74:7 */ #include <stdlib.h> #include <stdio.h> int main(int argc, char * argv[]) { int i; int len = 100; int numNodes = len, numNodes2 = 0; int x[100]; /* initialize x[] */ int _ret_val_0; #pragma cetus private(i) #pragma loop name main#0 #pragma cetus parallel #pragma omp parallel for private(i) for (i=0; i<len; i ++ ) { if ((i%2)==0) { x[i]=5; } else { x[i]=( - 5); } } #pragma cetus private(i) #pragma loop name main#1 #pragma cetus reduction(+: numNodes2) #pragma cetus parallel #pragma omp parallel for private(i) reduction(+: numNodes2) for (i=(numNodes-1); i>( - 1); -- i) { if (x[i]<=0) { numNodes2 -- ; } } printf("numNodes2 = %d\n", numNodes2); _ret_val_0=0; return _ret_val_0; }

use_memory.c

/* * This is just a test, to do a sanity check * on the actual peak_memusage * $Id$ * */ #include <stdio.h> /* print */ #include <stdlib.h> /* malloc */ #include <unistd.h> /* optarg */ #ifdef COMPILE_MPI #include <mpi.h> #endif #define MAX_SIZE 2147483647 #define DEFAULT_SIZE 1000000 #define MAX_REPEAT 100 void printUsage(char **argv) { fprintf(stderr, "\nUsage:\n%s [-s size] [-r repetitions] [-d delay (ms)] \n\n", argv[0]); exit(1); } void parseInt(int *data, char *param) { if (param != NULL) *data = atoi(param); } int main(int argc, char **argv) { int i, j, last, size = DEFAULT_SIZE, repeat = 1, delay=1000; int *spare_data, c, error, rank, poolsize; char *ch_size = NULL, *ch_repeat = NULL, *ch_delay=NULL, *ch_rank="thread"; #ifdef COMPILE_MPI if(error = MPI_Init(NULL, NULL)) { fprintf(stderr, "MPI INIT error: %d", error); return 1; } if(error = MPI_Comm_rank(MPI_COMM_WORLD, &rank)) { fprintf(stderr, "MPI RANK error: %d", error); return 1; } if(error = MPI_Comm_size(MPI_COMM_WORLD, &poolsize)) { fprintf(stderr, "MPI SIZE error: %d", error); return 1; } ch_rank="task"; #endif while ((c = getopt (argc, argv, "s:r:d:")) != -1) { switch(c) { case 's': ch_size = optarg; break; case 'r': ch_repeat = optarg; break; case 'd': ch_delay = optarg; break; default: printUsage(argv); } } parseInt(&size, ch_size); parseInt(&repeat, ch_repeat); parseInt(&delay, ch_delay); if (size <= 0 || size > MAX_SIZE || repeat < 1 || repeat > MAX_REPEAT || delay < 0) { fprintf(stderr, "size:%d, repeat:%d, delay:%f\n", size, repeat, delay); printUsage(argv); } #ifdef COMPILE_OMP #pragma omp parallel default(none) private(rank, poolsize, i, j, last, spare_data) shared(size, delay, repeat, ch_rank) { rank = omp_get_thread_num(); poolsize = omp_get_num_threads(); #elif !defined COMPILE_MPI rank = 0; poolsize = 1; #endif for(i=0; i<repeat; i++) { last = size *(rank+1); /* every rank will have a different number */ int amount = last*sizeof(int); printf("Allocating, using and freeing %d ints (%.2f MiB) in %s %d/%d\n", last, amount/1048576., ch_rank, rank, poolsize); spare_data = malloc(amount); for (j=0; j<last; j++) spare_data[j] = 24; usleep(delay * 1000); } free(spare_data); #ifdef COMPILE_MPI if(error = MPI_Finalize()) { fprintf(stderr, "MPI FINALIZE error: %d", error); return 1; } #else #ifdef COMPILE_OMP } #endif #endif return 0; }

image.c

/* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % IIIII M M AAA GGGG EEEEE % % I MM MM A A G E % % I M M M AAAAA G GG EEE % % I M M A A G G E % % IIIII M M A A GGGG EEEEE % % % % % % MagickCore Image Methods % % % % Software Design % % Cristy % % July 1992 % % % % % % Copyright 1999-2020 ImageMagick Studio LLC, a non-profit organization % % dedicated to making software imaging solutions freely available. % % % % You may not use this file except in compliance with the License. You may % % obtain a copy of the License at % % % % https://imagemagick.org/script/license.php % % % % Unless required by applicable law or agreed to in writing, software % % distributed under the License is distributed on an "AS IS" BASIS, % % WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. % % See the License for the specific language governing permissions and % % limitations under the License. % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % */ /* Include declarations. */ #include "MagickCore/studio.h" #include "MagickCore/animate.h" #include "MagickCore/artifact.h" #include "MagickCore/attribute.h" #include "MagickCore/blob.h" #include "MagickCore/blob-private.h" #include "MagickCore/cache.h" #include "MagickCore/cache-private.h" #include "MagickCore/cache-view.h" #include "MagickCore/channel.h" #include "MagickCore/client.h" #include "MagickCore/color.h" #include "MagickCore/color-private.h" #include "MagickCore/colormap.h" #include "MagickCore/colorspace.h" #include "MagickCore/colorspace-private.h" #include "MagickCore/composite.h" #include "MagickCore/composite-private.h" #include "MagickCore/compress.h" #include "MagickCore/constitute.h" #include "MagickCore/delegate.h" #include "MagickCore/display.h" #include "MagickCore/draw.h" #include "MagickCore/enhance.h" #include "MagickCore/exception.h" #include "MagickCore/exception-private.h" #include "MagickCore/gem.h" #include "MagickCore/geometry.h" #include "MagickCore/histogram.h" #include "MagickCore/image-private.h" #include "MagickCore/list.h" #include "MagickCore/magic.h" #include "MagickCore/magick.h" #include "MagickCore/magick-private.h" #include "MagickCore/memory_.h" #include "MagickCore/memory-private.h" #include "MagickCore/module.h" #include "MagickCore/monitor.h" #include "MagickCore/monitor-private.h" #include "MagickCore/option.h" #include "MagickCore/paint.h" #include "MagickCore/pixel-accessor.h" #include "MagickCore/profile.h" #include "MagickCore/property.h" #include "MagickCore/quantize.h" #include "MagickCore/random_.h" #include "MagickCore/resource_.h" #include "MagickCore/segment.h" #include "MagickCore/semaphore.h" #include "MagickCore/signature-private.h" #include "MagickCore/statistic.h" #include "MagickCore/string_.h" #include "MagickCore/string-private.h" #include "MagickCore/thread-private.h" #include "MagickCore/threshold.h" #include "MagickCore/timer.h" #include "MagickCore/timer-private.h" #include "MagickCore/token.h" #include "MagickCore/token-private.h" #include "MagickCore/utility.h" #include "MagickCore/utility-private.h" #include "MagickCore/version.h" #include "MagickCore/xwindow-private.h" /* Constant declaration. */ const char BackgroundColor[] = "#ffffff", /* white */ BorderColor[] = "#dfdfdf", /* gray */ DefaultTileFrame[] = "15x15+3+3", DefaultTileGeometry[] = "120x120+4+3>", DefaultTileLabel[] = "%f\n%G\n%b", ForegroundColor[] = "#000", /* black */ LoadImageTag[] = "Load/Image", LoadImagesTag[] = "Load/Images", MatteColor[] = "#bdbdbd", /* gray */ PSDensityGeometry[] = "72.0x72.0", PSPageGeometry[] = "612x792", SaveImageTag[] = "Save/Image", SaveImagesTag[] = "Save/Images", TransparentColor[] = "#00000000"; /* transparent black */ const double DefaultResolution = 72.0; /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % A c q u i r e I m a g e % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % AcquireImage() returns a pointer to an image structure initialized to % default values. % % The format of the AcquireImage method is: % % Image *AcquireImage(const ImageInfo *image_info,ExceptionInfo *exception) % % A description of each parameter follows: % % o image_info: Many of the image default values are set from this % structure. For example, filename, compression, depth, background color, % and others. % % o exception: return any errors or warnings in this structure. % */ MagickExport Image *AcquireImage(const ImageInfo *image_info, ExceptionInfo *exception) { const char *option; Image *image; MagickStatusType flags; /* Allocate image structure. */ (void) LogMagickEvent(TraceEvent,GetMagickModule(),"..."); image=(Image *) AcquireCriticalMemory(sizeof(*image)); (void) memset(image,0,sizeof(*image)); /* Initialize Image structure. */ (void) CopyMagickString(image->magick,"MIFF",MagickPathExtent); image->storage_class=DirectClass; image->depth=MAGICKCORE_QUANTUM_DEPTH; image->colorspace=sRGBColorspace; image->rendering_intent=PerceptualIntent; image->gamma=1.000f/2.200f; image->chromaticity.red_primary.x=0.6400f; image->chromaticity.red_primary.y=0.3300f; image->chromaticity.red_primary.z=0.0300f; image->chromaticity.green_primary.x=0.3000f; image->chromaticity.green_primary.y=0.6000f; image->chromaticity.green_primary.z=0.1000f; image->chromaticity.blue_primary.x=0.1500f; image->chromaticity.blue_primary.y=0.0600f; image->chromaticity.blue_primary.z=0.7900f; image->chromaticity.white_point.x=0.3127f; image->chromaticity.white_point.y=0.3290f; image->chromaticity.white_point.z=0.3583f; image->interlace=NoInterlace; image->ticks_per_second=UndefinedTicksPerSecond; image->compose=OverCompositeOp; (void) QueryColorCompliance(MatteColor,AllCompliance,&image->matte_color, exception); (void) QueryColorCompliance(BackgroundColor,AllCompliance, &image->background_color,exception); (void) QueryColorCompliance(BorderColor,AllCompliance,&image->border_color, exception); (void) QueryColorCompliance(TransparentColor,AllCompliance, &image->transparent_color,exception); GetTimerInfo(&image->timer); image->cache=AcquirePixelCache(0); image->channel_mask=DefaultChannels; image->channel_map=AcquirePixelChannelMap(); image->blob=CloneBlobInfo((BlobInfo *) NULL); image->timestamp=GetMagickTime(); image->debug=IsEventLogging(); image->reference_count=1; image->semaphore=AcquireSemaphoreInfo(); image->signature=MagickCoreSignature; if (image_info == (ImageInfo *) NULL) return(image); /* Transfer image info. */ SetBlobExempt(image,image_info->file != (FILE *) NULL ? MagickTrue : MagickFalse); (void) CopyMagickString(image->filename,image_info->filename, MagickPathExtent); (void) CopyMagickString(image->magick_filename,image_info->filename, MagickPathExtent); (void) CopyMagickString(image->magick,image_info->magick,MagickPathExtent); if (image_info->size != (char *) NULL) { (void) ParseAbsoluteGeometry(image_info->size,&image->extract_info); image->columns=image->extract_info.width; image->rows=image->extract_info.height; image->offset=image->extract_info.x; image->extract_info.x=0; image->extract_info.y=0; } if (image_info->extract != (char *) NULL) { RectangleInfo geometry; (void) memset(&geometry,0,sizeof(geometry)); flags=ParseAbsoluteGeometry(image_info->extract,&geometry); if (((flags & XValue) != 0) || ((flags & YValue) != 0)) { image->extract_info=geometry; Swap(image->columns,image->extract_info.width); Swap(image->rows,image->extract_info.height); } } image->compression=image_info->compression; image->quality=image_info->quality; image->endian=image_info->endian; image->interlace=image_info->interlace; image->units=image_info->units; if (image_info->density != (char *) NULL) { GeometryInfo geometry_info; flags=ParseGeometry(image_info->density,&geometry_info); if ((flags & RhoValue) != 0) image->resolution.x=geometry_info.rho; image->resolution.y=image->resolution.x; if ((flags & SigmaValue) != 0) image->resolution.y=geometry_info.sigma; } if (image_info->page != (char *) NULL) { char *geometry; image->page=image->extract_info; geometry=GetPageGeometry(image_info->page); (void) ParseAbsoluteGeometry(geometry,&image->page); geometry=DestroyString(geometry); } if (image_info->depth != 0) image->depth=image_info->depth; image->dither=image_info->dither; image->matte_color=image_info->matte_color; image->background_color=image_info->background_color; image->border_color=image_info->border_color; image->transparent_color=image_info->transparent_color; image->ping=image_info->ping; image->progress_monitor=image_info->progress_monitor; image->client_data=image_info->client_data; if (image_info->cache != (void *) NULL) ClonePixelCacheMethods(image->cache,image_info->cache); /* Set all global options that map to per-image settings. */ (void) SyncImageSettings(image_info,image,exception); /* Global options that are only set for new images. */ option=GetImageOption(image_info,"delay"); if (option != (const char *) NULL) { GeometryInfo geometry_info; flags=ParseGeometry(option,&geometry_info); if ((flags & GreaterValue) != 0) { if (image->delay > (size_t) floor(geometry_info.rho+0.5)) image->delay=(size_t) floor(geometry_info.rho+0.5); } else if ((flags & LessValue) != 0) { if (image->delay < (size_t) floor(geometry_info.rho+0.5)) image->ticks_per_second=(ssize_t) floor(geometry_info.sigma+0.5); } else image->delay=(size_t) floor(geometry_info.rho+0.5); if ((flags & SigmaValue) != 0) image->ticks_per_second=(ssize_t) floor(geometry_info.sigma+0.5); } option=GetImageOption(image_info,"dispose"); if (option != (const char *) NULL) image->dispose=(DisposeType) ParseCommandOption(MagickDisposeOptions, MagickFalse,option); return(image); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % A c q u i r e I m a g e I n f o % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % AcquireImageInfo() allocates the ImageInfo structure. % % The format of the AcquireImageInfo method is: % % ImageInfo *AcquireImageInfo(void) % */ MagickExport ImageInfo *AcquireImageInfo(void) { ImageInfo *image_info; image_info=(ImageInfo *) AcquireCriticalMemory(sizeof(*image_info)); GetImageInfo(image_info); return(image_info); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % A c q u i r e N e x t I m a g e % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % AcquireNextImage() initializes the next image in a sequence to % default values. The next member of image points to the newly allocated % image. If there is a memory shortage, next is assigned NULL. % % The format of the AcquireNextImage method is: % % void AcquireNextImage(const ImageInfo *image_info,Image *image, % ExceptionInfo *exception) % % A description of each parameter follows: % % o image_info: Many of the image default values are set from this % structure. For example, filename, compression, depth, background color, % and others. % % o image: the image. % % o exception: return any errors or warnings in this structure. % */ MagickExport void AcquireNextImage(const ImageInfo *image_info,Image *image, ExceptionInfo *exception) { /* Allocate image structure. */ assert(image != (Image *) NULL); assert(image->signature == MagickCoreSignature); if (image->debug != MagickFalse) (void) LogMagickEvent(TraceEvent,GetMagickModule(),"%s",image->filename); image->next=AcquireImage(image_info,exception); if (GetNextImageInList(image) == (Image *) NULL) return; (void) CopyMagickString(GetNextImageInList(image)->filename,image->filename, MagickPathExtent); if (image_info != (ImageInfo *) NULL) (void) CopyMagickString(GetNextImageInList(image)->filename, image_info->filename,MagickPathExtent); DestroyBlob(GetNextImageInList(image)); image->next->blob=ReferenceBlob(image->blob); image->next->endian=image->endian; image->next->scene=image->scene+1; image->next->previous=image; } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % A p p e n d I m a g e s % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % AppendImages() takes all images from the current image pointer to the end % of the image list and appends them to each other top-to-bottom if the % stack parameter is true, otherwise left-to-right. % % The current gravity setting effects how the image is justified in the % final image. % % The format of the AppendImages method is: % % Image *AppendImages(const Image *images,const MagickBooleanType stack, % ExceptionInfo *exception) % % A description of each parameter follows: % % o images: the image sequence. % % o stack: A value other than 0 stacks the images top-to-bottom. % % o exception: return any errors or warnings in this structure. % */ MagickExport Image *AppendImages(const Image *images, const MagickBooleanType stack,ExceptionInfo *exception) { #define AppendImageTag "Append/Image" CacheView *append_view; Image *append_image; MagickBooleanType homogeneous_colorspace, status; MagickOffsetType n; PixelTrait alpha_trait; RectangleInfo geometry; register const Image *next; size_t depth, height, number_images, width; ssize_t x_offset, y, y_offset; /* Compute maximum area of appended area. */ assert(images != (Image *) NULL); assert(images->signature == MagickCoreSignature); if (images->debug != MagickFalse) (void) LogMagickEvent(TraceEvent,GetMagickModule(),"%s",images->filename); assert(exception != (ExceptionInfo *) NULL); assert(exception->signature == MagickCoreSignature); alpha_trait=images->alpha_trait; number_images=1; width=images->columns; height=images->rows; depth=images->depth; homogeneous_colorspace=MagickTrue; next=GetNextImageInList(images); for ( ; next != (Image *) NULL; next=GetNextImageInList(next)) { if (next->depth > depth) depth=next->depth; if (next->colorspace != images->colorspace) homogeneous_colorspace=MagickFalse; if (next->alpha_trait != UndefinedPixelTrait) alpha_trait=BlendPixelTrait; number_images++; if (stack != MagickFalse) { if (next->columns > width) width=next->columns; height+=next->rows; continue; } width+=next->columns; if (next->rows > height) height=next->rows; } /* Append images. */ append_image=CloneImage(images,width,height,MagickTrue,exception); if (append_image == (Image *) NULL) return((Image *) NULL); if (SetImageStorageClass(append_image,DirectClass,exception) == MagickFalse) { append_image=DestroyImage(append_image); return((Image *) NULL); } if (homogeneous_colorspace == MagickFalse) (void) SetImageColorspace(append_image,sRGBColorspace,exception); append_image->depth=depth; append_image->alpha_trait=alpha_trait; append_image->page=images->page; (void) SetImageBackgroundColor(append_image,exception); status=MagickTrue; x_offset=0; y_offset=0; next=images; append_view=AcquireAuthenticCacheView(append_image,exception); for (n=0; n < (MagickOffsetType) number_images; n++) { CacheView *image_view; MagickBooleanType proceed; SetGeometry(append_image,&geometry); GravityAdjustGeometry(next->columns,next->rows,next->gravity,&geometry); if (stack != MagickFalse) x_offset-=geometry.x; else y_offset-=geometry.y; image_view=AcquireVirtualCacheView(next,exception); #if defined(MAGICKCORE_OPENMP_SUPPORT) #pragma omp parallel for schedule(static) shared(status) \ magick_number_threads(next,next,next->rows,1) #endif for (y=0; y < (ssize_t) next->rows; y++) { MagickBooleanType sync; PixelInfo pixel; register const Quantum *magick_restrict p; register Quantum *magick_restrict q; register ssize_t x; if (status == MagickFalse) continue; p=GetCacheViewVirtualPixels(image_view,0,y,next->columns,1,exception); q=QueueCacheViewAuthenticPixels(append_view,x_offset,y+y_offset, next->columns,1,exception); if ((p == (const Quantum *) NULL) || (q == (Quantum *) NULL)) { status=MagickFalse; continue; } GetPixelInfo(next,&pixel); for (x=0; x < (ssize_t) next->columns; x++) { GetPixelInfoPixel(next,p,&pixel); SetPixelViaPixelInfo(append_image,&pixel,q); p+=GetPixelChannels(next); q+=GetPixelChannels(append_image); } sync=SyncCacheViewAuthenticPixels(append_view,exception); if (sync == MagickFalse) status=MagickFalse; } image_view=DestroyCacheView(image_view); if (stack == MagickFalse) { x_offset+=(ssize_t) next->columns; y_offset=0; } else { x_offset=0; y_offset+=(ssize_t) next->rows; } proceed=SetImageProgress(append_image,AppendImageTag,n,number_images); if (proceed == MagickFalse) break; next=GetNextImageInList(next); } append_view=DestroyCacheView(append_view); if (status == MagickFalse) append_image=DestroyImage(append_image); return(append_image); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % C a t c h I m a g e E x c e p t i o n % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % CatchImageException() returns if no exceptions are found in the image % sequence, otherwise it determines the most severe exception and reports % it as a warning or error depending on the severity. % % The format of the CatchImageException method is: % % ExceptionType CatchImageException(Image *image) % % A description of each parameter follows: % % o image: An image sequence. % */ MagickExport ExceptionType CatchImageException(Image *image) { ExceptionInfo *exception; ExceptionType severity; assert(image != (const Image *) NULL); assert(image->signature == MagickCoreSignature); if (image->debug != MagickFalse) (void) LogMagickEvent(TraceEvent,GetMagickModule(),"%s",image->filename); exception=AcquireExceptionInfo(); CatchException(exception); severity=exception->severity; exception=DestroyExceptionInfo(exception); return(severity); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % C l i p I m a g e P a t h % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % ClipImagePath() sets the image clip mask based any clipping path information % if it exists. % % The format of the ClipImagePath method is: % % MagickBooleanType ClipImagePath(Image *image,const char *pathname, % const MagickBooleanType inside,ExceptionInfo *exception) % % A description of each parameter follows: % % o image: the image. % % o pathname: name of clipping path resource. If name is preceded by #, use % clipping path numbered by name. % % o inside: if non-zero, later operations take effect inside clipping path. % Otherwise later operations take effect outside clipping path. % % o exception: return any errors or warnings in this structure. % */ MagickExport MagickBooleanType ClipImage(Image *image,ExceptionInfo *exception) { return(ClipImagePath(image,"#1",MagickTrue,exception)); } MagickExport MagickBooleanType ClipImagePath(Image *image,const char *pathname, const MagickBooleanType inside,ExceptionInfo *exception) { #define ClipImagePathTag "ClipPath/Image" char *property; const char *value; Image *clip_mask; ImageInfo *image_info; assert(image != (const Image *) NULL); assert(image->signature == MagickCoreSignature); if (image->debug != MagickFalse) (void) LogMagickEvent(TraceEvent,GetMagickModule(),"%s",image->filename); assert(pathname != NULL); property=AcquireString(pathname); (void) FormatLocaleString(property,MagickPathExtent,"8BIM:1999,2998:%s", pathname); value=GetImageProperty(image,property,exception); property=DestroyString(property); if (value == (const char *) NULL) { ThrowFileException(exception,OptionError,"NoClipPathDefined", image->filename); return(MagickFalse); } image_info=AcquireImageInfo(); (void) CopyMagickString(image_info->filename,image->filename, MagickPathExtent); (void) ConcatenateMagickString(image_info->filename,pathname, MagickPathExtent); clip_mask=BlobToImage(image_info,value,strlen(value),exception); image_info=DestroyImageInfo(image_info); if (clip_mask == (Image *) NULL) return(MagickFalse); if (clip_mask->storage_class == PseudoClass) { (void) SyncImage(clip_mask,exception); if (SetImageStorageClass(clip_mask,DirectClass,exception) == MagickFalse) return(MagickFalse); } if (inside == MagickFalse) (void) NegateImage(clip_mask,MagickFalse,exception); (void) FormatLocaleString(clip_mask->magick_filename,MagickPathExtent, "8BIM:1999,2998:%s\nPS",pathname); (void) SetImageMask(image,WritePixelMask,clip_mask,exception); clip_mask=DestroyImage(clip_mask); return(MagickTrue); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % C l o n e I m a g e % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % CloneImage() copies an image and returns the copy as a new image object. % % If the specified columns and rows is 0, an exact copy of the image is % returned, otherwise the pixel data is undefined and must be initialized % with the QueueAuthenticPixels() and SyncAuthenticPixels() methods. On % failure, a NULL image is returned and exception describes the reason for the % failure. % % The format of the CloneImage method is: % % Image *CloneImage(const Image *image,const size_t columns, % const size_t rows,const MagickBooleanType orphan, % ExceptionInfo *exception) % % A description of each parameter follows: % % o image: the image. % % o columns: the number of columns in the cloned image. % % o rows: the number of rows in the cloned image. % % o detach: With a value other than 0, the cloned image is detached from % its parent I/O stream. % % o exception: return any errors or warnings in this structure. % */ MagickExport Image *CloneImage(const Image *image,const size_t columns, const size_t rows,const MagickBooleanType detach,ExceptionInfo *exception) { Image *clone_image; double scale; size_t length; /* Clone the image. */ assert(image != (const Image *) NULL); assert(image->signature == MagickCoreSignature); if (image->debug != MagickFalse) (void) LogMagickEvent(TraceEvent,GetMagickModule(),"%s",image->filename); assert(exception != (ExceptionInfo *) NULL); assert(exception->signature == MagickCoreSignature); if ((image->columns == 0) || (image->rows == 0)) { (void) ThrowMagickException(exception,GetMagickModule(),CorruptImageError, "NegativeOrZeroImageSize","`%s'",image->filename); return((Image *) NULL); } clone_image=(Image *) AcquireCriticalMemory(sizeof(*clone_image)); (void) memset(clone_image,0,sizeof(*clone_image)); clone_image->signature=MagickCoreSignature; clone_image->storage_class=image->storage_class; clone_image->number_channels=image->number_channels; clone_image->number_meta_channels=image->number_meta_channels; clone_image->metacontent_extent=image->metacontent_extent; clone_image->colorspace=image->colorspace; clone_image->alpha_trait=image->alpha_trait; clone_image->channels=image->channels; clone_image->mask_trait=image->mask_trait; clone_image->columns=image->columns; clone_image->rows=image->rows; clone_image->dither=image->dither; clone_image->image_info=CloneImageInfo(image->image_info); (void) CloneImageProfiles(clone_image,image); (void) CloneImageProperties(clone_image,image); (void) CloneImageArtifacts(clone_image,image); GetTimerInfo(&clone_image->timer); if (image->ascii85 != (void *) NULL) Ascii85Initialize(clone_image); clone_image->extent=image->extent; clone_image->magick_columns=image->magick_columns; clone_image->magick_rows=image->magick_rows; clone_image->type=image->type; clone_image->channel_mask=image->channel_mask; clone_image->channel_map=ClonePixelChannelMap(image->channel_map); (void) CopyMagickString(clone_image->magick_filename,image->magick_filename, MagickPathExtent); (void) CopyMagickString(clone_image->magick,image->magick,MagickPathExtent); (void) CopyMagickString(clone_image->filename,image->filename, MagickPathExtent); clone_image->progress_monitor=image->progress_monitor; clone_image->client_data=image->client_data; clone_image->reference_count=1; clone_image->next=image->next; clone_image->previous=image->previous; clone_image->list=NewImageList(); if (detach == MagickFalse) clone_image->blob=ReferenceBlob(image->blob); else { clone_image->next=NewImageList(); clone_image->previous=NewImageList(); clone_image->blob=CloneBlobInfo((BlobInfo *) NULL); } clone_image->ping=image->ping; clone_image->debug=IsEventLogging(); clone_image->semaphore=AcquireSemaphoreInfo(); if (image->colormap != (PixelInfo *) NULL) { /* Allocate and copy the image colormap. */ clone_image->colors=image->colors; length=(size_t) image->colors; clone_image->colormap=(PixelInfo *) AcquireQuantumMemory(length+1, sizeof(*clone_image->colormap)); if (clone_image->colormap == (PixelInfo *) NULL) { clone_image=DestroyImage(clone_image); ThrowImageException(ResourceLimitError,"MemoryAllocationFailed"); } (void) memcpy(clone_image->colormap,image->colormap,length* sizeof(*clone_image->colormap)); } if ((columns == 0) || (rows == 0)) { if (image->montage != (char *) NULL) (void) CloneString(&clone_image->montage,image->montage); if (image->directory != (char *) NULL) (void) CloneString(&clone_image->directory,image->directory); clone_image->cache=ReferencePixelCache(image->cache); return(clone_image); } scale=1.0; if (image->columns != 0) scale=(double) columns/(double) image->columns; clone_image->page.width=(size_t) floor(scale*image->page.width+0.5); clone_image->page.x=(ssize_t) ceil(scale*image->page.x-0.5); clone_image->tile_offset.x=(ssize_t) ceil(scale*image->tile_offset.x-0.5); scale=1.0; if (image->rows != 0) scale=(double) rows/(double) image->rows; clone_image->page.height=(size_t) floor(scale*image->page.height+0.5); clone_image->page.y=(ssize_t) ceil(scale*image->page.y-0.5); clone_image->tile_offset.y=(ssize_t) ceil(scale*image->tile_offset.y-0.5); clone_image->cache=ClonePixelCache(image->cache); if (SetImageExtent(clone_image,columns,rows,exception) == MagickFalse) clone_image=DestroyImage(clone_image); return(clone_image); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % C l o n e I m a g e I n f o % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % CloneImageInfo() makes a copy of the given image info structure. If % NULL is specified, a new image info structure is created initialized to % default values. % % The format of the CloneImageInfo method is: % % ImageInfo *CloneImageInfo(const ImageInfo *image_info) % % A description of each parameter follows: % % o image_info: the image info. % */ MagickExport ImageInfo *CloneImageInfo(const ImageInfo *image_info) { ImageInfo *clone_info; clone_info=AcquireImageInfo(); if (image_info == (ImageInfo *) NULL) return(clone_info); clone_info->compression=image_info->compression; clone_info->temporary=image_info->temporary; clone_info->adjoin=image_info->adjoin; clone_info->antialias=image_info->antialias; clone_info->scene=image_info->scene; clone_info->number_scenes=image_info->number_scenes; clone_info->depth=image_info->depth; if (image_info->size != (char *) NULL) (void) CloneString(&clone_info->size,image_info->size); if (image_info->extract != (char *) NULL) (void) CloneString(&clone_info->extract,image_info->extract); if (image_info->scenes != (char *) NULL) (void) CloneString(&clone_info->scenes,image_info->scenes); if (image_info->page != (char *) NULL) (void) CloneString(&clone_info->page,image_info->page); clone_info->interlace=image_info->interlace; clone_info->endian=image_info->endian; clone_info->units=image_info->units; clone_info->quality=image_info->quality; if (image_info->sampling_factor != (char *) NULL) (void) CloneString(&clone_info->sampling_factor, image_info->sampling_factor); if (image_info->server_name != (char *) NULL) (void) CloneString(&clone_info->server_name,image_info->server_name); if (image_info->font != (char *) NULL) (void) CloneString(&clone_info->font,image_info->font); if (image_info->texture != (char *) NULL) (void) CloneString(&clone_info->texture,image_info->texture); if (image_info->density != (char *) NULL) (void) CloneString(&clone_info->density,image_info->density); clone_info->pointsize=image_info->pointsize; clone_info->fuzz=image_info->fuzz; clone_info->matte_color=image_info->matte_color; clone_info->background_color=image_info->background_color; clone_info->border_color=image_info->border_color; clone_info->transparent_color=image_info->transparent_color; clone_info->dither=image_info->dither; clone_info->monochrome=image_info->monochrome; clone_info->colorspace=image_info->colorspace; clone_info->type=image_info->type; clone_info->orientation=image_info->orientation; clone_info->ping=image_info->ping; clone_info->verbose=image_info->verbose; clone_info->progress_monitor=image_info->progress_monitor; clone_info->client_data=image_info->client_data; clone_info->cache=image_info->cache; if (image_info->cache != (void *) NULL) clone_info->cache=ReferencePixelCache(image_info->cache); if (image_info->profile != (void *) NULL) clone_info->profile=(void *) CloneStringInfo((StringInfo *) image_info->profile); SetImageInfoFile(clone_info,image_info->file); SetImageInfoBlob(clone_info,image_info->blob,image_info->length); clone_info->stream=image_info->stream; clone_info->custom_stream=image_info->custom_stream; (void) CopyMagickString(clone_info->magick,image_info->magick, MagickPathExtent); (void) CopyMagickString(clone_info->unique,image_info->unique, MagickPathExtent); (void) CopyMagickString(clone_info->filename,image_info->filename, MagickPathExtent); clone_info->channel=image_info->channel; (void) CloneImageOptions(clone_info,image_info); clone_info->debug=IsEventLogging(); clone_info->signature=image_info->signature; return(clone_info); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % C o p y I m a g e P i x e l s % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % CopyImagePixels() copies pixels from the source image as defined by the % geometry the destination image at the specified offset. % % The format of the CopyImagePixels method is: % % MagickBooleanType CopyImagePixels(Image *image,const Image *source_image, % const RectangleInfo *geometry,const OffsetInfo *offset, % ExceptionInfo *exception); % % A description of each parameter follows: % % o image: the destination image. % % o source_image: the source image. % % o geometry: define the dimensions of the source pixel rectangle. % % o offset: define the offset in the destination image. % % o exception: return any errors or warnings in this structure. % */ MagickExport MagickBooleanType CopyImagePixels(Image *image, const Image *source_image,const RectangleInfo *geometry, const OffsetInfo *offset,ExceptionInfo *exception) { #define CopyImageTag "Copy/Image" CacheView *image_view, *source_view; MagickBooleanType status; MagickOffsetType progress; ssize_t y; assert(image != (Image *) NULL); if (image->debug != MagickFalse) (void) LogMagickEvent(TraceEvent,GetMagickModule(),"..."); assert(source_image != (Image *) NULL); assert(geometry != (RectangleInfo *) NULL); assert(offset != (OffsetInfo *) NULL); if ((offset->x < 0) || (offset->y < 0) || ((ssize_t) (offset->x+geometry->width) > (ssize_t) image->columns) || ((ssize_t) (offset->y+geometry->height) > (ssize_t) image->rows)) ThrowBinaryException(OptionError,"GeometryDoesNotContainImage", image->filename); if (SetImageStorageClass(image,DirectClass,exception) == MagickFalse) return(MagickFalse); /* Copy image pixels. */ status=MagickTrue; progress=0; source_view=AcquireVirtualCacheView(source_image,exception); image_view=AcquireAuthenticCacheView(image,exception); #if defined(MAGICKCORE_OPENMP_SUPPORT) #pragma omp parallel for schedule(static) shared(progress,status) \ magick_number_threads(image,source_image,geometry->height,1) #endif for (y=0; y < (ssize_t) geometry->height; y++) { MagickBooleanType sync; register const Quantum *magick_restrict p; register ssize_t x; register Quantum *magick_restrict q; if (status == MagickFalse) continue; p=GetCacheViewVirtualPixels(source_view,geometry->x,y+geometry->y, geometry->width,1,exception); q=QueueCacheViewAuthenticPixels(image_view,offset->x,y+offset->y, geometry->width,1,exception); if ((p == (const Quantum *) NULL) || (q == (Quantum *) NULL)) { status=MagickFalse; continue; } for (x=0; x < (ssize_t) geometry->width; x++) { register ssize_t i; for (i=0; i < (ssize_t) GetPixelChannels(image); i++) { PixelChannel channel = GetPixelChannelChannel(image,i); PixelTrait traits = GetPixelChannelTraits(image,channel); PixelTrait source_traits=GetPixelChannelTraits(source_image,channel); if ((traits == UndefinedPixelTrait) || ((traits & UpdatePixelTrait) == 0) || (source_traits == UndefinedPixelTrait)) continue; SetPixelChannel(image,channel,p[i],q); } p+=GetPixelChannels(source_image); q+=GetPixelChannels(image); } sync=SyncCacheViewAuthenticPixels(image_view,exception); if (sync == MagickFalse) status=MagickFalse; if (image->progress_monitor != (MagickProgressMonitor) NULL) { MagickBooleanType proceed; #if defined(MAGICKCORE_OPENMP_SUPPORT) #pragma omp atomic #endif progress++; proceed=SetImageProgress(image,CopyImageTag,progress,image->rows); if (proceed == MagickFalse) status=MagickFalse; } } source_view=DestroyCacheView(source_view); image_view=DestroyCacheView(image_view); return(status); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % D e s t r o y I m a g e % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % DestroyImage() dereferences an image, deallocating memory associated with % the image if the reference count becomes zero. % % The format of the DestroyImage method is: % % Image *DestroyImage(Image *image) % % A description of each parameter follows: % % o image: the image. % */ MagickExport Image *DestroyImage(Image *image) { MagickBooleanType destroy; /* Dereference image. */ assert(image != (Image *) NULL); assert(image->signature == MagickCoreSignature); if (image->debug != MagickFalse) (void) LogMagickEvent(TraceEvent,GetMagickModule(),"%s",image->filename); destroy=MagickFalse; LockSemaphoreInfo(image->semaphore); image->reference_count--; if (image->reference_count == 0) destroy=MagickTrue; UnlockSemaphoreInfo(image->semaphore); if (destroy == MagickFalse) return((Image *) NULL); /* Destroy image. */ DestroyImagePixels(image); image->channel_map=DestroyPixelChannelMap(image->channel_map); if (image->montage != (char *) NULL) image->montage=DestroyString(image->montage); if (image->directory != (char *) NULL) image->directory=DestroyString(image->directory); if (image->colormap != (PixelInfo *) NULL) image->colormap=(PixelInfo *) RelinquishMagickMemory(image->colormap); if (image->geometry != (char *) NULL) image->geometry=DestroyString(image->geometry); DestroyImageProfiles(image); DestroyImageProperties(image); DestroyImageArtifacts(image); if (image->ascii85 != (Ascii85Info *) NULL) image->ascii85=(Ascii85Info *) RelinquishMagickMemory(image->ascii85); if (image->image_info != (ImageInfo *) NULL) image->image_info=DestroyImageInfo(image->image_info); DestroyBlob(image); if (image->semaphore != (SemaphoreInfo *) NULL) RelinquishSemaphoreInfo(&image->semaphore); image->signature=(~MagickCoreSignature); image=(Image *) RelinquishMagickMemory(image); return(image); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % D e s t r o y I m a g e I n f o % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % DestroyImageInfo() deallocates memory associated with an ImageInfo % structure. % % The format of the DestroyImageInfo method is: % % ImageInfo *DestroyImageInfo(ImageInfo *image_info) % % A description of each parameter follows: % % o image_info: the image info. % */ MagickExport ImageInfo *DestroyImageInfo(ImageInfo *image_info) { assert(image_info != (ImageInfo *) NULL); assert(image_info->signature == MagickCoreSignature); if (image_info->debug != MagickFalse) (void) LogMagickEvent(TraceEvent,GetMagickModule(),"%s", image_info->filename); if (image_info->size != (char *) NULL) image_info->size=DestroyString(image_info->size); if (image_info->extract != (char *) NULL) image_info->extract=DestroyString(image_info->extract); if (image_info->scenes != (char *) NULL) image_info->scenes=DestroyString(image_info->scenes); if (image_info->page != (char *) NULL) image_info->page=DestroyString(image_info->page); if (image_info->sampling_factor != (char *) NULL) image_info->sampling_factor=DestroyString( image_info->sampling_factor); if (image_info->server_name != (char *) NULL) image_info->server_name=DestroyString( image_info->server_name); if (image_info->font != (char *) NULL) image_info->font=DestroyString(image_info->font); if (image_info->texture != (char *) NULL) image_info->texture=DestroyString(image_info->texture); if (image_info->density != (char *) NULL) image_info->density=DestroyString(image_info->density); if (image_info->cache != (void *) NULL) image_info->cache=DestroyPixelCache(image_info->cache); if (image_info->profile != (StringInfo *) NULL) image_info->profile=(void *) DestroyStringInfo((StringInfo *) image_info->profile); DestroyImageOptions(image_info); image_info->signature=(~MagickCoreSignature); image_info=(ImageInfo *) RelinquishMagickMemory(image_info); return(image_info); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % + D i s a s s o c i a t e I m a g e S t r e a m % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % DisassociateImageStream() disassociates the image stream. It checks if the % blob of the specified image is referenced by other images. If the reference % count is higher then 1 a new blob is assigned to the specified image. % % The format of the DisassociateImageStream method is: % % void DisassociateImageStream(const Image *image) % % A description of each parameter follows: % % o image: the image. % */ MagickExport void DisassociateImageStream(Image *image) { assert(image != (Image *) NULL); assert(image->signature == MagickCoreSignature); if (image->debug != MagickFalse) (void) LogMagickEvent(TraceEvent,GetMagickModule(),"%s",image->filename); DisassociateBlob(image); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % G e t I m a g e I n f o % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % GetImageInfo() initializes image_info to default values. % % The format of the GetImageInfo method is: % % void GetImageInfo(ImageInfo *image_info) % % A description of each parameter follows: % % o image_info: the image info. % */ MagickExport void GetImageInfo(ImageInfo *image_info) { char *synchronize; ExceptionInfo *exception; /* File and image dimension members. */ (void) LogMagickEvent(TraceEvent,GetMagickModule(),"..."); assert(image_info != (ImageInfo *) NULL); (void) memset(image_info,0,sizeof(*image_info)); image_info->adjoin=MagickTrue; image_info->interlace=NoInterlace; image_info->channel=DefaultChannels; image_info->quality=UndefinedCompressionQuality; image_info->antialias=MagickTrue; image_info->dither=MagickTrue; synchronize=GetEnvironmentValue("MAGICK_SYNCHRONIZE"); if (synchronize != (const char *) NULL) { image_info->synchronize=IsStringTrue(synchronize); synchronize=DestroyString(synchronize); } exception=AcquireExceptionInfo(); (void) QueryColorCompliance(BackgroundColor,AllCompliance, &image_info->background_color,exception); (void) QueryColorCompliance(BorderColor,AllCompliance, &image_info->border_color,exception); (void) QueryColorCompliance(MatteColor,AllCompliance,&image_info->matte_color, exception); (void) QueryColorCompliance(TransparentColor,AllCompliance, &image_info->transparent_color,exception); exception=DestroyExceptionInfo(exception); image_info->debug=IsEventLogging(); image_info->signature=MagickCoreSignature; } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % G e t I m a g e I n f o F i l e % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % GetImageInfoFile() returns the image info file member. % % The format of the GetImageInfoFile method is: % % FILE *GetImageInfoFile(const ImageInfo *image_info) % % A description of each parameter follows: % % o image_info: the image info. % */ MagickExport FILE *GetImageInfoFile(const ImageInfo *image_info) { return(image_info->file); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % G e t I m a g e M a s k % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % GetImageMask() returns the mask associated with the image. % % The format of the GetImageMask method is: % % Image *GetImageMask(const Image *image,const PixelMask type, % ExceptionInfo *exception) % % A description of each parameter follows: % % o image: the image. % % o type: the mask type, ReadPixelMask or WritePixelMask. % */ MagickExport Image *GetImageMask(const Image *image,const PixelMask type, ExceptionInfo *exception) { CacheView *mask_view, *image_view; Image *mask_image; MagickBooleanType status; ssize_t y; /* Get image mask. */ assert(image != (Image *) NULL); if (image->debug != MagickFalse) (void) LogMagickEvent(TraceEvent,GetMagickModule(),"..."); assert(image->signature == MagickCoreSignature); switch (type) { case ReadPixelMask: { if ((image->channels & ReadMaskChannel) == 0) return((Image *) NULL); break; } case WritePixelMask: { if ((image->channels & WriteMaskChannel) == 0) return((Image *) NULL); break; } default: { if ((image->channels & CompositeMaskChannel) == 0) return((Image *) NULL); break; } } mask_image=AcquireImage((ImageInfo *) NULL,exception); status=SetImageExtent(mask_image,image->columns,image->rows,exception); if (status == MagickFalse) return(DestroyImage(mask_image)); status=MagickTrue; mask_image->alpha_trait=UndefinedPixelTrait; (void) SetImageColorspace(mask_image,GRAYColorspace,exception); image_view=AcquireVirtualCacheView(image,exception); mask_view=AcquireAuthenticCacheView(mask_image,exception); for (y=0; y < (ssize_t) image->rows; y++) { register const Quantum *magick_restrict p; register Quantum *magick_restrict q; register ssize_t x; if (status == MagickFalse) continue; p=GetCacheViewVirtualPixels(image_view,0,y,image->columns,1,exception); q=GetCacheViewAuthenticPixels(mask_view,0,y,mask_image->columns,1, exception); if ((p == (const Quantum *) NULL) || (q == (Quantum *) NULL)) { status=MagickFalse; continue; } for (x=0; x < (ssize_t) image->columns; x++) { switch (type) { case ReadPixelMask: { SetPixelGray(mask_image,GetPixelReadMask(image,p),q); break; } case WritePixelMask: { SetPixelGray(mask_image,GetPixelWriteMask(image,p),q); break; } default: { SetPixelGray(mask_image,GetPixelCompositeMask(image,p),q); break; } } p+=GetPixelChannels(image); q+=GetPixelChannels(mask_image); } if (SyncCacheViewAuthenticPixels(mask_view,exception) == MagickFalse) status=MagickFalse; } mask_view=DestroyCacheView(mask_view); image_view=DestroyCacheView(image_view); if (status == MagickFalse) mask_image=DestroyImage(mask_image); return(mask_image); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % + G e t I m a g e R e f e r e n c e C o u n t % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % GetImageReferenceCount() returns the image reference count. % % The format of the GetReferenceCount method is: % % ssize_t GetImageReferenceCount(Image *image) % % A description of each parameter follows: % % o image: the image. % */ MagickExport ssize_t GetImageReferenceCount(Image *image) { ssize_t reference_count; assert(image != (Image *) NULL); assert(image->signature == MagickCoreSignature); if (image->debug != MagickFalse) (void) LogMagickEvent(TraceEvent,GetMagickModule(),"%s",image->filename); LockSemaphoreInfo(image->semaphore); reference_count=image->reference_count; UnlockSemaphoreInfo(image->semaphore); return(reference_count); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % G e t I m a g e V i r t u a l P i x e l M e t h o d % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % GetImageVirtualPixelMethod() gets the "virtual pixels" method for the % image. A virtual pixel is any pixel access that is outside the boundaries % of the image cache. % % The format of the GetImageVirtualPixelMethod() method is: % % VirtualPixelMethod GetImageVirtualPixelMethod(const Image *image) % % A description of each parameter follows: % % o image: the image. % */ MagickExport VirtualPixelMethod GetImageVirtualPixelMethod(const Image *image) { assert(image != (Image *) NULL); assert(image->signature == MagickCoreSignature); if (image->debug != MagickFalse) (void) LogMagickEvent(TraceEvent,GetMagickModule(),"%s",image->filename); return(GetPixelCacheVirtualMethod(image)); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % I n t e r p r e t I m a g e F i l e n a m e % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % InterpretImageFilename() interprets embedded characters in an image filename. % The filename length is returned. % % The format of the InterpretImageFilename method is: % % size_t InterpretImageFilename(const ImageInfo *image_info,Image *image, % const char *format,int value,char *filename,ExceptionInfo *exception) % % A description of each parameter follows. % % o image_info: the image info.. % % o image: the image. % % o format: A filename describing the format to use to write the numeric % argument. Only the first numeric format identifier is replaced. % % o value: Numeric value to substitute into format filename. % % o filename: return the formatted filename in this character buffer. % % o exception: return any errors or warnings in this structure. % */ MagickExport size_t InterpretImageFilename(const ImageInfo *image_info, Image *image,const char *format,int value,char *filename, ExceptionInfo *exception) { char *q; int c; MagickBooleanType canonical; register const char *p; ssize_t field_width, offset; canonical=MagickFalse; offset=0; (void) CopyMagickString(filename,format,MagickPathExtent); for (p=strchr(format,'%'); p != (char *) NULL; p=strchr(p+1,'%')) { q=(char *) p+1; if (*q == '%') { p=q+1; continue; } field_width=0; if (*q == '0') field_width=(ssize_t) strtol(q,&q,10); switch (*q) { case 'd': case 'o': case 'x': { q++; c=(*q); *q='\0'; (void) FormatLocaleString(filename+(p-format-offset),(size_t) (MagickPathExtent-(p-format-offset)),p,value); offset+=(4-field_width); *q=c; (void) ConcatenateMagickString(filename,q,MagickPathExtent); canonical=MagickTrue; if (*(q-1) != '%') break; p++; break; } case '[': { char pattern[MagickPathExtent]; const char *option; register char *r; register ssize_t i; ssize_t depth; /* Image option. */ if (strchr(p,']') == (char *) NULL) break; depth=1; r=q+1; for (i=0; (i < (MagickPathExtent-1L)) && (*r != '\0'); i++) { if (*r == '[') depth++; if (*r == ']') depth--; if (depth <= 0) break; pattern[i]=(*r++); } pattern[i]='\0'; if (LocaleNCompare(pattern,"filename:",9) != 0) break; option=(const char *) NULL; if (image != (Image *) NULL) option=GetImageProperty(image,pattern,exception); if ((option == (const char *) NULL) && (image != (Image *) NULL)) option=GetImageArtifact(image,pattern); if ((option == (const char *) NULL) && (image_info != (ImageInfo *) NULL)) option=GetImageOption(image_info,pattern); if (option == (const char *) NULL) break; q--; c=(*q); *q='\0'; (void) CopyMagickString(filename+(p-format-offset),option,(size_t) (MagickPathExtent-(p-format-offset))); offset+=strlen(pattern)-strlen(option)+3; *q=c; (void) ConcatenateMagickString(filename,r+1,MagickPathExtent); canonical=MagickTrue; if (*(q-1) != '%') break; p++; break; } default: break; } } if (canonical == MagickFalse) (void) CopyMagickString(filename,format,MagickPathExtent); else for (q=filename; *q != '\0'; q++) if ((*q == '%') && (*(q+1) == '%')) (void) CopyMagickString(q,q+1,(size_t) (MagickPathExtent-(q-filename))); return(strlen(filename)); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % I s H i g h D y n a m i c R a n g e I m a g e % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % IsHighDynamicRangeImage() returns MagickTrue if any pixel component is % non-integer or exceeds the bounds of the quantum depth (e.g. for Q16 % 0..65535. % % The format of the IsHighDynamicRangeImage method is: % % MagickBooleanType IsHighDynamicRangeImage(const Image *image, % ExceptionInfo *exception) % % A description of each parameter follows: % % o image: the image. % % o exception: return any errors or warnings in this structure. % */ MagickExport MagickBooleanType IsHighDynamicRangeImage(const Image *image, ExceptionInfo *exception) { #if !defined(MAGICKCORE_HDRI_SUPPORT) (void) image; (void) exception; return(MagickFalse); #else CacheView *image_view; MagickBooleanType status; ssize_t y; assert(image != (Image *) NULL); assert(image->signature == MagickCoreSignature); if (image->debug != MagickFalse) (void) LogMagickEvent(TraceEvent,GetMagickModule(),"%s",image->filename); status=MagickTrue; image_view=AcquireVirtualCacheView(image,exception); #if defined(MAGICKCORE_OPENMP_SUPPORT) #pragma omp parallel for schedule(static) shared(status) \ magick_number_threads(image,image,image->rows,1) #endif for (y=0; y < (ssize_t) image->rows; y++) { register const Quantum *p; register ssize_t x; if (status == MagickFalse) continue; p=GetCacheViewVirtualPixels(image_view,0,y,image->columns,1,exception); if (p == (const Quantum *) NULL) { status=MagickFalse; continue; } for (x=0; x < (ssize_t) image->columns; x++) { register ssize_t i; for (i=0; i < (ssize_t) GetPixelChannels(image); i++) { double pixel; PixelTrait traits; traits=GetPixelChannelTraits(image,(PixelChannel) i); if (traits == UndefinedPixelTrait) continue; pixel=(double) p[i]; if ((pixel < 0.0) || (pixel > QuantumRange) || (pixel != (double) ((QuantumAny) pixel))) break; } p+=GetPixelChannels(image); if (i < (ssize_t) GetPixelChannels(image)) status=MagickFalse; } if (x < (ssize_t) image->columns) status=MagickFalse; } image_view=DestroyCacheView(image_view); return(status != MagickFalse ? MagickFalse : MagickTrue); #endif } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % I s I m a g e O b j e c t % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % IsImageObject() returns MagickTrue if the image sequence contains a valid % set of image objects. % % The format of the IsImageObject method is: % % MagickBooleanType IsImageObject(const Image *image) % % A description of each parameter follows: % % o image: the image. % */ MagickExport MagickBooleanType IsImageObject(const Image *image) { register const Image *p; assert(image != (Image *) NULL); if (image->debug != MagickFalse) (void) LogMagickEvent(TraceEvent,GetMagickModule(),"..."); for (p=image; p != (Image *) NULL; p=GetNextImageInList(p)) if (p->signature != MagickCoreSignature) return(MagickFalse); return(MagickTrue); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % I s T a i n t I m a g e % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % IsTaintImage() returns MagickTrue any pixel in the image has been altered % since it was first constituted. % % The format of the IsTaintImage method is: % % MagickBooleanType IsTaintImage(const Image *image) % % A description of each parameter follows: % % o image: the image. % */ MagickExport MagickBooleanType IsTaintImage(const Image *image) { char magick[MagickPathExtent], filename[MagickPathExtent]; register const Image *p; assert(image != (Image *) NULL); if (image->debug != MagickFalse) (void) LogMagickEvent(TraceEvent,GetMagickModule(),"..."); assert(image->signature == MagickCoreSignature); (void) CopyMagickString(magick,image->magick,MagickPathExtent); (void) CopyMagickString(filename,image->filename,MagickPathExtent); for (p=image; p != (Image *) NULL; p=GetNextImageInList(p)) { if (p->taint != MagickFalse) return(MagickTrue); if (LocaleCompare(p->magick,magick) != 0) return(MagickTrue); if (LocaleCompare(p->filename,filename) != 0) return(MagickTrue); } return(MagickFalse); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % M o d i f y I m a g e % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % ModifyImage() ensures that there is only a single reference to the image % to be modified, updating the provided image pointer to point to a clone of % the original image if necessary. % % The format of the ModifyImage method is: % % MagickBooleanType ModifyImage(Image *image,ExceptionInfo *exception) % % A description of each parameter follows: % % o image: the image. % % o exception: return any errors or warnings in this structure. % */ MagickExport MagickBooleanType ModifyImage(Image **image, ExceptionInfo *exception) { Image *clone_image; assert(image != (Image **) NULL); assert(*image != (Image *) NULL); assert((*image)->signature == MagickCoreSignature); if ((*image)->debug != MagickFalse) (void) LogMagickEvent(TraceEvent,GetMagickModule(),"%s",(*image)->filename); if (GetImageReferenceCount(*image) <= 1) return(MagickTrue); clone_image=CloneImage(*image,0,0,MagickTrue,exception); LockSemaphoreInfo((*image)->semaphore); (*image)->reference_count--; UnlockSemaphoreInfo((*image)->semaphore); *image=clone_image; return(MagickTrue); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % N e w M a g i c k I m a g e % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % NewMagickImage() creates a blank image canvas of the specified size and % background color. % % The format of the NewMagickImage method is: % % Image *NewMagickImage(const ImageInfo *image_info,const size_t width, % const size_t height,const PixelInfo *background, % ExceptionInfo *exception) % % A description of each parameter follows: % % o image: the image. % % o width: the image width. % % o height: the image height. % % o background: the image color. % % o exception: return any errors or warnings in this structure. % */ MagickExport Image *NewMagickImage(const ImageInfo *image_info, const size_t width,const size_t height,const PixelInfo *background, ExceptionInfo *exception) { CacheView *image_view; Image *image; MagickBooleanType status; ssize_t y; assert(image_info != (const ImageInfo *) NULL); if (image_info->debug != MagickFalse) (void) LogMagickEvent(TraceEvent,GetMagickModule(),"..."); assert(image_info->signature == MagickCoreSignature); assert(background != (const PixelInfo *) NULL); image=AcquireImage(image_info,exception); image->columns=width; image->rows=height; image->colorspace=background->colorspace; image->alpha_trait=background->alpha_trait; image->fuzz=background->fuzz; image->depth=background->depth; status=MagickTrue; image_view=AcquireAuthenticCacheView(image,exception); #if defined(MAGICKCORE_OPENMP_SUPPORT) #pragma omp parallel for schedule(static) shared(status) \ magick_number_threads(image,image,image->rows,1) #endif for (y=0; y < (ssize_t) image->rows; y++) { register Quantum *magick_restrict q; register ssize_t x; if (status == MagickFalse) continue; q=QueueCacheViewAuthenticPixels(image_view,0,y,image->columns,1,exception); if (q == (Quantum *) NULL) { status=MagickFalse; continue; } for (x=0; x < (ssize_t) image->columns; x++) { SetPixelViaPixelInfo(image,background,q); q+=GetPixelChannels(image); } if (SyncCacheViewAuthenticPixels(image_view,exception) == MagickFalse) status=MagickFalse; } image_view=DestroyCacheView(image_view); if (status == MagickFalse) image=DestroyImage(image); return(image); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % R e f e r e n c e I m a g e % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % ReferenceImage() increments the reference count associated with an image % returning a pointer to the image. % % The format of the ReferenceImage method is: % % Image *ReferenceImage(Image *image) % % A description of each parameter follows: % % o image: the image. % */ MagickExport Image *ReferenceImage(Image *image) { assert(image != (Image *) NULL); if (image->debug != MagickFalse) (void) LogMagickEvent(TraceEvent,GetMagickModule(),"..."); assert(image->signature == MagickCoreSignature); LockSemaphoreInfo(image->semaphore); image->reference_count++; UnlockSemaphoreInfo(image->semaphore); return(image); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % R e s e t I m a g e P a g e % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % ResetImagePage() resets the image page canvas and position. % % The format of the ResetImagePage method is: % % MagickBooleanType ResetImagePage(Image *image,const char *page) % % A description of each parameter follows: % % o image: the image. % % o page: the relative page specification. % */ MagickExport MagickBooleanType ResetImagePage(Image *image,const char *page) { MagickStatusType flags; RectangleInfo geometry; assert(image != (Image *) NULL); assert(image->signature == MagickCoreSignature); if (image->debug != MagickFalse) (void) LogMagickEvent(TraceEvent,GetMagickModule(),"%s",image->filename); flags=ParseAbsoluteGeometry(page,&geometry); if ((flags & WidthValue) != 0) { if ((flags & HeightValue) == 0) geometry.height=geometry.width; image->page.width=geometry.width; image->page.height=geometry.height; } if ((flags & AspectValue) != 0) { if ((flags & XValue) != 0) image->page.x+=geometry.x; if ((flags & YValue) != 0) image->page.y+=geometry.y; } else { if ((flags & XValue) != 0) { image->page.x=geometry.x; if ((image->page.width == 0) && (geometry.x > 0)) image->page.width=image->columns+geometry.x; } if ((flags & YValue) != 0) { image->page.y=geometry.y; if ((image->page.height == 0) && (geometry.y > 0)) image->page.height=image->rows+geometry.y; } } return(MagickTrue); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % R e s e t I m a g e P i x e l s % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % ResetImagePixels() reset the image pixels, that is, all the pixel components % are zereod. % % The format of the SetImage method is: % % MagickBooleanType ResetImagePixels(Image *image, % ExceptionInfo *exception) % % A description of each parameter follows: % % o image: the image. % % o exception: return any errors or warnings in this structure. % */ MagickExport MagickBooleanType ResetImagePixels(Image *image, ExceptionInfo *exception) { CacheView *image_view; MagickBooleanType status; size_t length; ssize_t y; void *pixels; assert(image != (Image *) NULL); if (image->debug != MagickFalse) (void) LogMagickEvent(TraceEvent,GetMagickModule(),"..."); assert(image->signature == MagickCoreSignature); pixels=AcquirePixelCachePixels(image,&length,exception); if (pixels != (void *) NULL) { /* Reset in-core image pixels. */ (void) memset(pixels,0,length); return(MagickTrue); } /* Reset image pixels. */ status=MagickTrue; image_view=AcquireAuthenticCacheView(image,exception); #if defined(MAGICKCORE_OPENMP_SUPPORT) #pragma omp parallel for schedule(static) shared(status) \ magick_number_threads(image,image,image->rows,1) #endif for (y=0; y < (ssize_t) image->rows; y++) { register Quantum *magick_restrict q; register ssize_t x; if (status == MagickFalse) continue; q=QueueCacheViewAuthenticPixels(image_view,0,y,image->columns,1,exception); if (q == (Quantum *) NULL) { status=MagickFalse; continue; } for (x=0; x < (ssize_t) image->columns; x++) { (void) memset(q,0,GetPixelChannels(image)*sizeof(Quantum)); q+=GetPixelChannels(image); } if (SyncCacheViewAuthenticPixels(image_view,exception) == MagickFalse) status=MagickFalse; } image_view=DestroyCacheView(image_view); return(status); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % S e t I m a g e A l p h a % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % SetImageAlpha() sets the alpha levels of the image. % % The format of the SetImageAlpha method is: % % MagickBooleanType SetImageAlpha(Image *image,const Quantum alpha, % ExceptionInfo *exception) % % A description of each parameter follows: % % o image: the image. % % o alpha: the level of transparency: 0 is fully transparent and QuantumRange % is fully opaque. % % o exception: return any errors or warnings in this structure. % */ MagickExport MagickBooleanType SetImageAlpha(Image *image,const Quantum alpha, ExceptionInfo *exception) { CacheView *image_view; MagickBooleanType status; ssize_t y; assert(image != (Image *) NULL); if (image->debug != MagickFalse) (void) LogMagickEvent(TraceEvent,GetMagickModule(),"..."); assert(image->signature == MagickCoreSignature); image->alpha_trait=BlendPixelTrait; status=MagickTrue; image_view=AcquireAuthenticCacheView(image,exception); #if defined(MAGICKCORE_OPENMP_SUPPORT) #pragma omp parallel for schedule(static) shared(status) \ magick_number_threads(image,image,image->rows,1) #endif for (y=0; y < (ssize_t) image->rows; y++) { register Quantum *magick_restrict q; register ssize_t x; if (status == MagickFalse) continue; q=GetCacheViewAuthenticPixels(image_view,0,y,image->columns,1,exception); if (q == (Quantum *) NULL) { status=MagickFalse; continue; } for (x=0; x < (ssize_t) image->columns; x++) { SetPixelAlpha(image,alpha,q); q+=GetPixelChannels(image); } if (SyncCacheViewAuthenticPixels(image_view,exception) == MagickFalse) status=MagickFalse; } image_view=DestroyCacheView(image_view); return(status); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % S e t I m a g e B a c k g r o u n d C o l o r % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % SetImageBackgroundColor() initializes the image pixels to the image % background color. The background color is defined by the background_color % member of the image structure. % % The format of the SetImage method is: % % MagickBooleanType SetImageBackgroundColor(Image *image, % ExceptionInfo *exception) % % A description of each parameter follows: % % o image: the image. % % o exception: return any errors or warnings in this structure. % */ MagickExport MagickBooleanType SetImageBackgroundColor(Image *image, ExceptionInfo *exception) { CacheView *image_view; MagickBooleanType status; PixelInfo background; ssize_t y; assert(image != (Image *) NULL); if (image->debug != MagickFalse) (void) LogMagickEvent(TraceEvent,GetMagickModule(),"..."); assert(image->signature == MagickCoreSignature); if (SetImageStorageClass(image,DirectClass,exception) == MagickFalse) return(MagickFalse); if ((image->background_color.alpha_trait != UndefinedPixelTrait) && (image->alpha_trait == UndefinedPixelTrait)) (void) SetImageAlphaChannel(image,OnAlphaChannel,exception); ConformPixelInfo(image,&image->background_color,&background,exception); /* Set image background color. */ status=MagickTrue; image_view=AcquireAuthenticCacheView(image,exception); for (y=0; y < (ssize_t) image->rows; y++) { register Quantum *magick_restrict q; register ssize_t x; if (status == MagickFalse) continue; q=QueueCacheViewAuthenticPixels(image_view,0,y,image->columns,1,exception); if (q == (Quantum *) NULL) { status=MagickFalse; continue; } for (x=0; x < (ssize_t) image->columns; x++) { SetPixelViaPixelInfo(image,&background,q); q+=GetPixelChannels(image); } if (SyncCacheViewAuthenticPixels(image_view,exception) == MagickFalse) status=MagickFalse; } image_view=DestroyCacheView(image_view); return(status); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % S e t I m a g e C h a n n e l M a s k % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % SetImageChannelMask() sets the image channel mask from the specified channel % mask. % % The format of the SetImageChannelMask method is: % % ChannelType SetImageChannelMask(Image *image, % const ChannelType channel_mask) % % A description of each parameter follows: % % o image: the image. % % o channel_mask: the channel mask. % */ MagickExport ChannelType SetImageChannelMask(Image *image, const ChannelType channel_mask) { return(SetPixelChannelMask(image,channel_mask)); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % S e t I m a g e C o l o r % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % SetImageColor() set the entire image canvas to the specified color. % % The format of the SetImageColor method is: % % MagickBooleanType SetImageColor(Image *image,const PixelInfo *color, % ExeptionInfo *exception) % % A description of each parameter follows: % % o image: the image. % % o background: the image color. % % o exception: return any errors or warnings in this structure. % */ MagickExport MagickBooleanType SetImageColor(Image *image, const PixelInfo *color,ExceptionInfo *exception) { CacheView *image_view; MagickBooleanType status; ssize_t y; assert(image != (Image *) NULL); if (image->debug != MagickFalse) (void) LogMagickEvent(TraceEvent,GetMagickModule(),"..."); assert(image->signature == MagickCoreSignature); assert(color != (const PixelInfo *) NULL); image->colorspace=color->colorspace; image->alpha_trait=color->alpha_trait; image->fuzz=color->fuzz; image->depth=color->depth; status=MagickTrue; image_view=AcquireAuthenticCacheView(image,exception); #if defined(MAGICKCORE_OPENMP_SUPPORT) #pragma omp parallel for schedule(static) shared(status) \ magick_number_threads(image,image,image->rows,1) #endif for (y=0; y < (ssize_t) image->rows; y++) { register Quantum *magick_restrict q; register ssize_t x; if (status == MagickFalse) continue; q=QueueCacheViewAuthenticPixels(image_view,0,y,image->columns,1,exception); if (q == (Quantum *) NULL) { status=MagickFalse; continue; } for (x=0; x < (ssize_t) image->columns; x++) { SetPixelViaPixelInfo(image,color,q); q+=GetPixelChannels(image); } if (SyncCacheViewAuthenticPixels(image_view,exception) == MagickFalse) status=MagickFalse; } image_view=DestroyCacheView(image_view); return(status); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % S e t I m a g e S t o r a g e C l a s s % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % SetImageStorageClass() sets the image class: DirectClass for true color % images or PseudoClass for colormapped images. % % The format of the SetImageStorageClass method is: % % MagickBooleanType SetImageStorageClass(Image *image, % const ClassType storage_class,ExceptionInfo *exception) % % A description of each parameter follows: % % o image: the image. % % o storage_class: The image class. % % o exception: return any errors or warnings in this structure. % */ MagickExport MagickBooleanType SetImageStorageClass(Image *image, const ClassType storage_class,ExceptionInfo *exception) { assert(image != (Image *) NULL); assert(image->signature == MagickCoreSignature); if (image->debug != MagickFalse) (void) LogMagickEvent(TraceEvent,GetMagickModule(),"%s",image->filename); assert(exception != (ExceptionInfo *) NULL); assert(exception->signature == MagickCoreSignature); image->storage_class=storage_class; return(SyncImagePixelCache(image,exception)); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % S e t I m a g e E x t e n t % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % SetImageExtent() sets the image size (i.e. columns & rows). % % The format of the SetImageExtent method is: % % MagickBooleanType SetImageExtent(Image *image,const size_t columns, % const size_t rows,ExceptionInfo *exception) % % A description of each parameter follows: % % o image: the image. % % o columns: The image width in pixels. % % o rows: The image height in pixels. % % o exception: return any errors or warnings in this structure. % */ MagickExport MagickBooleanType SetImageExtent(Image *image,const size_t columns, const size_t rows,ExceptionInfo *exception) { if ((columns == 0) || (rows == 0)) ThrowBinaryException(ImageError,"NegativeOrZeroImageSize",image->filename); image->columns=columns; image->rows=rows; if (image->depth == 0) { image->depth=8; (void) ThrowMagickException(exception,GetMagickModule(),ImageError, "ImageDepthNotSupported","`%s'",image->filename); } if (image->depth > (8*sizeof(MagickSizeType))) { image->depth=8*sizeof(MagickSizeType); (void) ThrowMagickException(exception,GetMagickModule(),ImageError, "ImageDepthNotSupported","`%s'",image->filename); } return(SyncImagePixelCache(image,exception)); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % + S e t I m a g e I n f o % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % SetImageInfo() initializes the 'magick' field of the ImageInfo structure. % It is set to a type of image format based on the prefix or suffix of the % filename. For example, 'ps:image' returns PS indicating a Postscript image. % JPEG is returned for this filename: 'image.jpg'. The filename prefix has % precendence over the suffix. Use an optional index enclosed in brackets % after a file name to specify a desired scene of a multi-resolution image % format like Photo CD (e.g. img0001.pcd[4]). A True (non-zero) return value % indicates success. % % The format of the SetImageInfo method is: % % MagickBooleanType SetImageInfo(ImageInfo *image_info, % const unsigned int frames,ExceptionInfo *exception) % % A description of each parameter follows: % % o image_info: the image info. % % o frames: the number of images you intend to write. % % o exception: return any errors or warnings in this structure. % */ MagickExport MagickBooleanType SetImageInfo(ImageInfo *image_info, const unsigned int frames,ExceptionInfo *exception) { char component[MagickPathExtent], magic[MagickPathExtent], #if defined(MAGICKCORE_ZLIB_DELEGATE) || defined(MAGICKCORE_BZLIB_DELEGATE) path[MagickPathExtent], #endif *q; const MagicInfo *magic_info; const MagickInfo *magick_info; ExceptionInfo *sans_exception; Image *image; MagickBooleanType status; register const char *p; ssize_t count; /* Look for 'image.format' in filename. */ assert(image_info != (ImageInfo *) NULL); assert(image_info->signature == MagickCoreSignature); if (image_info->debug != MagickFalse) (void) LogMagickEvent(TraceEvent,GetMagickModule(),"%s", image_info->filename); *component='\0'; GetPathComponent(image_info->filename,SubimagePath,component); if (*component != '\0') { /* Look for scene specification (e.g. img0001.pcd[4]). */ if (IsSceneGeometry(component,MagickFalse) == MagickFalse) { if (IsGeometry(component) != MagickFalse) (void) CloneString(&image_info->extract,component); } else { size_t first, last; (void) CloneString(&image_info->scenes,component); image_info->scene=StringToUnsignedLong(image_info->scenes); image_info->number_scenes=image_info->scene; p=image_info->scenes; for (q=(char *) image_info->scenes; *q != '\0'; p++) { while ((isspace((int) ((unsigned char) *p)) != 0) || (*p == ',')) p++; first=(size_t) strtol(p,&q,10); last=first; while (isspace((int) ((unsigned char) *q)) != 0) q++; if (*q == '-') last=(size_t) strtol(q+1,&q,10); if (first > last) Swap(first,last); if (first < image_info->scene) image_info->scene=first; if (last > image_info->number_scenes) image_info->number_scenes=last; p=q; } image_info->number_scenes-=image_info->scene-1; } } *component='\0'; if (*image_info->magick == '\0') GetPathComponent(image_info->filename,ExtensionPath,component); #if defined(MAGICKCORE_ZLIB_DELEGATE) if (*component != '\0') if ((LocaleCompare(component,"gz") == 0) || (LocaleCompare(component,"Z") == 0) || (LocaleCompare(component,"svgz") == 0) || (LocaleCompare(component,"wmz") == 0)) { (void) CopyMagickString(path,image_info->filename,MagickPathExtent); path[strlen(path)-strlen(component)-1]='\0'; GetPathComponent(path,ExtensionPath,component); } #endif #if defined(MAGICKCORE_BZLIB_DELEGATE) if (*component != '\0') if (LocaleCompare(component,"bz2") == 0) { (void) CopyMagickString(path,image_info->filename,MagickPathExtent); path[strlen(path)-strlen(component)-1]='\0'; GetPathComponent(path,ExtensionPath,component); } #endif image_info->affirm=MagickFalse; sans_exception=AcquireExceptionInfo(); if ((*component != '\0') && (IsGlob(component) == MagickFalse)) { MagickFormatType format_type; register ssize_t i; static const char *format_type_formats[] = { "AUTOTRACE", "BROWSE", "DCRAW", "EDIT", "LAUNCH", "MPEG:DECODE", "MPEG:ENCODE", "PRINT", "PS:ALPHA", "PS:CMYK", "PS:COLOR", "PS:GRAY", "PS:MONO", "SCAN", "SHOW", "WIN", (char *) NULL }; /* User specified image format. */ (void) CopyMagickString(magic,component,MagickPathExtent); LocaleUpper(magic); /* Look for explicit image formats. */ format_type=UndefinedFormatType; magick_info=GetMagickInfo(magic,sans_exception); if ((magick_info != (const MagickInfo *) NULL) && (magick_info->format_type != UndefinedFormatType)) format_type=magick_info->format_type; i=0; while ((format_type == UndefinedFormatType) && (format_type_formats[i] != (char *) NULL)) { if ((*magic == *format_type_formats[i]) && (LocaleCompare(magic,format_type_formats[i]) == 0)) format_type=ExplicitFormatType; i++; } if (format_type == UndefinedFormatType) (void) CopyMagickString(image_info->magick,magic,MagickPathExtent); else if (format_type == ExplicitFormatType) { image_info->affirm=MagickTrue; (void) CopyMagickString(image_info->magick,magic,MagickPathExtent); } if (LocaleCompare(magic,"RGB") == 0) image_info->affirm=MagickFalse; /* maybe SGI disguised as RGB */ } /* Look for explicit 'format:image' in filename. */ *magic='\0'; GetPathComponent(image_info->filename,MagickPath,magic); if (*magic == '\0') { (void) CopyMagickString(magic,image_info->magick,MagickPathExtent); magick_info=GetMagickInfo(magic,sans_exception); if (frames == 0) GetPathComponent(image_info->filename,CanonicalPath,component); else GetPathComponent(image_info->filename,SubcanonicalPath,component); (void) CopyMagickString(image_info->filename,component,MagickPathExtent); } else { const DelegateInfo *delegate_info; /* User specified image format. */ LocaleUpper(magic); magick_info=GetMagickInfo(magic,sans_exception); delegate_info=GetDelegateInfo(magic,"*",sans_exception); if (delegate_info == (const DelegateInfo *) NULL) delegate_info=GetDelegateInfo("*",magic,sans_exception); if (((magick_info != (const MagickInfo *) NULL) || (delegate_info != (const DelegateInfo *) NULL)) && (IsMagickConflict(magic) == MagickFalse)) { image_info->affirm=MagickTrue; (void) CopyMagickString(image_info->magick,magic,MagickPathExtent); GetPathComponent(image_info->filename,CanonicalPath,component); (void) CopyMagickString(image_info->filename,component, MagickPathExtent); } } sans_exception=DestroyExceptionInfo(sans_exception); if ((magick_info == (const MagickInfo *) NULL) || (GetMagickEndianSupport(magick_info) == MagickFalse)) image_info->endian=UndefinedEndian; if ((image_info->adjoin != MagickFalse) && (frames > 1)) { /* Test for multiple image support (e.g. image%02d.png). */ (void) InterpretImageFilename(image_info,(Image *) NULL, image_info->filename,(int) image_info->scene,component,exception); if ((LocaleCompare(component,image_info->filename) != 0) && (strchr(component,'%') == (char *) NULL)) image_info->adjoin=MagickFalse; } if ((image_info->adjoin != MagickFalse) && (frames > 0)) { /* Some image formats do not support multiple frames per file. */ magick_info=GetMagickInfo(magic,exception); if (magick_info != (const MagickInfo *) NULL) if (GetMagickAdjoin(magick_info) == MagickFalse) image_info->adjoin=MagickFalse; } if (image_info->affirm != MagickFalse) return(MagickTrue); if (frames == 0) { unsigned char *magick; size_t magick_size; /* Determine the image format from the first few bytes of the file. */ magick_size=GetMagicPatternExtent(exception); if (magick_size == 0) return(MagickFalse); image=AcquireImage(image_info,exception); (void) CopyMagickString(image->filename,image_info->filename, MagickPathExtent); status=OpenBlob(image_info,image,ReadBinaryBlobMode,exception); if (status == MagickFalse) { image=DestroyImage(image); return(MagickFalse); } if ((IsBlobSeekable(image) == MagickFalse) || (IsBlobExempt(image) != MagickFalse)) { /* Copy image to seekable temporary file. */ *component='\0'; status=ImageToFile(image,component,exception); (void) CloseBlob(image); if (status == MagickFalse) { image=DestroyImage(image); return(MagickFalse); } SetImageInfoFile(image_info,(FILE *) NULL); (void) CopyMagickString(image->filename,component,MagickPathExtent); status=OpenBlob(image_info,image,ReadBinaryBlobMode,exception); if (status == MagickFalse) { image=DestroyImage(image); return(MagickFalse); } (void) CopyMagickString(image_info->filename,component, MagickPathExtent); image_info->temporary=MagickTrue; } magick=(unsigned char *) AcquireMagickMemory(magick_size); if (magick == (unsigned char *) NULL) { (void) CloseBlob(image); image=DestroyImage(image); return(MagickFalse); } (void) memset(magick,0,magick_size); count=ReadBlob(image,magick_size,magick); (void) SeekBlob(image,-((MagickOffsetType) count),SEEK_CUR); (void) CloseBlob(image); image=DestroyImage(image); /* Check magic cache. */ sans_exception=AcquireExceptionInfo(); magic_info=GetMagicInfo(magick,(size_t) count,sans_exception); magick=(unsigned char *) RelinquishMagickMemory(magick); if ((magic_info != (const MagicInfo *) NULL) && (GetMagicName(magic_info) != (char *) NULL)) { /* Try to use magick_info that was determined earlier by the extension */ if ((magick_info != (const MagickInfo *) NULL) && (GetMagickUseExtension(magick_info) != MagickFalse) && (LocaleCompare(magick_info->magick_module,GetMagicName( magic_info)) == 0)) (void) CopyMagickString(image_info->magick,magick_info->name, MagickPathExtent); else { (void) CopyMagickString(image_info->magick,GetMagicName( magic_info),MagickPathExtent); magick_info=GetMagickInfo(image_info->magick,sans_exception); } if ((magick_info == (const MagickInfo *) NULL) || (GetMagickEndianSupport(magick_info) == MagickFalse)) image_info->endian=UndefinedEndian; sans_exception=DestroyExceptionInfo(sans_exception); return(MagickTrue); } magick_info=GetMagickInfo(image_info->magick,sans_exception); if ((magick_info == (const MagickInfo *) NULL) || (GetMagickEndianSupport(magick_info) == MagickFalse)) image_info->endian=UndefinedEndian; sans_exception=DestroyExceptionInfo(sans_exception); } return(MagickTrue); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % S e t I m a g e I n f o B l o b % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % SetImageInfoBlob() sets the image info blob member. % % The format of the SetImageInfoBlob method is: % % void SetImageInfoBlob(ImageInfo *image_info,const void *blob, % const size_t length) % % A description of each parameter follows: % % o image_info: the image info. % % o blob: the blob. % % o length: the blob length. % */ MagickExport void SetImageInfoBlob(ImageInfo *image_info,const void *blob, const size_t length) { assert(image_info != (ImageInfo *) NULL); assert(image_info->signature == MagickCoreSignature); if (image_info->debug != MagickFalse) (void) LogMagickEvent(TraceEvent,GetMagickModule(),"%s", image_info->filename); image_info->blob=(void *) blob; image_info->length=length; } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % S e t I m a g e I n f o C u s t o m S t r e a m % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % SetImageInfoCustomStream() sets the image info custom stream handlers. % % The format of the SetImageInfoCustomStream method is: % % void SetImageInfoCustomStream(ImageInfo *image_info, % CustomStreamInfo *custom_stream) % % A description of each parameter follows: % % o image_info: the image info. % % o custom_stream: your custom stream methods. % */ MagickExport void SetImageInfoCustomStream(ImageInfo *image_info, CustomStreamInfo *custom_stream) { assert(image_info != (ImageInfo *) NULL); assert(image_info->signature == MagickCoreSignature); if (image_info->debug != MagickFalse) (void) LogMagickEvent(TraceEvent,GetMagickModule(),"%s", image_info->filename); image_info->custom_stream=(CustomStreamInfo *) custom_stream; } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % S e t I m a g e I n f o F i l e % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % SetImageInfoFile() sets the image info file member. % % The format of the SetImageInfoFile method is: % % void SetImageInfoFile(ImageInfo *image_info,FILE *file) % % A description of each parameter follows: % % o image_info: the image info. % % o file: the file. % */ MagickExport void SetImageInfoFile(ImageInfo *image_info,FILE *file) { assert(image_info != (ImageInfo *) NULL); assert(image_info->signature == MagickCoreSignature); if (image_info->debug != MagickFalse) (void) LogMagickEvent(TraceEvent,GetMagickModule(),"%s", image_info->filename); image_info->file=file; } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % S e t I m a g e M a s k % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % SetImageMask() associates a mask with the image. The mask must be the same % dimensions as the image. % % The format of the SetImageMask method is: % % MagickBooleanType SetImageMask(Image *image,const PixelMask type, % const Image *mask,ExceptionInfo *exception) % % A description of each parameter follows: % % o image: the image. % % o type: the mask type, ReadPixelMask or WritePixelMask. % % o mask: the image mask. % % o exception: return any errors or warnings in this structure. % */ MagickExport MagickBooleanType SetImageMask(Image *image,const PixelMask type, const Image *mask,ExceptionInfo *exception) { CacheView *mask_view, *image_view; MagickBooleanType status; ssize_t y; /* Set image mask. */ assert(image != (Image *) NULL); if (image->debug != MagickFalse) (void) LogMagickEvent(TraceEvent,GetMagickModule(),"..."); assert(image->signature == MagickCoreSignature); if (mask == (const Image *) NULL) { switch (type) { case ReadPixelMask: { image->channels=(ChannelType) (image->channels & ~ReadMaskChannel); break; } case WritePixelMask: { image->channels=(ChannelType) (image->channels & ~WriteMaskChannel); } default: { image->channels=(ChannelType) (image->channels & ~CompositeMaskChannel); break; } } return(SyncImagePixelCache(image,exception)); } switch (type) { case ReadPixelMask: { image->channels=(ChannelType) (image->channels | ReadMaskChannel); break; } case WritePixelMask: { image->channels=(ChannelType) (image->channels | WriteMaskChannel); break; } default: { image->channels=(ChannelType) (image->channels | CompositeMaskChannel); break; } } if (SyncImagePixelCache(image,exception) == MagickFalse) return(MagickFalse); status=MagickTrue; image->mask_trait=UpdatePixelTrait; mask_view=AcquireVirtualCacheView(mask,exception); image_view=AcquireAuthenticCacheView(image,exception); #if defined(MAGICKCORE_OPENMP_SUPPORT) #pragma omp parallel for schedule(static) shared(status) \ magick_number_threads(mask,image,image->rows,1) #endif for (y=0; y < (ssize_t) image->rows; y++) { register const Quantum *magick_restrict p; register Quantum *magick_restrict q; register ssize_t x; if (status == MagickFalse) continue; p=GetCacheViewVirtualPixels(mask_view,0,y,mask->columns,1,exception); q=GetCacheViewAuthenticPixels(image_view,0,y,image->columns,1,exception); if ((p == (const Quantum *) NULL) || (q == (Quantum *) NULL)) { status=MagickFalse; continue; } for (x=0; x < (ssize_t) image->columns; x++) { MagickRealType intensity; intensity=0.0; if ((x < (ssize_t) mask->columns) && (y < (ssize_t) mask->rows)) intensity=GetPixelIntensity(mask,p); switch (type) { case ReadPixelMask: { SetPixelReadMask(image,ClampToQuantum(intensity),q); break; } case WritePixelMask: { SetPixelWriteMask(image,ClampToQuantum(intensity),q); break; } default: { SetPixelCompositeMask(image,ClampToQuantum(intensity),q); break; } } p+=GetPixelChannels(mask); q+=GetPixelChannels(image); } if (SyncCacheViewAuthenticPixels(image_view,exception) == MagickFalse) status=MagickFalse; } image->mask_trait=UndefinedPixelTrait; mask_view=DestroyCacheView(mask_view); image_view=DestroyCacheView(image_view); return(status); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % S e t I m a g e R e g i o n M a s k % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % SetImageRegionMask() associates a mask with the image as defined by the % specified region. % % The format of the SetImageRegionMask method is: % % MagickBooleanType SetImageRegionMask(Image *image,const PixelMask type, % const RectangleInfo *region,ExceptionInfo *exception) % % A description of each parameter follows: % % o image: the image. % % o type: the mask type, ReadPixelMask or WritePixelMask. % % o geometry: the mask region. % % o exception: return any errors or warnings in this structure. % */ MagickExport MagickBooleanType SetImageRegionMask(Image *image, const PixelMask type,const RectangleInfo *region,ExceptionInfo *exception) { CacheView *image_view; MagickBooleanType status; ssize_t y; /* Set image mask as defined by the region. */ assert(image != (Image *) NULL); if (image->debug != MagickFalse) (void) LogMagickEvent(TraceEvent,GetMagickModule(),"..."); assert(image->signature == MagickCoreSignature); if (region == (const RectangleInfo *) NULL) { switch (type) { case ReadPixelMask: { image->channels=(ChannelType) (image->channels & ~ReadMaskChannel); break; } case WritePixelMask: { image->channels=(ChannelType) (image->channels & ~WriteMaskChannel); break; } default: { image->channels=(ChannelType) (image->channels & ~CompositeMaskChannel); break; } } return(SyncImagePixelCache(image,exception)); } switch (type) { case ReadPixelMask: { image->channels=(ChannelType) (image->channels | ReadMaskChannel); break; } case WritePixelMask: { image->channels=(ChannelType) (image->channels | WriteMaskChannel); break; } default: { image->channels=(ChannelType) (image->channels | CompositeMaskChannel); break; } } if (SyncImagePixelCache(image,exception) == MagickFalse) return(MagickFalse); status=MagickTrue; image->mask_trait=UpdatePixelTrait; image_view=AcquireAuthenticCacheView(image,exception); #if defined(MAGICKCORE_OPENMP_SUPPORT) #pragma omp parallel for schedule(static) shared(status) \ magick_number_threads(image,image,image->rows,1) #endif for (y=0; y < (ssize_t) image->rows; y++) { register Quantum *magick_restrict q; register ssize_t x; if (status == MagickFalse) continue; q=GetCacheViewAuthenticPixels(image_view,0,y,image->columns,1,exception); if (q == (Quantum *) NULL) { status=MagickFalse; continue; } for (x=0; x < (ssize_t) image->columns; x++) { Quantum pixel; pixel=QuantumRange; if (((x >= region->x) && (x < (region->x+(ssize_t) region->width))) && ((y >= region->y) && (y < (region->y+(ssize_t) region->height)))) pixel=(Quantum) 0; switch (type) { case ReadPixelMask: { SetPixelReadMask(image,pixel,q); break; } case WritePixelMask: { SetPixelWriteMask(image,pixel,q); break; } default: { SetPixelCompositeMask(image,pixel,q); break; } } q+=GetPixelChannels(image); } if (SyncCacheViewAuthenticPixels(image_view,exception) == MagickFalse) status=MagickFalse; } image->mask_trait=UndefinedPixelTrait; image_view=DestroyCacheView(image_view); return(status); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % S e t I m a g e V i r t u a l P i x e l M e t h o d % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % SetImageVirtualPixelMethod() sets the "virtual pixels" method for the % image and returns the previous setting. A virtual pixel is any pixel access % that is outside the boundaries of the image cache. % % The format of the SetImageVirtualPixelMethod() method is: % % VirtualPixelMethod SetImageVirtualPixelMethod(Image *image, % const VirtualPixelMethod virtual_pixel_method,ExceptionInfo *exception) % % A description of each parameter follows: % % o image: the image. % % o virtual_pixel_method: choose the type of virtual pixel. % % o exception: return any errors or warnings in this structure. % */ MagickExport VirtualPixelMethod SetImageVirtualPixelMethod(Image *image, const VirtualPixelMethod virtual_pixel_method,ExceptionInfo *exception) { assert(image != (const Image *) NULL); assert(image->signature == MagickCoreSignature); if (image->debug != MagickFalse) (void) LogMagickEvent(TraceEvent,GetMagickModule(),"%s",image->filename); return(SetPixelCacheVirtualMethod(image,virtual_pixel_method,exception)); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % S m u s h I m a g e s % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % SmushImages() takes all images from the current image pointer to the end % of the image list and smushes them to each other top-to-bottom if the % stack parameter is true, otherwise left-to-right. % % The current gravity setting now effects how the image is justified in the % final image. % % The format of the SmushImages method is: % % Image *SmushImages(const Image *images,const MagickBooleanType stack, % ExceptionInfo *exception) % % A description of each parameter follows: % % o images: the image sequence. % % o stack: A value other than 0 stacks the images top-to-bottom. % % o offset: minimum distance in pixels between images. % % o exception: return any errors or warnings in this structure. % */ static ssize_t SmushXGap(const Image *smush_image,const Image *images, const ssize_t offset,ExceptionInfo *exception) { CacheView *left_view, *right_view; const Image *left_image, *right_image; RectangleInfo left_geometry, right_geometry; register const Quantum *p; register ssize_t i, y; size_t gap; ssize_t x; if (images->previous == (Image *) NULL) return(0); right_image=images; SetGeometry(smush_image,&right_geometry); GravityAdjustGeometry(right_image->columns,right_image->rows, right_image->gravity,&right_geometry); left_image=images->previous; SetGeometry(smush_image,&left_geometry); GravityAdjustGeometry(left_image->columns,left_image->rows, left_image->gravity,&left_geometry); gap=right_image->columns; left_view=AcquireVirtualCacheView(left_image,exception); right_view=AcquireVirtualCacheView(right_image,exception); for (y=0; y < (ssize_t) smush_image->rows; y++) { for (x=(ssize_t) left_image->columns-1; x > 0; x--) { p=GetCacheViewVirtualPixels(left_view,x,left_geometry.y+y,1,1,exception); if ((p == (const Quantum *) NULL) || (GetPixelAlpha(left_image,p) != TransparentAlpha) || ((left_image->columns-x-1) >= gap)) break; } i=(ssize_t) left_image->columns-x-1; for (x=0; x < (ssize_t) right_image->columns; x++) { p=GetCacheViewVirtualPixels(right_view,x,right_geometry.y+y,1,1, exception); if ((p == (const Quantum *) NULL) || (GetPixelAlpha(right_image,p) != TransparentAlpha) || ((x+i) >= (ssize_t) gap)) break; } if ((x+i) < (ssize_t) gap) gap=(size_t) (x+i); } right_view=DestroyCacheView(right_view); left_view=DestroyCacheView(left_view); if (y < (ssize_t) smush_image->rows) return(offset); return((ssize_t) gap-offset); } static ssize_t SmushYGap(const Image *smush_image,const Image *images, const ssize_t offset,ExceptionInfo *exception) { CacheView *bottom_view, *top_view; const Image *bottom_image, *top_image; RectangleInfo bottom_geometry, top_geometry; register const Quantum *p; register ssize_t i, x; size_t gap; ssize_t y; if (images->previous == (Image *) NULL) return(0); bottom_image=images; SetGeometry(smush_image,&bottom_geometry); GravityAdjustGeometry(bottom_image->columns,bottom_image->rows, bottom_image->gravity,&bottom_geometry); top_image=images->previous; SetGeometry(smush_image,&top_geometry); GravityAdjustGeometry(top_image->columns,top_image->rows,top_image->gravity, &top_geometry); gap=bottom_image->rows; top_view=AcquireVirtualCacheView(top_image,exception); bottom_view=AcquireVirtualCacheView(bottom_image,exception); for (x=0; x < (ssize_t) smush_image->columns; x++) { for (y=(ssize_t) top_image->rows-1; y > 0; y--) { p=GetCacheViewVirtualPixels(top_view,top_geometry.x+x,y,1,1,exception); if ((p == (const Quantum *) NULL) || (GetPixelAlpha(top_image,p) != TransparentAlpha) || ((top_image->rows-y-1) >= gap)) break; } i=(ssize_t) top_image->rows-y-1; for (y=0; y < (ssize_t) bottom_image->rows; y++) { p=GetCacheViewVirtualPixels(bottom_view,bottom_geometry.x+x,y,1,1, exception); if ((p == (const Quantum *) NULL) || (GetPixelAlpha(bottom_image,p) != TransparentAlpha) || ((y+i) >= (ssize_t) gap)) break; } if ((y+i) < (ssize_t) gap) gap=(size_t) (y+i); } bottom_view=DestroyCacheView(bottom_view); top_view=DestroyCacheView(top_view); if (x < (ssize_t) smush_image->columns) return(offset); return((ssize_t) gap-offset); } MagickExport Image *SmushImages(const Image *images, const MagickBooleanType stack,const ssize_t offset,ExceptionInfo *exception) { #define SmushImageTag "Smush/Image" const Image *image; Image *smush_image; MagickBooleanType proceed, status; MagickOffsetType n; PixelTrait alpha_trait; RectangleInfo geometry; register const Image *next; size_t height, number_images, width; ssize_t x_offset, y_offset; /* Compute maximum area of smushed area. */ assert(images != (Image *) NULL); assert(images->signature == MagickCoreSignature); if (images->debug != MagickFalse) (void) LogMagickEvent(TraceEvent,GetMagickModule(),"%s",images->filename); assert(exception != (ExceptionInfo *) NULL); assert(exception->signature == MagickCoreSignature); image=images; alpha_trait=image->alpha_trait; number_images=1; width=image->columns; height=image->rows; next=GetNextImageInList(image); for ( ; next != (Image *) NULL; next=GetNextImageInList(next)) { if (next->alpha_trait != UndefinedPixelTrait) alpha_trait=BlendPixelTrait; number_images++; if (stack != MagickFalse) { if (next->columns > width) width=next->columns; height+=next->rows; if (next->previous != (Image *) NULL) height+=offset; continue; } width+=next->columns; if (next->previous != (Image *) NULL) width+=offset; if (next->rows > height) height=next->rows; } /* Smush images. */ smush_image=CloneImage(image,width,height,MagickTrue,exception); if (smush_image == (Image *) NULL) return((Image *) NULL); if (SetImageStorageClass(smush_image,DirectClass,exception) == MagickFalse) { smush_image=DestroyImage(smush_image); return((Image *) NULL); } smush_image->alpha_trait=alpha_trait; (void) SetImageBackgroundColor(smush_image,exception); status=MagickTrue; x_offset=0; y_offset=0; for (n=0; n < (MagickOffsetType) number_images; n++) { SetGeometry(smush_image,&geometry); GravityAdjustGeometry(image->columns,image->rows,image->gravity,&geometry); if (stack != MagickFalse) { x_offset-=geometry.x; y_offset-=SmushYGap(smush_image,image,offset,exception); } else { x_offset-=SmushXGap(smush_image,image,offset,exception); y_offset-=geometry.y; } status=CompositeImage(smush_image,image,OverCompositeOp,MagickTrue,x_offset, y_offset,exception); proceed=SetImageProgress(image,SmushImageTag,n,number_images); if (proceed == MagickFalse) break; if (stack == MagickFalse) { x_offset+=(ssize_t) image->columns; y_offset=0; } else { x_offset=0; y_offset+=(ssize_t) image->rows; } image=GetNextImageInList(image); } if (stack == MagickFalse) smush_image->columns=(size_t) x_offset; else smush_image->rows=(size_t) y_offset; if (status == MagickFalse) smush_image=DestroyImage(smush_image); return(smush_image); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % S t r i p I m a g e % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % StripImage() strips an image of all profiles and comments. % % The format of the StripImage method is: % % MagickBooleanType StripImage(Image *image,ExceptionInfo *exception) % % A description of each parameter follows: % % o image: the image. % % o exception: return any errors or warnings in this structure. % */ MagickExport MagickBooleanType StripImage(Image *image,ExceptionInfo *exception) { MagickBooleanType status; assert(image != (Image *) NULL); if (image->debug != MagickFalse) (void) LogMagickEvent(TraceEvent,GetMagickModule(),"..."); (void) exception; DestroyImageProfiles(image); (void) DeleteImageProperty(image,"comment"); (void) DeleteImageProperty(image,"date:create"); (void) DeleteImageProperty(image,"date:modify"); status=SetImageArtifact(image,"png:exclude-chunk", "bKGD,caNv,cHRM,eXIf,gAMA,iCCP,iTXt,pHYs,sRGB,tEXt,zCCP,zTXt,date"); return(status); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % + S y n c I m a g e % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % SyncImage() initializes the red, green, and blue intensities of each pixel % as defined by the colormap index. % % The format of the SyncImage method is: % % MagickBooleanType SyncImage(Image *image,ExceptionInfo *exception) % % A description of each parameter follows: % % o image: the image. % % o exception: return any errors or warnings in this structure. % */ static inline Quantum PushColormapIndex(Image *image,const Quantum index, MagickBooleanType *range_exception) { if ((size_t) index < image->colors) return(index); *range_exception=MagickTrue; return((Quantum) 0); } MagickExport MagickBooleanType SyncImage(Image *image,ExceptionInfo *exception) { CacheView *image_view; MagickBooleanType range_exception, status, taint; ssize_t y; assert(image != (Image *) NULL); if (image->debug != MagickFalse) (void) LogMagickEvent(TraceEvent,GetMagickModule(),"..."); assert(image->signature == MagickCoreSignature); if (image->ping != MagickFalse) return(MagickTrue); if (image->storage_class != PseudoClass) return(MagickFalse); assert(image->colormap != (PixelInfo *) NULL); range_exception=MagickFalse; status=MagickTrue; taint=image->taint; image_view=AcquireAuthenticCacheView(image,exception); #if defined(MAGICKCORE_OPENMP_SUPPORT) #pragma omp parallel for schedule(static) shared(range_exception,status) \ magick_number_threads(image,image,image->rows,1) #endif for (y=0; y < (ssize_t) image->rows; y++) { Quantum index; register Quantum *magick_restrict q; register ssize_t x; if (status == MagickFalse) continue; q=GetCacheViewAuthenticPixels(image_view,0,y,image->columns,1,exception); if (q == (Quantum *) NULL) { status=MagickFalse; continue; } for (x=0; x < (ssize_t) image->columns; x++) { index=PushColormapIndex(image,GetPixelIndex(image,q),&range_exception); SetPixelViaPixelInfo(image,image->colormap+(ssize_t) index,q); q+=GetPixelChannels(image); } if (SyncCacheViewAuthenticPixels(image_view,exception) == MagickFalse) status=MagickFalse; } image_view=DestroyCacheView(image_view); image->taint=taint; if ((image->ping == MagickFalse) && (range_exception != MagickFalse)) (void) ThrowMagickException(exception,GetMagickModule(), CorruptImageWarning,"InvalidColormapIndex","`%s'",image->filename); return(status); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % S y n c I m a g e S e t t i n g s % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % SyncImageSettings() syncs any image_info global options into per-image % attributes. % % Note: in IMv6 free form 'options' were always mapped into 'artifacts', so % that operations and coders can find such settings. In IMv7 if a desired % per-image artifact is not set, then it will directly look for a global % option as a fallback, as such this copy is no longer needed, only the % link set up. % % The format of the SyncImageSettings method is: % % MagickBooleanType SyncImageSettings(const ImageInfo *image_info, % Image *image,ExceptionInfo *exception) % MagickBooleanType SyncImagesSettings(const ImageInfo *image_info, % Image *image,ExceptionInfo *exception) % % A description of each parameter follows: % % o image_info: the image info. % % o image: the image. % % o exception: return any errors or warnings in this structure. % */ MagickExport MagickBooleanType SyncImagesSettings(ImageInfo *image_info, Image *images,ExceptionInfo *exception) { Image *image; assert(image_info != (const ImageInfo *) NULL); assert(image_info->signature == MagickCoreSignature); assert(images != (Image *) NULL); assert(images->signature == MagickCoreSignature); if (images->debug != MagickFalse) (void) LogMagickEvent(TraceEvent,GetMagickModule(),"%s",images->filename); image=images; for ( ; image != (Image *) NULL; image=GetNextImageInList(image)) (void) SyncImageSettings(image_info,image,exception); (void) DeleteImageOption(image_info,"page"); return(MagickTrue); } MagickExport MagickBooleanType SyncImageSettings(const ImageInfo *image_info, Image *image,ExceptionInfo *exception) { const char *option; GeometryInfo geometry_info; MagickStatusType flags; ResolutionType units; /* Sync image options. */ assert(image_info != (const ImageInfo *) NULL); assert(image_info->signature == MagickCoreSignature); assert(image != (Image *) NULL); assert(image->signature == MagickCoreSignature); if (image->debug != MagickFalse) (void) LogMagickEvent(TraceEvent,GetMagickModule(),"%s",image->filename); option=GetImageOption(image_info,"background"); if (option != (const char *) NULL) (void) QueryColorCompliance(option,AllCompliance,&image->background_color, exception); option=GetImageOption(image_info,"black-point-compensation"); if (option != (const char *) NULL) image->black_point_compensation=(MagickBooleanType) ParseCommandOption( MagickBooleanOptions,MagickFalse,option); option=GetImageOption(image_info,"blue-primary"); if (option != (const char *) NULL) { flags=ParseGeometry(option,&geometry_info); image->chromaticity.blue_primary.x=geometry_info.rho; image->chromaticity.blue_primary.y=geometry_info.sigma; if ((flags & SigmaValue) == 0) image->chromaticity.blue_primary.y=image->chromaticity.blue_primary.x; } option=GetImageOption(image_info,"bordercolor"); if (option != (const char *) NULL) (void) QueryColorCompliance(option,AllCompliance,&image->border_color, exception); /* FUTURE: do not sync compose to per-image compose setting here */ option=GetImageOption(image_info,"compose"); if (option != (const char *) NULL) image->compose=(CompositeOperator) ParseCommandOption(MagickComposeOptions, MagickFalse,option); /* -- */ option=GetImageOption(image_info,"compress"); if (option != (const char *) NULL) image->compression=(CompressionType) ParseCommandOption( MagickCompressOptions,MagickFalse,option); option=GetImageOption(image_info,"debug"); if (option != (const char *) NULL) image->debug=(MagickBooleanType) ParseCommandOption(MagickBooleanOptions, MagickFalse,option); option=GetImageOption(image_info,"density"); if (option != (const char *) NULL) { flags=ParseGeometry(option,&geometry_info); image->resolution.x=geometry_info.rho; image->resolution.y=geometry_info.sigma; if ((flags & SigmaValue) == 0) image->resolution.y=image->resolution.x; } option=GetImageOption(image_info,"depth"); if (option != (const char *) NULL) image->depth=StringToUnsignedLong(option); option=GetImageOption(image_info,"endian"); if (option != (const char *) NULL) image->endian=(EndianType) ParseCommandOption(MagickEndianOptions, MagickFalse,option); option=GetImageOption(image_info,"filter"); if (option != (const char *) NULL) image->filter=(FilterType) ParseCommandOption(MagickFilterOptions, MagickFalse,option); option=GetImageOption(image_info,"fuzz"); if (option != (const char *) NULL) image->fuzz=StringToDoubleInterval(option,(double) QuantumRange+1.0); option=GetImageOption(image_info,"gravity"); if (option != (const char *) NULL) image->gravity=(GravityType) ParseCommandOption(MagickGravityOptions, MagickFalse,option); option=GetImageOption(image_info,"green-primary"); if (option != (const char *) NULL) { flags=ParseGeometry(option,&geometry_info); image->chromaticity.green_primary.x=geometry_info.rho; image->chromaticity.green_primary.y=geometry_info.sigma; if ((flags & SigmaValue) == 0) image->chromaticity.green_primary.y=image->chromaticity.green_primary.x; } option=GetImageOption(image_info,"intent"); if (option != (const char *) NULL) image->rendering_intent=(RenderingIntent) ParseCommandOption( MagickIntentOptions,MagickFalse,option); option=GetImageOption(image_info,"intensity"); if (option != (const char *) NULL) image->intensity=(PixelIntensityMethod) ParseCommandOption( MagickPixelIntensityOptions,MagickFalse,option); option=GetImageOption(image_info,"interlace"); if (option != (const char *) NULL) image->interlace=(InterlaceType) ParseCommandOption(MagickInterlaceOptions, MagickFalse,option); option=GetImageOption(image_info,"interpolate"); if (option != (const char *) NULL) image->interpolate=(PixelInterpolateMethod) ParseCommandOption( MagickInterpolateOptions,MagickFalse,option); option=GetImageOption(image_info,"loop"); if (option != (const char *) NULL) image->iterations=StringToUnsignedLong(option); option=GetImageOption(image_info,"mattecolor"); if (option != (const char *) NULL) (void) QueryColorCompliance(option,AllCompliance,&image->matte_color, exception); option=GetImageOption(image_info,"orient"); if (option != (const char *) NULL) image->orientation=(OrientationType) ParseCommandOption( MagickOrientationOptions,MagickFalse,option); option=GetImageOption(image_info,"page"); if (option != (const char *) NULL) { char *geometry; geometry=GetPageGeometry(option); flags=ParseAbsoluteGeometry(geometry,&image->page); geometry=DestroyString(geometry); } option=GetImageOption(image_info,"quality"); if (option != (const char *) NULL) image->quality=StringToUnsignedLong(option); option=GetImageOption(image_info,"red-primary"); if (option != (const char *) NULL) { flags=ParseGeometry(option,&geometry_info); image->chromaticity.red_primary.x=geometry_info.rho; image->chromaticity.red_primary.y=geometry_info.sigma; if ((flags & SigmaValue) == 0) image->chromaticity.red_primary.y=image->chromaticity.red_primary.x; } if (image_info->quality != UndefinedCompressionQuality) image->quality=image_info->quality; option=GetImageOption(image_info,"scene"); if (option != (const char *) NULL) image->scene=StringToUnsignedLong(option); option=GetImageOption(image_info,"taint"); if (option != (const char *) NULL) image->taint=(MagickBooleanType) ParseCommandOption(MagickBooleanOptions, MagickFalse,option); option=GetImageOption(image_info,"tile-offset"); if (option != (const char *) NULL) { char *geometry; geometry=GetPageGeometry(option); flags=ParseAbsoluteGeometry(geometry,&image->tile_offset); geometry=DestroyString(geometry); } option=GetImageOption(image_info,"transparent-color"); if (option != (const char *) NULL) (void) QueryColorCompliance(option,AllCompliance,&image->transparent_color, exception); option=GetImageOption(image_info,"type"); if (option != (const char *) NULL) image->type=(ImageType) ParseCommandOption(MagickTypeOptions,MagickFalse, option); option=GetImageOption(image_info,"units"); units=image_info->units; if (option != (const char *) NULL) units=(ResolutionType) ParseCommandOption(MagickResolutionOptions, MagickFalse,option); if (units != UndefinedResolution) { if (image->units != units) switch (image->units) { case PixelsPerInchResolution: { if (units == PixelsPerCentimeterResolution) { image->resolution.x/=2.54; image->resolution.y/=2.54; } break; } case PixelsPerCentimeterResolution: { if (units == PixelsPerInchResolution) { image->resolution.x=(double) ((size_t) (100.0*2.54* image->resolution.x+0.5))/100.0; image->resolution.y=(double) ((size_t) (100.0*2.54* image->resolution.y+0.5))/100.0; } break; } default: break; } image->units=units; option=GetImageOption(image_info,"density"); if (option != (const char *) NULL) { flags=ParseGeometry(option,&geometry_info); image->resolution.x=geometry_info.rho; image->resolution.y=geometry_info.sigma; if ((flags & SigmaValue) == 0) image->resolution.y=image->resolution.x; } } option=GetImageOption(image_info,"virtual-pixel"); if (option != (const char *) NULL) (void) SetImageVirtualPixelMethod(image,(VirtualPixelMethod) ParseCommandOption(MagickVirtualPixelOptions,MagickFalse,option), exception); option=GetImageOption(image_info,"white-point"); if (option != (const char *) NULL) { flags=ParseGeometry(option,&geometry_info); image->chromaticity.white_point.x=geometry_info.rho; image->chromaticity.white_point.y=geometry_info.sigma; if ((flags & SigmaValue) == 0) image->chromaticity.white_point.y=image->chromaticity.white_point.x; } /* Pointer to allow the lookup of pre-image artifact will fallback to a global option setting/define. This saves a lot of duplication of global options into per-image artifacts, while ensuring only specifically set per-image artifacts are preserved when parenthesis ends. */ if (image->image_info != (ImageInfo *) NULL) image->image_info=DestroyImageInfo(image->image_info); image->image_info=CloneImageInfo(image_info); return(MagickTrue); }

grid.c

#include <stdio.h> #include <stdlib.h> #include <stdbool.h> #include <mpi.h> #include <math.h> #include <string.h> #include "grid.h" #include "common.h" double k_coeff(int i, int j, struct Grid* grid) { return 4.0 + __x(grid, i) + __y(grid, j); } void init_inter(struct Grid* grid) { int height = grid->height, width = grid->width; //#pragma omp parallel for /*for (int i = 0; i < width; ++i) for (int j = 0; j < height; ++j) { (grid->inter)[idx(i, j, height)] = 1.0 + cos(M_PI * __x(grid, i) * __y(grid, j)); (grid->resid)[idx(i, j, height)] = grid->rank; }*/ memset(grid->inter, 0, sizeof(double) * grid->width * grid->height); memset(grid->resid, 0, sizeof(double) * grid->width * grid->height); } void init_b_con(struct Grid* grid) { int height = grid->height, width = grid->width, width_ = width - 1, height_ = height - 1; #pragma omp parallel for for (int i = 0; i < width; ++i) for (int j = 0; j < height; ++j) { double x = __x(grid, i), y = __y(grid, j); (grid->b_con)[idx(i, j, height)] = PI_SQR * (4 + x + y) * (x*x + y*y) * cos(M_PI * x * y) + M_PI * (x + y) * sin(M_PI * x * y); } if (!grid->mpi_top) for (int i = 0; i < width; ++i) { double x = __x(grid, i), y = __y(grid, height_); (grid->b_con)[idx(i, height_, height)] += 2.0 * grid->y_h_inv * (- M_PI * (5.0 + x) * x * sin(M_PI * x) + 1.0 + cos(M_PI * x)); } if (!grid->mpi_right) for (int j = 0; j < height; ++j) { double x = __x(grid, width_), y = __y(grid, j); (grid->b_con)[idx(width_, j, height)] += 2.0 * grid->x_h_inv * (- (6.0 + y) * (M_PI * y * sin(2.0 * M_PI * y)) + 1.0 + cos(2.0 * M_PI * y)); } // memset(grid->b_con, 0, sizeof(double) * grid->width * grid->height); } void init_grid(struct Grid* grid, int* coords, int* dims, int* grid_size, int rank, MPI_Comm* mpi_world) { // setup coord structure int grid_x = grid_size[0] / dims[0]; int grid_x_rem = grid_size[0] % dims[0]; int grid_y = grid_size[1] / dims[1]; int grid_y_rem = grid_size[1] % dims[1]; grid->mpi_world = mpi_world; grid->left = grid_x * coords[0] + (min(grid_x_rem, coords[0])); grid->bot = grid_y * coords[1] + (min(grid_y_rem, coords[1])); grid->right = grid->left + grid_x + (coords[0] < grid_x_rem); grid->top = grid->bot + grid_y + (coords[1] < grid_y_rem); grid->width = grid->right - grid->left; grid->height = grid->top - grid->bot; grid->rank = rank; (grid->coords)[0] = coords[0]; (grid->coords)[1] = coords[1]; // figure edges out grid->mpi_left = grid->left != 0; grid->mpi_bot = grid->bot != 0; grid->mpi_right = grid->right != grid_size[0]; grid->mpi_top = grid->top != grid_size[1]; // allocate inter grid->inter = malloc_array(grid->width, grid->height); grid->resid = malloc_array(grid->width, grid->height); grid->b_con = malloc_array(grid->width, grid->height); grid->x_h = X_W / (grid_size[0] - 1); grid->y_h = Y_H / (grid_size[0] - 1); grid->x_h_2 = grid->x_h * 0.5; grid->y_h_2 = grid->y_h * 0.5; grid->x_h_inv = 1.0 / grid->x_h; grid->y_h_inv = 1.0 / grid->y_h; grid->x_start = grid->left * grid->x_h; grid->y_start = grid->bot * grid->y_h; // allocate guest arrays, when required if (grid->mpi_left) { grid->guest_left = malloc_array(1, grid->height); } if (grid->mpi_right) { grid->guest_right = malloc_array(1, grid->height); } if (grid->mpi_bot) { grid->guest_bot = malloc_array(grid->width, 1); grid->buf_bot = malloc_array(grid->width, 1); } if (grid->mpi_top) { grid->guest_top = malloc_array(grid->width, 1); grid->buf_top = malloc_array(grid->width, 1); } init_inter(grid); init_b_con(grid); } void display_grid_coords(struct Grid* grid) { printf("Rank %i grid coords: MPI %3ix%-3i X %4ix%-4i Y %4ix%-4i\n" "MPI communication square:\n" ".%1i.\n" "%1ix%-1i\n" ".%1i.\n", grid->rank, (grid->coords)[0], (grid->coords)[1], grid->left, grid->right, grid->bot, grid->top, grid->mpi_left, grid->mpi_bot, grid->mpi_top, grid->mpi_right); } void unmake_grid(struct Grid* grid) { free(grid->inter); free(grid->resid); free(grid->b_con); if (grid->mpi_left) { free(grid->guest_left); } if (grid->mpi_right) { free(grid->guest_right); } if (grid->mpi_bot) { free(grid->guest_bot); free(grid->buf_bot); } if (grid->mpi_top) { free(grid->guest_top); free(grid->buf_top); } } double operator(struct Grid* grid, double k, double base, double x_fwd, double x_bwd, double y_fwd, double y_bwd) { operator_vars; return -(x_h_inv * ( (k + x_h_2) * x_h_inv * (x_fwd - base) -(k - x_h_2) * x_h_inv * (base - x_bwd)) + y_h_inv * ( (k + y_h_2) * y_h_inv * (y_fwd - base) -(k - y_h_2) * y_h_inv * (base - y_bwd))); } double operator_left(struct Grid* grid, double k, double base, double x_fwd, double y_fwd, double y_bwd) { operator_vars; return - 2.0 * x_h_inv * (k + x_h_2) * x_h_inv * (x_fwd - base) - y_h_inv * ( (k + y_h_2) * y_h_inv * (y_fwd - base) -(k - y_h_2) * y_h_inv * (base - y_bwd)); } double operator_right(struct Grid* grid, double k, double base, double x_bwd, double y_fwd, double y_bwd) { operator_vars; return 2.0 * x_h_inv * (k - x_h_2) * x_h_inv * (base - x_bwd) + 2.0 * x_h_inv * base - y_h_inv * ( (k + y_h_2) * y_h_inv * (y_fwd - base) -(k - y_h_2) * y_h_inv * (base - y_bwd)); } double operator_bot(struct Grid* grid, double k, double base, double x_fwd, double x_bwd, double y_fwd) { operator_vars; return - 2.0 * y_h_inv * (k + y_h_2) * y_h_inv * (y_fwd - base) - x_h_inv * ( (k + x_h_2) * x_h_inv * (x_fwd - base) -(k - x_h_2) * x_h_inv * (base - x_bwd)); } double operator_top(struct Grid* grid, double k, double base, double x_fwd, double x_bwd, double y_bwd) { operator_vars; return 2.0 * y_h_inv * (k - y_h_2) * y_h_inv * (base - y_bwd) + 2.0 * y_h_inv * base - x_h_inv * ( (k + x_h_2) * x_h_inv * (x_fwd - base) -(k - x_h_2) * x_h_inv * (base - x_bwd)); } double operator_top_right(struct Grid* grid, double k, double base, double x_bwd, double y_bwd) { operator_vars; return 2.0 * x_h_inv * (k - x_h_2) * x_h_inv * (base - x_bwd) + 2.0 * y_h_inv * (k - y_h_2) * y_h_inv * (base - y_bwd) + 2.0 * (x_h_inv + y_h_inv) * base; } double operator_top_left(struct Grid* grid, double k, double base, double x_fwd, double y_bwd) { operator_vars; return -2.0 * x_h_inv * (k + x_h_2) * x_h_inv * (x_fwd - base) + 2.0 * y_h_inv * (k - y_h_2) * y_h_inv * (base - y_bwd) + 2.0 * y_h_inv * base; } double operator_bot_right(struct Grid* grid, double k, double base, double x_bwd, double y_fwd) { operator_vars; return 2.0 * x_h_inv * (k - x_h_2) * x_h_inv * (base - x_bwd) -2.0 * y_h_inv * (k + y_h_2) * y_h_inv * (y_fwd - base) + 2.0 * x_h_inv * base; } double operator_bot_left(struct Grid* grid, double k, double base, double x_fwd, double y_fwd) { operator_vars; return - 2.0 * x_h_inv * (k + x_h_2) * x_h_inv * (x_fwd - base) - 2.0 * y_h_inv * (k + y_h_2) * y_h_inv * (y_fwd - base); } void internal_op(struct Grid* grid, int resid) { common_vars; if (resid) { grid->norm = 0; grid->scalar = 0; } #pragma omp parallel for reduction(+:norm,scalar) for (int i = 1; i < width_; ++i) for (int j = 1; j < height_; ++j) { index_factory(i, j); resid_arr_switch; (*left_arr) = operator( grid, k_coeff(i, j, grid), right_arr[base_idx], right_arr[x_fwd_idx], right_arr[x_bwd_idx], right_arr[y_fwd_idx], right_arr[y_bwd_idx] ) - (resid ? 0 : 1) * grid->b_con[base_idx]; resid_loc_norm_advance; } resid_glob_norm_advance(1.0); } void border_op_left(struct Grid* grid, int resid) { common_vars; #pragma omp parallel for reduction(+:norm,scalar) for (int j = 1; j < height_; ++j) { index_factory(0, j); resid_arr_switch; if (grid->mpi_left) { (*left_arr) = operator( grid, k_coeff(0, j, grid), right_arr[base_idx], right_arr[x_fwd_idx], grid->guest_left[j], right_arr[y_fwd_idx], right_arr[y_bwd_idx] ) - (resid ? 0 : 1) * grid->b_con[base_idx]; } else { (*left_arr) = operator_left( grid, k_coeff(0, j, grid), right_arr[base_idx], right_arr[x_fwd_idx], right_arr[y_fwd_idx], right_arr[y_bwd_idx] ) - (resid ? 0 : 1) * grid->b_con[base_idx]; } resid_loc_norm_advance; } resid_glob_norm_advance(0.5); } void border_op_right(struct Grid* grid, int resid) { common_vars; #pragma omp parallel for reduction(+:norm,scalar) for (int j = 1; j < height_; ++j) { index_factory(width_, j); resid_arr_switch; if (grid->mpi_right) { (*left_arr) = operator( grid, k_coeff(width_, j, grid), right_arr[base_idx], grid->guest_right[j], right_arr[x_bwd_idx], right_arr[y_fwd_idx], right_arr[y_bwd_idx] ) - (resid ? 0 : 1) * grid->b_con[base_idx]; } else { (*left_arr) = operator_right( grid, k_coeff(width_, j, grid), right_arr[base_idx], right_arr[x_bwd_idx], right_arr[y_fwd_idx], right_arr[y_bwd_idx] ) - (resid ? 0 : 1) * grid->b_con[base_idx]; } resid_loc_norm_advance; } resid_glob_norm_advance(0.5); } void border_op_bot(struct Grid* grid, int resid) { common_vars; #pragma omp parallel for reduction(+:norm,scalar) for (int i = 1; i < width_; ++i) { index_factory(i, 0); resid_arr_switch; if (grid->mpi_bot) { (*left_arr) = operator( grid, k_coeff(i, 0, grid), right_arr[base_idx], right_arr[x_fwd_idx], right_arr[x_bwd_idx], right_arr[y_fwd_idx], grid->guest_bot[i] ) - (resid ? 0 : 1) * grid->b_con[base_idx]; } else { (*left_arr) = operator_bot( grid, k_coeff(i, 0, grid), right_arr[base_idx], right_arr[x_fwd_idx], right_arr[x_bwd_idx], right_arr[y_fwd_idx] ) - (resid ? 0 : 1) * grid->b_con[base_idx]; } resid_loc_norm_advance; } resid_glob_norm_advance(0.5); } void border_op_top(struct Grid* grid, int resid) { common_vars; #pragma omp parallel for reduction(+:norm,scalar) for (int i = 1; i < width_; ++i) { index_factory(i, height_); resid_arr_switch; if (grid->mpi_top) { (*left_arr) = operator( grid, k_coeff(i, height_, grid), right_arr[base_idx], right_arr[x_fwd_idx], right_arr[x_bwd_idx], grid->guest_top[i], right_arr[y_bwd_idx] ) - (resid ? 0 : 1) * grid->b_con[base_idx]; } else { (*left_arr) = operator_top( grid, k_coeff(i, height_, grid), right_arr[base_idx], right_arr[x_fwd_idx], right_arr[x_bwd_idx], right_arr[y_bwd_idx] ) - (resid ? 0 : 1) * grid->b_con[base_idx]; } resid_loc_norm_advance; } resid_glob_norm_advance(0.5); } void corner_op_top_right(struct Grid* grid, int resid) { common_vars; operator_vars; index_factory(width_, height_); resid_arr_switch; double base = right_arr[base_idx], x_bwd = right_arr[x_bwd_idx], y_bwd = right_arr[y_bwd_idx]; if ((!grid->mpi_top) && (!grid->mpi_right)) (*left_arr) = operator_top_right(grid, k_coeff(width_, height_, grid), base, x_bwd, y_bwd) - (resid ? 0 : 1) * grid->b_con[base_idx]; else if (!grid->mpi_top) (*left_arr) = operator_top(grid, k_coeff(width_, height_, grid), base, grid->guest_right[height_], x_bwd, y_bwd) - (resid ? 0 : 1) * grid->b_con[base_idx]; else if (!grid->mpi_right) (*left_arr) = operator_right(grid, k_coeff(width_, height_, grid), base, x_bwd, grid->guest_top[width_], y_bwd) - (resid ? 0 : 1) * grid->b_con[base_idx]; else (*left_arr) = operator(grid, k_coeff(width_, height_, grid), base, grid->guest_right[height_], x_bwd, grid->guest_top[width_], y_bwd) - (resid ? 0 : 1) * grid->b_con[base_idx]; resid_glob_norm_advance(0.25); } void corner_op_top_left(struct Grid* grid, int resid) { common_vars; operator_vars; index_factory(0, height_); resid_arr_switch; double base = right_arr[base_idx], x_fwd = right_arr[x_fwd_idx], y_bwd = right_arr[y_bwd_idx]; if ((!grid->mpi_top) && (!grid->mpi_left)) (*left_arr) = operator_top_left(grid, k_coeff(0, height_, grid), base, x_fwd, y_bwd) - (resid ? 0 : 1) * grid->b_con[base_idx]; else if (!grid->mpi_top) (*left_arr) = operator_top(grid, k_coeff(0, height_, grid), base, x_fwd, grid->guest_left[height_], y_bwd) - (resid ? 0 : 1) * grid->b_con[base_idx]; else if (!grid->mpi_left) (*left_arr) = operator_left(grid, k_coeff(0, height_, grid), base, x_fwd, grid->guest_top[0], y_bwd) - (resid ? 0 : 1) * grid->b_con[base_idx]; else (*left_arr) = operator(grid, k_coeff(0, height_, grid), base, x_fwd, grid->guest_left[height_], grid->guest_top[0], y_bwd) - (resid ? 0 : 1) * grid->b_con[base_idx]; resid_glob_norm_advance(0.25); } void corner_op_bot_right(struct Grid* grid, int resid) { common_vars; operator_vars; index_factory(width_, 0); resid_arr_switch; double base = right_arr[base_idx], x_bwd = right_arr[x_bwd_idx], y_fwd = right_arr[y_fwd_idx]; if ((!grid->mpi_bot) && (!grid->mpi_right)) (*left_arr) = operator_bot_right(grid, k_coeff(width_, 0, grid), base, x_bwd, y_fwd) - (resid ? 0 : 1) * grid->b_con[base_idx]; else if (!grid->mpi_right) (*left_arr) = operator_right(grid, k_coeff(width_, 0, grid), base, x_bwd, y_fwd, grid->guest_bot[width_]) - (resid ? 0 : 1) * grid->b_con[base_idx]; else if (!grid->mpi_bot) (*left_arr) = operator_bot(grid, k_coeff(width_, 0, grid), base, grid->guest_right[0], x_bwd, y_fwd) - (resid ? 0 : 1) * grid->b_con[base_idx]; else (*left_arr) = operator(grid, k_coeff(width_, 0, grid), base, grid->guest_right[0], x_bwd, y_fwd, grid->guest_bot[width_]) - (resid ? 0 : 1) * grid->b_con[base_idx]; resid_glob_norm_advance(0.25); } void corner_op_bot_left(struct Grid* grid, int resid) { common_vars; operator_vars; index_factory(0, 0); resid_arr_switch; double base = right_arr[base_idx], x_fwd = right_arr[x_fwd_idx], y_fwd = right_arr[y_fwd_idx]; if ((!grid->mpi_bot) && (!grid->mpi_left)) (*left_arr) = operator_bot_left(grid, k_coeff(0, 0, grid), base, x_fwd, y_fwd) - (resid ? 0 : 1) * grid->b_con[base_idx]; else if (!grid->mpi_left) (*left_arr) = operator_left(grid, k_coeff(0, 0, grid), base, x_fwd, y_fwd, grid->guest_bot[0]) - (resid ? 0 : 1) * grid->b_con[base_idx]; else if (!grid->mpi_bot) (*left_arr) = operator_bot(grid, k_coeff(0, 0, grid), base, x_fwd, grid->guest_left[0], y_fwd) - (resid ? 0 : 1) * grid->b_con[base_idx]; else (*left_arr) = operator(grid, k_coeff(0, 0, grid), base, x_fwd, grid->guest_left[0], y_fwd, grid->guest_bot[0]) - (resid ? 0 : 1) * grid->b_con[base_idx]; resid_glob_norm_advance(0.25); } void border_op(struct Grid* grid, int resid) { border_op_left(grid, resid); border_op_right(grid, resid); border_op_top(grid, resid); border_op_bot(grid, resid); corner_op_top_right(grid, resid); corner_op_top_left(grid, resid); corner_op_bot_right(grid, resid); corner_op_bot_left(grid, resid); } void display_grid_h(struct Grid* grid) { int height = grid->height, width = grid->width; printf("x_h: %f, y_h: %f\n", grid->x_h, grid->y_h); for (int i = 0; i < width; ++i) { for (int j = 0; j < height; ++j) printf("(%-2.2f %2.2f)", __x(grid, i), __y(grid, j)); //printf("%-2.2f ", k_coeff(i, j, grid)); printf("\n"); } } void display_grid_arr(struct Grid* grid, double* arr, double displacement) { int height = grid->height, width = grid->width; for (int i = 0; i < width; ++i) { for (int j = 0; j < height; ++j) printf("%9.2e ", arr[idx(i, j, height)] + displacement); printf("\n"); } } void display_grid_arr_idx(struct Grid* grid) { int height = grid->height, width = grid->width; for (int i = 0; i < width; ++i) { for (int j = 0; j < height; ++j) { printf("%-3i ", idx(i, j, height)); } printf("\n"); } } void dump_array(struct Grid* grid, double* arr, int counter, int grid_size) { int height = grid->height, width = grid->width; char full_name[80]; // hardcoded for maximum FIRE sprintf(full_name, "data/mpi_four/%i_%i_%i", grid_size, grid->rank, counter); FILE* file = fopen(full_name, "w"); fprintf(file, "["); for (int i = 0; i < width; ++i) { fprintf(file, "["); for (int j = 0; j < height; ++j) { fprintf(file, "%f,", arr[idx(i, j, height)]); } fprintf(file, "],\n"); } fprintf(file, "]\n"); fclose(file); } double max_abs_resid(struct Grid* grid) { double max_abs_resid = 0, max_abs_resid_2 = 0; int max_i = 0, max_j = 0; for (int i = 0; i < grid->width-1; ++i) for (int j = 0; j < grid->height-1; ++j) { if (fabs(grid->resid[idx(i, j, grid->height)]) > max_abs_resid) { max_abs_resid = fabs(grid->resid[idx(i, j, grid->height)]); max_i = i; max_j = j; } } //printf("Max resid i,j: (%i, %i)\n", max_i, max_j); MPI_Reduce(&max_abs_resid, &max_abs_resid_2, 1, MPI_DOUBLE, MPI_MAX, 0, (*grid->mpi_world)); return max_abs_resid_2; } double max_solution_error(struct Grid* grid) { double max_sol_err = -1, max_sol_err_2; int max_i = 0, max_j = 0; for (int i = 0; i < grid->width; ++i) for (int j = 0; j < grid->height; ++j) { double sol_err = fabs(grid->inter[idx(i, j, grid->height)] - (1 + cos(M_PI * __x(grid, i) * __y(grid, j)))); if (sol_err > max_sol_err) { max_sol_err = sol_err; max_i = i; max_j = j; } } MPI_Reduce(&max_sol_err, &max_sol_err_2, 1, MPI_DOUBLE, MPI_MAX, 0, (*grid->mpi_world)); return max_sol_err_2; } double norm_abs_solution_error(struct Grid* grid) { double norm = 0, norm_2 = 0; int max_i = 0, max_j = 0; for (int i = 0; i < grid->width; ++i) for (int j = 0; j < grid->height; ++j) { double sol_err = fabs(grid->inter[idx(i, j, grid->height)] - (1 + cos(M_PI * __x(grid, i) * __y(grid, j)))); norm += sol_err * sol_err * (((i > 0) && (i < grid->width-1)) ? 1 : 0.5) * (((j > 0) && (j < grid->height-1)) ? 1 : 0.5); } norm *= grid->x_h * grid->y_h; MPI_Reduce(&norm, &norm_2, 1, MPI_DOUBLE, MPI_SUM, 0, (*grid->mpi_world)); return sqrt(norm_2); } void display_solution(struct Grid* grid) { int height = grid->height, width = grid->width; for (int i = 0; i < width; ++i) { for (int j = 0; j < height; ++j) printf("%7.2e ", (1 + cos(M_PI * __x(grid, i) * __y(grid, j)))); printf("\n"); } } void async_send_guests(struct Grid* grid, bool resid) { MPI_Comm* mpi_world = grid->mpi_world; // ignore this, sync is done by recieve MPI_Request request; double *send_arr; int rc, dest_rank, junk_rank, height = grid->height, width = grid->width, height_ = height - 1, width_ = width - 1; // set the right send arrays if (resid) { send_arr = grid->resid; } else { send_arr = grid->inter; } if (grid->mpi_left) { mpi_wrap(MPI_Cart_shift((*mpi_world), 0, -1, &junk_rank, &dest_rank), (*mpi_world), rc); mpi_wrap(MPI_Isend(&(send_arr[idx(0, 0, height)]), height, MPI_DOUBLE, dest_rank, 0, (*mpi_world), &request), (*mpi_world), rc); mpi_wrap(MPI_Request_free(&request), (*mpi_world), rc); } if (grid->mpi_right) { mpi_wrap(MPI_Cart_shift((*mpi_world), 0, 1, &junk_rank, &dest_rank), (*mpi_world), rc); mpi_wrap(MPI_Isend(&(send_arr[idx(width_, 0, height)]), height, MPI_DOUBLE, dest_rank, 0, (*mpi_world), &request), (*mpi_world), rc); mpi_wrap(MPI_Request_free(&request), (*mpi_world), rc); } if (grid->mpi_bot) { mpi_wrap(MPI_Cart_shift((*mpi_world), 1, -1, &junk_rank, &dest_rank), (*mpi_world), rc); for (int i = 0; i < width; ++i) grid->buf_bot[i] = send_arr[idx(i, 0, height)]; mpi_wrap(MPI_Isend(grid->buf_bot, width, MPI_DOUBLE, dest_rank, 0, (*mpi_world), &request), (*mpi_world), rc); mpi_wrap(MPI_Request_free(&request), (*mpi_world), rc); } if (grid->mpi_top) { mpi_wrap(MPI_Cart_shift((*mpi_world), 1, 1, &junk_rank, &dest_rank), (*mpi_world), rc); for (int i = 0; i < width; ++i) grid->buf_top[i] = send_arr[idx(i, height_, height)]; mpi_wrap(MPI_Isend(grid->buf_top, width, MPI_DOUBLE, dest_rank, 0, (*mpi_world), &request), (*mpi_world), rc); mpi_wrap(MPI_Request_free(&request), (*mpi_world), rc); } } void sync_recv_guests(struct Grid* grid) { MPI_Comm* mpi_world = grid->mpi_world; int rc, src_rank, junk_rank, height = grid->height, width = grid->width; // receiving buffers are the same no matter what if (grid->mpi_left) { mpi_wrap(MPI_Cart_shift((*mpi_world), 0, -1, &junk_rank, &src_rank), (*mpi_world), rc); mpi_wrap(MPI_Recv(grid->guest_left, height, MPI_DOUBLE, src_rank, 0, (*mpi_world), MPI_STATUS_IGNORE), (*mpi_world), rc); } if (grid->mpi_right) { mpi_wrap(MPI_Cart_shift((*mpi_world), 0, 1, &junk_rank, &src_rank), (*mpi_world), rc); mpi_wrap(MPI_Recv(grid->guest_right, height, MPI_DOUBLE, src_rank, 0, (*mpi_world), MPI_STATUS_IGNORE), (*mpi_world), rc); } if (grid->mpi_bot) { mpi_wrap(MPI_Cart_shift((*mpi_world), 1, -1, &junk_rank, &src_rank), (*mpi_world), rc); mpi_wrap(MPI_Recv(grid->guest_bot, width, MPI_DOUBLE, src_rank, 0, (*mpi_world), MPI_STATUS_IGNORE), (*mpi_world), rc); } if (grid->mpi_top) { mpi_wrap(MPI_Cart_shift((*mpi_world), 1, 1, &junk_rank, &src_rank), (*mpi_world), rc); mpi_wrap(MPI_Recv(grid->guest_top, width, MPI_DOUBLE, src_rank, 0, (*mpi_world), MPI_STATUS_IGNORE), (*mpi_world), rc); } } void step_up(struct Grid* grid, double diff) { common_vars; double error = 0; #pragma omp parallel for reduction(+:error) for (int i = 0; i < width; ++i) for (int j = 0; j < height; ++j) { int base_idx = idx(i, j, height); double sub_error = diff * grid->resid[base_idx]; grid->inter[base_idx] = grid->inter[base_idx] - sub_error; error += sub_error * sub_error * (((i > 0) && (i < width_)) ? 1 : 0.5) * (((j > 0) && (j < height_)) ? 1 : 0.5); } grid->error = error; }

yolov2_forward_network_quantized.c

#include "additionally.h" // some definitions from: im2col.h, blas.h, list.h, utils.h, activations.h, tree.h, layer.h, network.h // softmax_layer.h, reorg_layer.h, route_layer.h, region_layer.h, maxpool_layer.h, convolutional_layer.h #define GEMMCONV #define W_MAX_VAL (256/2 - 1) // 7-bit (1-bit sign) #define I_MAX_VAL (256/2 - 1) // 7-bit (1-bit sign) #define R_MAX_VAL (256*256/2 - 1) // 31-bit (1-bit sign) #define R_MULT (32) // 4 - 32 /* // from: box.h typedef struct { float x, y, w, h; } box; */ int max_abs(int src, int max_val) { if (abs(src) > abs(max_val)) src = (src > 0) ? max_val : -max_val; return src; } short int max_abs_short(short int src, short int max_val) { if (abs(src) > abs(max_val)) src = (src > 0) ? max_val : -max_val; return src; } int *get_distribution(float *arr_ptr, int arr_size, int number_of_ranges, float start_range) { //const int number_of_ranges = 32; //const float start_range = 1.F / 65536; int *count = calloc(number_of_ranges, sizeof(int)); float min_val = 10000, max_val = 0; int i, j; for (i = 0; i < arr_size; ++i) { float w = arr_ptr[i]; float cur_range = start_range; for (j = 0; j < number_of_ranges; ++j) { if (fabs(cur_range) <= w && w < fabs(cur_range * 2)) count[j]++;// , printf("found \n"); cur_range *= 2; //printf("%f, ", w); } } return count; } float get_multiplier(float *arr_ptr, int arr_size, int bits_length) { const int number_of_ranges = 32; const float start_range = 1.F / 65536; int i, j; int *count = get_distribution(arr_ptr, arr_size, number_of_ranges, start_range); int max_count_range = 0; int index_max_count = 0; for (j = 0; j < number_of_ranges; ++j) { int counter = 0; for (i = j; i < (j + bits_length) && i < number_of_ranges; ++i) { counter += count[i]; //counter += log2(count[i]); } if (max_count_range < counter) { max_count_range = counter; index_max_count = j; } } //index_max_count = index_max_count + 2; // optimal shift multipler float multiplier = 1 / (start_range * powf(2., (float) index_max_count)); //printf(" max_count_range = %d, index_max_count = %d, multiplier = %g \n", // max_count_range, index_max_count, multiplier); free(count); return multiplier; } #ifdef OPENCV #include <opencv2/core/fast_math.hpp> #include "opencv2/highgui/highgui_c.h" #include "opencv2/core/core_c.h" #include "opencv2/core/version.hpp" #define CV_RGB(r, g, b) cvScalar( (b), (g), (r), 0 ) void draw_distribution(float *arr_ptr, int arr_size, char *name) { int img_w = 1200, img_h = 800; const int number_of_ranges = 32; const float start_range = 1.F / 65536; //int *count = calloc(number_of_ranges, sizeof(int)); //float min_val = 100, max_val = 0; int i, j; int *count = get_distribution(arr_ptr, arr_size, number_of_ranges, start_range); float multiplier = get_multiplier(arr_ptr, arr_size, 8); int max_count_range = 0; for (j = 0; j < number_of_ranges; ++j) { count[j] = log2(count[j]); if (max_count_range < count[j]) max_count_range = count[j]; } cvNamedWindow("Distribution", CV_WINDOW_NORMAL); cvResizeWindow("Distribution", img_w, img_h); IplImage *img = cvCreateImage(cvSize(img_w, img_h), IPL_DEPTH_8U, 3); if (max_count_range > 0) { for (j = 0; j < number_of_ranges; ++j) { //printf("count[j] = %d, max_count_range = %d, img_w = %d, img_h = %d, j = %d, number_of_ranges = %d \n", // count[j], max_count_range, img_w, img_h, j, number_of_ranges); CvPoint pt1, pt2; pt1.x = j*img_w / number_of_ranges; pt2.x = (j + 1)*img_w / number_of_ranges; pt1.y = img_h; pt2.y = img_h - img_h*count[j] / max_count_range; //printf("pt1.x = %d, pt1.y = %d, pt2.x = %d, pt2.y = %d \n", pt1.x, pt1.y, pt2.x, pt2.y); //if(pt2.y < pt1.y) cvRectangle(img, pt1, pt2, CV_RGB(128, 64, 32), CV_FILLED, 8, 0); cvRectangle(img, pt1, pt2, CV_RGB(32, 32, 32), 1, 8, 0); } } int index_multiplier = log2(1 / (multiplier*start_range)); int x_coord_multiplier = index_multiplier*img_w / number_of_ranges; cvLine(img, cvPoint(x_coord_multiplier, 0), cvPoint(x_coord_multiplier, img_h), CV_RGB(255, 32, 32), 1, 8, 0); char buff[256]; //sprintf(buff, "[%g - %g]", min_val, max_val); sprintf(buff, "optimal multiplier = %g", multiplier); //printf("[%g - %g]", min_val, max_val); CvFont font; cvInitFont(&font, CV_FONT_HERSHEY_COMPLEX, 1, 1, 0, 2, 8); cvPutText(img, buff, cvPoint(100, 50), &font, CV_RGB(32, 64, 128)); if (name) cvPutText(img, name, cvPoint(0, 20), &font, CV_RGB(32, 64, 128)); float cur_range = start_range; cvInitFont(&font, CV_FONT_HERSHEY_COMPLEX, 0.5, 0.5, 0, 1, 8); for (j = 0; j < number_of_ranges; ++j) { CvPoint pt_text = cvPoint(j*img_w / number_of_ranges, img_h - 50); int lg = log2(cur_range); sprintf(buff, "%d", lg); cvPutText(img, buff, pt_text, &font, CV_RGB(32, 64, 128)); cur_range *= 2; } cvPutText(img, "X and Y are log2", cvPoint(img_w / 2 - 100, img_h - 10), &font, CV_RGB(32, 64, 128)); cvShowImage("Distribution", img); cvWaitKey(0); free(count); } #endif // OPENCV // im2col.c int8_t im2col_get_pixel_int8(int8_t *im, int height, int width, int channels, int row, int col, int channel, int pad) { row -= pad; col -= pad; if (row < 0 || col < 0 || row >= height || col >= width) return 0; return im[col + width * (row + height * channel)]; } // im2col.c //From Berkeley Vision's Caffe! //https://github.com/BVLC/caffe/blob/master/LICENSE void im2col_cpu_int8(int8_t *data_im, int channels, int height, int width, int ksize, int stride, int pad, int8_t *data_col) { int c, h, w; int height_col = (height + 2 * pad - ksize) / stride + 1; int width_col = (width + 2 * pad - ksize) / stride + 1; int channels_col = channels * ksize * ksize; for (c = 0; c < channels_col; ++c) { int w_offset = c % ksize; int h_offset = (c / ksize) % ksize; int c_im = c / ksize / ksize; for (h = 0; h < height_col; ++h) { for (w = 0; w < width_col; ++w) { int im_row = h_offset + h * stride; int im_col = w_offset + w * stride; int col_index = (c * height_col + h) * width_col + w; data_col[col_index] = im2col_get_pixel_int8(data_im, height, width, channels, im_row, im_col, c_im, pad); } } } } // Use to enable AVX or SSE41 //#define AVX // 1.35 sec (0.8 FPS) 2.3x - GCC -mavx -mavx2 -mfma -ffp-contract=fast //#define SSE41 // 1.55 sec (0.7 FPS) 2x // default 3.10 sec (0.3 FPS) #if defined(AVX) || defined(SSE41) #ifdef _WIN64 #include <intrin.h> #else #include <x86intrin.h> #endif #include <ammintrin.h> #include <immintrin.h> #include <smmintrin.h> #include <emmintrin.h> // https://software.intel.com/sites/landingpage/IntrinsicsGuide/#text=broad&expand=561 #endif // AVX or SSE41 #if defined(AVX) __m256i _mm256_div_epi16(const __m256i va, const int b) { __m256i vb = _mm256_set1_epi16(32768 / b); return _mm256_mulhrs_epi16(va, vb); } #define INTERMEDIATE_MULT 15 // 8 or 15 #define FINAL_MULT (R_MULT / INTERMEDIATE_MULT) // 0.89 sec void gemm_nn_int8_int16_conv16(int M, int N, int K, int8_t ALPHA, int8_t *A, int lda, int8_t *B, int ldb, int16_t *C, int ldc) { __m256i res; __m256i a, b, d; __m128i tmp128; __m256i div256 = _mm256_set1_epi16(INTERMEDIATE_MULT); int16_t *c_tmp = calloc(N, sizeof(int16_t)); int i, j, k; for (i = 0; i < M; ++i) { for (k = 0; k < K; ++k) { register int16_t A_PART = ALPHA*A[i*lda + k]; a = _mm256_set1_epi16(A_PART); for (j = 0; j < N - 32; j += 32) { int index = k*ldb + j; d = _mm256_loadu_si256((__m256i*)&B[index]); tmp128 = _mm256_extractf128_si256(d, 0);// get low 128 bit b = _mm256_cvtepi8_epi16(tmp128); // int8 -> int16 b = _mm256_mullo_epi16(a, b); // B = A * B b = _mm256_div_epi16(b, INTERMEDIATE_MULT); // B = (A * B) / INTERMEDIATE_MULL res = _mm256_loadu_si256(&c_tmp[j]); // load temp C res = _mm256_add_epi16(b, res); // (A*B) + C _mm256_storeu_si256(&c_tmp[j], res); // store temp C tmp128 = _mm256_extractf128_si256(d, 1);// get high 128 bit b = _mm256_cvtepi8_epi16(tmp128); // int8 -> int16 (for low 8 bytes) b = _mm256_mullo_epi16(a, b); // B = A * B b = _mm256_div_epi16(b, INTERMEDIATE_MULT); // B = (A * B) / INTERMEDIATE_MULL res = _mm256_loadu_si256(&c_tmp[j + 16]); // Load next temp C res = _mm256_add_epi16(b, res); // (A*B) + C _mm256_storeu_si256(&c_tmp[j + 16], res); // store temp C //c_tmp[j] += A_PART*B[k*ldb + j]; //C[i*ldc + j] += max_abs(A_PART*B[k*ldb + j] / (INTERMEDIATE_MULL), (256 * 128 - 1)); } int prev_end = (N % 32 == 0) ? (N - 32) : (N / 32) * 32; for (j = prev_end; j < N; ++j) { c_tmp[j] += A_PART*B[k*ldb + j] / (INTERMEDIATE_MULT); } } for (j = 0; j < N; ++j) { C[i*ldc + j] += (c_tmp[j] / FINAL_MULT); c_tmp[j] = 0; } } free(c_tmp); } // 1.15 sec void gemm_nn_int8_int16(int M, int N, int K, int8_t ALPHA, int8_t *A, int lda, int8_t *B, int ldb, int16_t *C, int ldc) { __m256i multyplied_i32, res; __m256i a, b, d; __m128i tmp128; int32_t *c_tmp = calloc(N, sizeof(int32_t)); int i, j, k; for (i = 0; i < M; ++i) { for (k = 0; k < K; ++k) { register int16_t A_PART = ALPHA*A[i*lda + k]; a = _mm256_set1_epi16(A_PART); for (j = 0; j < N - 32; j += 32) { int index = k*ldb + j; d = _mm256_loadu_si256((__m256i*)&B[index]); tmp128 = _mm256_extractf128_si256(d, 0);// get low 128 bit b = _mm256_cvtepi8_epi16(tmp128); // int8 -> int16 b = _mm256_mullo_epi16(a, b); // B = A * B tmp128 = _mm256_extractf128_si256(b, 0); // get low 128 bit multyplied_i32 = _mm256_cvtepi16_epi32(tmp128); // int16 -> int32 res = _mm256_loadu_si256(&c_tmp[j]); // load temp C res = _mm256_add_epi32(multyplied_i32, res);// (A*B) + C _mm256_storeu_si256(&c_tmp[j], res); // store temp C tmp128 = _mm256_extractf128_si256(b, 1); // get high 128 bit multyplied_i32 = _mm256_cvtepi16_epi32(tmp128); // int16 -> int32 res = _mm256_loadu_si256(&c_tmp[j + 8]); // Load next temp C res = _mm256_add_epi32(multyplied_i32, res);// (A*B) + C _mm256_storeu_si256(&c_tmp[j + 8], res); // store temp C tmp128 = _mm256_extractf128_si256(d, 1);// get high 128 bit b = _mm256_cvtepi8_epi16(tmp128); // int8 -> int16 (for low 8 bytes) b = _mm256_mullo_epi16(a, b); // B = A * B tmp128 = _mm256_extractf128_si256(b, 0); // get low 128 bit multyplied_i32 = _mm256_cvtepi16_epi32(tmp128); // int16 -> int32 res = _mm256_loadu_si256(&c_tmp[j + 16]); // Load next temp C res = _mm256_add_epi32(multyplied_i32, res);// (A*B) + C _mm256_storeu_si256(&c_tmp[j + 16], res); // store temp C tmp128 = _mm256_extractf128_si256(b, 1); // get high 128 bit multyplied_i32 = _mm256_cvtepi16_epi32(tmp128); // int16 -> int32 res = _mm256_loadu_si256(&c_tmp[j + 24]); // Load next temp C res = _mm256_add_epi32(multyplied_i32, res);// (A*B) + C _mm256_storeu_si256(&c_tmp[j + 24], res); // store temp C //c_tmp[j] += A_PART*B[k*ldb + j]; //C[i*ldc + j] += max_abs(A_PART*B[k*ldb + j] / (32), (256 * 128 - 1)); } int prev_end = (N % 32 == 0) ? (N - 32) : (N / 32) * 32; for (j = prev_end; j < N; ++j) { c_tmp[j] += A_PART*B[k*ldb + j]; } } for (j = 0; j < N; ++j) { C[i*ldc + j] += max_abs(c_tmp[j] / (R_MULT), (256 * 128 - 1)); c_tmp[j] = 0; } //for (j = 0; j < N; ++j) C[i*ldc + j] += c_tmp[j] / (R_MULT); } free(c_tmp); } #elif defined(SSE41) // 1.3 sec void gemm_nn_int8_int16(int M, int N, int K, int8_t ALPHA, int8_t *A, int lda, int8_t *B, int ldb, int16_t *C, int ldc) { __m128i multyplied_i32, res; __m128i a, b, d; //c = _mm_set1_epi16(32); int32_t *c_tmp = calloc(N, sizeof(int32_t)); int i, j, k; for (i = 0; i < M; ++i) { for (k = 0; k < K; ++k) { register int16_t A_PART = ALPHA*A[i*lda + k]; a = _mm_set1_epi16(A_PART); for (j = 0; j < N - 16; j += 16) { int index = k*ldb + j; d = _mm_loadu_si128((__m128i*)&B[index]); b = _mm_cvtepi8_epi16(d); // int8 -> int16 b = _mm_mullo_epi16(a, b); // B = A * B multyplied_i32 = _mm_cvtepi16_epi32(b); // int16 -> int32 res = _mm_loadu_si128(&c_tmp[j]); // load temp C res = _mm_add_epi32(multyplied_i32, res);// (A*B) + C _mm_store_si128(&c_tmp[j], res); // store temp C b = _mm_srli_si128(b, 8); // Shift Right -> 8 bytes multyplied_i32 = _mm_cvtepi16_epi32(b); // int16 -> int32 res = _mm_loadu_si128(&c_tmp[j + 4]); // Load next temp C res = _mm_add_epi32(multyplied_i32, res);// (A*B) + C _mm_store_si128(&c_tmp[j + 4], res); // store temp C d = _mm_srli_si128(d, 8); // Shift Right -> 8 bytes b = _mm_cvtepi8_epi16(d); // int8 -> int16 (for low 8 bytes) b = _mm_mullo_epi16(a, b); // B = A * B multyplied_i32 = _mm_cvtepi16_epi32(b); // int16 -> int32 res = _mm_loadu_si128(&c_tmp[j + 8]); // Load next temp C res = _mm_add_epi32(multyplied_i32, res);// (A*B) + C _mm_store_si128(&c_tmp[j + 8], res); // store temp C b = _mm_srli_si128(b, 8); // Shift Right -> 8 bytes multyplied_i32 = _mm_cvtepi16_epi32(b); // int16 -> int32 res = _mm_loadu_si128(&c_tmp[j + 12]); // Load next temp C res = _mm_add_epi32(multyplied_i32, res);// (A*B) + C _mm_store_si128(&c_tmp[j + 12], res); // store temp C //c_tmp[j] += A_PART*B[k*ldb + j]; //C[i*ldc + j] += max_abs(A_PART*B[k*ldb + j] / (32), (256 * 128 - 1)); } int prev_end = (N % 16 == 0) ? (N - 16) : (N / 16) * 16; for (j = prev_end; j < N; ++j) { c_tmp[j] += A_PART*B[k*ldb + j]; } } for (j = 0; j < N; ++j) { C[i*ldc + j] += max_abs(c_tmp[j] / (R_MULT), (256 * 128 - 1)); c_tmp[j] = 0; } //for (j = 0; j < N; ++j) C[i*ldc + j] += c_tmp[j] / (R_MULT); } free(c_tmp); } void gemm_nn_int8_int16_conv16(int M, int N, int K, int8_t ALPHA, int8_t *A, int lda, int8_t *B, int ldb, int16_t *C, int ldc) { printf(" gemm_nn_int8_int16_conv16() isn't implemented for SSE4.1 \n"); } #else // 2.9 sec void gemm_nn_int8_int16(int M, int N, int K, int8_t ALPHA, int8_t *A, int lda, int8_t *B, int ldb, int16_t *C, int ldc) { int32_t *c_tmp = calloc(N, sizeof(int32_t)); int i, j, k; for (i = 0; i < M; ++i) { for (k = 0; k < K; ++k) { register int16_t A_PART = ALPHA * A[i * lda + k]; //#pragma simd parallel for for (j = 0; j < N; ++j) { c_tmp[j] += A_PART * B[k * ldb + j]; //C[i*ldc + j] += max_abs(A_PART*B[k*ldb + j] / (R_MULT), (256 * 128 - 1)); } } for (j = 0; j < N; ++j) { C[i * ldc + j] += max_abs(c_tmp[j] / (R_MULT), (256 * 128 - 1)); c_tmp[j] = 0; } } free(c_tmp); } void gemm_nn_int8_int32(int M, int N, int K, int8_t ALPHA, int8_t *A, int lda, int8_t *B, int ldb, int32_t *C, int ldc) { int32_t *c_tmp = calloc(N, sizeof(int32_t)); int i, j, k; for (i = 0; i < M; ++i) { for (k = 0; k < K; ++k) { register int16_t A_PART = ALPHA * A[i * lda + k]; //#pragma simd parallel for for (j = 0; j < N; ++j) { c_tmp[j] += A_PART * B[k * ldb + j]; //C[i*ldc + j] += max_abs(A_PART*B[k*ldb + j] / (R_MULT), (256 * 128 - 1)); } } for (j = 0; j < N; ++j) { C[i * ldc + j] += max_abs(c_tmp[j] / (R_MULT), (256 * 128 - 1)); c_tmp[j] = 0; } } free(c_tmp); } void gemm_nn_int8_int16_conv16(int M, int N, int K, int8_t ALPHA, int8_t *A, int lda, int8_t *B, int ldb, int16_t *C, int ldc) { printf(" gemm_nn_int8_int16_conv16() isn't implemented \n"); } #endif // SSE41 or AVX void forward_convolutional_layer_q(layer l, network_state state) { int out_h = (l.h + 2 * l.pad - l.size) / l.stride + 1; // output_height=input_height for stride=1 and pad=1 int out_w = (l.w + 2 * l.pad - l.size) / l.stride + 1; // output_width=input_width for stride=1 and pad=1 int i, f, j; int const out_size = out_h * out_w; size_t const weights_size = l.size * l.size * l.c * l.n; // fill zero (ALPHA) //for (i = 0; i < l.outputs; ++i) l.output[i] = 0; // l.n - number of filters on this layer // l.c - channels of input-array // l.h - height of input-array // l.w - width of input-array // l.size - width and height of filters (the same size for all filters) //draw_distribution(l.weights, weights_size, "weights"); //draw_distribution(state.input, l.inputs, "input"); //typedef int32_t conv_t; // l.output typedef int16_t conv_t; // l.output conv_t *output_q = calloc(l.outputs, sizeof(conv_t)); state.input_int8 = (int *) calloc(l.inputs, sizeof(int)); int z; for (z = 0; z < l.inputs; ++z) { //int16_t src = lround(state.input[k] * net.layers[0].input_quant_multipler); int16_t src = state.input[z] * l.input_quant_multipler; state.input_int8[z] = max_abs(src, I_MAX_VAL); } //////////////////////////////////// // cudnnConvolutionBiasActivationForward() // y = act ( alpha1 * conv(x) + alpha2 * z + bias ) // int8 = activation( float * conv(int8) + float * int8 + float ) // int8 = activation( conv(input_int8) + bias_float ) // X_INT8x4 or X_INT8 // https://docs.nvidia.com/deeplearning/sdk/cudnn-developer-guide/index.html#cudnnConvolutionBiasActivationForward /////////////////////////////////// // 1. Convolution !!! int fil; // cuDNN: y = conv(x) int m = l.n; int k = l.size * l.size * l.c; int n = out_h * out_w; int8_t *a = l.weights_int8; int8_t *b = (int8_t *) state.workspace; conv_t *c = output_q; // int16_t // convolution as GEMM (as part of BLAS) //for (i = 0; i < l.batch; ++i) { im2col_cpu_int8(state.input_int8, l.c, l.h, l.w, l.size, l.stride, l.pad, b); // here //gemm_nn_int8_int16(m, n, k, 1, a, k, b, n, c, n); // single-thread gemm int t; // multi-thread gemm #pragma omp parallel for for (t = 0; t < m; ++t) { gemm_nn_int8_int16(1, n, k, 1, a + t * k, k, b, n, c + t * n, n); //gemm_nn_int8_int16_conv16(1, n, k, 1, a + t*k, k, b, n, c + t*n, n); //gemm_nn_int8_int32(1, n, k, 1, a + t*k, k, b, n, c + t*n, n); // conv_t should be int32_t } //} free(state.input_int8); float ALPHA1 = R_MULT / (l.input_quant_multipler * l.weights_quant_multipler); // cuDNN: y = alpha1 * conv(x) for (i = 0; i < l.outputs; ++i) { l.output[i] = output_q[i] * ALPHA1; // cuDNN: alpha1 } //for (fil = 0; fil < l.n; ++fil) { // for (j = 0; j < out_size; ++j) { // l.output[fil*out_size + j] = l.output[fil*out_size + j] * ALPHA1; // } //} // cuDNN: y = alpha1 * conv(x) + bias for (fil = 0; fil < l.n; ++fil) { for (j = 0; j < out_size; ++j) { l.output[fil * out_size + j] += l.biases[fil]; } } //draw_distribution(l.output, l.outputs, "output"); // cuDNN: y = act ( alpha1 * conv(x) + bias ) // bias is always FLOAT if (l.activation == LEAKY) { for (i = 0; i < l.n * out_size; ++i) { l.output[i] = (l.output[i] > 0) ? l.output[i] : l.output[i] / 10; //leaky_activate(l.output[i]); } } free(output_q); } // 4 layers in 1: convolution, batch-normalization, BIAS and activation void forward_convolutional_layer_q_old(layer l, network_state state, int return_float) { int out_h = (l.h + 2 * l.pad - l.size) / l.stride + 1; // output_height=input_height for stride=1 and pad=1 int out_w = (l.w + 2 * l.pad - l.size) / l.stride + 1; // output_width=input_width for stride=1 and pad=1 int i, f, j; int const out_size = out_h * out_w; size_t const weights_size = l.size * l.size * l.c * l.n; // fill zero (ALPHA) //for (i = 0; i < l.outputs; ++i) l.output[i] = 0; // l.n - number of filters on this layer // l.c - channels of input-array // l.h - height of input-array // l.w - width of input-array // l.size - width and height of filters (the same size for all filters) //draw_distribution(l.weights, weights_size, NULL); //draw_distribution(state.input, l.inputs, NULL); typedef int16_t conv_t; // l.output conv_t *output_q = calloc(l.outputs, sizeof(conv_t)); //////////////////////////////////// // cudnnConvolutionBiasActivationForward() // y = act ( alpha1 * conv(x) + alpha2 * z + bias ) // int8 = activation( float * conv(int8) + float * int8 + float ) // int8 = activation( conv(input_int8) + bias_float ) // X_INT8x4 or X_INT8 // https://docs.nvidia.com/deeplearning/sdk/cudnn-developer-guide/index.html#cudnnConvolutionBiasActivationForward /////////////////////////////////// // 1. Convolution !!! #ifndef GEMMCONV int fil; // filter index #pragma omp parallel for // "omp parallel for" - automatic parallelization of loop by using OpenMP for (fil = 0; fil < l.n; ++fil) { int chan, y, x, f_y, f_x; // channel index for (chan = 0; chan < l.c; ++chan) // input - y for (y = 0; y < l.h; ++y) // input - x for (x = 0; x < l.w; ++x) { int const output_index = fil*l.w*l.h + y*l.w + x; int const weights_pre_index = fil*l.c*l.size*l.size + chan*l.size*l.size; int const input_pre_index = chan*l.w*l.h; //float sum = 0; //int16_t sum = 0; int32_t sum = 0; //conv_t sum = 0; // filter - y for (f_y = 0; f_y < l.size; ++f_y) { int input_y = y + f_y - l.pad; // filter - x for (f_x = 0; f_x < l.size; ++f_x) { int input_x = x + f_x - l.pad; if (input_y < 0 || input_x < 0 || input_y >= l.h || input_x >= l.w) continue; int input_index = input_pre_index + input_y*l.w + input_x; int weights_index = weights_pre_index + f_y*l.size + f_x; //sum += state.input[input_index] * l.weights[weights_index]; // int16 += int8 * int8; sum += (int32_t)state.input_int8[input_index] * (int32_t)l.weights_int8[weights_index]; } } // l.output[filters][width][height] += // state.input[channels][width][height] * // l.weights[filters][channels][filter_width][filter_height]; //output_q[output_index] += max_abs(sum, R_MAX_VAL); output_q[output_index] += max_abs(sum / R_MULT, R_MAX_VAL); //output_q[output_index] += sum / R_MULT; //if (fabs(output_q[output_index]) > 65535) printf(" fabs(output_q[output_index]) > 65535 \n"); } } #else int fil; // cuDNN: y = conv(x) int m = l.n; int k = l.size * l.size * l.c; int n = out_h * out_w; int8_t *a = l.weights_int8; int8_t *b = (int8_t *) state.workspace; conv_t *c = output_q; // int16_t // convolution as GEMM (as part of BLAS) //for (i = 0; i < l.batch; ++i) { im2col_cpu_int8(state.input_int8, l.c, l.h, l.w, l.size, l.stride, l.pad, b); // here //gemm_nn_int8_int16(m, n, k, 1, a, k, b, n, c, n); // single-thread gemm int t; // multi-thread gemm #pragma omp parallel for for (t = 0; t < m; ++t) { gemm_nn_int8_int16(1, n, k, 1, a + t * k, k, b, n, c + t * n, n); //gemm_nn_int8_int16_conv16(1, n, k, 1, a + t*k, k, b, n, c + t*n, n); //gemm_nn_int8_int32(1, n, k, 1, a + t*k, k, b, n, c + t*n, n); conv_t should be int32_t } //} #endif // cuDNN: y = alpha1 * conv(x) //for (i = 0; i < l.outputs; ++i) { // output_q[i] = output_q[i] * l.output_multipler; // cuDNN: alpha1 //} for (fil = 0; fil < l.n; ++fil) { for (j = 0; j < out_size; ++j) { output_q[fil * out_size + j] = output_q[fil * out_size + j] * l.output_multipler; } } // cuDNN: y = alpha1 * conv(x) + bias for (fil = 0; fil < l.n; ++fil) { for (j = 0; j < out_size; ++j) { output_q[fil * out_size + j] += l.biases_quant[fil]; } } //for (i = 0; i < l.inputs; ++i) state.input[i] = state.input_int8[i]; //char buff[1024]; //sprintf(buff, "inputs - filters %d", l.n); //draw_distribution(state.input, l.inputs, buff); //for (i = 0; i < l.outputs; ++i) l.output[i] = (float)output_q[i]; //draw_distribution(l.output, l.outputs, "output"); // cuDNN: y = act ( alpha1 * conv(x) + bias ) // bias is always FLOAT if (l.activation == LEAKY) { for (i = 0; i < l.n * out_size; ++i) { output_q[i] = (output_q[i] > 0) ? output_q[i] : output_q[i] / 10; //leaky_activate(l.output[i]); } } // cuDNN: y = act ( alpha1 * conv(x) + alpha2 * z + bias ), where: alpha2=0, z=NULL if (return_float) { // y - FLOAT, x,w - X_INT8 / X_INT8x4 for (i = 0; i < l.outputs; ++i) { l.output[i] = (float) output_q[i] / 16.F; // /8 // float32 // 15.769 } } else { // y - X_INT8 / X_INT8x4, x,w - X_INT8 / X_INT8x4 for (i = 0; i < l.outputs; ++i) { l.output_int8[i] = max_abs(output_q[i], I_MAX_VAL); // int8 } } free(output_q); } #define MIN_INT8 -128 // MAX pooling layer void forward_maxpool_layer_q(const layer l, network_state state) { int b, i, j, k, m, n; int w_offset = -l.pad; int h_offset = -l.pad; int h = l.out_h; int w = l.out_w; int c = l.c; // batch index for (b = 0; b < l.batch; ++b) { // channel index for (k = 0; k < c; ++k) { // y - input for (i = 0; i < h; ++i) { // x - input for (j = 0; j < w; ++j) { int out_index = j + w * (i + h * (k + c * b)); int8_t max = MIN_INT8; int max_i = -1; // pooling x-index for (n = 0; n < l.size; ++n) { // pooling y-index for (m = 0; m < l.size; ++m) { int cur_h = h_offset + i * l.stride + n; int cur_w = w_offset + j * l.stride + m; int index = cur_w + l.w * (cur_h + l.h * (k + b * l.c)); int valid = (cur_h >= 0 && cur_h < l.h && cur_w >= 0 && cur_w < l.w); int8_t val = (valid != 0) ? state.input_int8[index] : MIN_INT8; max_i = (val > max) ? index : max_i; // get max index max = (val > max) ? val : max; // get max value } } //l.output[out_index] = max; // store max value l.output_int8[out_index] = max; // store max value l.indexes[out_index] = max_i; // store max index } } } } } // Route layer - just copy 1 or more layers into the current layer void forward_route_layer_q(const layer l, network_state state) { int i, j; int offset = 0; // number of merged layers for (i = 0; i < l.n; ++i) { int index = l.input_layers[i]; // source layer index //float *input = state.net.layers[index].output; // source layer output ptr int8_t *input = state.net.layers[index].output_int8; // source layer output ptr int input_size = l.input_sizes[i]; // source layer size // batch index for (j = 0; j < l.batch; ++j) { memcpy(l.output_int8 + offset + j * l.outputs, input + j * input_size, input_size * sizeof(int8_t)); } offset += input_size; } } // Reorg layer - just change dimension sizes of the previous layer (some dimension sizes are increased by decreasing other) void forward_reorg_layer_q(const layer l, network_state state) { //float *out = l.output; //float *x = state.input; int8_t *out = l.output_int8; int8_t *x = state.input_int8; int out_w = l.out_w; int out_h = l.out_h; int out_c = l.out_c; int batch = l.batch; int stride = l.stride; int b, i, j, k; int in_c = out_c / (stride * stride); int out_w_X_stride = out_w * stride; int out_h_X_stride = out_h * stride; //printf("\n out_c = %d, out_w = %d, out_h = %d, stride = %d, forward = %d \n", out_c, out_w, out_h, stride, forward); //printf(" in_c = %d, in_w = %d, in_h = %d \n", in_c, out_w*stride, out_h*stride); // batch for (b = 0; b < batch; ++b) { // channel for (k = 0; k < out_c; ++k) { int c2 = k % in_c; int pre_out_index = out_h_X_stride * (c2 + in_c * b); int offset = k / in_c; int offset_mod_stride = offset % stride; int offset_div_stride = offset / stride; // y for (j = 0; j < out_h; ++j) { int pre_in_index = out_w * (j + out_h * (k + out_c * b)); // x for (i = 0; i < out_w; ++i) { int in_index = i + pre_in_index; int w2 = i * stride + offset_mod_stride; int h2 = j * stride + offset_div_stride; int out_index = w2 + out_w_X_stride * (h2 + pre_out_index); out[in_index] = x[out_index]; } } } } } // ---- region layer ---- static void softmax_q(float *input, int n, float temp, float *output) { int i; float sum = 0; float largest = -FLT_MAX; for (i = 0; i < n; ++i) { if (input[i] > largest) largest = input[i]; } for (i = 0; i < n; ++i) { float e = expf(input[i] / temp - largest / temp); sum += e; output[i] = e; } for (i = 0; i < n; ++i) { output[i] /= sum; } } static void softmax_tree(float *input, int batch, int inputs, float temp, tree *hierarchy, float *output) { int b; for (b = 0; b < batch; ++b) { int i; int count = 0; for (i = 0; i < hierarchy->groups; ++i) { int group_size = hierarchy->group_size[i]; softmax_q(input + b * inputs + count, group_size, temp, output + b * inputs + count); count += group_size; } } } // --- // Region layer - just change places of array items, then do logistic_activate and softmax void forward_region_layer_q(const layer l, network_state state) { int i, b; int size = l.coords + l.classes + 1; // 4 Coords(x,y,w,h) + Classes + 1 Probability-t0 //printf("\n l.coords = %d \n", l.coords); memcpy(l.output, state.input, l.outputs * l.batch * sizeof(float)); //flatten(l.output, l.w*l.h, size*l.n, l.batch, 1); // convert many channels to the one channel (depth=1) // (each grid cell will have a number of float-variables equal = to the initial number of channels) { float *x = l.output; int layer_size = l.w * l.h; // W x H - size of layer int layers = size * l.n; // number of channels (where l.n = number of anchors) int batch = l.batch; float *swap = calloc(layer_size * layers * batch, sizeof(float)); int i, c, b; // batch index for (b = 0; b < batch; ++b) { // channel index for (c = 0; c < layers; ++c) { // layer grid index for (i = 0; i < layer_size; ++i) { int i1 = b * layers * layer_size + c * layer_size + i; int i2 = b * layers * layer_size + i * layers + c; swap[i2] = x[i1]; } } } memcpy(x, swap, layer_size * layers * batch * sizeof(float)); free(swap); } // logistic activation only for: t0 (where is t0 = Probability * IoU(box, object)) for (b = 0; b < l.batch; ++b) { // for each item (x, y, anchor-index) for (i = 0; i < l.h * l.w * l.n; ++i) { int index = size * i + b * l.outputs; float x = l.output[index + 4]; l.output[index + 4] = 1.0F / (1.0F + expf(-x)); // logistic_activate_q(l.output[index + 4]); } } if (l.softmax_tree) { // Yolo 9000 for (b = 0; b < l.batch; ++b) { for (i = 0; i < l.h * l.w * l.n; ++i) { int index = size * i + b * l.outputs; softmax_tree(l.output + index + 5, 1, 0, 1, l.softmax_tree, l.output + index + 5); } } } else if (l.softmax) { // Yolo v2 // softmax activation only for Classes probability for (b = 0; b < l.batch; ++b) { // for each item (x, y, anchor-index) //#pragma omp parallel for for (i = 0; i < l.h * l.w * l.n; ++i) { int index = size * i + b * l.outputs; softmax_q(l.output + index + 5, l.classes, 1, l.output + index + 5); } } } } void yolov2_forward_network_q(network net, network_state state) { state.workspace = net.workspace; int i, k; for (i = 0; i < net.n; ++i) { state.index = i; layer l = net.layers[i]; if (l.type == CONVOLUTIONAL) { if (i >= 1 && l.activation != LINEAR) forward_convolutional_layer_q(l, state); else forward_convolutional_layer_cpu(l, state); printf("\n %d - CONVOLUTIONAL \t\t l.size = %d \n", i, l.size); } else if (l.type == MAXPOOL) { forward_maxpool_layer_cpu(l, state); //printf("\n MAXPOOL \t\t l.size = %d \n", l.size); } else if (l.type == ROUTE) { forward_route_layer_cpu(l, state); //printf("\n ROUTE \t\t\t l.n = %d \n", l.n); } else if (l.type == REORG) { forward_reorg_layer_cpu(l, state); //printf("\n REORG \n"); } else if (l.type == UPSAMPLE) { forward_upsample_layer_cpu(l, state); //printf("\n UPSAMPLE \n"); } else if (l.type == SHORTCUT) { forward_shortcut_layer_cpu(l, state); //printf("\n SHORTCUT \n"); } else if (l.type == YOLO) { forward_yolo_layer_cpu(l, state); //printf("\n YOLO \n"); } else if (l.type == REGION) { forward_region_layer_cpu(l, state); //printf("\n REGION \n"); } else { printf("\n layer: %d \n", l.type); } state.input = l.output; //state.input_int8 = l.output_int8; /* if (i == 0) { //draw_distribution(state.input, l.outputs, NULL); int k; for (k = 0; k < l.out_w*l.out_h*l.out_c; ++k) { int16_t src = state.input[k] * 3.88677;// *net.layers[2].input_quant_multipler; state.input_int8[k] = max_abs(src, I_MAX_VAL); //printf(" %d, ", src); } } */ } } void yolov2_forward_network_q_old(network net, network_state state) { state.workspace = net.workspace; int i, k; for (i = 0; i < net.n; ++i) { state.index = i; layer l = net.layers[i]; if (l.type == CONVOLUTIONAL) { int return_float = (net.layers[i + 1].activation == LINEAR); // if next layer has LINEAR activation if (i >= 1 && l.activation != LINEAR) forward_convolutional_layer_q_old(l, state, return_float); else forward_convolutional_layer_cpu(l, state); printf("\n %d - CONVOLUTIONAL \t\t l.size = %d \n", i, l.size); } else if (l.type == MAXPOOL) { forward_maxpool_layer_q(l, state); //printf("\n MAXPOOL \t\t l.size = %d \n", l.size); } else if (l.type == ROUTE) { forward_route_layer_q(l, state); //printf("\n ROUTE \t\t\t l.n = %d \n", l.n); } else if (l.type == REORG) { forward_reorg_layer_q(l, state); //printf("\n REORG \n"); } /* else if (l.type == UPSAMPLE) { forward_upsample_layer_cpu(l, state); //printf("\n UPSAMPLE \n"); } else if (l.type == SHORTCUT) { forward_shortcut_layer_cpu(l, state); //printf("\n SHORTCUT \n"); } else if (l.type == YOLO) { forward_yolo_layer_cpu(l, state); //printf("\n YOLO \n"); } */ else if (l.type == REGION) { forward_region_layer_q(l, state); //printf("\n REGION \n"); } else { printf("\n layer: %d \n", l.type); } state.input = l.output; state.input_int8 = l.output_int8; if (i == 0) { //draw_distribution(state.input, l.outputs, NULL); int k; for (k = 0; k < l.out_w * l.out_h * l.out_c; ++k) { int16_t src = state.input[k] * 3.88677;// *net.layers[2].input_quant_multipler; state.input_int8[k] = max_abs(src, I_MAX_VAL); //printf(" %d, ", src); } } } } // detect on CPU float *network_predict_quantized(network net, float *input) { network_state state; state.net = net; state.index = 0; state.input = input; //state.input_int8 = calloc(net.w*net.h*net.c, sizeof(int8_t)); state.truth = 0; state.train = 0; state.delta = 0; /*/ int k; for (k = 0; k < net.w*net.h*net.c; ++k) { //int16_t src = lround(state.input[k] * net.layers[0].input_quant_multipler); int16_t src = state.input[k] * net.layers[0].input_quant_multipler; state.input_int8[k] = max_abs(src, I_MAX_VAL); } */ yolov2_forward_network_q(net, state); // network on CPU //float *out = get_network_output(net); int i; for (i = net.n - 1; i > 0; --i) if (net.layers[i].type != COST) break; //free(state.input_int8); return net.layers[i].output; } // detect on CPU float *network_predict_quantized_old(network net, float *input) { network_state state; state.net = net; state.index = 0; state.input = input; state.input_int8 = calloc(net.w * net.h * net.c, sizeof(int8_t)); state.truth = 0; state.train = 0; state.delta = 0; int k; for (k = 0; k < net.w * net.h * net.c; ++k) { //int16_t src = lround(state.input[k] * net.layers[0].input_quant_multipler); int16_t src = state.input[k] * net.layers[0].input_quant_multipler; state.input_int8[k] = max_abs(src, I_MAX_VAL); } yolov2_forward_network_q_old(net, state); // network on CPU //float *out = get_network_output(net); int i; for (i = net.n - 1; i > 0; --i) if (net.layers[i].type != COST) break; free(state.input_int8); return net.layers[i].output; } // -------------------- // x - last conv-layer output // biases - anchors from cfg-file // n - number of anchors from cfg-file box get_region_box_q(float *x, float *biases, int n, int index, int i, int j, int w, int h) { box b; b.x = (i + logistic_activate(x[index + 0])) / w; // (col + 1./(1. + exp(-x))) / width_last_layer b.y = (j + logistic_activate(x[index + 1])) / h; // (row + 1./(1. + exp(-x))) / height_last_layer b.w = expf(x[index + 2]) * biases[2 * n] / w; // exp(x) * anchor_w / width_last_layer b.h = expf(x[index + 3]) * biases[2 * n + 1] / h; // exp(x) * anchor_h / height_last_layer return b; } // get prediction boxes void get_region_boxes_q(layer l, int w, int h, float thresh, float **probs, box *boxes, int only_objectness, int *map) { int i, j, n; float *predictions = l.output; // grid index for (i = 0; i < l.w * l.h; ++i) { int row = i / l.w; int col = i % l.w; // anchor index for (n = 0; n < l.n; ++n) { int index = i * l.n + n; // index for each grid-cell & anchor int p_index = index * (l.classes + 5) + 4; float scale = predictions[p_index]; // scale = t0 = Probability * IoU(box, object) if (l.classfix == -1 && scale < .5) scale = 0; // if(t0 < 0.5) t0 = 0; int box_index = index * (l.classes + 5); boxes[index] = get_region_box_q(predictions, l.biases, n, box_index, col, row, l.w, l.h); boxes[index].x *= w; boxes[index].y *= h; boxes[index].w *= w; boxes[index].h *= h; int class_index = index * (l.classes + 5) + 5; // Yolo 9000 or Yolo v2 if (l.softmax_tree) { // Yolo 9000 hierarchy_predictions(predictions + class_index, l.classes, l.softmax_tree, 0); int found = 0; if (map) { for (j = 0; j < 200; ++j) { float prob = scale * predictions[class_index + map[j]]; probs[index][j] = (prob > thresh) ? prob : 0; } } else { for (j = l.classes - 1; j >= 0; --j) { if (!found && predictions[class_index + j] > .5) { found = 1; } else { predictions[class_index + j] = 0; } float prob = predictions[class_index + j]; probs[index][j] = (scale > thresh) ? prob : 0; } } } else { // Yolo v2 for (j = 0; j < l.classes; ++j) { float prob = scale * predictions[class_index + j]; // prob = IoU(box, object) = t0 * class-probability probs[index][j] = (prob > thresh) ? prob : 0; // if (IoU < threshold) IoU = 0; } } if (only_objectness) { probs[index][0] = scale; } } } } float entropy_calibration(float *src_arr, const size_t size, const float bin_width, const int max_bin) { //const float bin_width = 1.0 / 4096;// 1.0F / 64.0F; //const int max_bin = 2048*2;// 2048; const int max_global_val = max_bin * bin_width; // 1024 // 32 float *m_array = (float *) calloc(max_bin, sizeof(float)); float *H_histogram = (float *) calloc(max_bin, sizeof(float)); float *P_array = (float *) calloc(max_bin, sizeof(float)); float *Q_array = (float *) calloc(max_bin, sizeof(float)); float *quant_Q_array = (float *) calloc(128, sizeof(float)); // 128 for INT8 uint64_t *quant_Q_array_count = (uint64_t *) calloc(128, sizeof(uint64_t)); // 128 for INT8 int i, j; { //uint64_t outliers = 0; const int last_bin = max_bin - 1; for (j = 0; j <= last_bin; ++j) P_array[j] = 0; for (j = 0; j < size; ++j) { int bin_num = lround(fabs(src_arr[j]) / bin_width); int bin_num_saturated = (bin_num >= last_bin) ? last_bin : bin_num; H_histogram[bin_num_saturated]++; //if (bin_num > last_bin) outliers++; //else H_histogram[bin_num]++; } } for (i = 128; i < max_bin; ++i) { // [1/64; 1024] // [1/64; 32] //if (i > max_bin) printf(" i > max_bin = %d, ", i); //printf(" %d \r", i); // calculate bin histogram uint64_t outliers = 0; const int last_bin = i - 1; for (j = 0; j <= last_bin; ++j) P_array[j] = 0; /*for (j = 0; j < size; ++j) { int bin_num = lround(fabs(src_arr[j]) / bin_width); //int bin_num_saturated = (bin_num >= last_bin) ? last_bin : bin_num; if (bin_num > last_bin) outliers++; else P_array[bin_num]++; }*/ for (j = 0; j < max_bin; ++j) { if (j <= last_bin) P_array[j] = H_histogram[j]; else outliers += H_histogram[j]; } // quantinization P-i-bins to Q-128-bins const float quant_expand_width = i / 128.0F; for (j = 0; j < 128; ++j) quant_Q_array[j] = 0, quant_Q_array_count[j] = 0; for (j = 0; j < i; ++j) { int quant_bin = lround(j / quant_expand_width); if (quant_bin > 127) quant_bin = 127; // printf(" quant_bin > 127 = %d \n", quant_bin); quant_Q_array[quant_bin] += P_array[j]; if (P_array[j] != 0) quant_Q_array_count[quant_bin]++; } // expand 128-bins to i-bins for (j = 0; j < i; ++j) Q_array[j] = 0; for (j = 0; j < i; ++j) { int quant_bin = lround(j / quant_expand_width); if (quant_bin > 127) quant_bin = 127;// printf(" quant_bin > 127 = %d \n", quant_bin); //Q_array[j] = llround(quant_Q_array[quant_bin] / quant_expand_width); if (P_array[j] != 0) // preserve empty bins from original P Q_array[j] = quant_Q_array[quant_bin] / quant_Q_array_count[quant_bin]; //printf(" quant_bin = %d, Q[j] = %f = q_Q %f / q_w %f, P = %f \n", quant_bin, Q_array[j], quant_Q_array[quant_bin], quant_expand_width, P_array[j]); } P_array[last_bin] += outliers; // saturation // P /= SUM(P); Q /= SUM(Q); float sum_P = 0, sum_Q = 0, quant_sum_Q = 0; for (j = 0; j < 128; ++j) quant_sum_Q += quant_Q_array[j]; for (j = 0; j < i; ++j) { sum_P += P_array[j]; sum_Q += Q_array[j]; //printf(" P_array = %f, Q_array = %f \n", P_array[j], Q_array[j]); } for (j = 0; j < i; ++j) { P_array[j] /= sum_P; Q_array[j] /= sum_Q; } // KL_divergence(P, Q); for (j = 0; j < i; ++j) { m_array[i] += P_array[j] * (log((P_array[j] + FLT_MIN) / (Q_array[j] + FLT_MIN))); //printf(" p = %f, q = %f, p/q = %f, log(p/q) = %f, m = %f \n", P_array[j], Q_array[j], P_array[j] / Q_array[j], log((P_array[j] + FLT_MIN) / (Q_array[j] + FLT_MIN)), m_array[i]); } //printf("\n i = %d, size = %zu, sum_P = %f, sum_Q = %f, q_sum_Q = %f, q_e_width = %f, m = %f \n", i, size, sum_P, sum_Q, quant_sum_Q, quant_expand_width, m_array[i]); //getchar(); } float m_index = 128, min_m = FLT_MAX; for (i = 128; i < max_bin; ++i) { if (m_array[i] < min_m) { min_m = m_array[i]; m_index = i; } } float threshold = (m_index + 0.5) * bin_width; float multiplier = 127 / threshold; printf(" mult = %g, threshold = %g, min_m = %g, m_index = %g \n", multiplier, threshold, min_m, m_index); free(H_histogram); free(P_array); free(Q_array); free(quant_Q_array); free(quant_Q_array_count); free(m_array); //getchar(); return multiplier; } // Quantinization and get multiplers for convolutional weights for quantinization void quantinization_and_get_multipliers(network net) { // ----------- entropy_calibration(,, 1.0 / 16, 4096); - FULL ---------------------- //float input_mult[] = { 256, 4,32,64,32,32,32,32,32,64,64,64,64,64,128,64,128,128,64,128,64,128,128 }; // divided 4 - full works int counter = 0; //const int input_mult_size = sizeof(input_mult) / sizeof(float); int j; for (j = 0; j < net.n; ++j) { layer *l = &net.layers[j]; if (l->type == CONVOLUTIONAL) { size_t const weights_size = l->size * l->size * l->c * l->n; size_t const filter_size = l->size * l->size * l->c; int i, k, fil; // get optimal multipliers - for Weights //float *weights_multiplier = (float *)calloc(l->n, sizeof(float)); //l->output_multipler = (float *)calloc(l->n, sizeof(float)); //float weights_multiplier_single = entropy_calibration(l->weights, weights_size, 1.0 / (2048), (2048)); //float weights_multiplier_single = entropy_calibration(l->weights, weights_size, 1.0 / 4096, 4096) / 2; //if (j == 0) weights_multiplier_single = entropy_calibration(l->weights, weights_size, 1.0 / 2, 2048); float old_weight_mult = get_multiplier(l->weights, weights_size, 8) / 4; // good [2 - 8], best 4 float weights_multiplier_single = old_weight_mult; //float old_weight_mult = get_multiplier(l->weights, weights_size, 7) / 4; printf(" old_weight_mult = %f, weights_multiplier_single = %f \n\n", old_weight_mult, weights_multiplier_single); //weights_multiplier_single = old_weight_mult; l->weights_quant_multipler = weights_multiplier_single; for (fil = 0; fil < l->n; ++fil) { for (i = 0; i < filter_size; ++i) { float w = l->weights[fil * filter_size + i] * l->weights_quant_multipler;// [fil]; l->weights_int8[fil * filter_size + i] = max_abs(w, W_MAX_VAL); //l->weights_int8[fil*filter_size + i] = max_abs(lround(w), W_MAX_VAL); } } if (counter >= net.input_calibration_size) { printf("\n Warning: input_calibration= in the cfg-file has less values %d than convolutional layers %d \n", net.input_calibration_size, counter); } //l->input_quant_multipler = 40;//(counter < net.input_calibration_size) ? net.input_calibration[counter] : 16; // best 40 l->input_quant_multipler = (counter < net.input_calibration_size) ? net.input_calibration[counter] : 40; ++counter; //float current_input_mult = 40;//(counter < net.input_calibration_size) ? net.input_calibration[counter] : 16; float current_input_mult = (counter < net.input_calibration_size) ? net.input_calibration[counter] : 40; for (fil = 0; fil < l->n; ++fil) { if (counter == 1) l->output_multipler = current_input_mult / (l->weights_quant_multipler * l->input_quant_multipler / R_MULT); if (counter == 2) l->output_multipler = current_input_mult / (l->weights_quant_multipler * l->input_quant_multipler / R_MULT); else if (counter >= 2) l->output_multipler = current_input_mult / (l->weights_quant_multipler * l->input_quant_multipler / R_MULT); } // quantinization Biases for (fil = 0; fil < l->n; ++fil) { // calculate optimal multipliers - for Biases float biases_multipler = (l->output_multipler * l->weights_quant_multipler * l->input_quant_multipler / R_MULT); l->biases_quant[fil] = l->biases[fil] * biases_multipler; } printf(" Multiplers: weights %g, input %g, output %g \n", l->weights_quant_multipler, l->input_quant_multipler, l->output_multipler); } else { printf(" Skip layer: %d \n", l->type); } } #ifdef GPU // init weights and cuDNN for quantized IINT8x4 init_gpu_int8x4(net); #endif //GPU }

effect.c

/* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % EEEEE FFFFF FFFFF EEEEE CCCC TTTTT % % E F F E C T % % EEE FFF FFF EEE C T % % E F F E C T % % EEEEE F F EEEEE CCCC T % % % % % % MagickCore Image Effects Methods % % % % Software Design % % Cristy % % October 1996 % % % % % % Copyright 1999-2019 ImageMagick Studio LLC, a non-profit organization % % dedicated to making software imaging solutions freely available. % % % % You may not use this file except in compliance with the License. You may % % obtain a copy of the License at % % % % https://imagemagick.org/script/license.php % % % % Unless required by applicable law or agreed to in writing, software % % distributed under the License is distributed on an "AS IS" BASIS, % % WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. % % See the License for the specific language governing permissions and % % limitations under the License. % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % */ /* Include declarations. */ #include "magick/studio.h" #include "magick/accelerate-private.h" #include "magick/blob.h" #include "magick/cache-view.h" #include "magick/color.h" #include "magick/color-private.h" #include "magick/colorspace.h" #include "magick/constitute.h" #include "magick/decorate.h" #include "magick/distort.h" #include "magick/draw.h" #include "magick/enhance.h" #include "magick/exception.h" #include "magick/exception-private.h" #include "magick/effect.h" #include "magick/fx.h" #include "magick/gem.h" #include "magick/geometry.h" #include "magick/image-private.h" #include "magick/list.h" #include "magick/log.h" #include "magick/matrix.h" #include "magick/memory_.h" #include "magick/memory-private.h" #include "magick/monitor.h" #include "magick/monitor-private.h" #include "magick/montage.h" #include "magick/morphology.h" #include "magick/morphology-private.h" #include "magick/opencl-private.h" #include "magick/paint.h" #include "magick/pixel-accessor.h" #include "magick/pixel-private.h" #include "magick/property.h" #include "magick/quantize.h" #include "magick/quantum.h" #include "magick/random_.h" #include "magick/random-private.h" #include "magick/resample.h" #include "magick/resample-private.h" #include "magick/resize.h" #include "magick/resource_.h" #include "magick/segment.h" #include "magick/shear.h" #include "magick/signature-private.h" #include "magick/statistic.h" #include "magick/string_.h" #include "magick/thread-private.h" #include "magick/transform.h" #include "magick/threshold.h" #ifdef MAGICKCORE_CLPERFMARKER #include "CLPerfMarker.h" #endif /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % A d a p t i v e B l u r I m a g e % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % AdaptiveBlurImage() adaptively blurs the image by blurring less % intensely near image edges and more intensely far from edges. We blur the % image with a Gaussian operator of the given radius and standard deviation % (sigma). For reasonable results, radius should be larger than sigma. Use a % radius of 0 and AdaptiveBlurImage() selects a suitable radius for you. % % The format of the AdaptiveBlurImage method is: % % Image *AdaptiveBlurImage(const Image *image,const double radius, % const double sigma,ExceptionInfo *exception) % Image *AdaptiveBlurImageChannel(const Image *image, % const ChannelType channel,double radius,const double sigma, % ExceptionInfo *exception) % % A description of each parameter follows: % % o image: the image. % % o channel: the channel type. % % o radius: the radius of the Gaussian, in pixels, not counting the center % pixel. % % o sigma: the standard deviation of the Laplacian, in pixels. % % o exception: return any errors or warnings in this structure. % */ MagickExport Image *AdaptiveBlurImage(const Image *image,const double radius, const double sigma,ExceptionInfo *exception) { Image *blur_image; blur_image=AdaptiveBlurImageChannel(image,DefaultChannels,radius,sigma, exception); return(blur_image); } MagickExport Image *AdaptiveBlurImageChannel(const Image *image, const ChannelType channel,const double radius,const double sigma, ExceptionInfo *exception) { #define AdaptiveBlurImageTag "Convolve/Image" #define MagickSigma (fabs(sigma) < MagickEpsilon ? MagickEpsilon : sigma) CacheView *blur_view, *edge_view, *image_view; double **kernel, normalize; Image *blur_image, *edge_image, *gaussian_image; MagickBooleanType status; MagickOffsetType progress; MagickPixelPacket bias; register ssize_t i; size_t width; ssize_t j, k, u, v, y; assert(image != (const Image *) NULL); assert(image->signature == MagickCoreSignature); if (image->debug != MagickFalse) (void) LogMagickEvent(TraceEvent,GetMagickModule(),"%s",image->filename); assert(exception != (ExceptionInfo *) NULL); assert(exception->signature == MagickCoreSignature); blur_image=CloneImage(image,0,0,MagickTrue,exception); if (blur_image == (Image *) NULL) return((Image *) NULL); if (fabs(sigma) <= MagickEpsilon) return(blur_image); if (SetImageStorageClass(blur_image,DirectClass) == MagickFalse) { InheritException(exception,&blur_image->exception); blur_image=DestroyImage(blur_image); return((Image *) NULL); } /* Edge detect the image brighness channel, level, blur, and level again. */ edge_image=EdgeImage(image,radius,exception); if (edge_image == (Image *) NULL) { blur_image=DestroyImage(blur_image); return((Image *) NULL); } (void) AutoLevelImage(edge_image); gaussian_image=BlurImage(edge_image,radius,sigma,exception); if (gaussian_image != (Image *) NULL) { edge_image=DestroyImage(edge_image); edge_image=gaussian_image; } (void) AutoLevelImage(edge_image); /* Create a set of kernels from maximum (radius,sigma) to minimum. */ width=GetOptimalKernelWidth2D(radius,sigma); kernel=(double **) MagickAssumeAligned(AcquireAlignedMemory((size_t) width, sizeof(*kernel))); if (kernel == (double **) NULL) { edge_image=DestroyImage(edge_image); blur_image=DestroyImage(blur_image); ThrowImageException(ResourceLimitError,"MemoryAllocationFailed"); } (void) memset(kernel,0,(size_t) width*sizeof(*kernel)); for (i=0; i < (ssize_t) width; i+=2) { kernel[i]=(double *) MagickAssumeAligned(AcquireAlignedMemory((size_t) (width-i),(width-i)*sizeof(**kernel))); if (kernel[i] == (double *) NULL) break; normalize=0.0; j=(ssize_t) (width-i-1)/2; k=0; for (v=(-j); v <= j; v++) { for (u=(-j); u <= j; u++) { kernel[i][k]=(double) (exp(-((double) u*u+v*v)/(2.0*MagickSigma* MagickSigma))/(2.0*MagickPI*MagickSigma*MagickSigma)); normalize+=kernel[i][k]; k++; } } kernel[i][(k-1)/2]+=(1.0-normalize); if (sigma < MagickEpsilon) kernel[i][(k-1)/2]=1.0; } if (i < (ssize_t) width) { for (i-=2; i >= 0; i-=2) kernel[i]=(double *) RelinquishAlignedMemory(kernel[i]); kernel=(double **) RelinquishAlignedMemory(kernel); edge_image=DestroyImage(edge_image); blur_image=DestroyImage(blur_image); ThrowImageException(ResourceLimitError,"MemoryAllocationFailed"); } /* Adaptively blur image. */ status=MagickTrue; progress=0; GetMagickPixelPacket(image,&bias); SetMagickPixelPacketBias(image,&bias); image_view=AcquireVirtualCacheView(image,exception); edge_view=AcquireVirtualCacheView(edge_image,exception); blur_view=AcquireAuthenticCacheView(blur_image,exception); #if defined(MAGICKCORE_OPENMP_SUPPORT) #pragma omp parallel for schedule(static) shared(progress,status) \ magick_number_threads(image,blur_image,blur_image->rows,1) #endif for (y=0; y < (ssize_t) blur_image->rows; y++) { register const IndexPacket *magick_restrict indexes; register const PixelPacket *magick_restrict p, *magick_restrict r; register IndexPacket *magick_restrict blur_indexes; register PixelPacket *magick_restrict q; register ssize_t x; if (status == MagickFalse) continue; r=GetCacheViewVirtualPixels(edge_view,0,y,edge_image->columns,1,exception); q=QueueCacheViewAuthenticPixels(blur_view,0,y,blur_image->columns,1, exception); if ((r == (const PixelPacket *) NULL) || (q == (PixelPacket *) NULL)) { status=MagickFalse; continue; } blur_indexes=GetCacheViewAuthenticIndexQueue(blur_view); for (x=0; x < (ssize_t) blur_image->columns; x++) { double alpha, gamma; DoublePixelPacket pixel; register const double *magick_restrict k; register ssize_t i, u, v; gamma=0.0; i=(ssize_t) ceil((double) width*QuantumScale* GetPixelIntensity(edge_image,r)-0.5); if (i < 0) i=0; else if (i > (ssize_t) width) i=(ssize_t) width; if ((i & 0x01) != 0) i--; p=GetCacheViewVirtualPixels(image_view,x-((ssize_t) (width-i)/2L),y- (ssize_t) ((width-i)/2L),width-i,width-i,exception); if (p == (const PixelPacket *) NULL) break; indexes=GetCacheViewVirtualIndexQueue(image_view); pixel.red=bias.red; pixel.green=bias.green; pixel.blue=bias.blue; pixel.opacity=bias.opacity; pixel.index=bias.index; k=kernel[i]; for (v=0; v < (ssize_t) (width-i); v++) { for (u=0; u < (ssize_t) (width-i); u++) { alpha=1.0; if (((channel & OpacityChannel) != 0) && (image->matte != MagickFalse)) alpha=(MagickRealType) (QuantumScale*GetPixelAlpha(p)); if ((channel & RedChannel) != 0) pixel.red+=(*k)*alpha*GetPixelRed(p); if ((channel & GreenChannel) != 0) pixel.green+=(*k)*alpha*GetPixelGreen(p); if ((channel & BlueChannel) != 0) pixel.blue+=(*k)*alpha*GetPixelBlue(p); if ((channel & OpacityChannel) != 0) pixel.opacity+=(*k)*GetPixelOpacity(p); if (((channel & IndexChannel) != 0) && (image->colorspace == CMYKColorspace)) pixel.index+=(*k)*alpha*GetPixelIndex(indexes+x+(width-i)*v+u); gamma+=(*k)*alpha; k++; p++; } } gamma=PerceptibleReciprocal(gamma); if ((channel & RedChannel) != 0) SetPixelRed(q,ClampToQuantum(gamma*pixel.red)); if ((channel & GreenChannel) != 0) SetPixelGreen(q,ClampToQuantum(gamma*pixel.green)); if ((channel & BlueChannel) != 0) SetPixelBlue(q,ClampToQuantum(gamma*pixel.blue)); if ((channel & OpacityChannel) != 0) SetPixelOpacity(q,ClampToQuantum(pixel.opacity)); if (((channel & IndexChannel) != 0) && (image->colorspace == CMYKColorspace)) SetPixelIndex(blur_indexes+x,ClampToQuantum(gamma*pixel.index)); q++; r++; } if (SyncCacheViewAuthenticPixels(blur_view,exception) == MagickFalse) status=MagickFalse; if (image->progress_monitor != (MagickProgressMonitor) NULL) { MagickBooleanType proceed; #if defined(MAGICKCORE_OPENMP_SUPPORT) #pragma omp atomic #endif progress++; proceed=SetImageProgress(image,AdaptiveBlurImageTag,progress, image->rows); if (proceed == MagickFalse) status=MagickFalse; } } blur_image->type=image->type; blur_view=DestroyCacheView(blur_view); edge_view=DestroyCacheView(edge_view); image_view=DestroyCacheView(image_view); edge_image=DestroyImage(edge_image); for (i=0; i < (ssize_t) width; i+=2) kernel[i]=(double *) RelinquishAlignedMemory(kernel[i]); kernel=(double **) RelinquishAlignedMemory(kernel); if (status == MagickFalse) blur_image=DestroyImage(blur_image); return(blur_image); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % A d a p t i v e S h a r p e n I m a g e % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % AdaptiveSharpenImage() adaptively sharpens the image by sharpening more % intensely near image edges and less intensely far from edges. We sharpen the % image with a Gaussian operator of the given radius and standard deviation % (sigma). For reasonable results, radius should be larger than sigma. Use a % radius of 0 and AdaptiveSharpenImage() selects a suitable radius for you. % % The format of the AdaptiveSharpenImage method is: % % Image *AdaptiveSharpenImage(const Image *image,const double radius, % const double sigma,ExceptionInfo *exception) % Image *AdaptiveSharpenImageChannel(const Image *image, % const ChannelType channel,double radius,const double sigma, % ExceptionInfo *exception) % % A description of each parameter follows: % % o image: the image. % % o channel: the channel type. % % o radius: the radius of the Gaussian, in pixels, not counting the center % pixel. % % o sigma: the standard deviation of the Laplacian, in pixels. % % o exception: return any errors or warnings in this structure. % */ MagickExport Image *AdaptiveSharpenImage(const Image *image,const double radius, const double sigma,ExceptionInfo *exception) { Image *sharp_image; sharp_image=AdaptiveSharpenImageChannel(image,DefaultChannels,radius,sigma, exception); return(sharp_image); } MagickExport Image *AdaptiveSharpenImageChannel(const Image *image, const ChannelType channel,const double radius,const double sigma, ExceptionInfo *exception) { #define AdaptiveSharpenImageTag "Convolve/Image" #define MagickSigma (fabs(sigma) < MagickEpsilon ? MagickEpsilon : sigma) CacheView *sharp_view, *edge_view, *image_view; double **kernel, normalize; Image *sharp_image, *edge_image, *gaussian_image; MagickBooleanType status; MagickOffsetType progress; MagickPixelPacket bias; register ssize_t i; size_t width; ssize_t j, k, u, v, y; assert(image != (const Image *) NULL); assert(image->signature == MagickCoreSignature); if (image->debug != MagickFalse) (void) LogMagickEvent(TraceEvent,GetMagickModule(),"%s",image->filename); assert(exception != (ExceptionInfo *) NULL); assert(exception->signature == MagickCoreSignature); sharp_image=CloneImage(image,0,0,MagickTrue,exception); if (sharp_image == (Image *) NULL) return((Image *) NULL); if (fabs(sigma) <= MagickEpsilon) return(sharp_image); if (SetImageStorageClass(sharp_image,DirectClass) == MagickFalse) { InheritException(exception,&sharp_image->exception); sharp_image=DestroyImage(sharp_image); return((Image *) NULL); } /* Edge detect the image brighness channel, level, sharp, and level again. */ edge_image=EdgeImage(image,radius,exception); if (edge_image == (Image *) NULL) { sharp_image=DestroyImage(sharp_image); return((Image *) NULL); } (void) AutoLevelImage(edge_image); gaussian_image=BlurImage(edge_image,radius,sigma,exception); if (gaussian_image != (Image *) NULL) { edge_image=DestroyImage(edge_image); edge_image=gaussian_image; } (void) AutoLevelImage(edge_image); /* Create a set of kernels from maximum (radius,sigma) to minimum. */ width=GetOptimalKernelWidth2D(radius,sigma); kernel=(double **) MagickAssumeAligned(AcquireAlignedMemory((size_t) width, sizeof(*kernel))); if (kernel == (double **) NULL) { edge_image=DestroyImage(edge_image); sharp_image=DestroyImage(sharp_image); ThrowImageException(ResourceLimitError,"MemoryAllocationFailed"); } (void) memset(kernel,0,(size_t) width*sizeof(*kernel)); for (i=0; i < (ssize_t) width; i+=2) { kernel[i]=(double *) MagickAssumeAligned(AcquireAlignedMemory((size_t) (width-i),(width-i)*sizeof(**kernel))); if (kernel[i] == (double *) NULL) break; normalize=0.0; j=(ssize_t) (width-i-1)/2; k=0; for (v=(-j); v <= j; v++) { for (u=(-j); u <= j; u++) { kernel[i][k]=(double) (-exp(-((double) u*u+v*v)/(2.0*MagickSigma* MagickSigma))/(2.0*MagickPI*MagickSigma*MagickSigma)); normalize+=kernel[i][k]; k++; } } kernel[i][(k-1)/2]=(double) ((-2.0)*normalize); if (sigma < MagickEpsilon) kernel[i][(k-1)/2]=1.0; } if (i < (ssize_t) width) { for (i-=2; i >= 0; i-=2) kernel[i]=(double *) RelinquishAlignedMemory(kernel[i]); kernel=(double **) RelinquishAlignedMemory(kernel); edge_image=DestroyImage(edge_image); sharp_image=DestroyImage(sharp_image); ThrowImageException(ResourceLimitError,"MemoryAllocationFailed"); } /* Adaptively sharpen image. */ status=MagickTrue; progress=0; GetMagickPixelPacket(image,&bias); SetMagickPixelPacketBias(image,&bias); image_view=AcquireVirtualCacheView(image,exception); edge_view=AcquireVirtualCacheView(edge_image,exception); sharp_view=AcquireAuthenticCacheView(sharp_image,exception); #if defined(MAGICKCORE_OPENMP_SUPPORT) #pragma omp parallel for schedule(static) shared(progress,status) \ magick_number_threads(image,sharp_image,sharp_image->rows,1) #endif for (y=0; y < (ssize_t) sharp_image->rows; y++) { register const IndexPacket *magick_restrict indexes; register const PixelPacket *magick_restrict p, *magick_restrict r; register IndexPacket *magick_restrict sharp_indexes; register PixelPacket *magick_restrict q; register ssize_t x; if (status == MagickFalse) continue; r=GetCacheViewVirtualPixels(edge_view,0,y,edge_image->columns,1,exception); q=QueueCacheViewAuthenticPixels(sharp_view,0,y,sharp_image->columns,1, exception); if ((r == (const PixelPacket *) NULL) || (q == (PixelPacket *) NULL)) { status=MagickFalse; continue; } sharp_indexes=GetCacheViewAuthenticIndexQueue(sharp_view); for (x=0; x < (ssize_t) sharp_image->columns; x++) { double alpha, gamma; DoublePixelPacket pixel; register const double *magick_restrict k; register ssize_t i, u, v; gamma=0.0; i=(ssize_t) ceil((double) width*(1.0-QuantumScale* GetPixelIntensity(edge_image,r))-0.5); if (i < 0) i=0; else if (i > (ssize_t) width) i=(ssize_t) width; if ((i & 0x01) != 0) i--; p=GetCacheViewVirtualPixels(image_view,x-((ssize_t) (width-i)/2L),y- (ssize_t) ((width-i)/2L),width-i,width-i,exception); if (p == (const PixelPacket *) NULL) break; indexes=GetCacheViewVirtualIndexQueue(image_view); k=kernel[i]; pixel.red=bias.red; pixel.green=bias.green; pixel.blue=bias.blue; pixel.opacity=bias.opacity; pixel.index=bias.index; for (v=0; v < (ssize_t) (width-i); v++) { for (u=0; u < (ssize_t) (width-i); u++) { alpha=1.0; if (((channel & OpacityChannel) != 0) && (image->matte != MagickFalse)) alpha=(MagickRealType) (QuantumScale*GetPixelAlpha(p)); if ((channel & RedChannel) != 0) pixel.red+=(*k)*alpha*GetPixelRed(p); if ((channel & GreenChannel) != 0) pixel.green+=(*k)*alpha*GetPixelGreen(p); if ((channel & BlueChannel) != 0) pixel.blue+=(*k)*alpha*GetPixelBlue(p); if ((channel & OpacityChannel) != 0) pixel.opacity+=(*k)*GetPixelOpacity(p); if (((channel & IndexChannel) != 0) && (image->colorspace == CMYKColorspace)) pixel.index+=(*k)*alpha*GetPixelIndex(indexes+x+(width-i)*v+u); gamma+=(*k)*alpha; k++; p++; } } gamma=PerceptibleReciprocal(gamma); if ((channel & RedChannel) != 0) SetPixelRed(q,ClampToQuantum(gamma*pixel.red)); if ((channel & GreenChannel) != 0) SetPixelGreen(q,ClampToQuantum(gamma*pixel.green)); if ((channel & BlueChannel) != 0) SetPixelBlue(q,ClampToQuantum(gamma*pixel.blue)); if ((channel & OpacityChannel) != 0) SetPixelOpacity(q,ClampToQuantum(pixel.opacity)); if (((channel & IndexChannel) != 0) && (image->colorspace == CMYKColorspace)) SetPixelIndex(sharp_indexes+x,ClampToQuantum(gamma*pixel.index)); q++; r++; } if (SyncCacheViewAuthenticPixels(sharp_view,exception) == MagickFalse) status=MagickFalse; if (image->progress_monitor != (MagickProgressMonitor) NULL) { MagickBooleanType proceed; #if defined(MAGICKCORE_OPENMP_SUPPORT) #pragma omp atomic #endif progress++; proceed=SetImageProgress(image,AdaptiveSharpenImageTag,progress, image->rows); if (proceed == MagickFalse) status=MagickFalse; } } sharp_image->type=image->type; sharp_view=DestroyCacheView(sharp_view); edge_view=DestroyCacheView(edge_view); image_view=DestroyCacheView(image_view); edge_image=DestroyImage(edge_image); for (i=0; i < (ssize_t) width; i+=2) kernel[i]=(double *) RelinquishAlignedMemory(kernel[i]); kernel=(double **) RelinquishAlignedMemory(kernel); if (status == MagickFalse) sharp_image=DestroyImage(sharp_image); return(sharp_image); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % B l u r I m a g e % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % BlurImage() blurs an image. We convolve the image with a Gaussian operator % of the given radius and standard deviation (sigma). For reasonable results, % the radius should be larger than sigma. Use a radius of 0 and BlurImage() % selects a suitable radius for you. % % The format of the BlurImage method is: % % Image *BlurImage(const Image *image,const double radius, % const double sigma,ExceptionInfo *exception) % Image *BlurImageChannel(const Image *image,const ChannelType channel, % const double radius,const double sigma,ExceptionInfo *exception) % % A description of each parameter follows: % % o image: the image. % % o channel: the channel type. % % o radius: the radius of the Gaussian, in pixels, not counting the center % pixel. % % o sigma: the standard deviation of the Gaussian, in pixels. % % o exception: return any errors or warnings in this structure. % */ MagickExport Image *BlurImage(const Image *image,const double radius, const double sigma,ExceptionInfo *exception) { Image *blur_image; blur_image=BlurImageChannel(image,DefaultChannels,radius,sigma,exception); return(blur_image); } MagickExport Image *BlurImageChannel(const Image *image, const ChannelType channel,const double radius,const double sigma, ExceptionInfo *exception) { char geometry[MaxTextExtent]; KernelInfo *kernel_info; Image *blur_image = NULL; assert(image != (const Image *) NULL); assert(image->signature == MagickCoreSignature); if (image->debug != MagickFalse) (void) LogMagickEvent(TraceEvent,GetMagickModule(),"%s",image->filename); assert(exception != (ExceptionInfo *) NULL); assert(exception->signature == MagickCoreSignature); #if defined(MAGICKCORE_OPENCL_SUPPORT) blur_image=AccelerateBlurImage(image,channel,radius,sigma,exception); if (blur_image != (Image *) NULL) return(blur_image); #endif (void) FormatLocaleString(geometry,MaxTextExtent, "blur:%.20gx%.20g;blur:%.20gx%.20g+90",radius,sigma,radius,sigma); kernel_info=AcquireKernelInfo(geometry); if (kernel_info == (KernelInfo *) NULL) ThrowImageException(ResourceLimitError,"MemoryAllocationFailed"); blur_image=MorphologyImageChannel(image,channel,ConvolveMorphology,1, kernel_info,exception); kernel_info=DestroyKernelInfo(kernel_info); return(blur_image); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % C o n v o l v e I m a g e % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % ConvolveImage() applies a custom convolution kernel to the image. % % The format of the ConvolveImage method is: % % Image *ConvolveImage(const Image *image,const size_t order, % const double *kernel,ExceptionInfo *exception) % Image *ConvolveImageChannel(const Image *image,const ChannelType channel, % const size_t order,const double *kernel,ExceptionInfo *exception) % % A description of each parameter follows: % % o image: the image. % % o channel: the channel type. % % o order: the number of columns and rows in the filter kernel. % % o kernel: An array of double representing the convolution kernel. % % o exception: return any errors or warnings in this structure. % */ MagickExport Image *ConvolveImage(const Image *image,const size_t order, const double *kernel,ExceptionInfo *exception) { Image *convolve_image; #ifdef MAGICKCORE_CLPERFMARKER clBeginPerfMarkerAMD(__FUNCTION__,""); #endif convolve_image=ConvolveImageChannel(image,DefaultChannels,order,kernel, exception); #ifdef MAGICKCORE_CLPERFMARKER clEndPerfMarkerAMD(); #endif return(convolve_image); } MagickExport Image *ConvolveImageChannel(const Image *image, const ChannelType channel,const size_t order,const double *kernel, ExceptionInfo *exception) { Image *convolve_image; KernelInfo *kernel_info; register ssize_t i; kernel_info=AcquireKernelInfo((const char *) NULL); if (kernel_info == (KernelInfo *) NULL) ThrowImageException(ResourceLimitError,"MemoryAllocationFailed"); kernel_info->width=order; kernel_info->height=order; kernel_info->x=(ssize_t) (order-1)/2; kernel_info->y=(ssize_t) (order-1)/2; kernel_info->signature=MagickCoreSignature; kernel_info->values=(double *) MagickAssumeAligned(AcquireAlignedMemory( kernel_info->width,kernel_info->width*sizeof(*kernel_info->values))); if (kernel_info->values == (double *) NULL) { kernel_info=DestroyKernelInfo(kernel_info); ThrowImageException(ResourceLimitError,"MemoryAllocationFailed"); } for (i=0; i < (ssize_t) (order*order); i++) kernel_info->values[i]=kernel[i]; convolve_image=(Image *) NULL; #if defined(MAGICKCORE_OPENCL_SUPPORT) convolve_image=AccelerateConvolveImageChannel(image,channel,kernel_info, exception); #endif if (convolve_image == (Image *) NULL) convolve_image=MorphologyImageChannel(image,channel,ConvolveMorphology,1, kernel_info,exception); kernel_info=DestroyKernelInfo(kernel_info); return(convolve_image); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % D e s p e c k l e I m a g e % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % DespeckleImage() reduces the speckle noise in an image while perserving the % edges of the original image. A speckle removing filter uses a complementary % hulling technique (raising pixels that are darker than their surrounding % neighbors, then complementarily lowering pixels that are brighter than their % surrounding neighbors) to reduce the speckle index of that image (reference % Crimmins speckle removal). % % The format of the DespeckleImage method is: % % Image *DespeckleImage(const Image *image,ExceptionInfo *exception) % % A description of each parameter follows: % % o image: the image. % % o exception: return any errors or warnings in this structure. % */ static void Hull(const Image *image,const ssize_t x_offset, const ssize_t y_offset,const size_t columns,const size_t rows, const int polarity,Quantum *magick_restrict f,Quantum *magick_restrict g) { register Quantum *p, *q, *r, *s; ssize_t y; assert(f != (Quantum *) NULL); assert(g != (Quantum *) NULL); p=f+(columns+2); q=g+(columns+2); r=p+(y_offset*(columns+2)+x_offset); #if defined(MAGICKCORE_OPENMP_SUPPORT) #pragma omp parallel for schedule(static) \ magick_number_threads(image,image,rows,1) #endif for (y=0; y < (ssize_t) rows; y++) { register ssize_t i, x; SignedQuantum v; i=(2*y+1)+y*columns; if (polarity > 0) for (x=0; x < (ssize_t) columns; x++) { v=(SignedQuantum) p[i]; if ((SignedQuantum) r[i] >= (v+ScaleCharToQuantum(2))) v+=ScaleCharToQuantum(1); q[i]=(Quantum) v; i++; } else for (x=0; x < (ssize_t) columns; x++) { v=(SignedQuantum) p[i]; if ((SignedQuantum) r[i] <= (v-ScaleCharToQuantum(2))) v-=ScaleCharToQuantum(1); q[i]=(Quantum) v; i++; } } p=f+(columns+2); q=g+(columns+2); r=q+(y_offset*(columns+2)+x_offset); s=q-(y_offset*(columns+2)+x_offset); #if defined(MAGICKCORE_OPENMP_SUPPORT) #pragma omp parallel for schedule(static) \ magick_number_threads(image,image,rows,1) #endif for (y=0; y < (ssize_t) rows; y++) { register ssize_t i, x; SignedQuantum v; i=(2*y+1)+y*columns; if (polarity > 0) for (x=0; x < (ssize_t) columns; x++) { v=(SignedQuantum) q[i]; if (((SignedQuantum) s[i] >= (v+ScaleCharToQuantum(2))) && ((SignedQuantum) r[i] > v)) v+=ScaleCharToQuantum(1); p[i]=(Quantum) v; i++; } else for (x=0; x < (ssize_t) columns; x++) { v=(SignedQuantum) q[i]; if (((SignedQuantum) s[i] <= (v-ScaleCharToQuantum(2))) && ((SignedQuantum) r[i] < v)) v-=ScaleCharToQuantum(1); p[i]=(Quantum) v; i++; } } } MagickExport Image *DespeckleImage(const Image *image,ExceptionInfo *exception) { #define DespeckleImageTag "Despeckle/Image" CacheView *despeckle_view, *image_view; Image *despeckle_image; MagickBooleanType status; MemoryInfo *buffer_info, *pixel_info; register ssize_t i; Quantum *magick_restrict buffer, *magick_restrict pixels; size_t length, number_channels; static const ssize_t X[4] = {0, 1, 1,-1}, Y[4] = {1, 0, 1, 1}; /* Allocate despeckled image. */ assert(image != (const Image *) NULL); assert(image->signature == MagickCoreSignature); if (image->debug != MagickFalse) (void) LogMagickEvent(TraceEvent,GetMagickModule(),"%s",image->filename); assert(exception != (ExceptionInfo *) NULL); assert(exception->signature == MagickCoreSignature); #if defined(MAGICKCORE_OPENCL_SUPPORT) despeckle_image=AccelerateDespeckleImage(image, exception); if (despeckle_image != (Image *) NULL) return(despeckle_image); #endif despeckle_image=CloneImage(image,0,0,MagickTrue,exception); if (despeckle_image == (Image *) NULL) return((Image *) NULL); if (SetImageStorageClass(despeckle_image,DirectClass) == MagickFalse) { InheritException(exception,&despeckle_image->exception); despeckle_image=DestroyImage(despeckle_image); return((Image *) NULL); } /* Allocate image buffer. */ length=(size_t) ((image->columns+2)*(image->rows+2)); pixel_info=AcquireVirtualMemory(length,sizeof(*pixels)); buffer_info=AcquireVirtualMemory(length,sizeof(*buffer)); if ((pixel_info == (MemoryInfo *) NULL) || (buffer_info == (MemoryInfo *) NULL)) { if (buffer_info != (MemoryInfo *) NULL) buffer_info=RelinquishVirtualMemory(buffer_info); if (pixel_info != (MemoryInfo *) NULL) pixel_info=RelinquishVirtualMemory(pixel_info); despeckle_image=DestroyImage(despeckle_image); ThrowImageException(ResourceLimitError,"MemoryAllocationFailed"); } pixels=(Quantum *) GetVirtualMemoryBlob(pixel_info); buffer=(Quantum *) GetVirtualMemoryBlob(buffer_info); /* Reduce speckle in the image. */ status=MagickTrue; number_channels=(size_t) (image->colorspace == CMYKColorspace ? 5 : 4); image_view=AcquireVirtualCacheView(image,exception); despeckle_view=AcquireAuthenticCacheView(despeckle_image,exception); for (i=0; i < (ssize_t) number_channels; i++) { register ssize_t k, x; ssize_t j, y; if (status == MagickFalse) continue; if ((image->matte == MagickFalse) && (i == 3)) continue; (void) memset(pixels,0,length*sizeof(*pixels)); j=(ssize_t) image->columns+2; for (y=0; y < (ssize_t) image->rows; y++) { register const IndexPacket *magick_restrict indexes; register const PixelPacket *magick_restrict p; p=GetCacheViewVirtualPixels(image_view,0,y,image->columns,1,exception); if (p == (const PixelPacket *) NULL) break; indexes=GetCacheViewVirtualIndexQueue(image_view); j++; for (x=0; x < (ssize_t) image->columns; x++) { switch (i) { case 0: pixels[j]=GetPixelRed(p); break; case 1: pixels[j]=GetPixelGreen(p); break; case 2: pixels[j]=GetPixelBlue(p); break; case 3: pixels[j]=GetPixelOpacity(p); break; case 4: pixels[j]=GetPixelBlack(indexes+x); break; default: break; } p++; j++; } j++; } (void) memset(buffer,0,length*sizeof(*buffer)); for (k=0; k < 4; k++) { Hull(image,X[k],Y[k],image->columns,image->rows,1,pixels,buffer); Hull(image,-X[k],-Y[k],image->columns,image->rows,1,pixels,buffer); Hull(image,-X[k],-Y[k],image->columns,image->rows,-1,pixels,buffer); Hull(image,X[k],Y[k],image->columns,image->rows,-1,pixels,buffer); } j=(ssize_t) image->columns+2; for (y=0; y < (ssize_t) image->rows; y++) { MagickBooleanType sync; register IndexPacket *magick_restrict indexes; register PixelPacket *magick_restrict q; q=GetCacheViewAuthenticPixels(despeckle_view,0,y,despeckle_image->columns, 1,exception); if (q == (PixelPacket *) NULL) break; indexes=GetCacheViewAuthenticIndexQueue(despeckle_view); j++; for (x=0; x < (ssize_t) image->columns; x++) { switch (i) { case 0: SetPixelRed(q,pixels[j]); break; case 1: SetPixelGreen(q,pixels[j]); break; case 2: SetPixelBlue(q,pixels[j]); break; case 3: SetPixelOpacity(q,pixels[j]); break; case 4: SetPixelIndex(indexes+x,pixels[j]); break; default: break; } q++; j++; } sync=SyncCacheViewAuthenticPixels(despeckle_view,exception); if (sync == MagickFalse) { status=MagickFalse; break; } j++; } if (image->progress_monitor != (MagickProgressMonitor) NULL) { MagickBooleanType proceed; proceed=SetImageProgress(image,DespeckleImageTag,(MagickOffsetType) i, number_channels); if (proceed == MagickFalse) status=MagickFalse; } } despeckle_view=DestroyCacheView(despeckle_view); image_view=DestroyCacheView(image_view); buffer_info=RelinquishVirtualMemory(buffer_info); pixel_info=RelinquishVirtualMemory(pixel_info); despeckle_image->type=image->type; if (status == MagickFalse) despeckle_image=DestroyImage(despeckle_image); return(despeckle_image); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % E d g e I m a g e % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % EdgeImage() finds edges in an image. Radius defines the radius of the % convolution filter. Use a radius of 0 and EdgeImage() selects a suitable % radius for you. % % The format of the EdgeImage method is: % % Image *EdgeImage(const Image *image,const double radius, % ExceptionInfo *exception) % % A description of each parameter follows: % % o image: the image. % % o radius: the radius of the pixel neighborhood. % % o exception: return any errors or warnings in this structure. % */ MagickExport Image *EdgeImage(const Image *image,const double radius, ExceptionInfo *exception) { Image *edge_image; KernelInfo *kernel_info; register ssize_t i; size_t width; assert(image != (const Image *) NULL); assert(image->signature == MagickCoreSignature); if (image->debug != MagickFalse) (void) LogMagickEvent(TraceEvent,GetMagickModule(),"%s",image->filename); assert(exception != (ExceptionInfo *) NULL); assert(exception->signature == MagickCoreSignature); width=GetOptimalKernelWidth1D(radius,0.5); kernel_info=AcquireKernelInfo((const char *) NULL); if (kernel_info == (KernelInfo *) NULL) ThrowImageException(ResourceLimitError,"MemoryAllocationFailed"); (void) memset(kernel_info,0,sizeof(*kernel_info)); kernel_info->width=width; kernel_info->height=width; kernel_info->x=(ssize_t) (kernel_info->width-1)/2; kernel_info->y=(ssize_t) (kernel_info->height-1)/2; kernel_info->signature=MagickCoreSignature; kernel_info->values=(double *) MagickAssumeAligned(AcquireAlignedMemory( kernel_info->width,kernel_info->height*sizeof(*kernel_info->values))); if (kernel_info->values == (double *) NULL) { kernel_info=DestroyKernelInfo(kernel_info); ThrowImageException(ResourceLimitError,"MemoryAllocationFailed"); } for (i=0; i < (ssize_t) (kernel_info->width*kernel_info->height); i++) kernel_info->values[i]=(-1.0); kernel_info->values[i/2]=(double) kernel_info->width*kernel_info->height-1.0; edge_image=(Image *) NULL; #if defined(MAGICKCORE_OPENCL_SUPPORT) edge_image=AccelerateConvolveImageChannel(image,DefaultChannels,kernel_info, exception); #endif if (edge_image == (Image *) NULL) edge_image=MorphologyImageChannel(image,DefaultChannels,ConvolveMorphology, 1,kernel_info,exception); kernel_info=DestroyKernelInfo(kernel_info); return(edge_image); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % E m b o s s I m a g e % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % EmbossImage() returns a grayscale image with a three-dimensional effect. % We convolve the image with a Gaussian operator of the given radius and % standard deviation (sigma). For reasonable results, radius should be % larger than sigma. Use a radius of 0 and Emboss() selects a suitable % radius for you. % % The format of the EmbossImage method is: % % Image *EmbossImage(const Image *image,const double radius, % const double sigma,ExceptionInfo *exception) % % A description of each parameter follows: % % o image: the image. % % o radius: the radius of the pixel neighborhood. % % o sigma: the standard deviation of the Gaussian, in pixels. % % o exception: return any errors or warnings in this structure. % */ MagickExport Image *EmbossImage(const Image *image,const double radius, const double sigma,ExceptionInfo *exception) { double gamma, normalize; Image *emboss_image; KernelInfo *kernel_info; register ssize_t i; size_t width; ssize_t j, k, u, v; assert(image != (const Image *) NULL); assert(image->signature == MagickCoreSignature); if (image->debug != MagickFalse) (void) LogMagickEvent(TraceEvent,GetMagickModule(),"%s",image->filename); assert(exception != (ExceptionInfo *) NULL); assert(exception->signature == MagickCoreSignature); width=GetOptimalKernelWidth1D(radius,sigma); kernel_info=AcquireKernelInfo((const char *) NULL); if (kernel_info == (KernelInfo *) NULL) ThrowImageException(ResourceLimitError,"MemoryAllocationFailed"); kernel_info->width=width; kernel_info->height=width; kernel_info->x=(ssize_t) (width-1)/2; kernel_info->y=(ssize_t) (width-1)/2; kernel_info->values=(double *) MagickAssumeAligned(AcquireAlignedMemory( kernel_info->width,kernel_info->width*sizeof(*kernel_info->values))); if (kernel_info->values == (double *) NULL) { kernel_info=DestroyKernelInfo(kernel_info); ThrowImageException(ResourceLimitError,"MemoryAllocationFailed"); } j=(ssize_t) (kernel_info->width-1)/2; k=j; i=0; for (v=(-j); v <= j; v++) { for (u=(-j); u <= j; u++) { kernel_info->values[i]=(double) (((u < 0) || (v < 0) ? -8.0 : 8.0)*exp(-((double) u*u+v*v)/(2.0*MagickSigma*MagickSigma))/ (2.0*MagickPI*MagickSigma*MagickSigma)); if (u != k) kernel_info->values[i]=0.0; i++; } k--; } normalize=0.0; for (i=0; i < (ssize_t) (kernel_info->width*kernel_info->height); i++) normalize+=kernel_info->values[i]; gamma=PerceptibleReciprocal(normalize); for (i=0; i < (ssize_t) (kernel_info->width*kernel_info->height); i++) kernel_info->values[i]*=gamma; emboss_image=(Image *) NULL; #if defined(MAGICKCORE_OPENCL_SUPPORT) emboss_image=AccelerateConvolveImageChannel(image,DefaultChannels,kernel_info, exception); #endif if (emboss_image == (Image *) NULL) emboss_image=MorphologyImageChannel(image,DefaultChannels, ConvolveMorphology,1,kernel_info,exception); kernel_info=DestroyKernelInfo(kernel_info); if (emboss_image != (Image *) NULL) (void) EqualizeImageChannel(emboss_image,(ChannelType) (AllChannels &~ SyncChannels)); return(emboss_image); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % F i l t e r I m a g e % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % FilterImage() applies a custom convolution kernel to the image. % % The format of the FilterImage method is: % % Image *FilterImage(const Image *image,const KernelInfo *kernel, % ExceptionInfo *exception) % Image *FilterImageChannel(const Image *image,const ChannelType channel, % const KernelInfo *kernel,ExceptionInfo *exception) % % A description of each parameter follows: % % o image: the image. % % o channel: the channel type. % % o kernel: the filtering kernel. % % o exception: return any errors or warnings in this structure. % */ MagickExport Image *FilterImage(const Image *image,const KernelInfo *kernel, ExceptionInfo *exception) { Image *filter_image; filter_image=FilterImageChannel(image,DefaultChannels,kernel,exception); return(filter_image); } MagickExport Image *FilterImageChannel(const Image *image, const ChannelType channel,const KernelInfo *kernel,ExceptionInfo *exception) { #define FilterImageTag "Filter/Image" CacheView *filter_view, *image_view; Image *filter_image; MagickBooleanType status; MagickOffsetType progress; MagickPixelPacket bias; MagickRealType *filter_kernel; register ssize_t i; ssize_t y; #ifdef MAGICKCORE_CLPERFMARKER clBeginPerfMarkerAMD(__FUNCTION__,""); #endif /* Initialize filter image attributes. */ assert(image != (Image *) NULL); assert(image->signature == MagickCoreSignature); if (image->debug != MagickFalse) (void) LogMagickEvent(TraceEvent,GetMagickModule(),"%s",image->filename); assert(exception != (ExceptionInfo *) NULL); assert(exception->signature == MagickCoreSignature); if ((kernel->width % 2) == 0) ThrowImageException(OptionError,"KernelWidthMustBeAnOddNumber"); if (image->debug != MagickFalse) { char format[MaxTextExtent], *message; register const double *k; ssize_t u, v; (void) LogMagickEvent(TransformEvent,GetMagickModule(), " FilterImage with %.20gx%.20g kernel:",(double) kernel->width,(double) kernel->height); message=AcquireString(""); k=kernel->values; for (v=0; v < (ssize_t) kernel->height; v++) { *message='\0'; (void) FormatLocaleString(format,MaxTextExtent,"%.20g: ",(double) v); (void) ConcatenateString(&message,format); for (u=0; u < (ssize_t) kernel->width; u++) { (void) FormatLocaleString(format,MaxTextExtent,"%g ",*k++); (void) ConcatenateString(&message,format); } (void) LogMagickEvent(TransformEvent,GetMagickModule(),"%s",message); } message=DestroyString(message); } #if defined(MAGICKCORE_OPENCL_SUPPORT) filter_image=AccelerateConvolveImageChannel(image,channel,kernel,exception); if (filter_image != (Image *) NULL) { #ifdef MAGICKCORE_CLPERFMARKER clEndPerfMarkerAMD(); #endif return(filter_image); } #endif filter_image=CloneImage(image,0,0,MagickTrue,exception); if (filter_image == (Image *) NULL) return((Image *) NULL); if (SetImageStorageClass(filter_image,DirectClass) == MagickFalse) { InheritException(exception,&filter_image->exception); filter_image=DestroyImage(filter_image); return((Image *) NULL); } /* Normalize kernel. */ filter_kernel=(MagickRealType *) MagickAssumeAligned(AcquireAlignedMemory( kernel->width,kernel->height*sizeof(*filter_kernel))); if (filter_kernel == (MagickRealType *) NULL) { filter_image=DestroyImage(filter_image); ThrowImageException(ResourceLimitError,"MemoryAllocationFailed"); } for (i=0; i < (ssize_t) (kernel->width*kernel->height); i++) filter_kernel[i]=(MagickRealType) kernel->values[i]; /* Filter image. */ status=MagickTrue; progress=0; GetMagickPixelPacket(image,&bias); SetMagickPixelPacketBias(image,&bias); image_view=AcquireVirtualCacheView(image,exception); filter_view=AcquireAuthenticCacheView(filter_image,exception); #if defined(MAGICKCORE_OPENMP_SUPPORT) #pragma omp parallel for schedule(static) shared(progress,status) \ magick_number_threads(image,filter_image,image->rows,1) #endif for (y=0; y < (ssize_t) image->rows; y++) { MagickBooleanType sync; register const IndexPacket *magick_restrict indexes; register const PixelPacket *magick_restrict p; register IndexPacket *magick_restrict filter_indexes; register PixelPacket *magick_restrict q; register ssize_t x; if (status == MagickFalse) continue; p=GetCacheViewVirtualPixels(image_view,-((ssize_t) (kernel->width-1)/2L),y- (ssize_t) ((kernel->height-1)/2L),image->columns+kernel->width, kernel->height,exception); q=GetCacheViewAuthenticPixels(filter_view,0,y,filter_image->columns,1, exception); if ((p == (const PixelPacket *) NULL) || (q == (PixelPacket *) NULL)) { status=MagickFalse; continue; } indexes=GetCacheViewVirtualIndexQueue(image_view); filter_indexes=GetCacheViewAuthenticIndexQueue(filter_view); for (x=0; x < (ssize_t) image->columns; x++) { DoublePixelPacket pixel; register const MagickRealType *magick_restrict k; register const PixelPacket *magick_restrict kernel_pixels; register ssize_t u; ssize_t v; pixel.red=bias.red; pixel.green=bias.green; pixel.blue=bias.blue; pixel.opacity=bias.opacity; pixel.index=bias.index; k=filter_kernel; kernel_pixels=p; if (((channel & OpacityChannel) == 0) || (image->matte == MagickFalse)) { for (v=0; v < (ssize_t) kernel->width; v++) { for (u=0; u < (ssize_t) kernel->height; u++) { pixel.red+=(*k)*kernel_pixels[u].red; pixel.green+=(*k)*kernel_pixels[u].green; pixel.blue+=(*k)*kernel_pixels[u].blue; k++; } kernel_pixels+=image->columns+kernel->width; } if ((channel & RedChannel) != 0) SetPixelRed(q,ClampToQuantum(pixel.red)); if ((channel & GreenChannel) != 0) SetPixelGreen(q,ClampToQuantum(pixel.green)); if ((channel & BlueChannel) != 0) SetPixelBlue(q,ClampToQuantum(pixel.blue)); if ((channel & OpacityChannel) != 0) { k=filter_kernel; kernel_pixels=p; for (v=0; v < (ssize_t) kernel->width; v++) { for (u=0; u < (ssize_t) kernel->height; u++) { pixel.opacity+=(*k)*kernel_pixels[u].opacity; k++; } kernel_pixels+=image->columns+kernel->width; } SetPixelOpacity(q,ClampToQuantum(pixel.opacity)); } if (((channel & IndexChannel) != 0) && (image->colorspace == CMYKColorspace)) { register const IndexPacket *magick_restrict kernel_indexes; k=filter_kernel; kernel_indexes=indexes; for (v=0; v < (ssize_t) kernel->width; v++) { for (u=0; u < (ssize_t) kernel->height; u++) { pixel.index+=(*k)*GetPixelIndex(kernel_indexes+u); k++; } kernel_indexes+=image->columns+kernel->width; } SetPixelIndex(filter_indexes+x,ClampToQuantum(pixel.index)); } } else { double alpha, gamma; gamma=0.0; for (v=0; v < (ssize_t) kernel->width; v++) { for (u=0; u < (ssize_t) kernel->height; u++) { alpha=(MagickRealType) (QuantumScale*(QuantumRange- GetPixelOpacity(kernel_pixels+u))); pixel.red+=(*k)*alpha*GetPixelRed(kernel_pixels+u); pixel.green+=(*k)*alpha*GetPixelGreen(kernel_pixels+u); pixel.blue+=(*k)*alpha*GetPixelBlue(kernel_pixels+u); gamma+=(*k)*alpha; k++; } kernel_pixels+=image->columns+kernel->width; } gamma=PerceptibleReciprocal(gamma); if ((channel & RedChannel) != 0) SetPixelRed(q,ClampToQuantum(gamma*pixel.red)); if ((channel & GreenChannel) != 0) SetPixelGreen(q,ClampToQuantum(gamma*pixel.green)); if ((channel & BlueChannel) != 0) SetPixelBlue(q,ClampToQuantum(gamma*pixel.blue)); if ((channel & OpacityChannel) != 0) { k=filter_kernel; kernel_pixels=p; for (v=0; v < (ssize_t) kernel->width; v++) { for (u=0; u < (ssize_t) kernel->height; u++) { pixel.opacity+=(*k)*GetPixelOpacity(kernel_pixels+u); k++; } kernel_pixels+=image->columns+kernel->width; } SetPixelOpacity(q,ClampToQuantum(pixel.opacity)); } if (((channel & IndexChannel) != 0) && (image->colorspace == CMYKColorspace)) { register const IndexPacket *magick_restrict kernel_indexes; k=filter_kernel; kernel_pixels=p; kernel_indexes=indexes; for (v=0; v < (ssize_t) kernel->width; v++) { for (u=0; u < (ssize_t) kernel->height; u++) { alpha=(MagickRealType) (QuantumScale*(QuantumRange- kernel_pixels[u].opacity)); pixel.index+=(*k)*alpha*GetPixelIndex(kernel_indexes+u); k++; } kernel_pixels+=image->columns+kernel->width; kernel_indexes+=image->columns+kernel->width; } SetPixelIndex(filter_indexes+x,ClampToQuantum(gamma*pixel.index)); } } indexes++; p++; q++; } sync=SyncCacheViewAuthenticPixels(filter_view,exception); if (sync == MagickFalse) status=MagickFalse; if (image->progress_monitor != (MagickProgressMonitor) NULL) { MagickBooleanType proceed; #if defined(MAGICKCORE_OPENMP_SUPPORT) #pragma omp atomic #endif progress++; proceed=SetImageProgress(image,FilterImageTag,progress,image->rows); if (proceed == MagickFalse) status=MagickFalse; } } filter_image->type=image->type; filter_view=DestroyCacheView(filter_view); image_view=DestroyCacheView(image_view); filter_kernel=(MagickRealType *) RelinquishAlignedMemory(filter_kernel); if (status == MagickFalse) filter_image=DestroyImage(filter_image); #ifdef MAGICKCORE_CLPERFMARKER clEndPerfMarkerAMD(); #endif return(filter_image); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % G a u s s i a n B l u r I m a g e % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % GaussianBlurImage() blurs an image. We convolve the image with a % Gaussian operator of the given radius and standard deviation (sigma). % For reasonable results, the radius should be larger than sigma. Use a % radius of 0 and GaussianBlurImage() selects a suitable radius for you % % The format of the GaussianBlurImage method is: % % Image *GaussianBlurImage(const Image *image,onst double radius, % const double sigma,ExceptionInfo *exception) % Image *GaussianBlurImageChannel(const Image *image, % const ChannelType channel,const double radius,const double sigma, % ExceptionInfo *exception) % % A description of each parameter follows: % % o image: the image. % % o channel: the channel type. % % o radius: the radius of the Gaussian, in pixels, not counting the center % pixel. % % o sigma: the standard deviation of the Gaussian, in pixels. % % o exception: return any errors or warnings in this structure. % */ MagickExport Image *GaussianBlurImage(const Image *image,const double radius, const double sigma,ExceptionInfo *exception) { Image *blur_image; blur_image=GaussianBlurImageChannel(image,DefaultChannels,radius,sigma, exception); return(blur_image); } MagickExport Image *GaussianBlurImageChannel(const Image *image, const ChannelType channel,const double radius,const double sigma, ExceptionInfo *exception) { char geometry[MaxTextExtent]; KernelInfo *kernel_info; Image *blur_image; assert(image != (const Image *) NULL); assert(image->signature == MagickCoreSignature); if (image->debug != MagickFalse) (void) LogMagickEvent(TraceEvent,GetMagickModule(),"%s",image->filename); assert(exception != (ExceptionInfo *) NULL); assert(exception->signature == MagickCoreSignature); (void) FormatLocaleString(geometry,MaxTextExtent,"gaussian:%.20gx%.20g", radius,sigma); kernel_info=AcquireKernelInfo(geometry); if (kernel_info == (KernelInfo *) NULL) ThrowImageException(ResourceLimitError,"MemoryAllocationFailed"); blur_image=(Image *) NULL; #if defined(MAGICKCORE_OPENCL_SUPPORT) blur_image=AccelerateConvolveImageChannel(image,channel,kernel_info, exception); #endif if (blur_image == (Image *) NULL) blur_image=MorphologyImageChannel(image,channel,ConvolveMorphology,1, kernel_info,exception); kernel_info=DestroyKernelInfo(kernel_info); return(blur_image); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % M o t i o n B l u r I m a g e % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % MotionBlurImage() simulates motion blur. We convolve the image with a % Gaussian operator of the given radius and standard deviation (sigma). % For reasonable results, radius should be larger than sigma. Use a % radius of 0 and MotionBlurImage() selects a suitable radius for you. % Angle gives the angle of the blurring motion. % % Andrew Protano contributed this effect. % % The format of the MotionBlurImage method is: % % Image *MotionBlurImage(const Image *image,const double radius, % const double sigma,const double angle,ExceptionInfo *exception) % Image *MotionBlurImageChannel(const Image *image,const ChannelType channel, % const double radius,const double sigma,const double angle, % ExceptionInfo *exception) % % A description of each parameter follows: % % o image: the image. % % o channel: the channel type. % % o radius: the radius of the Gaussian, in pixels, not counting the center % pixel. % % o sigma: the standard deviation of the Gaussian, in pixels. % % o angle: Apply the effect along this angle. % % o exception: return any errors or warnings in this structure. % */ static double *GetMotionBlurKernel(const size_t width,const double sigma) { double *kernel, normalize; register ssize_t i; /* Generate a 1-D convolution kernel. */ (void) LogMagickEvent(TraceEvent,GetMagickModule(),"..."); kernel=(double *) MagickAssumeAligned(AcquireAlignedMemory((size_t) width, sizeof(*kernel))); if (kernel == (double *) NULL) return(kernel); normalize=0.0; for (i=0; i < (ssize_t) width; i++) { kernel[i]=(double) (exp((-((double) i*i)/(double) (2.0*MagickSigma* MagickSigma)))/(MagickSQ2PI*MagickSigma)); normalize+=kernel[i]; } for (i=0; i < (ssize_t) width; i++) kernel[i]/=normalize; return(kernel); } MagickExport Image *MotionBlurImage(const Image *image,const double radius, const double sigma,const double angle,ExceptionInfo *exception) { Image *motion_blur; motion_blur=MotionBlurImageChannel(image,DefaultChannels,radius,sigma,angle, exception); return(motion_blur); } MagickExport Image *MotionBlurImageChannel(const Image *image, const ChannelType channel,const double radius,const double sigma, const double angle,ExceptionInfo *exception) { #define BlurImageTag "Blur/Image" CacheView *blur_view, *image_view; double *kernel; Image *blur_image; MagickBooleanType status; MagickOffsetType progress; MagickPixelPacket bias; OffsetInfo *offset; PointInfo point; register ssize_t i; size_t width; ssize_t y; assert(image != (Image *) NULL); assert(image->signature == MagickCoreSignature); if (image->debug != MagickFalse) (void) LogMagickEvent(TraceEvent,GetMagickModule(),"%s",image->filename); assert(exception != (ExceptionInfo *) NULL); width=GetOptimalKernelWidth1D(radius,sigma); kernel=GetMotionBlurKernel(width,sigma); if (kernel == (double *) NULL) ThrowImageException(ResourceLimitError,"MemoryAllocationFailed"); offset=(OffsetInfo *) AcquireQuantumMemory(width,sizeof(*offset)); if (offset == (OffsetInfo *) NULL) { kernel=(double *) RelinquishAlignedMemory(kernel); ThrowImageException(ResourceLimitError,"MemoryAllocationFailed"); } point.x=(double) width*sin(DegreesToRadians(angle)); point.y=(double) width*cos(DegreesToRadians(angle)); for (i=0; i < (ssize_t) width; i++) { offset[i].x=(ssize_t) ceil((double) (i*point.y)/hypot(point.x,point.y)-0.5); offset[i].y=(ssize_t) ceil((double) (i*point.x)/hypot(point.x,point.y)-0.5); } /* Motion blur image. */ #if defined(MAGICKCORE_OPENCL_SUPPORT) blur_image=AccelerateMotionBlurImage(image,channel,kernel,width,offset, exception); if (blur_image != (Image *) NULL) return blur_image; #endif blur_image=CloneImage(image,0,0,MagickTrue,exception); if (blur_image == (Image *) NULL) { kernel=(double *) RelinquishAlignedMemory(kernel); offset=(OffsetInfo *) RelinquishMagickMemory(offset); return((Image *) NULL); } if (SetImageStorageClass(blur_image,DirectClass) == MagickFalse) { kernel=(double *) RelinquishAlignedMemory(kernel); offset=(OffsetInfo *) RelinquishMagickMemory(offset); InheritException(exception,&blur_image->exception); blur_image=DestroyImage(blur_image); return((Image *) NULL); } status=MagickTrue; progress=0; GetMagickPixelPacket(image,&bias); image_view=AcquireVirtualCacheView(image,exception); blur_view=AcquireAuthenticCacheView(blur_image,exception); #if defined(MAGICKCORE_OPENMP_SUPPORT) #pragma omp parallel for schedule(static) shared(progress,status) \ magick_number_threads(image,blur_image,image->rows,1) #endif for (y=0; y < (ssize_t) image->rows; y++) { register IndexPacket *magick_restrict blur_indexes; register PixelPacket *magick_restrict q; register ssize_t x; if (status == MagickFalse) continue; q=GetCacheViewAuthenticPixels(blur_view,0,y,blur_image->columns,1, exception); if (q == (PixelPacket *) NULL) { status=MagickFalse; continue; } blur_indexes=GetCacheViewAuthenticIndexQueue(blur_view); for (x=0; x < (ssize_t) image->columns; x++) { MagickPixelPacket qixel; PixelPacket pixel; register const IndexPacket *magick_restrict indexes; register double *magick_restrict k; register ssize_t i; k=kernel; qixel=bias; if (((channel & OpacityChannel) == 0) || (image->matte == MagickFalse)) { for (i=0; i < (ssize_t) width; i++) { (void) GetOneCacheViewVirtualPixel(image_view,x+offset[i].x,y+ offset[i].y,&pixel,exception); qixel.red+=(*k)*pixel.red; qixel.green+=(*k)*pixel.green; qixel.blue+=(*k)*pixel.blue; qixel.opacity+=(*k)*pixel.opacity; if (image->colorspace == CMYKColorspace) { indexes=GetCacheViewVirtualIndexQueue(image_view); qixel.index+=(*k)*(*indexes); } k++; } if ((channel & RedChannel) != 0) SetPixelRed(q,ClampToQuantum(qixel.red)); if ((channel & GreenChannel) != 0) SetPixelGreen(q,ClampToQuantum(qixel.green)); if ((channel & BlueChannel) != 0) SetPixelBlue(q,ClampToQuantum(qixel.blue)); if ((channel & OpacityChannel) != 0) SetPixelOpacity(q,ClampToQuantum(qixel.opacity)); if (((channel & IndexChannel) != 0) && (image->colorspace == CMYKColorspace)) SetPixelIndex(blur_indexes+x,ClampToQuantum(qixel.index)); } else { double alpha, gamma; alpha=0.0; gamma=0.0; for (i=0; i < (ssize_t) width; i++) { (void) GetOneCacheViewVirtualPixel(image_view,x+offset[i].x,y+ offset[i].y,&pixel,exception); alpha=(MagickRealType) (QuantumScale*GetPixelAlpha(&pixel)); qixel.red+=(*k)*alpha*pixel.red; qixel.green+=(*k)*alpha*pixel.green; qixel.blue+=(*k)*alpha*pixel.blue; qixel.opacity+=(*k)*pixel.opacity; if (image->colorspace == CMYKColorspace) { indexes=GetCacheViewVirtualIndexQueue(image_view); qixel.index+=(*k)*alpha*GetPixelIndex(indexes); } gamma+=(*k)*alpha; k++; } gamma=PerceptibleReciprocal(gamma); if ((channel & RedChannel) != 0) SetPixelRed(q,ClampToQuantum(gamma*qixel.red)); if ((channel & GreenChannel) != 0) SetPixelGreen(q,ClampToQuantum(gamma*qixel.green)); if ((channel & BlueChannel) != 0) SetPixelBlue(q,ClampToQuantum(gamma*qixel.blue)); if ((channel & OpacityChannel) != 0) SetPixelOpacity(q,ClampToQuantum(qixel.opacity)); if (((channel & IndexChannel) != 0) && (image->colorspace == CMYKColorspace)) SetPixelIndex(blur_indexes+x,ClampToQuantum(gamma*qixel.index)); } q++; } if (SyncCacheViewAuthenticPixels(blur_view,exception) == MagickFalse) status=MagickFalse; if (image->progress_monitor != (MagickProgressMonitor) NULL) { MagickBooleanType proceed; #if defined(MAGICKCORE_OPENMP_SUPPORT) #pragma omp atomic #endif progress++; proceed=SetImageProgress(image,BlurImageTag,progress,image->rows); if (proceed == MagickFalse) status=MagickFalse; } } blur_view=DestroyCacheView(blur_view); image_view=DestroyCacheView(image_view); kernel=(double *) RelinquishAlignedMemory(kernel); offset=(OffsetInfo *) RelinquishMagickMemory(offset); if (status == MagickFalse) blur_image=DestroyImage(blur_image); return(blur_image); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % K u w a h a r a I m a g e % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % KuwaharaImage() is an edge preserving noise reduction filter. % % The format of the KuwaharaImage method is: % % Image *KuwaharaImage(const Image *image,const double width, % const double sigma,ExceptionInfo *exception) % Image *KuwaharaImageChannel(const Image *image,const ChannelType channel, % const double width,const double sigma,ExceptionInfo *exception) % % A description of each parameter follows: % % o image: the image. % % o channel: the channel type. % % o radius: the square window radius. % % o sigma: the standard deviation of the Gaussian, in pixels. % % o exception: return any errors or warnings in this structure. % */ MagickExport Image *KuwaharaImage(const Image *image,const double radius, const double sigma,ExceptionInfo *exception) { Image *kuwahara_image; kuwahara_image=KuwaharaImageChannel(image,DefaultChannels,radius,sigma, exception); return(kuwahara_image); } MagickExport Image *KuwaharaImageChannel(const Image *image, const ChannelType channel,const double radius,const double sigma, ExceptionInfo *exception) { #define KuwaharaImageTag "Kiwahara/Image" CacheView *image_view, *kuwahara_view; Image *gaussian_image, *kuwahara_image; MagickBooleanType status; MagickOffsetType progress; size_t width; ssize_t y; /* Initialize Kuwahara image attributes. */ assert(image != (Image *) NULL); assert(image->signature == MagickCoreSignature); if (image->debug != MagickFalse) (void) LogMagickEvent(TraceEvent,GetMagickModule(),"%s",image->filename); assert(exception != (ExceptionInfo *) NULL); assert(exception->signature == MagickCoreSignature); (void) channel; width=(size_t) radius+1; gaussian_image=BlurImage(image,radius,sigma,exception); if (gaussian_image == (Image *) NULL) return((Image *) NULL); kuwahara_image=CloneImage(image,0,0,MagickTrue,exception); if (kuwahara_image == (Image *) NULL) { gaussian_image=DestroyImage(gaussian_image); return((Image *) NULL); } if (SetImageStorageClass(kuwahara_image,DirectClass) == MagickFalse) { InheritException(exception,&kuwahara_image->exception); gaussian_image=DestroyImage(gaussian_image); kuwahara_image=DestroyImage(kuwahara_image); return((Image *) NULL); } /* Edge preserving noise reduction filter. */ status=MagickTrue; progress=0; image_view=AcquireVirtualCacheView(gaussian_image,exception); kuwahara_view=AcquireAuthenticCacheView(kuwahara_image,exception); #if defined(MAGICKCORE_OPENMP_SUPPORT) #pragma omp parallel for schedule(static) shared(progress,status) \ magick_number_threads(image,kuwahara_image,kuwahara_image->rows,1) #endif for (y=0; y < (ssize_t) kuwahara_image->rows; y++) { register IndexPacket *magick_restrict kuwahara_indexes; register PixelPacket *magick_restrict q; register ssize_t x; if (status == MagickFalse) continue; q=QueueCacheViewAuthenticPixels(kuwahara_view,0,y,kuwahara_image->columns,1, exception); if (q == (PixelPacket *) NULL) { status=MagickFalse; continue; } kuwahara_indexes=GetCacheViewAuthenticIndexQueue(kuwahara_view); for (x=0; x < (ssize_t) kuwahara_image->columns; x++) { double min_variance; MagickPixelPacket pixel; RectangleInfo quadrant, target; register ssize_t i; min_variance=MagickMaximumValue; SetGeometry(gaussian_image,&target); quadrant.width=width; quadrant.height=width; for (i=0; i < 4; i++) { const PixelPacket *magick_restrict p; double variance; MagickPixelPacket mean; register const PixelPacket *magick_restrict k; register ssize_t n; quadrant.x=x; quadrant.y=y; switch (i) { case 0: { quadrant.x=x-(ssize_t) (width-1); quadrant.y=y-(ssize_t) (width-1); break; } case 1: { quadrant.y=y-(ssize_t) (width-1); break; } case 2: { quadrant.x=x-(ssize_t) (width-1); break; } default: break; } p=GetCacheViewVirtualPixels(image_view,quadrant.x,quadrant.y, quadrant.width,quadrant.height,exception); if (p == (const PixelPacket *) NULL) break; GetMagickPixelPacket(image,&mean); k=p; for (n=0; n < (ssize_t) (width*width); n++) { mean.red+=(double) k->red; mean.green+=(double) k->green; mean.blue+=(double) k->blue; k++; } mean.red/=(double) (width*width); mean.green/=(double) (width*width); mean.blue/=(double) (width*width); k=p; variance=0.0; for (n=0; n < (ssize_t) (width*width); n++) { double luma; luma=GetPixelLuma(image,k); variance+=(luma-MagickPixelLuma(&mean))*(luma-MagickPixelLuma(&mean)); k++; } if (variance < min_variance) { min_variance=variance; target=quadrant; } } if (i < 4) { status=MagickFalse; break; } status=InterpolateMagickPixelPacket(gaussian_image,image_view, UndefinedInterpolatePixel,(double) target.x+target.width/2.0, (double) target.y+target.height/2.0,&pixel,exception); if (status == MagickFalse) break; SetPixelPacket(kuwahara_image,&pixel,q,kuwahara_indexes+x); q++; } if (SyncCacheViewAuthenticPixels(kuwahara_view,exception) == MagickFalse) status=MagickFalse; if (image->progress_monitor != (MagickProgressMonitor) NULL) { MagickBooleanType proceed; #if defined(MAGICKCORE_OPENMP_SUPPORT) #pragma omp atomic #endif progress++; proceed=SetImageProgress(image,KuwaharaImageTag,progress,image->rows); if (proceed == MagickFalse) status=MagickFalse; } } kuwahara_view=DestroyCacheView(kuwahara_view); image_view=DestroyCacheView(image_view); gaussian_image=DestroyImage(gaussian_image); if (status == MagickFalse) kuwahara_image=DestroyImage(kuwahara_image); return(kuwahara_image); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % L o c a l C o n t r a s t I m a g e % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % LocalContrastImage() attempts to increase the appearance of large-scale % light-dark transitions. Local contrast enhancement works similarly to % sharpening with an unsharp mask, however the mask is instead created using % an image with a greater blur distance. % % The format of the LocalContrastImage method is: % % Image *LocalContrastImage(const Image *image, const double radius, % const double strength, ExceptionInfo *exception) % % A description of each parameter follows: % % o image: the image. % % o radius: the radius of the Gaussian blur, in percentage with 100% % resulting in a blur radius of 20% of largest dimension. % % o strength: the strength of the blur mask in percentage. % % o exception: return any errors or warnings in this structure. % */ MagickExport Image *LocalContrastImage(const Image *image,const double radius, const double strength,ExceptionInfo *exception) { #define LocalContrastImageTag "LocalContrast/Image" CacheView *image_view, *contrast_view; float *interImage, *scanLinePixels, totalWeight; Image *contrast_image; MagickBooleanType status; MemoryInfo *scanLinePixels_info, *interImage_info; ssize_t scanLineSize, width; /* Initialize contrast image attributes. */ assert(image != (const Image *) NULL); assert(image->signature == MagickCoreSignature); if (image->debug != MagickFalse) (void) LogMagickEvent(TraceEvent,GetMagickModule(),"%s",image->filename); assert(exception != (ExceptionInfo *) NULL); assert(exception->signature == MagickCoreSignature); #if defined(MAGICKCORE_OPENCL_SUPPORT) contrast_image=AccelerateLocalContrastImage(image,radius,strength,exception); if (contrast_image != (Image *) NULL) return(contrast_image); #endif contrast_image=CloneImage(image,0,0,MagickTrue,exception); if (contrast_image == (Image *) NULL) return((Image *) NULL); if (SetImageStorageClass(contrast_image,DirectClass) == MagickFalse) { InheritException(exception,&contrast_image->exception); contrast_image=DestroyImage(contrast_image); return((Image *) NULL); } image_view=AcquireVirtualCacheView(image,exception); contrast_view=AcquireAuthenticCacheView(contrast_image,exception); scanLineSize=(ssize_t) MagickMax(image->columns,image->rows); width=(ssize_t) scanLineSize*0.002f*fabs(radius); scanLineSize+=(2*width); scanLinePixels_info=AcquireVirtualMemory(GetOpenMPMaximumThreads()* scanLineSize,sizeof(*scanLinePixels)); if (scanLinePixels_info == (MemoryInfo *) NULL) { contrast_view=DestroyCacheView(contrast_view); image_view=DestroyCacheView(image_view); contrast_image=DestroyImage(contrast_image); ThrowImageException(ResourceLimitError,"MemoryAllocationFailed"); } scanLinePixels=(float *) GetVirtualMemoryBlob(scanLinePixels_info); /* Create intermediate buffer. */ interImage_info=AcquireVirtualMemory(image->rows*(image->columns+(2*width)), sizeof(*interImage)); if (interImage_info == (MemoryInfo *) NULL) { scanLinePixels_info=RelinquishVirtualMemory(scanLinePixels_info); contrast_view=DestroyCacheView(contrast_view); image_view=DestroyCacheView(image_view); contrast_image=DestroyImage(contrast_image); ThrowImageException(ResourceLimitError,"MemoryAllocationFailed"); } interImage=(float *) GetVirtualMemoryBlob(interImage_info); totalWeight=(width+1)*(width+1); /* Vertical pass. */ status=MagickTrue; { ssize_t x; #if defined(MAGICKCORE_OPENMP_SUPPORT) #pragma omp parallel for schedule(static) \ magick_number_threads(image,image,image->columns,1) #endif for (x=0; x < (ssize_t) image->columns; x++) { const int id = GetOpenMPThreadId(); const PixelPacket *magick_restrict p; float *out, *pix, *pixels; register ssize_t y; ssize_t i; if (status == MagickFalse) continue; pixels=scanLinePixels; pixels+=id*scanLineSize; pix=pixels; p=GetCacheViewVirtualPixels(image_view,x,-width,1,image->rows+(2*width), exception); if (p == (const PixelPacket *) NULL) { status=MagickFalse; continue; } for (y=0; y < (ssize_t) image->rows+(2*width); y++) { *pix++=(float)GetPixelLuma(image,p); p++; } out=interImage+x+width; for (y=0; y < (ssize_t) image->rows; y++) { float sum, weight; weight=1.0f; sum=0; pix=pixels+y; for (i=0; i < width; i++) { sum+=weight*(*pix++); weight+=1.0f; } for (i=width+1; i < (2*width); i++) { sum+=weight*(*pix++); weight-=1.0f; } /* write to output */ *out=sum/totalWeight; /* mirror into padding */ if (x <= width && x != 0) *(out-(x*2))=*out; if ((x > (ssize_t) image->columns-width-2) && (x != (ssize_t) image->columns-1)) *(out+((image->columns-x-1)*2))=*out; out+=image->columns+(width*2); } } } /* Horizontal pass. */ { ssize_t y; #if defined(MAGICKCORE_OPENMP_SUPPORT) #pragma omp parallel for schedule(static) \ magick_number_threads(image,image,image->rows,1) #endif for (y=0; y < (ssize_t) image->rows; y++) { const int id = GetOpenMPThreadId(); const PixelPacket *magick_restrict p; float *pix, *pixels; register PixelPacket *magick_restrict q; register ssize_t x; ssize_t i; if (status == MagickFalse) continue; pixels=scanLinePixels; pixels+=id*scanLineSize; p=GetCacheViewVirtualPixels(image_view,0,y,image->columns,1, exception); q=GetCacheViewAuthenticPixels(contrast_view,0,y,image->columns,1, exception); if ((p == (const PixelPacket *) NULL) || (q == (PixelPacket *) NULL)) { status=MagickFalse; continue; } memcpy(pixels,interImage+(y*(image->columns+(2*width))),(image->columns+ (2*width))*sizeof(float)); for (x=0; x < (ssize_t) image->columns; x++) { float mult, srcVal, sum, weight; weight=1.0f; sum=0; pix=pixels+x; for (i=0; i < width; i++) { sum+=weight*(*pix++); weight+=1.0f; } for (i=width+1; i < (2*width); i++) { sum+=weight*(*pix++); weight-=1.0f; } /* Apply and write */ srcVal=(float) GetPixelLuma(image,p); mult=(srcVal-(sum/totalWeight))*(strength/100.0f); mult=(srcVal+mult)/srcVal; SetPixelRed(q,ClampToQuantum(GetPixelRed(p)*mult)); SetPixelGreen(q,ClampToQuantum(GetPixelGreen(p)*mult)); SetPixelBlue(q,ClampToQuantum(GetPixelBlue(p)*mult)); p++; q++; } if (SyncCacheViewAuthenticPixels(contrast_view,exception) == MagickFalse) status=MagickFalse; } } scanLinePixels_info=RelinquishVirtualMemory(scanLinePixels_info); interImage_info=RelinquishVirtualMemory(interImage_info); contrast_view=DestroyCacheView(contrast_view); image_view=DestroyCacheView(image_view); if (status == MagickFalse) contrast_image=DestroyImage(contrast_image); return(contrast_image); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % P r e v i e w I m a g e % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % PreviewImage() tiles 9 thumbnails of the specified image with an image % processing operation applied with varying parameters. This may be helpful % pin-pointing an appropriate parameter for a particular image processing % operation. % % The format of the PreviewImages method is: % % Image *PreviewImages(const Image *image,const PreviewType preview, % ExceptionInfo *exception) % % A description of each parameter follows: % % o image: the image. % % o preview: the image processing operation. % % o exception: return any errors or warnings in this structure. % */ MagickExport Image *PreviewImage(const Image *image,const PreviewType preview, ExceptionInfo *exception) { #define NumberTiles 9 #define PreviewImageTag "Preview/Image" #define DefaultPreviewGeometry "204x204+10+10" char factor[MaxTextExtent], label[MaxTextExtent]; double degrees, gamma, percentage, radius, sigma, threshold; Image *images, *montage_image, *preview_image, *thumbnail; ImageInfo *preview_info; MagickBooleanType proceed; MontageInfo *montage_info; QuantizeInfo quantize_info; RectangleInfo geometry; register ssize_t i, x; size_t colors; ssize_t y; /* Open output image file. */ assert(image != (Image *) NULL); assert(image->signature == MagickCoreSignature); if (image->debug != MagickFalse) (void) LogMagickEvent(TraceEvent,GetMagickModule(),"%s",image->filename); colors=2; degrees=0.0; gamma=(-0.2f); preview_info=AcquireImageInfo(); SetGeometry(image,&geometry); (void) ParseMetaGeometry(DefaultPreviewGeometry,&geometry.x,&geometry.y, &geometry.width,&geometry.height); images=NewImageList(); percentage=12.5; GetQuantizeInfo(&quantize_info); radius=0.0; sigma=1.0; threshold=0.0; x=0; y=0; for (i=0; i < NumberTiles; i++) { thumbnail=ThumbnailImage(image,geometry.width,geometry.height,exception); if (thumbnail == (Image *) NULL) break; (void) SetImageProgressMonitor(thumbnail,(MagickProgressMonitor) NULL, (void *) NULL); (void) SetImageProperty(thumbnail,"label",DefaultTileLabel); if (i == (NumberTiles/2)) { (void) QueryColorDatabase("#dfdfdf",&thumbnail->matte_color,exception); AppendImageToList(&images,thumbnail); continue; } switch (preview) { case RotatePreview: { degrees+=45.0; preview_image=RotateImage(thumbnail,degrees,exception); (void) FormatLocaleString(label,MaxTextExtent,"rotate %g",degrees); break; } case ShearPreview: { degrees+=5.0; preview_image=ShearImage(thumbnail,degrees,degrees,exception); (void) FormatLocaleString(label,MaxTextExtent,"shear %gx%g", degrees,2.0*degrees); break; } case RollPreview: { x=(ssize_t) ((i+1)*thumbnail->columns)/NumberTiles; y=(ssize_t) ((i+1)*thumbnail->rows)/NumberTiles; preview_image=RollImage(thumbnail,x,y,exception); (void) FormatLocaleString(label,MaxTextExtent,"roll %+.20gx%+.20g", (double) x,(double) y); break; } case HuePreview: { preview_image=CloneImage(thumbnail,0,0,MagickTrue,exception); if (preview_image == (Image *) NULL) break; (void) FormatLocaleString(factor,MaxTextExtent,"100,100,%g", 2.0*percentage); (void) ModulateImage(preview_image,factor); (void) FormatLocaleString(label,MaxTextExtent,"modulate %s",factor); break; } case SaturationPreview: { preview_image=CloneImage(thumbnail,0,0,MagickTrue,exception); if (preview_image == (Image *) NULL) break; (void) FormatLocaleString(factor,MaxTextExtent,"100,%g",2.0*percentage); (void) ModulateImage(preview_image,factor); (void) FormatLocaleString(label,MaxTextExtent,"modulate %s",factor); break; } case BrightnessPreview: { preview_image=CloneImage(thumbnail,0,0,MagickTrue,exception); if (preview_image == (Image *) NULL) break; (void) FormatLocaleString(factor,MaxTextExtent,"%g",2.0*percentage); (void) ModulateImage(preview_image,factor); (void) FormatLocaleString(label,MaxTextExtent,"modulate %s",factor); break; } case GammaPreview: default: { preview_image=CloneImage(thumbnail,0,0,MagickTrue,exception); if (preview_image == (Image *) NULL) break; gamma+=0.4f; (void) GammaImageChannel(preview_image,DefaultChannels,gamma); (void) FormatLocaleString(label,MaxTextExtent,"gamma %g",gamma); break; } case SpiffPreview: { preview_image=CloneImage(thumbnail,0,0,MagickTrue,exception); if (preview_image != (Image *) NULL) for (x=0; x < i; x++) (void) ContrastImage(preview_image,MagickTrue); (void) FormatLocaleString(label,MaxTextExtent,"contrast (%.20g)", (double) i+1); break; } case DullPreview: { preview_image=CloneImage(thumbnail,0,0,MagickTrue,exception); if (preview_image == (Image *) NULL) break; for (x=0; x < i; x++) (void) ContrastImage(preview_image,MagickFalse); (void) FormatLocaleString(label,MaxTextExtent,"+contrast (%.20g)", (double) i+1); break; } case GrayscalePreview: { preview_image=CloneImage(thumbnail,0,0,MagickTrue,exception); if (preview_image == (Image *) NULL) break; colors<<=1; quantize_info.number_colors=colors; quantize_info.colorspace=GRAYColorspace; (void) QuantizeImage(&quantize_info,preview_image); (void) FormatLocaleString(label,MaxTextExtent, "-colorspace gray -colors %.20g",(double) colors); break; } case QuantizePreview: { preview_image=CloneImage(thumbnail,0,0,MagickTrue,exception); if (preview_image == (Image *) NULL) break; colors<<=1; quantize_info.number_colors=colors; (void) QuantizeImage(&quantize_info,preview_image); (void) FormatLocaleString(label,MaxTextExtent,"colors %.20g",(double) colors); break; } case DespecklePreview: { for (x=0; x < (i-1); x++) { preview_image=DespeckleImage(thumbnail,exception); if (preview_image == (Image *) NULL) break; thumbnail=DestroyImage(thumbnail); thumbnail=preview_image; } preview_image=DespeckleImage(thumbnail,exception); if (preview_image == (Image *) NULL) break; (void) FormatLocaleString(label,MaxTextExtent,"despeckle (%.20g)", (double) i+1); break; } case ReduceNoisePreview: { preview_image=StatisticImage(thumbnail,NonpeakStatistic,(size_t) radius, (size_t) radius,exception); (void) FormatLocaleString(label,MaxTextExtent,"noise %g",radius); break; } case AddNoisePreview: { switch ((int) i) { case 0: { (void) CopyMagickString(factor,"uniform",MaxTextExtent); break; } case 1: { (void) CopyMagickString(factor,"gaussian",MaxTextExtent); break; } case 2: { (void) CopyMagickString(factor,"multiplicative",MaxTextExtent); break; } case 3: { (void) CopyMagickString(factor,"impulse",MaxTextExtent); break; } case 5: { (void) CopyMagickString(factor,"laplacian",MaxTextExtent); break; } case 6: { (void) CopyMagickString(factor,"poisson",MaxTextExtent); break; } default: { (void) CopyMagickString(thumbnail->magick,"NULL",MaxTextExtent); break; } } preview_image=StatisticImage(thumbnail,NonpeakStatistic,(size_t) i, (size_t) i,exception); (void) FormatLocaleString(label,MaxTextExtent,"+noise %s",factor); break; } case SharpenPreview: { preview_image=SharpenImage(thumbnail,radius,sigma,exception); (void) FormatLocaleString(label,MaxTextExtent,"sharpen %gx%g", radius,sigma); break; } case BlurPreview: { preview_image=BlurImage(thumbnail,radius,sigma,exception); (void) FormatLocaleString(label,MaxTextExtent,"blur %gx%g",radius, sigma); break; } case ThresholdPreview: { preview_image=CloneImage(thumbnail,0,0,MagickTrue,exception); if (preview_image == (Image *) NULL) break; (void) BilevelImage(thumbnail, (double) (percentage*((MagickRealType) QuantumRange+1.0))/100.0); (void) FormatLocaleString(label,MaxTextExtent,"threshold %g", (double) (percentage*((MagickRealType) QuantumRange+1.0))/100.0); break; } case EdgeDetectPreview: { preview_image=EdgeImage(thumbnail,radius,exception); (void) FormatLocaleString(label,MaxTextExtent,"edge %g",radius); break; } case SpreadPreview: { preview_image=SpreadImage(thumbnail,radius,exception); (void) FormatLocaleString(label,MaxTextExtent,"spread %g", radius+0.5); break; } case SolarizePreview: { preview_image=CloneImage(thumbnail,0,0,MagickTrue,exception); if (preview_image == (Image *) NULL) break; (void) SolarizeImage(preview_image,(double) QuantumRange* percentage/100.0); (void) FormatLocaleString(label,MaxTextExtent,"solarize %g", (QuantumRange*percentage)/100.0); break; } case ShadePreview: { degrees+=10.0; preview_image=ShadeImage(thumbnail,MagickTrue,degrees,degrees, exception); (void) FormatLocaleString(label,MaxTextExtent,"shade %gx%g", degrees,degrees); break; } case RaisePreview: { preview_image=CloneImage(thumbnail,0,0,MagickTrue,exception); if (preview_image == (Image *) NULL) break; geometry.width=(size_t) (2*i+2); geometry.height=(size_t) (2*i+2); geometry.x=(i-1)/2; geometry.y=(i-1)/2; (void) RaiseImage(preview_image,&geometry,MagickTrue); (void) FormatLocaleString(label,MaxTextExtent, "raise %.20gx%.20g%+.20g%+.20g",(double) geometry.width,(double) geometry.height,(double) geometry.x,(double) geometry.y); break; } case SegmentPreview: { preview_image=CloneImage(thumbnail,0,0,MagickTrue,exception); if (preview_image == (Image *) NULL) break; threshold+=0.4f; (void) SegmentImage(preview_image,sRGBColorspace,MagickFalse,threshold, threshold); (void) FormatLocaleString(label,MaxTextExtent,"segment %gx%g", threshold,threshold); break; } case SwirlPreview: { preview_image=SwirlImage(thumbnail,degrees,exception); (void) FormatLocaleString(label,MaxTextExtent,"swirl %g",degrees); degrees+=45.0; break; } case ImplodePreview: { degrees+=0.1f; preview_image=ImplodeImage(thumbnail,degrees,exception); (void) FormatLocaleString(label,MaxTextExtent,"implode %g",degrees); break; } case WavePreview: { degrees+=5.0f; preview_image=WaveImage(thumbnail,0.5*degrees,2.0*degrees,exception); (void) FormatLocaleString(label,MaxTextExtent,"wave %gx%g", 0.5*degrees,2.0*degrees); break; } case OilPaintPreview: { preview_image=OilPaintImage(thumbnail,(double) radius,exception); (void) FormatLocaleString(label,MaxTextExtent,"paint %g",radius); break; } case CharcoalDrawingPreview: { preview_image=CharcoalImage(thumbnail,(double) radius,(double) sigma, exception); (void) FormatLocaleString(label,MaxTextExtent,"charcoal %gx%g", radius,sigma); break; } case JPEGPreview: { char filename[MaxTextExtent]; int file; MagickBooleanType status; preview_image=CloneImage(thumbnail,0,0,MagickTrue,exception); if (preview_image == (Image *) NULL) break; preview_info->quality=(size_t) percentage; (void) FormatLocaleString(factor,MaxTextExtent,"%.20g",(double) preview_info->quality); file=AcquireUniqueFileResource(filename); if (file != -1) file=close(file)-1; (void) FormatLocaleString(preview_image->filename,MaxTextExtent, "jpeg:%s",filename); status=WriteImage(preview_info,preview_image); if (status != MagickFalse) { Image *quality_image; (void) CopyMagickString(preview_info->filename, preview_image->filename,MaxTextExtent); quality_image=ReadImage(preview_info,exception); if (quality_image != (Image *) NULL) { preview_image=DestroyImage(preview_image); preview_image=quality_image; } } (void) RelinquishUniqueFileResource(preview_image->filename); if ((GetBlobSize(preview_image)/1024) >= 1024) (void) FormatLocaleString(label,MaxTextExtent,"quality %s\n%gmb ", factor,(double) ((MagickOffsetType) GetBlobSize(preview_image))/ 1024.0/1024.0); else if (GetBlobSize(preview_image) >= 1024) (void) FormatLocaleString(label,MaxTextExtent, "quality %s\n%gkb ",factor,(double) ((MagickOffsetType) GetBlobSize(preview_image))/1024.0); else (void) FormatLocaleString(label,MaxTextExtent,"quality %s\n%.20gb ", factor,(double) ((MagickOffsetType) GetBlobSize(thumbnail))); break; } } thumbnail=DestroyImage(thumbnail); percentage+=12.5; radius+=0.5; sigma+=0.25; if (preview_image == (Image *) NULL) break; (void) DeleteImageProperty(preview_image,"label"); (void) SetImageProperty(preview_image,"label",label); AppendImageToList(&images,preview_image); proceed=SetImageProgress(image,PreviewImageTag,(MagickOffsetType) i, NumberTiles); if (proceed == MagickFalse) break; } if (images == (Image *) NULL) { preview_info=DestroyImageInfo(preview_info); return((Image *) NULL); } /* Create the montage. */ montage_info=CloneMontageInfo(preview_info,(MontageInfo *) NULL); (void) CopyMagickString(montage_info->filename,image->filename,MaxTextExtent); montage_info->shadow=MagickTrue; (void) CloneString(&montage_info->tile,"3x3"); (void) CloneString(&montage_info->geometry,DefaultPreviewGeometry); (void) CloneString(&montage_info->frame,DefaultTileFrame); montage_image=MontageImages(images,montage_info,exception); montage_info=DestroyMontageInfo(montage_info); images=DestroyImageList(images); if (montage_image == (Image *) NULL) ThrowImageException(ResourceLimitError,"MemoryAllocationFailed"); if (montage_image->montage != (char *) NULL) { /* Free image directory. */ montage_image->montage=(char *) RelinquishMagickMemory( montage_image->montage); if (image->directory != (char *) NULL) montage_image->directory=(char *) RelinquishMagickMemory( montage_image->directory); } preview_info=DestroyImageInfo(preview_info); return(montage_image); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % R o t a t i o n a l B l u r I m a g e % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % RotationalBlurImage() applies a rotational blur to the image. % % Andrew Protano contributed this effect. % % The format of the RotationalBlurImage method is: % % Image *RotationalBlurImage(const Image *image,const double angle, % ExceptionInfo *exception) % Image *RotationalBlurImageChannel(const Image *image, % const ChannelType channel,const double angle,ExceptionInfo *exception) % % A description of each parameter follows: % % o image: the image. % % o channel: the channel type. % % o angle: the angle of the rotational blur. % % o exception: return any errors or warnings in this structure. % */ MagickExport Image *RotationalBlurImage(const Image *image,const double angle, ExceptionInfo *exception) { Image *blur_image; blur_image=RotationalBlurImageChannel(image,DefaultChannels,angle,exception); return(blur_image); } MagickExport Image *RotationalBlurImageChannel(const Image *image, const ChannelType channel,const double angle,ExceptionInfo *exception) { CacheView *blur_view, *image_view; Image *blur_image; MagickBooleanType status; MagickOffsetType progress; MagickPixelPacket bias; MagickRealType blur_radius, *cos_theta, offset, *sin_theta, theta; PointInfo blur_center; register ssize_t i; size_t n; ssize_t y; /* Allocate blur image. */ assert(image != (Image *) NULL); assert(image->signature == MagickCoreSignature); if (image->debug != MagickFalse) (void) LogMagickEvent(TraceEvent,GetMagickModule(),"%s",image->filename); assert(exception != (ExceptionInfo *) NULL); assert(exception->signature == MagickCoreSignature); #if defined(MAGICKCORE_OPENCL_SUPPORT) blur_image=AccelerateRadialBlurImage(image,channel,angle,exception); if (blur_image != (Image *) NULL) return(blur_image); #endif blur_image=CloneImage(image,0,0,MagickTrue,exception); if (blur_image == (Image *) NULL) return((Image *) NULL); if (SetImageStorageClass(blur_image,DirectClass) == MagickFalse) { InheritException(exception,&blur_image->exception); blur_image=DestroyImage(blur_image); return((Image *) NULL); } blur_center.x=(double) (image->columns-1)/2.0; blur_center.y=(double) (image->rows-1)/2.0; blur_radius=hypot(blur_center.x,blur_center.y); n=(size_t) fabs(4.0*DegreesToRadians(angle)*sqrt((double) blur_radius)+2UL); theta=DegreesToRadians(angle)/(MagickRealType) (n-1); cos_theta=(MagickRealType *) AcquireQuantumMemory((size_t) n, sizeof(*cos_theta)); sin_theta=(MagickRealType *) AcquireQuantumMemory((size_t) n, sizeof(*sin_theta)); if ((cos_theta == (MagickRealType *) NULL) || (sin_theta == (MagickRealType *) NULL)) { if (cos_theta != (double *) NULL) cos_theta=(double *) RelinquishMagickMemory(cos_theta); if (sin_theta != (double *) NULL) sin_theta=(double *) RelinquishMagickMemory(sin_theta); blur_image=DestroyImage(blur_image); ThrowImageException(ResourceLimitError,"MemoryAllocationFailed"); } offset=theta*(MagickRealType) (n-1)/2.0; for (i=0; i < (ssize_t) n; i++) { cos_theta[i]=cos((double) (theta*i-offset)); sin_theta[i]=sin((double) (theta*i-offset)); } /* Radial blur image. */ status=MagickTrue; progress=0; GetMagickPixelPacket(image,&bias); image_view=AcquireVirtualCacheView(image,exception); blur_view=AcquireAuthenticCacheView(blur_image,exception); #if defined(MAGICKCORE_OPENMP_SUPPORT) #pragma omp parallel for schedule(static) shared(progress,status) \ magick_number_threads(image,blur_image,blur_image->rows,1) #endif for (y=0; y < (ssize_t) blur_image->rows; y++) { register const IndexPacket *magick_restrict indexes; register IndexPacket *magick_restrict blur_indexes; register PixelPacket *magick_restrict q; register ssize_t x; if (status == MagickFalse) continue; q=GetCacheViewAuthenticPixels(blur_view,0,y,blur_image->columns,1, exception); if (q == (PixelPacket *) NULL) { status=MagickFalse; continue; } blur_indexes=GetCacheViewAuthenticIndexQueue(blur_view); for (x=0; x < (ssize_t) blur_image->columns; x++) { MagickPixelPacket qixel; MagickRealType normalize, radius; PixelPacket pixel; PointInfo center; register ssize_t i; size_t step; center.x=(double) x-blur_center.x; center.y=(double) y-blur_center.y; radius=hypot((double) center.x,center.y); if (radius == 0) step=1; else { step=(size_t) (blur_radius/radius); if (step == 0) step=1; else if (step >= n) step=n-1; } normalize=0.0; qixel=bias; if (((channel & OpacityChannel) == 0) || (image->matte == MagickFalse)) { for (i=0; i < (ssize_t) n; i+=(ssize_t) step) { (void) GetOneCacheViewVirtualPixel(image_view,(ssize_t) (blur_center.x+center.x*cos_theta[i]-center.y*sin_theta[i]+0.5), (ssize_t) (blur_center.y+center.x*sin_theta[i]+center.y* cos_theta[i]+0.5),&pixel,exception); qixel.red+=pixel.red; qixel.green+=pixel.green; qixel.blue+=pixel.blue; qixel.opacity+=pixel.opacity; if (image->colorspace == CMYKColorspace) { indexes=GetCacheViewVirtualIndexQueue(image_view); qixel.index+=(*indexes); } normalize+=1.0; } normalize=PerceptibleReciprocal(normalize); if ((channel & RedChannel) != 0) SetPixelRed(q,ClampToQuantum(normalize*qixel.red)); if ((channel & GreenChannel) != 0) SetPixelGreen(q,ClampToQuantum(normalize*qixel.green)); if ((channel & BlueChannel) != 0) SetPixelBlue(q,ClampToQuantum(normalize*qixel.blue)); if ((channel & OpacityChannel) != 0) SetPixelOpacity(q,ClampToQuantum(normalize*qixel.opacity)); if (((channel & IndexChannel) != 0) && (image->colorspace == CMYKColorspace)) SetPixelIndex(blur_indexes+x,ClampToQuantum(normalize*qixel.index)); } else { double alpha, gamma; alpha=1.0; gamma=0.0; for (i=0; i < (ssize_t) n; i+=(ssize_t) step) { (void) GetOneCacheViewVirtualPixel(image_view,(ssize_t) (blur_center.x+center.x*cos_theta[i]-center.y*sin_theta[i]+0.5), (ssize_t) (blur_center.y+center.x*sin_theta[i]+center.y* cos_theta[i]+0.5),&pixel,exception); alpha=(MagickRealType) (QuantumScale*GetPixelAlpha(&pixel)); qixel.red+=alpha*pixel.red; qixel.green+=alpha*pixel.green; qixel.blue+=alpha*pixel.blue; qixel.opacity+=pixel.opacity; if (image->colorspace == CMYKColorspace) { indexes=GetCacheViewVirtualIndexQueue(image_view); qixel.index+=alpha*(*indexes); } gamma+=alpha; normalize+=1.0; } gamma=PerceptibleReciprocal(gamma); normalize=PerceptibleReciprocal(normalize); if ((channel & RedChannel) != 0) SetPixelRed(q,ClampToQuantum(gamma*qixel.red)); if ((channel & GreenChannel) != 0) SetPixelGreen(q,ClampToQuantum(gamma*qixel.green)); if ((channel & BlueChannel) != 0) SetPixelBlue(q,ClampToQuantum(gamma*qixel.blue)); if ((channel & OpacityChannel) != 0) SetPixelOpacity(q,ClampToQuantum(normalize*qixel.opacity)); if (((channel & IndexChannel) != 0) && (image->colorspace == CMYKColorspace)) SetPixelIndex(blur_indexes+x,ClampToQuantum(gamma*qixel.index)); } q++; } if (SyncCacheViewAuthenticPixels(blur_view,exception) == MagickFalse) status=MagickFalse; if (image->progress_monitor != (MagickProgressMonitor) NULL) { MagickBooleanType proceed; #if defined(MAGICKCORE_OPENMP_SUPPORT) #pragma omp atomic #endif progress++; proceed=SetImageProgress(image,BlurImageTag,progress,image->rows); if (proceed == MagickFalse) status=MagickFalse; } } blur_view=DestroyCacheView(blur_view); image_view=DestroyCacheView(image_view); cos_theta=(MagickRealType *) RelinquishMagickMemory(cos_theta); sin_theta=(MagickRealType *) RelinquishMagickMemory(sin_theta); if (status == MagickFalse) blur_image=DestroyImage(blur_image); return(blur_image); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % S e l e c t i v e B l u r I m a g e % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % SelectiveBlurImage() selectively blur pixels within a contrast threshold. % It is similar to the unsharpen mask that sharpens everything with contrast % above a certain threshold. % % The format of the SelectiveBlurImage method is: % % Image *SelectiveBlurImage(const Image *image,const double radius, % const double sigma,const double threshold,ExceptionInfo *exception) % Image *SelectiveBlurImageChannel(const Image *image, % const ChannelType channel,const double radius,const double sigma, % const double threshold,ExceptionInfo *exception) % % A description of each parameter follows: % % o image: the image. % % o channel: the channel type. % % o radius: the radius of the Gaussian, in pixels, not counting the center % pixel. % % o sigma: the standard deviation of the Gaussian, in pixels. % % o threshold: only pixels within this contrast threshold are included % in the blur operation. % % o exception: return any errors or warnings in this structure. % */ MagickExport Image *SelectiveBlurImage(const Image *image,const double radius, const double sigma,const double threshold,ExceptionInfo *exception) { Image *blur_image; blur_image=SelectiveBlurImageChannel(image,DefaultChannels,radius,sigma, threshold,exception); return(blur_image); } MagickExport Image *SelectiveBlurImageChannel(const Image *image, const ChannelType channel,const double radius,const double sigma, const double threshold,ExceptionInfo *exception) { #define SelectiveBlurImageTag "SelectiveBlur/Image" CacheView *blur_view, *image_view, *luminance_view; double *kernel; Image *blur_image, *luminance_image; MagickBooleanType status; MagickOffsetType progress; MagickPixelPacket bias; register ssize_t i; size_t width; ssize_t center, j, u, v, y; /* Initialize blur image attributes. */ assert(image != (Image *) NULL); assert(image->signature == MagickCoreSignature); if (image->debug != MagickFalse) (void) LogMagickEvent(TraceEvent,GetMagickModule(),"%s",image->filename); assert(exception != (ExceptionInfo *) NULL); assert(exception->signature == MagickCoreSignature); width=GetOptimalKernelWidth1D(radius,sigma); kernel=(double *) MagickAssumeAligned(AcquireAlignedMemory((size_t) width, width*sizeof(*kernel))); if (kernel == (double *) NULL) ThrowImageException(ResourceLimitError,"MemoryAllocationFailed"); j=(ssize_t) (width-1)/2; i=0; for (v=(-j); v <= j; v++) { for (u=(-j); u <= j; u++) kernel[i++]=(double) (exp(-((double) u*u+v*v)/(2.0*MagickSigma* MagickSigma))/(2.0*MagickPI*MagickSigma*MagickSigma)); } if (image->debug != MagickFalse) { char format[MaxTextExtent], *message; register const double *k; ssize_t u, v; (void) LogMagickEvent(TransformEvent,GetMagickModule(), " SelectiveBlurImage with %.20gx%.20g kernel:",(double) width,(double) width); message=AcquireString(""); k=kernel; for (v=0; v < (ssize_t) width; v++) { *message='\0'; (void) FormatLocaleString(format,MaxTextExtent,"%.20g: ",(double) v); (void) ConcatenateString(&message,format); for (u=0; u < (ssize_t) width; u++) { (void) FormatLocaleString(format,MaxTextExtent,"%+f ",*k++); (void) ConcatenateString(&message,format); } (void) LogMagickEvent(TransformEvent,GetMagickModule(),"%s",message); } message=DestroyString(message); } blur_image=CloneImage(image,0,0,MagickTrue,exception); if (blur_image == (Image *) NULL) { kernel=(double *) RelinquishAlignedMemory(kernel); return((Image *) NULL); } if (SetImageStorageClass(blur_image,DirectClass) == MagickFalse) { kernel=(double *) RelinquishAlignedMemory(kernel); InheritException(exception,&blur_image->exception); blur_image=DestroyImage(blur_image); return((Image *) NULL); } luminance_image=CloneImage(image,0,0,MagickTrue,exception); if (luminance_image == (Image *) NULL) { kernel=(double *) RelinquishAlignedMemory(kernel); blur_image=DestroyImage(blur_image); return((Image *) NULL); } status=TransformImageColorspace(luminance_image,GRAYColorspace); if (status == MagickFalse) { InheritException(exception,&luminance_image->exception); kernel=(double *) RelinquishAlignedMemory(kernel); blur_image=DestroyImage(blur_image); luminance_image=DestroyImage(luminance_image); return((Image *) NULL); } /* Threshold blur image. */ status=MagickTrue; progress=0; center=(ssize_t) ((image->columns+width)*((width-1)/2L)+((width-1)/2L)); GetMagickPixelPacket(image,&bias); SetMagickPixelPacketBias(image,&bias); image_view=AcquireVirtualCacheView(image,exception); luminance_view=AcquireVirtualCacheView(luminance_image,exception); blur_view=AcquireAuthenticCacheView(blur_image,exception); #if defined(MAGICKCORE_OPENMP_SUPPORT) #pragma omp parallel for schedule(static) shared(progress,status) \ magick_number_threads(image,blur_image,image->rows,1) #endif for (y=0; y < (ssize_t) image->rows; y++) { double gamma; MagickBooleanType sync; register const IndexPacket *magick_restrict indexes; register const PixelPacket *magick_restrict l, *magick_restrict p; register IndexPacket *magick_restrict blur_indexes; register PixelPacket *magick_restrict q; register ssize_t x; if (status == MagickFalse) continue; p=GetCacheViewVirtualPixels(image_view,-((ssize_t) (width-1)/2L),y-(ssize_t) ((width-1)/2L),image->columns+width,width,exception); l=GetCacheViewVirtualPixels(luminance_view,-((ssize_t) (width-1)/2L),y- (ssize_t) ((width-1)/2L),luminance_image->columns+width,width,exception); q=GetCacheViewAuthenticPixels(blur_view,0,y,blur_image->columns,1, exception); if ((p == (const PixelPacket *) NULL) || (l == (const PixelPacket *) NULL) || (q == (PixelPacket *) NULL)) { status=MagickFalse; continue; } indexes=GetCacheViewVirtualIndexQueue(image_view); blur_indexes=GetCacheViewAuthenticIndexQueue(blur_view); for (x=0; x < (ssize_t) image->columns; x++) { double contrast; DoublePixelPacket pixel; MagickRealType intensity; register const double *magick_restrict k; register ssize_t u; ssize_t j, v; pixel.red=bias.red; pixel.green=bias.green; pixel.blue=bias.blue; pixel.opacity=bias.opacity; pixel.index=bias.index; k=kernel; intensity=GetPixelIntensity(image,p+center); gamma=0.0; j=0; if (((channel & OpacityChannel) == 0) || (image->matte == MagickFalse)) { for (v=0; v < (ssize_t) width; v++) { for (u=0; u < (ssize_t) width; u++) { contrast=GetPixelIntensity(luminance_image,l+u+j)-intensity; if (fabs(contrast) < threshold) { pixel.red+=(*k)*GetPixelRed(p+u+j); pixel.green+=(*k)*GetPixelGreen(p+u+j); pixel.blue+=(*k)*GetPixelBlue(p+u+j); gamma+=(*k); } k++; } j+=(ssize_t) (image->columns+width); } if (gamma != 0.0) { gamma=PerceptibleReciprocal(gamma); if ((channel & RedChannel) != 0) SetPixelRed(q,ClampToQuantum(gamma*pixel.red)); if ((channel & GreenChannel) != 0) SetPixelGreen(q,ClampToQuantum(gamma*pixel.green)); if ((channel & BlueChannel) != 0) SetPixelBlue(q,ClampToQuantum(gamma*pixel.blue)); } if ((channel & OpacityChannel) != 0) { gamma=0.0; j=0; for (v=0; v < (ssize_t) width; v++) { for (u=0; u < (ssize_t) width; u++) { contrast=GetPixelIntensity(luminance_image,l+u+j)-intensity; if (fabs(contrast) < threshold) { pixel.opacity+=(*k)*(p+u+j)->opacity; gamma+=(*k); } k++; } j+=(ssize_t) (image->columns+width); } gamma=PerceptibleReciprocal(gamma); SetPixelOpacity(q,ClampToQuantum(gamma*pixel.opacity)); } if (((channel & IndexChannel) != 0) && (image->colorspace == CMYKColorspace)) { gamma=0.0; j=0; for (v=0; v < (ssize_t) width; v++) { for (u=0; u < (ssize_t) width; u++) { contrast=GetPixelIntensity(luminance_image,l+u+j)-intensity; if (fabs(contrast) < threshold) { pixel.index+=(*k)*GetPixelIndex(indexes+x+u+j); gamma+=(*k); } k++; } j+=(ssize_t) (image->columns+width); } gamma=PerceptibleReciprocal(gamma); SetPixelIndex(blur_indexes+x,ClampToQuantum(gamma*pixel.index)); } } else { MagickRealType alpha; for (v=0; v < (ssize_t) width; v++) { for (u=0; u < (ssize_t) width; u++) { contrast=GetPixelIntensity(luminance_image,l+u+j)-intensity; if (fabs(contrast) < threshold) { alpha=(MagickRealType) (QuantumScale*GetPixelAlpha(p+u+j)); pixel.red+=(*k)*alpha*GetPixelRed(p+u+j); pixel.green+=(*k)*alpha*GetPixelGreen(p+u+j); pixel.blue+=(*k)*alpha*GetPixelBlue(p+u+j); pixel.opacity+=(*k)*GetPixelOpacity(p+u+j); gamma+=(*k)*alpha; } k++; } j+=(ssize_t) (image->columns+width); } if (gamma != 0.0) { gamma=PerceptibleReciprocal(gamma); if ((channel & RedChannel) != 0) SetPixelRed(q,ClampToQuantum(gamma*pixel.red)); if ((channel & GreenChannel) != 0) SetPixelGreen(q,ClampToQuantum(gamma*pixel.green)); if ((channel & BlueChannel) != 0) SetPixelBlue(q,ClampToQuantum(gamma*pixel.blue)); } if ((channel & OpacityChannel) != 0) { j=0; for (v=0; v < (ssize_t) width; v++) { for (u=0; u < (ssize_t) width; u++) { contrast=GetPixelIntensity(luminance_image,l+u+j)-intensity; if (fabs(contrast) < threshold) pixel.opacity+=(*k)*GetPixelOpacity(p+u+j); k++; } j+=(ssize_t) (image->columns+width); } SetPixelOpacity(q,ClampToQuantum(pixel.opacity)); } if (((channel & IndexChannel) != 0) && (image->colorspace == CMYKColorspace)) { gamma=0.0; j=0; for (v=0; v < (ssize_t) width; v++) { for (u=0; u < (ssize_t) width; u++) { contrast=GetPixelIntensity(luminance_image,l+u+j)-intensity; if (fabs(contrast) < threshold) { alpha=(MagickRealType) (QuantumScale* GetPixelAlpha(p+u+j)); pixel.index+=(*k)*alpha*GetPixelIndex(indexes+x+u+j); gamma+=(*k); } k++; } j+=(ssize_t) (image->columns+width); } gamma=PerceptibleReciprocal(gamma); SetPixelIndex(blur_indexes+x,ClampToQuantum(gamma*pixel.index)); } } p++; l++; q++; } sync=SyncCacheViewAuthenticPixels(blur_view,exception); if (sync == MagickFalse) status=MagickFalse; if (image->progress_monitor != (MagickProgressMonitor) NULL) { MagickBooleanType proceed; #if defined(MAGICKCORE_OPENMP_SUPPORT) #pragma omp atomic #endif progress++; proceed=SetImageProgress(image,SelectiveBlurImageTag,progress, image->rows); if (proceed == MagickFalse) status=MagickFalse; } } blur_image->type=image->type; blur_view=DestroyCacheView(blur_view); luminance_view=DestroyCacheView(luminance_view); image_view=DestroyCacheView(image_view); luminance_image=DestroyImage(luminance_image); kernel=(double *) RelinquishAlignedMemory(kernel); if (status == MagickFalse) blur_image=DestroyImage(blur_image); return(blur_image); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % S h a d e I m a g e % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % ShadeImage() shines a distant light on an image to create a % three-dimensional effect. You control the positioning of the light with % azimuth and elevation; azimuth is measured in degrees off the x axis % and elevation is measured in pixels above the Z axis. % % The format of the ShadeImage method is: % % Image *ShadeImage(const Image *image,const MagickBooleanType gray, % const double azimuth,const double elevation,ExceptionInfo *exception) % % A description of each parameter follows: % % o image: the image. % % o gray: A value other than zero shades the intensity of each pixel. % % o azimuth, elevation: Define the light source direction. % % o exception: return any errors or warnings in this structure. % */ MagickExport Image *ShadeImage(const Image *image,const MagickBooleanType gray, const double azimuth,const double elevation,ExceptionInfo *exception) { #define ShadeImageTag "Shade/Image" CacheView *image_view, *shade_view; Image *linear_image, *shade_image; MagickBooleanType status; MagickOffsetType progress; PrimaryInfo light; ssize_t y; /* Initialize shaded image attributes. */ assert(image != (const Image *) NULL); assert(image->signature == MagickCoreSignature); if (image->debug != MagickFalse) (void) LogMagickEvent(TraceEvent,GetMagickModule(),"%s",image->filename); assert(exception != (ExceptionInfo *) NULL); assert(exception->signature == MagickCoreSignature); linear_image=CloneImage(image,0,0,MagickTrue,exception); shade_image=CloneImage(image,0,0,MagickTrue,exception); if ((linear_image == (Image *) NULL) || (shade_image == (Image *) NULL)) { if (linear_image != (Image *) NULL) linear_image=DestroyImage(linear_image); if (shade_image != (Image *) NULL) shade_image=DestroyImage(shade_image); return((Image *) NULL); } if (SetImageStorageClass(shade_image,DirectClass) == MagickFalse) { InheritException(exception,&shade_image->exception); linear_image=DestroyImage(linear_image); shade_image=DestroyImage(shade_image); return((Image *) NULL); } /* Compute the light vector. */ light.x=(double) QuantumRange*cos(DegreesToRadians(azimuth))* cos(DegreesToRadians(elevation)); light.y=(double) QuantumRange*sin(DegreesToRadians(azimuth))* cos(DegreesToRadians(elevation)); light.z=(double) QuantumRange*sin(DegreesToRadians(elevation)); /* Shade image. */ status=MagickTrue; progress=0; image_view=AcquireVirtualCacheView(linear_image,exception); shade_view=AcquireAuthenticCacheView(shade_image,exception); #if defined(MAGICKCORE_OPENMP_SUPPORT) #pragma omp parallel for schedule(static) shared(progress,status) \ magick_number_threads(linear_image,shade_image,linear_image->rows,1) #endif for (y=0; y < (ssize_t) linear_image->rows; y++) { MagickRealType distance, normal_distance, shade; PrimaryInfo normal; register const PixelPacket *magick_restrict p, *magick_restrict s0, *magick_restrict s1, *magick_restrict s2; register PixelPacket *magick_restrict q; register ssize_t x; if (status == MagickFalse) continue; p=GetCacheViewVirtualPixels(image_view,-1,y-1,linear_image->columns+2,3, exception); q=QueueCacheViewAuthenticPixels(shade_view,0,y,shade_image->columns,1, exception); if ((p == (PixelPacket *) NULL) || (q == (PixelPacket *) NULL)) { status=MagickFalse; continue; } /* Shade this row of pixels. */ normal.z=2.0*(double) QuantumRange; /* constant Z of surface normal */ for (x=0; x < (ssize_t) linear_image->columns; x++) { /* Determine the surface normal and compute shading. */ s0=p+1; s1=s0+image->columns+2; s2=s1+image->columns+2; normal.x=(double) (GetPixelIntensity(linear_image,s0-1)+ GetPixelIntensity(linear_image,s1-1)+ GetPixelIntensity(linear_image,s2-1)- GetPixelIntensity(linear_image,s0+1)- GetPixelIntensity(linear_image,s1+1)- GetPixelIntensity(linear_image,s2+1)); normal.y=(double) (GetPixelIntensity(linear_image,s2-1)+ GetPixelIntensity(linear_image,s2)+ GetPixelIntensity(linear_image,s2+1)- GetPixelIntensity(linear_image,s0-1)- GetPixelIntensity(linear_image,s0)- GetPixelIntensity(linear_image,s0+1)); if ((fabs(normal.x) <= MagickEpsilon) && (fabs(normal.y) <= MagickEpsilon)) shade=light.z; else { shade=0.0; distance=normal.x*light.x+normal.y*light.y+normal.z*light.z; if (distance > MagickEpsilon) { normal_distance=normal.x*normal.x+normal.y*normal.y+normal.z* normal.z; if (normal_distance > (MagickEpsilon*MagickEpsilon)) shade=distance/sqrt((double) normal_distance); } } if (gray != MagickFalse) { SetPixelRed(q,shade); SetPixelGreen(q,shade); SetPixelBlue(q,shade); } else { SetPixelRed(q,ClampToQuantum(QuantumScale*shade*GetPixelRed(s1))); SetPixelGreen(q,ClampToQuantum(QuantumScale*shade*GetPixelGreen(s1))); SetPixelBlue(q,ClampToQuantum(QuantumScale*shade*GetPixelBlue(s1))); } q->opacity=s1->opacity; p++; q++; } if (SyncCacheViewAuthenticPixels(shade_view,exception) == MagickFalse) status=MagickFalse; if (image->progress_monitor != (MagickProgressMonitor) NULL) { MagickBooleanType proceed; #if defined(MAGICKCORE_OPENMP_SUPPORT) #pragma omp atomic #endif progress++; proceed=SetImageProgress(image,ShadeImageTag,progress,image->rows); if (proceed == MagickFalse) status=MagickFalse; } } shade_view=DestroyCacheView(shade_view); image_view=DestroyCacheView(image_view); linear_image=DestroyImage(linear_image); if (status == MagickFalse) shade_image=DestroyImage(shade_image); return(shade_image); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % S h a r p e n I m a g e % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % SharpenImage() sharpens the image. We convolve the image with a Gaussian % operator of the given radius and standard deviation (sigma). For % reasonable results, radius should be larger than sigma. Use a radius of 0 % and SharpenImage() selects a suitable radius for you. % % Using a separable kernel would be faster, but the negative weights cancel % out on the corners of the kernel producing often undesirable ringing in the % filtered result; this can be avoided by using a 2D gaussian shaped image % sharpening kernel instead. % % The format of the SharpenImage method is: % % Image *SharpenImage(const Image *image,const double radius, % const double sigma,ExceptionInfo *exception) % Image *SharpenImageChannel(const Image *image,const ChannelType channel, % const double radius,const double sigma,ExceptionInfo *exception) % % A description of each parameter follows: % % o image: the image. % % o channel: the channel type. % % o radius: the radius of the Gaussian, in pixels, not counting the center % pixel. % % o sigma: the standard deviation of the Laplacian, in pixels. % % o exception: return any errors or warnings in this structure. % */ MagickExport Image *SharpenImage(const Image *image,const double radius, const double sigma,ExceptionInfo *exception) { Image *sharp_image; sharp_image=SharpenImageChannel(image,DefaultChannels,radius,sigma,exception); return(sharp_image); } MagickExport Image *SharpenImageChannel(const Image *image, const ChannelType channel,const double radius,const double sigma, ExceptionInfo *exception) { double gamma, normalize; Image *sharp_image; KernelInfo *kernel_info; register ssize_t i; size_t width; ssize_t j, u, v; assert(image != (const Image *) NULL); assert(image->signature == MagickCoreSignature); if (image->debug != MagickFalse) (void) LogMagickEvent(TraceEvent,GetMagickModule(),"%s",image->filename); assert(exception != (ExceptionInfo *) NULL); assert(exception->signature == MagickCoreSignature); width=GetOptimalKernelWidth2D(radius,sigma); kernel_info=AcquireKernelInfo((const char *) NULL); if (kernel_info == (KernelInfo *) NULL) ThrowImageException(ResourceLimitError,"MemoryAllocationFailed"); (void) memset(kernel_info,0,sizeof(*kernel_info)); kernel_info->width=width; kernel_info->height=width; kernel_info->x=(ssize_t) (width-1)/2; kernel_info->y=(ssize_t) (width-1)/2; kernel_info->signature=MagickCoreSignature; kernel_info->values=(double *) MagickAssumeAligned(AcquireAlignedMemory( kernel_info->width,kernel_info->height*sizeof(*kernel_info->values))); if (kernel_info->values == (double *) NULL) { kernel_info=DestroyKernelInfo(kernel_info); ThrowImageException(ResourceLimitError,"MemoryAllocationFailed"); } normalize=0.0; j=(ssize_t) (kernel_info->width-1)/2; i=0; for (v=(-j); v <= j; v++) { for (u=(-j); u <= j; u++) { kernel_info->values[i]=(double) (-exp(-((double) u*u+v*v)/(2.0* MagickSigma*MagickSigma))/(2.0*MagickPI*MagickSigma*MagickSigma)); normalize+=kernel_info->values[i]; i++; } } kernel_info->values[i/2]=(double) ((-2.0)*normalize); normalize=0.0; for (i=0; i < (ssize_t) (kernel_info->width*kernel_info->height); i++) normalize+=kernel_info->values[i]; gamma=PerceptibleReciprocal(normalize); for (i=0; i < (ssize_t) (kernel_info->width*kernel_info->height); i++) kernel_info->values[i]*=gamma; sharp_image=MorphologyImageChannel(image,channel,ConvolveMorphology,1, kernel_info,exception); kernel_info=DestroyKernelInfo(kernel_info); return(sharp_image); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % S p r e a d I m a g e % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % SpreadImage() is a special effects method that randomly displaces each % pixel in a block defined by the radius parameter. % % The format of the SpreadImage method is: % % Image *SpreadImage(const Image *image,const double radius, % ExceptionInfo *exception) % % A description of each parameter follows: % % o image: the image. % % o radius: Choose a random pixel in a neighborhood of this extent. % % o exception: return any errors or warnings in this structure. % */ MagickExport Image *SpreadImage(const Image *image,const double radius, ExceptionInfo *exception) { #define SpreadImageTag "Spread/Image" CacheView *image_view, *spread_view; Image *spread_image; MagickBooleanType status; MagickOffsetType progress; MagickPixelPacket bias; RandomInfo **magick_restrict random_info; size_t width; ssize_t y; #if defined(MAGICKCORE_OPENMP_SUPPORT) unsigned long key; #endif /* Initialize spread image attributes. */ assert(image != (Image *) NULL); assert(image->signature == MagickCoreSignature); if (image->debug != MagickFalse) (void) LogMagickEvent(TraceEvent,GetMagickModule(),"%s",image->filename); assert(exception != (ExceptionInfo *) NULL); assert(exception->signature == MagickCoreSignature); spread_image=CloneImage(image,0,0,MagickTrue,exception); if (spread_image == (Image *) NULL) return((Image *) NULL); if (SetImageStorageClass(spread_image,DirectClass) == MagickFalse) { InheritException(exception,&spread_image->exception); spread_image=DestroyImage(spread_image); return((Image *) NULL); } /* Spread image. */ status=MagickTrue; progress=0; GetMagickPixelPacket(spread_image,&bias); width=GetOptimalKernelWidth1D(radius,0.5); random_info=AcquireRandomInfoThreadSet(); image_view=AcquireVirtualCacheView(image,exception); spread_view=AcquireAuthenticCacheView(spread_image,exception); #if defined(MAGICKCORE_OPENMP_SUPPORT) key=GetRandomSecretKey(random_info[0]); #pragma omp parallel for schedule(static) shared(progress,status) \ magick_number_threads(image,spread_image,spread_image->rows,key == ~0UL) #endif for (y=0; y < (ssize_t) spread_image->rows; y++) { const int id = GetOpenMPThreadId(); MagickPixelPacket pixel; register IndexPacket *magick_restrict indexes; register PixelPacket *magick_restrict q; register ssize_t x; if (status == MagickFalse) continue; q=QueueCacheViewAuthenticPixels(spread_view,0,y,spread_image->columns,1, exception); if (q == (PixelPacket *) NULL) { status=MagickFalse; continue; } indexes=GetCacheViewAuthenticIndexQueue(spread_view); pixel=bias; for (x=0; x < (ssize_t) spread_image->columns; x++) { PointInfo point; point.x=GetPseudoRandomValue(random_info[id]); point.y=GetPseudoRandomValue(random_info[id]); status=InterpolateMagickPixelPacket(image,image_view,image->interpolate, (double) x+width*(point.x-0.5),(double) y+width*(point.y-0.5),&pixel, exception); if (status == MagickFalse) break; SetPixelPacket(spread_image,&pixel,q,indexes+x); q++; } if (SyncCacheViewAuthenticPixels(spread_view,exception) == MagickFalse) status=MagickFalse; if (image->progress_monitor != (MagickProgressMonitor) NULL) { MagickBooleanType proceed; #if defined(MAGICKCORE_OPENMP_SUPPORT) #pragma omp atomic #endif progress++; proceed=SetImageProgress(image,SpreadImageTag,progress,image->rows); if (proceed == MagickFalse) status=MagickFalse; } } spread_view=DestroyCacheView(spread_view); image_view=DestroyCacheView(image_view); random_info=DestroyRandomInfoThreadSet(random_info); if (status == MagickFalse) spread_image=DestroyImage(spread_image); return(spread_image); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % U n s h a r p M a s k I m a g e % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % UnsharpMaskImage() sharpens one or more image channels. We convolve the % image with a Gaussian operator of the given radius and standard deviation % (sigma). For reasonable results, radius should be larger than sigma. Use a % radius of 0 and UnsharpMaskImage() selects a suitable radius for you. % % The format of the UnsharpMaskImage method is: % % Image *UnsharpMaskImage(const Image *image,const double radius, % const double sigma,const double amount,const double threshold, % ExceptionInfo *exception) % Image *UnsharpMaskImageChannel(const Image *image, % const ChannelType channel,const double radius,const double sigma, % const double gain,const double threshold,ExceptionInfo *exception) % % A description of each parameter follows: % % o image: the image. % % o channel: the channel type. % % o radius: the radius of the Gaussian, in pixels, not counting the center % pixel. % % o sigma: the standard deviation of the Gaussian, in pixels. % % o gain: the percentage of the difference between the original and the % blur image that is added back into the original. % % o threshold: the threshold in pixels needed to apply the diffence gain. % % o exception: return any errors or warnings in this structure. % */ MagickExport Image *UnsharpMaskImage(const Image *image,const double radius, const double sigma,const double gain,const double threshold, ExceptionInfo *exception) { Image *sharp_image; sharp_image=UnsharpMaskImageChannel(image,DefaultChannels,radius,sigma,gain, threshold,exception); return(sharp_image); } MagickExport Image *UnsharpMaskImageChannel(const Image *image, const ChannelType channel,const double radius,const double sigma, const double gain,const double threshold,ExceptionInfo *exception) { #define SharpenImageTag "Sharpen/Image" CacheView *image_view, *unsharp_view; Image *unsharp_image; MagickBooleanType status; MagickOffsetType progress; MagickPixelPacket bias; MagickRealType quantum_threshold; ssize_t y; assert(image != (const Image *) NULL); assert(image->signature == MagickCoreSignature); if (image->debug != MagickFalse) (void) LogMagickEvent(TraceEvent,GetMagickModule(),"%s",image->filename); assert(exception != (ExceptionInfo *) NULL); #if defined(MAGICKCORE_OPENCL_SUPPORT) unsharp_image=AccelerateUnsharpMaskImage(image,channel,radius,sigma,gain, threshold,exception); if (unsharp_image != (Image *) NULL) return(unsharp_image); #endif unsharp_image=BlurImageChannel(image,(ChannelType) (channel &~ SyncChannels), radius,sigma,exception); if (unsharp_image == (Image *) NULL) return((Image *) NULL); quantum_threshold=(MagickRealType) QuantumRange*threshold; /* Unsharp-mask image. */ status=MagickTrue; progress=0; GetMagickPixelPacket(image,&bias); image_view=AcquireVirtualCacheView(image,exception); unsharp_view=AcquireAuthenticCacheView(unsharp_image,exception); #if defined(MAGICKCORE_OPENMP_SUPPORT) #pragma omp parallel for schedule(static) shared(progress,status) \ magick_number_threads(image,unsharp_image,image->rows,1) #endif for (y=0; y < (ssize_t) image->rows; y++) { DoublePixelPacket pixel; register const IndexPacket *magick_restrict indexes; register const PixelPacket *magick_restrict p; register IndexPacket *magick_restrict unsharp_indexes; register PixelPacket *magick_restrict q; register ssize_t x; if (status == MagickFalse) continue; p=GetCacheViewVirtualPixels(image_view,0,y,image->columns,1,exception); q=GetCacheViewAuthenticPixels(unsharp_view,0,y,unsharp_image->columns,1, exception); if ((p == (const PixelPacket *) NULL) || (q == (PixelPacket *) NULL)) { status=MagickFalse; continue; } indexes=GetCacheViewVirtualIndexQueue(image_view); unsharp_indexes=GetCacheViewAuthenticIndexQueue(unsharp_view); pixel.red=bias.red; pixel.green=bias.green; pixel.blue=bias.blue; pixel.opacity=bias.opacity; pixel.index=bias.index; for (x=0; x < (ssize_t) image->columns; x++) { if ((channel & RedChannel) != 0) { pixel.red=GetPixelRed(p)-(MagickRealType) GetPixelRed(q); if (fabs(2.0*pixel.red) < quantum_threshold) pixel.red=(MagickRealType) GetPixelRed(p); else pixel.red=(MagickRealType) GetPixelRed(p)+(pixel.red*gain); SetPixelRed(q,ClampToQuantum(pixel.red)); } if ((channel & GreenChannel) != 0) { pixel.green=GetPixelGreen(p)-(MagickRealType) q->green; if (fabs(2.0*pixel.green) < quantum_threshold) pixel.green=(MagickRealType) GetPixelGreen(p); else pixel.green=(MagickRealType) GetPixelGreen(p)+(pixel.green*gain); SetPixelGreen(q,ClampToQuantum(pixel.green)); } if ((channel & BlueChannel) != 0) { pixel.blue=GetPixelBlue(p)-(MagickRealType) q->blue; if (fabs(2.0*pixel.blue) < quantum_threshold) pixel.blue=(MagickRealType) GetPixelBlue(p); else pixel.blue=(MagickRealType) GetPixelBlue(p)+(pixel.blue*gain); SetPixelBlue(q,ClampToQuantum(pixel.blue)); } if ((channel & OpacityChannel) != 0) { pixel.opacity=GetPixelOpacity(p)-(MagickRealType) q->opacity; if (fabs(2.0*pixel.opacity) < quantum_threshold) pixel.opacity=(MagickRealType) GetPixelOpacity(p); else pixel.opacity=GetPixelOpacity(p)+(pixel.opacity*gain); SetPixelOpacity(q,ClampToQuantum(pixel.opacity)); } if (((channel & IndexChannel) != 0) && (image->colorspace == CMYKColorspace)) { pixel.index=GetPixelIndex(indexes+x)-(MagickRealType) GetPixelIndex(unsharp_indexes+x); if (fabs(2.0*pixel.index) < quantum_threshold) pixel.index=(MagickRealType) GetPixelIndex(indexes+x); else pixel.index=(MagickRealType) GetPixelIndex(indexes+x)+ (pixel.index*gain); SetPixelIndex(unsharp_indexes+x,ClampToQuantum(pixel.index)); } p++; q++; } if (SyncCacheViewAuthenticPixels(unsharp_view,exception) == MagickFalse) status=MagickFalse; if (image->progress_monitor != (MagickProgressMonitor) NULL) { MagickBooleanType proceed; #if defined(MAGICKCORE_OPENMP_SUPPORT) #pragma omp atomic #endif progress++; proceed=SetImageProgress(image,SharpenImageTag,progress,image->rows); if (proceed == MagickFalse) status=MagickFalse; } } unsharp_image->type=image->type; unsharp_view=DestroyCacheView(unsharp_view); image_view=DestroyCacheView(image_view); if (status == MagickFalse) unsharp_image=DestroyImage(unsharp_image); return(unsharp_image); }

fill_int2e.c

/* Copyright 2014-2018 The PySCF Developers. All Rights Reserved. Licensed under the Apache License, Version 2.0 (the "License"); you may not use this file except in compliance with the License. You may obtain a copy of the License at http://www.apache.org/licenses/LICENSE-2.0 Unless required by applicable law or agreed to in writing, software distributed under the License is distributed on an "AS IS" BASIS, WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. See the License for the specific language governing permissions and limitations under the License. * * Author: Qiming Sun <osirpt.sun@gmail.com> */ #include <stdlib.h> #include <math.h> #include "config.h" #include "cint.h" #define MAX(I,J) ((I) > (J) ? (I) : (J)) #define MIN(I,J) ((I) < (J) ? (I) : (J)) int GTOmax_shell_dim(int *ao_loc, int *shls_slice, int ncenter) { int i; int i0 = shls_slice[0]; int i1 = shls_slice[1]; int di = 0; for (i = 1; i < ncenter; i++) { i0 = MIN(i0, shls_slice[i*2 ]); i1 = MAX(i1, shls_slice[i*2+1]); } for (i = i0; i < i1; i++) { di = MAX(di, ao_loc[i+1]-ao_loc[i]); } return di; } int GTOmax_cache_size(int (*intor)(), int *shls_slice, int ncenter, int *atm, int natm, int *bas, int nbas, double *env) { int i, n; int i0 = shls_slice[0]; int i1 = shls_slice[1]; for (i = 1; i < ncenter; i++) { i0 = MIN(i0, shls_slice[i*2 ]); i1 = MAX(i1, shls_slice[i*2+1]); } int shls[4]; int cache_size = 0; for (i = i0; i < i1; i++) { shls[0] = i; shls[1] = i; shls[2] = i; shls[3] = i; n = (*intor)(NULL, NULL, shls, atm, natm, bas, nbas, env, NULL, NULL); cache_size = MAX(cache_size, n); } return cache_size; } /* ************************************************* * 2e AO integrals in s4, s2ij, s2kl, s1 */ void GTOnr2e_fill_s1(int (*intor)(), int (*fprescreen)(), double *eri, double *buf, int comp, int ishp, int jshp, int *shls_slice, int *ao_loc, CINTOpt *cintopt, int *atm, int natm, int *bas, int nbas, double *env) { int ish0 = shls_slice[0]; int ish1 = shls_slice[1]; int jsh0 = shls_slice[2]; int jsh1 = shls_slice[3]; int ksh0 = shls_slice[4]; int ksh1 = shls_slice[5]; int lsh0 = shls_slice[6]; int lsh1 = shls_slice[7]; int ni = ao_loc[ish1] - ao_loc[ish0]; int nj = ao_loc[jsh1] - ao_loc[jsh0]; int nk = ao_loc[ksh1] - ao_loc[ksh0]; int nl = ao_loc[lsh1] - ao_loc[lsh0]; size_t nij = ni * nj; size_t nkl = nk * nl; size_t neri = nij * nkl; int ish = ishp + ish0; int jsh = jshp + jsh0; int i0 = ao_loc[ish] - ao_loc[ish0]; int j0 = ao_loc[jsh] - ao_loc[jsh0]; eri += nkl * (i0 * nj + j0); int di = ao_loc[ish+1] - ao_loc[ish]; int dj = ao_loc[jsh+1] - ao_loc[jsh]; int dij = di * dj; int k0, l0, dk, dl, dijk, dijkl; int i, j, k, l, icomp; int ksh, lsh; int shls[4]; double *eri0, *peri, *buf0, *pbuf, *cache; shls[0] = ish; shls[1] = jsh; for (ksh = ksh0; ksh < ksh1; ksh++) { for (lsh = lsh0; lsh < lsh1; lsh++) { shls[2] = ksh; shls[3] = lsh; k0 = ao_loc[ksh] - ao_loc[ksh0]; l0 = ao_loc[lsh] - ao_loc[lsh0]; dk = ao_loc[ksh+1] - ao_loc[ksh]; dl = ao_loc[lsh+1] - ao_loc[lsh]; dijk = dij * dk; dijkl = dijk * dl; cache = buf + dijkl * comp; if ((*fprescreen)(shls, atm, bas, env) && (*intor)(buf, NULL, shls, atm, natm, bas, nbas, env, cintopt, cache)) { eri0 = eri + k0*nl+l0; buf0 = buf; for (icomp = 0; icomp < comp; icomp++) { for (i = 0; i < di; i++) { for (j = 0; j < dj; j++) { peri = eri0 + nkl*(i*nj+j); for (k = 0; k < dk; k++) { for (pbuf = buf0 + k*dij + j*di + i, l = 0; l < dl; l++) { peri[k*nl+l] = pbuf[l*dijk]; } } } } buf0 += dijkl; eri0 += neri; } } else { eri0 = eri + k0*nl+l0; for (icomp = 0; icomp < comp; icomp++) { for (i = 0; i < di; i++) { for (j = 0; j < dj; j++) { peri = eri0 + nkl*(i*nj+j); for (k = 0; k < dk; k++) { for (l = 0; l < dl; l++) { peri[k*nl+l] = 0; } } } } eri0 += neri; } } } } } void GTOnr2e_fill_s2ij(int (*intor)(), int (*fprescreen)(), double *eri, double *buf, int comp, int ishp, int jshp, int *shls_slice, int *ao_loc, CINTOpt *cintopt, int *atm, int natm, int *bas, int nbas, double *env) { if (ishp < jshp) { return; } int ish0 = shls_slice[0]; int ish1 = shls_slice[1]; int jsh0 = shls_slice[2]; //int jsh1 = shls_slice[3]; int ksh0 = shls_slice[4]; int ksh1 = shls_slice[5]; int lsh0 = shls_slice[6]; int lsh1 = shls_slice[7]; int ni = ao_loc[ish1] - ao_loc[ish0]; //int nj = ao_loc[jsh1] - ao_loc[jsh0]; int nk = ao_loc[ksh1] - ao_loc[ksh0]; int nl = ao_loc[lsh1] - ao_loc[lsh0]; size_t nij = ni * (ni+1) / 2; size_t nkl = nk * nl; size_t neri = nij * nkl; int ish = ishp + ish0; int jsh = jshp + jsh0; int i0 = ao_loc[ish] - ao_loc[ish0]; int j0 = ao_loc[jsh] - ao_loc[jsh0]; eri += nkl * (i0*(i0+1)/2 + j0); int di = ao_loc[ish+1] - ao_loc[ish]; int dj = ao_loc[jsh+1] - ao_loc[jsh]; int dij = di * dj; int k0, l0, dk, dl, dijk, dijkl; int i, j, k, l, icomp; int ksh, lsh; int shls[4]; double *eri0, *peri0, *peri, *buf0, *pbuf, *cache; shls[0] = ish; shls[1] = jsh; for (ksh = ksh0; ksh < ksh1; ksh++) { for (lsh = lsh0; lsh < lsh1; lsh++) { shls[2] = ksh; shls[3] = lsh; k0 = ao_loc[ksh] - ao_loc[ksh0]; l0 = ao_loc[lsh] - ao_loc[lsh0]; dk = ao_loc[ksh+1] - ao_loc[ksh]; dl = ao_loc[lsh+1] - ao_loc[lsh]; dijk = dij * dk; dijkl = dijk * dl; cache = buf + dijkl * comp; if ((*fprescreen)(shls, atm, bas, env) && (*intor)(buf, NULL, shls, atm, natm, bas, nbas, env, cintopt, cache)) { eri0 = eri + k0*nl+l0; buf0 = buf; for (icomp = 0; icomp < comp; icomp++) { peri0 = eri0; if (ishp > jshp) { for (i = 0; i < di; i++, peri0+=nkl*(i0+i)) { for (j = 0; j < dj; j++) { peri = peri0 + nkl*j; for (k = 0; k < dk; k++) { for (pbuf = buf0 + k*dij + j*di + i, l = 0; l < dl; l++) { peri[k*nl+l] = pbuf[l*dijk]; } } } } } else { for (i = 0; i < di; i++, peri0+=nkl*(i0+i)) { for (j = 0; j <= i; j++) { peri = peri0 + nkl*j; for (k = 0; k < dk; k++) { for (pbuf = buf0 + k*dij + j*di + i, l = 0; l < dl; l++) { peri[k*nl+l] = pbuf[l*dijk]; } } } } } buf0 += dijkl; eri0 += neri; } } else { eri0 = eri + k0*nl+l0; for (icomp = 0; icomp < comp; icomp++) { peri0 = eri0; if (ishp > jshp) { for (i = 0; i < di; i++, peri0+=nkl*(i0+i)) { for (j = 0; j < dj; j++) { peri = peri0 + nkl*j; for (k = 0; k < dk; k++) { for (l = 0; l < dl; l++) { peri[k*nl+l] = 0; } } } } } else { for (i = 0; i < di; i++, peri0+=nkl*(i0+i)) { for (j = 0; j <= i; j++) { peri = peri0 + nkl*j; for (k = 0; k < dk; k++) { for (l = 0; l < dl; l++) { peri[k*nl+l] = 0; } } } } } eri0 += neri; } } } } } void GTOnr2e_fill_s2kl(int (*intor)(), int (*fprescreen)(), double *eri, double *buf, int comp, int ishp, int jshp, int *shls_slice, int *ao_loc, CINTOpt *cintopt, int *atm, int natm, int *bas, int nbas, double *env) { int ish0 = shls_slice[0]; int ish1 = shls_slice[1]; int jsh0 = shls_slice[2]; int jsh1 = shls_slice[3]; int ksh0 = shls_slice[4]; int ksh1 = shls_slice[5]; int lsh0 = shls_slice[6]; //int lsh1 = shls_slice[7]; int ni = ao_loc[ish1] - ao_loc[ish0]; int nj = ao_loc[jsh1] - ao_loc[jsh0]; int nk = ao_loc[ksh1] - ao_loc[ksh0]; //int nl = ao_loc[lsh1] - ao_loc[lsh0]; size_t nij = ni * nj; size_t nkl = nk * (nk+1) / 2; size_t neri = nij * nkl; int ish = ishp + ish0; int jsh = jshp + jsh0; int i0 = ao_loc[ish] - ao_loc[ish0]; int j0 = ao_loc[jsh] - ao_loc[jsh0]; eri += nkl * (i0 * nj + j0); int di = ao_loc[ish+1] - ao_loc[ish]; int dj = ao_loc[jsh+1] - ao_loc[jsh]; int dij = di * dj; int k0, l0, dk, dl, dijk, dijkl; int i, j, k, l, icomp; int ksh, lsh, kshp, lshp; int shls[4]; double *eri0, *peri, *buf0, *pbuf, *cache; shls[0] = ish; shls[1] = jsh; for (kshp = 0; kshp < ksh1-ksh0; kshp++) { for (lshp = 0; lshp <= kshp; lshp++) { ksh = kshp + ksh0; lsh = lshp + lsh0; shls[2] = ksh; shls[3] = lsh; k0 = ao_loc[ksh] - ao_loc[ksh0]; l0 = ao_loc[lsh] - ao_loc[lsh0]; dk = ao_loc[ksh+1] - ao_loc[ksh]; dl = ao_loc[lsh+1] - ao_loc[lsh]; dijk = dij * dk; dijkl = dijk * dl; cache = buf + dijkl * comp; if ((*fprescreen)(shls, atm, bas, env) && (*intor)(buf, NULL, shls, atm, natm, bas, nbas, env, cintopt, cache)) { eri0 = eri + k0*(k0+1)/2+l0; buf0 = buf; for (icomp = 0; icomp < comp; icomp++) { if (kshp > lshp) { for (i = 0; i < di; i++) { for (j = 0; j < dj; j++) { peri = eri0 + nkl*(i*nj+j); for (k = 0; k < dk; k++, peri+=k0+k) { for (pbuf = buf0 + k*dij + j*di + i, l = 0; l < dl; l++) { peri[l] = pbuf[l*dijk]; } } } } } else { for (i = 0; i < di; i++) { for (j = 0; j < dj; j++) { peri = eri0 + nkl*(i*nj+j); for (k = 0; k < dk; k++, peri+=k0+k) { for (pbuf = buf0 + k*dij + j*di + i, l = 0; l <= k; l++) { peri[l] = pbuf[l*dijk]; } } } } } buf0 += dijkl; eri0 += neri; } } else { eri0 = eri + k0*(k0+1)/2+l0; for (icomp = 0; icomp < comp; icomp++) { if (kshp > lshp) { for (i = 0; i < di; i++) { for (j = 0; j < dj; j++) { peri = eri0 + nkl*(i*nj+j); for (k = 0; k < dk; k++, peri+=k0+k) { for (l = 0; l < dl; l++) { peri[l] = 0; } } } } } else { for (i = 0; i < di; i++) { for (j = 0; j < dj; j++) { peri = eri0 + nkl*(i*nj+j); for (k = 0; k < dk; k++, peri+=k0+k) { for (l = 0; l <= k; l++) { peri[l] = 0; } } } } } eri0 += neri; } } } } } void GTOnr2e_fill_s4(int (*intor)(), int (*fprescreen)(), double *eri, double *buf, int comp, int ishp, int jshp, int *shls_slice, int *ao_loc, CINTOpt *cintopt, int *atm, int natm, int *bas, int nbas, double *env) { if (ishp < jshp) { return; } int ish0 = shls_slice[0]; int ish1 = shls_slice[1]; int jsh0 = shls_slice[2]; //int jsh1 = shls_slice[3]; int ksh0 = shls_slice[4]; int ksh1 = shls_slice[5]; int lsh0 = shls_slice[6]; //int lsh1 = shls_slice[7]; int ni = ao_loc[ish1] - ao_loc[ish0]; //int nj = ao_loc[jsh1] - ao_loc[jsh0]; int nk = ao_loc[ksh1] - ao_loc[ksh0]; //int nl = ao_loc[lsh1] - ao_loc[lsh0]; size_t nij = ni * (ni+1) / 2; size_t nkl = nk * (nk+1) / 2; size_t neri = nij * nkl; int ish = ishp + ish0; int jsh = jshp + jsh0; int i0 = ao_loc[ish] - ao_loc[ish0]; int j0 = ao_loc[jsh] - ao_loc[jsh0]; eri += nkl * (i0*(i0+1)/2 + j0); int di = ao_loc[ish+1] - ao_loc[ish]; int dj = ao_loc[jsh+1] - ao_loc[jsh]; int dij = di * dj; int k0, l0, dk, dl, dijk, dijkl; int i, j, k, l, icomp; int ksh, lsh, kshp, lshp; int shls[4]; double *eri0, *peri0, *peri, *buf0, *pbuf, *cache; shls[0] = ish; shls[1] = jsh; for (kshp = 0; kshp < ksh1-ksh0; kshp++) { for (lshp = 0; lshp <= kshp; lshp++) { ksh = kshp + ksh0; lsh = lshp + lsh0; shls[2] = ksh; shls[3] = lsh; k0 = ao_loc[ksh] - ao_loc[ksh0]; l0 = ao_loc[lsh] - ao_loc[lsh0]; dk = ao_loc[ksh+1] - ao_loc[ksh]; dl = ao_loc[lsh+1] - ao_loc[lsh]; dijk = dij * dk; dijkl = dijk * dl; cache = buf + dijkl * comp; if ((*fprescreen)(shls, atm, bas, env) && (*intor)(buf, NULL, shls, atm, natm, bas, nbas, env, cintopt, cache)) { eri0 = eri + k0*(k0+1)/2+l0; buf0 = buf; for (icomp = 0; icomp < comp; icomp++) { peri0 = eri0; if (kshp > lshp && ishp > jshp) { for (i = 0; i < di; i++, peri0+=nkl*(i0+i)) { for (j = 0; j < dj; j++) { peri = peri0 + nkl*j; for (k = 0; k < dk; k++, peri+=k0+k) { for (pbuf = buf0 + k*dij + j*di + i, l = 0; l < dl; l++) { peri[l] = pbuf[l*dijk]; } } } } } else if (ish > jsh) { for (i = 0; i < di; i++, peri0+=nkl*(i0+i)) { for (j = 0; j < dj; j++) { peri = peri0 + nkl*j; for (k = 0; k < dk; k++, peri+=k0+k) { for (pbuf = buf0 + k*dij + j*di + i, l = 0; l <= k; l++) { peri[l] = pbuf[l*dijk]; } } } } } else if (ksh > lsh) { for (i = 0; i < di; i++, peri0+=nkl*(i0+i)) { for (j = 0; j <= i; j++) { peri = peri0 + nkl*j; for (k = 0; k < dk; k++, peri+=k0+k) { for (pbuf = buf0 + k*dij + j*di + i, l = 0; l < dl; l++) { peri[l] = pbuf[l*dijk]; } } } } } else { for (i = 0; i < di; i++, peri0+=nkl*(i0+i)) { for (j = 0; j <= i; j++) { peri = peri0 + nkl*j; for (k = 0; k < dk; k++, peri+=k0+k) { for (pbuf = buf0 + k*dij + j*di + i, l = 0; l <= k; l++) { peri[l] = pbuf[l*dijk]; } } } } } buf0 += dijkl; eri0 += neri; } } else { eri0 = eri + k0*(k0+1)/2+l0; buf0 = buf; for (icomp = 0; icomp < comp; icomp++) { peri0 = eri0; if (kshp > lshp && ishp > jshp) { for (i = 0; i < di; i++, peri0+=nkl*(i0+i)) { for (j = 0; j < dj; j++) { peri = peri0 + nkl*j; for (k = 0; k < dk; k++, peri+=k0+k) { for (l = 0; l < dl; l++) { peri[l] = 0; } } } } } else if (ish > jsh) { for (i = 0; i < di; i++, peri0+=nkl*(i0+i)) { for (j = 0; j < dj; j++) { peri = peri0 + nkl*j; for (k = 0; k < dk; k++, peri+=k0+k) { for (l = 0; l <= k; l++) { peri[l] = 0; } } } } } else if (ksh > lsh) { for (i = 0; i < di; i++, peri0+=nkl*(i0+i)) { for (j = 0; j <= i; j++) { peri = peri0 + nkl*j; for (k = 0; k < dk; k++, peri+=k0+k) { for (l = 0; l < dl; l++) { peri[l] = 0; } } } } } else { for (i = 0; i < di; i++, peri0+=nkl*(i0+i)) { for (j = 0; j <= i; j++) { peri = peri0 + nkl*j; for (k = 0; k < dk; k++, peri+=k0+k) { for (l = 0; l <= k; l++) { peri[l] = 0; } } } } } eri0 += neri; } } } } } static int no_prescreen() { return 1; } void GTOnr2e_fill_drv(int (*intor)(), void (*fill)(), int (*fprescreen)(), double *eri, int comp, int *shls_slice, int *ao_loc, CINTOpt *cintopt, int *atm, int natm, int *bas, int nbas, double *env) { if (fprescreen == NULL) { fprescreen = no_prescreen; } const int ish0 = shls_slice[0]; const int ish1 = shls_slice[1]; const int jsh0 = shls_slice[2]; const int jsh1 = shls_slice[3]; const int nish = ish1 - ish0; const int njsh = jsh1 - jsh0; const int di = GTOmax_shell_dim(ao_loc, shls_slice, 4); const int cache_size = GTOmax_cache_size(intor, shls_slice, 4, atm, natm, bas, nbas, env); #pragma omp parallel { int ij, i, j; double *buf = malloc(sizeof(double) * (di*di*di*di*comp + cache_size)); #pragma omp for nowait schedule(dynamic) for (ij = 0; ij < nish*njsh; ij++) { i = ij / njsh; j = ij % njsh; (*fill)(intor, fprescreen, eri, buf, comp, i, j, shls_slice, ao_loc, cintopt, atm, natm, bas, nbas, env); } free(buf); } }

Data.h

/***************************************************************************** * * Copyright (c) 2003-2020 by The University of Queensland * http://www.uq.edu.au * * Primary Business: Queensland, Australia * Licensed under the Apache License, version 2.0 * http://www.apache.org/licenses/LICENSE-2.0 * * Development until 2012 by Earth Systems Science Computational Center (ESSCC) * Development 2012-2013 by School of Earth Sciences * Development from 2014-2017 by Centre for Geoscience Computing (GeoComp) * Development from 2019 by School of Earth and Environmental Sciences ** *****************************************************************************/ /** \file Data.h */ #ifndef __ESCRIPT_DATA_H__ #define __ESCRIPT_DATA_H__ #include "system_dep.h" #include "DataAbstract.h" #include "DataException.h" #include "DataTypes.h" #include "EsysMPI.h" #include "FunctionSpace.h" #include "DataVectorOps.h" #include <algorithm> #include <string> #include <sstream> #include <boost/python/object.hpp> #include <boost/python/tuple.hpp> #include <boost/math/special_functions/bessel.hpp> #ifndef ESCRIPT_MAX_DATA_RANK #define ESCRIPT_MAX_DATA_RANK 4 #endif namespace escript { // // Forward declaration for various implementations of Data. class DataConstant; class DataTagged; class DataExpanded; class DataLazy; /** \brief Data represents a collection of datapoints. Description: Internally, the datapoints are actually stored by a DataAbstract object. The specific instance of DataAbstract used may vary over the lifetime of the Data object. Some methods on this class return references (eg getShape()). These references should not be used after an operation which changes the underlying DataAbstract object. Doing so will lead to invalid memory access. This should not affect any methods exposed via boost::python. */ class ESCRIPT_DLL_API Data { public: /** Constructors. */ /** \brief Default constructor. Creates a DataEmpty object. */ Data(); /** \brief Copy constructor. WARNING: Only performs a shallow copy. */ Data(const Data& inData); /** \brief Constructor from another Data object. If "what" is different from the function space of inData the inData are tried to be interpolated to what, otherwise a shallow copy of inData is returned. */ Data(const Data& inData, const FunctionSpace& what); /** \brief Copy Data from an existing vector */ Data(const DataTypes::RealVectorType& value, const DataTypes::ShapeType& shape, const FunctionSpace& what, bool expanded); /** \brief Constructor which creates a Data with points having the specified shape. \param value - Input - Single real value applied to all Data. \param dataPointShape - Input - The shape of each data point. \param what - Input - A description of what this data represents. \param expanded - Input - Flag, if true fill the entire container with the given value. Otherwise a more efficient storage mechanism will be used. */ Data(DataTypes::real_t value, const DataTypes::ShapeType& dataPointShape, const FunctionSpace& what, bool expanded); /** \brief Constructor which creates a Data with points having the specified shape. \param value - Input - Single complex value applied to all Data. \param dataPointShape - Input - The shape of each data point. \param what - Input - A description of what this data represents. \param expanded - Input - Flag, if true fill the entire container with the given value. Otherwise a more efficient storage mechanism will be used. */ explicit Data(DataTypes::cplx_t value, const DataTypes::ShapeType& dataPointShape, const FunctionSpace& what, bool expanded); /** \brief Constructor which performs a deep copy of a region from another Data object. \param inData - Input - Input Data object. \param region - Input - Region to copy. */ Data(const Data& inData, const DataTypes::RegionType& region); /** \brief Constructor which copies data from a wrapped array. \param w - Input - Input data. \param what - Input - A description of what this data represents. \param expanded - Input - Flag, if true fill the entire container with the value. Otherwise a more efficient storage mechanism will be used. */ Data(const WrappedArray& w, const FunctionSpace& what, bool expanded); /** \brief Constructor which creates a DataConstant. Copies data from any object that can be treated like a python array/sequence. All other parameters are copied from other. \param value - Input - Input data. \param other - Input - contains all other parameters. */ Data(const boost::python::object& value, const Data& other); /** This constructor subsumes a number of previous python ones. Data(const boost::python::object& value, const FunctionSpace& what=FunctionSpace(), bool expanded=false); Data(DataTypes::real_t value, const boost::python::tuple& shape=boost::python::make_tuple(), const FunctionSpace& what=FunctionSpace(), bool expanded=false); and a new Data(cplx_t value, const boost::python::tuple& shape=boost::python::make_tuple(), const FunctionSpace& what=FunctionSpace(), bool expanded=false); */ Data(boost::python::object value, boost::python::object par1=boost::python::object(), boost::python::object par2=boost::python::object(), boost::python::object par3=boost::python::object()); /** \brief Create a Data using an existing DataAbstract. Warning: The new object assumes ownership of the pointer! Once you have passed the pointer, do not delete it. */ explicit Data(DataAbstract* underlyingdata); /** \brief Create a Data based on the supplied DataAbstract */ explicit Data(DataAbstract_ptr underlyingdata); /** \brief Destructor */ ~Data(); /** \brief Make this object a deep copy of "other". */ void copy(const Data& other); /** \brief Return a pointer to a deep copy of this object. */ Data copySelf() const; /** \brief produce a delayed evaluation version of this Data. */ Data delay(); /** \brief convert the current data into lazy data. */ void delaySelf(); /** Member access methods. */ /** \brief switches on update protection */ void setProtection(); /** \brief Returns true, if the data object is protected against update */ bool isProtected() const; /** \brief Return the value of a data point as a python tuple. */ const boost::python::object getValueOfDataPointAsTuple(int dataPointNo); /** \brief sets the values of a data-point from a python object on this process */ void setValueOfDataPointToPyObject(int dataPointNo, const boost::python::object& py_object); /** \brief sets the values of a data-point from a array-like object on this process */ void setValueOfDataPointToArray(int dataPointNo, const boost::python::object&); /** \brief sets the values of a data-point on this process */ void setValueOfDataPoint(int dataPointNo, const DataTypes::real_t); void setValueOfDataPointC(int dataPointNo, const DataTypes::cplx_t); /** \brief Return a data point across all processors as a python tuple. */ const boost::python::object getValueOfGlobalDataPointAsTuple(int procNo, int dataPointNo); /** \brief Set the value of a global data point */ void setTupleForGlobalDataPoint(int id, int proc, boost::python::object); /** \brief Return the tag number associated with the given data-point. */ int getTagNumber(int dpno); /** \brief Write the data as a string. For large amounts of data, a summary is printed. */ std::string toString() const; /** \brief Whatever the current Data type make this into a DataExpanded. */ void expand(); /** \brief If possible convert this Data to DataTagged. This will only allow Constant data to be converted to tagged. An attempt to convert Expanded data to tagged will throw an exception. */ void tag(); /** \brief If this data is lazy, then convert it to ready data. What type of ready data depends on the expression. For example, Constant+Tagged==Tagged. */ void resolve(); /** \brief returns return true if data contains NaN. \warning This is dependent on the ability to reliably detect NaNs on your compiler. See the nancheck function in LocalOps for details. */ bool hasNaN(); /** \brief replaces all NaN values with value */ void replaceNaN(DataTypes::real_t value); /** \brief replaces all NaN values with value */ void replaceNaN(DataTypes::cplx_t value); /** \brief replaces all NaN values with value */ void replaceNaNPython(boost::python::object obj); bool hasInf(); void replaceInf(DataTypes::real_t value); void replaceInf(DataTypes::cplx_t value); void replaceInfPython(boost::python::object obj); /** \brief Ensures data is ready for write access. This means that the data will be resolved if lazy and will be copied if shared with another Data object. \warning This method should only be called in single threaded sections of code. (It modifies m_data). Do not create any Data objects from this one between calling requireWrite and getSampleDataRW. Doing so might introduce additional sharing. */ void requireWrite(); /** \brief Return true if this Data is expanded. \note To determine if a sample will contain separate values for each datapoint. Use actsExpanded instead. */ bool isExpanded() const; /** \brief Return true if this Data is expanded or resolves to expanded. That is, if it has a separate value for each datapoint in the sample. */ bool actsExpanded() const; /** \brief Return true if this Data is tagged. */ bool isTagged() const; /** \brief Return true if this Data is constant. */ bool isConstant() const; /** \brief Return true if this Data is lazy. */ bool isLazy() const; /** \brief Return true if this data is ready. */ bool isReady() const; /** \brief Return true if this Data holds an instance of DataEmpty. This is _not_ the same as asking if the object contains datapoints. */ bool isEmpty() const; /** \brief True if components of this data are stored as complex */ bool isComplex() const; /** \brief Return the function space. */ inline const FunctionSpace& getFunctionSpace() const { return m_data->getFunctionSpace(); } /** \brief Returns the spatial locations of the data points. */ inline escript::Data getXFromFunctionSpace() const { // This is exposed to Python as [Data object].getX() return m_data->getFunctionSpace().getX(); } /** \brief Return the domain. */ inline // const AbstractDomain& const_Domain_ptr getDomain() const { return getFunctionSpace().getDomain(); } /** \brief Return the domain. TODO: For internal use only. This should be removed. */ inline // const AbstractDomain& Domain_ptr getDomainPython() const { return getFunctionSpace().getDomainPython(); } /** \brief Return the rank of the point data. */ inline unsigned int getDataPointRank() const { return m_data->getRank(); } /** \brief Return the number of data points */ inline int getNumDataPoints() const { return getNumSamples() * getNumDataPointsPerSample(); } /** \brief Return the number of samples. */ inline int getNumSamples() const { return m_data->getNumSamples(); } /** \brief Return the number of data points per sample. */ inline int getNumDataPointsPerSample() const { return m_data->getNumDPPSample(); } /** \brief Returns true if the number of data points per sample and the number of samples match the respective argument. DataEmpty always returns true. */ inline bool numSamplesEqual(int numDataPointsPerSample, int numSamples) const { return (isEmpty() || (numDataPointsPerSample==getNumDataPointsPerSample() && numSamples==getNumSamples())); } /** \brief Returns true if the shape matches the vector (dimensions[0],..., dimensions[rank-1]). DataEmpty always returns true. */ inline bool isDataPointShapeEqual(int rank, const int* dimensions) const { if (isEmpty()) return true; const DataTypes::ShapeType givenShape(&dimensions[0],&dimensions[rank]); return (getDataPointShape()==givenShape); } /** \brief Return the number of values in the shape for this object. */ int getNoValues() const { return m_data->getNoValues(); } /** \brief dumps the object into a netCDF file */ void dump(const std::string fileName) const; /** \brief returns the values of the object as a list of tuples (one for each datapoint). \param scalarastuple If true, scalar data will produce single valued tuples [(1,) (2,) ...] If false, the result is a list of scalars [1, 2, ...] */ const boost::python::object toListOfTuples(bool scalarastuple=true); /** \brief Return the sample data for the given sample no. Please do not use this unless you NEED to access samples individually \param sampleNo - Input - the given sample no. \return pointer to the sample data. */ const DataTypes::real_t* getSampleDataRO(DataTypes::RealVectorType::size_type sampleNo, DataTypes::real_t dummy=0) const; const DataTypes::cplx_t* getSampleDataRO(DataTypes::CplxVectorType::size_type sampleNo, DataTypes::cplx_t dummy) const; /** \brief Return the sample data for the given sample no. Please do not use this unless you NEED to access samples individually \param sampleNo - Input - the given sample no. \return pointer to the sample data. */ DataTypes::real_t* getSampleDataRW(DataTypes::RealVectorType::size_type sampleNo, DataTypes::real_t dummy=0); DataTypes::cplx_t* getSampleDataRW(DataTypes::RealVectorType::size_type sampleNo, DataTypes::cplx_t dummy); /** \brief Return a pointer to the beginning of the underlying data \warning please avoid using this method since it by-passes possible lazy improvements. May be removed without notice. \return pointer to the data. */ const DataTypes::real_t* getDataRO(DataTypes::real_t dummy=0) const; const DataTypes::cplx_t* getDataRO(DataTypes::cplx_t dummy) const; /** \brief Return the sample data for the given tag. If an attempt is made to access data that isn't tagged an exception will be thrown. \param tag - Input - the tag key. */ inline DataTypes::real_t* getSampleDataByTag(int tag, DataTypes::real_t dummy=0) { return m_data->getSampleDataByTag(tag, dummy); } inline DataTypes::cplx_t* getSampleDataByTag(int tag, DataTypes::cplx_t dummy) { return m_data->getSampleDataByTag(tag, dummy); } /** \brief Return a reference into the DataVector which points to the specified data point. \param sampleNo - Input - \param dataPointNo - Input - */ DataTypes::RealVectorType::const_reference getDataPointRO(int sampleNo, int dataPointNo); /** \brief Return a reference into the DataVector which points to the specified data point. \param sampleNo - Input - \param dataPointNo - Input - */ DataTypes::RealVectorType::reference getDataPointRW(int sampleNo, int dataPointNo); /** \brief Return the offset for the given sample and point within the sample */ inline DataTypes::RealVectorType::size_type getDataOffset(int sampleNo, int dataPointNo) { return m_data->getPointOffset(sampleNo,dataPointNo); } /** \brief Return a reference to the data point shape. */ inline const DataTypes::ShapeType& getDataPointShape() const { return m_data->getShape(); } /** \brief Return the data point shape as a tuple of integers. */ const boost::python::tuple getShapeTuple() const; /** \brief Returns the product of the data point shapes */ long getShapeProduct() const; /** \brief Return the size of the data point. It is the product of the data point shape dimensions. */ int getDataPointSize() const; /** \brief Return the number of doubles stored for this Data. */ DataTypes::RealVectorType::size_type getLength() const; /** \brief Return true if this object contains no samples. This is not the same as isEmpty() */ bool hasNoSamples() const { return m_data->getNumSamples()==0; } /** \brief Assign the given value to the tag assocciated with name. Implicitly converts this object to type DataTagged. Throws an exception if this object cannot be converted to a DataTagged object or name cannot be mapped onto a tag key. \param name - Input - name of tag. \param value - Input - Value to associate with given key. */ void setTaggedValueByName(std::string name, const boost::python::object& value); /** \brief Assign the given value to the tag. Implicitly converts this object to type DataTagged if it is constant. \param tagKey - Input - Integer key. \param value - Input - Value to associate with given key. ==>* */ void setTaggedValue(int tagKey, const boost::python::object& value); /** \brief Assign the given value to the tag. Implicitly converts this object to type DataTagged if it is constant. \param tagKey - Input - Integer key. \param pointshape - Input - The shape of the value parameter \param value - Input - Value to associate with given key. \param dataOffset - Input - Offset of the begining of the point within the value parameter */ void setTaggedValueFromCPP(int tagKey, const DataTypes::ShapeType& pointshape, const DataTypes::RealVectorType& value, int dataOffset=0); void setTaggedValueFromCPP(int tagKey, const DataTypes::ShapeType& pointshape, const DataTypes::CplxVectorType& value, int dataOffset=0); /** \brief Copy other Data object into this Data object where mask is positive. */ void copyWithMask(const Data& other, const Data& mask); /** Data object operation methods and operators. */ /** \brief set all values to zero * */ void setToZero(); /** \brief Interpolates this onto the given functionspace and returns the result as a Data object. * */ Data interpolate(const FunctionSpace& functionspace) const; Data interpolateFromTable3D(const WrappedArray& table, DataTypes::real_t Amin, DataTypes::real_t Astep, DataTypes::real_t undef, Data& B, DataTypes::real_t Bmin, DataTypes::real_t Bstep, Data& C, DataTypes::real_t Cmin, DataTypes::real_t Cstep, bool check_boundaries); Data interpolateFromTable2D(const WrappedArray& table, DataTypes::real_t Amin, DataTypes::real_t Astep, DataTypes::real_t undef, Data& B, DataTypes::real_t Bmin, DataTypes::real_t Bstep,bool check_boundaries); Data interpolateFromTable1D(const WrappedArray& table, DataTypes::real_t Amin, DataTypes::real_t Astep, DataTypes::real_t undef,bool check_boundaries); Data interpolateFromTable3DP(boost::python::object table, DataTypes::real_t Amin, DataTypes::real_t Astep, Data& B, DataTypes::real_t Bmin, DataTypes::real_t Bstep, Data& C, DataTypes::real_t Cmin, DataTypes::real_t Cstep, DataTypes::real_t undef,bool check_boundaries); Data interpolateFromTable2DP(boost::python::object table, DataTypes::real_t Amin, DataTypes::real_t Astep, Data& B, DataTypes::real_t Bmin, DataTypes::real_t Bstep, DataTypes::real_t undef,bool check_boundaries); Data interpolateFromTable1DP(boost::python::object table, DataTypes::real_t Amin, DataTypes::real_t Astep, DataTypes::real_t undef,bool check_boundaries); Data nonuniforminterp(boost::python::object in, boost::python::object out, bool check_boundaries); Data nonuniformslope(boost::python::object in, boost::python::object out, bool check_boundaries); /** \brief Calculates the gradient of the data at the data points of functionspace. If functionspace is not present the function space of Function(getDomain()) is used. * */ Data gradOn(const FunctionSpace& functionspace) const; Data grad() const; /** \brief Calculate the integral over the function space domain as a python tuple. */ boost::python::object integrateToTuple_const() const; /** \brief Calculate the integral over the function space domain as a python tuple. */ boost::python::object integrateToTuple(); /** \brief Returns 1./ Data object * */ Data oneOver() const; /** \brief Return a Data with a 1 for +ive values and a 0 for 0 or -ive values. * */ Data wherePositive() const; /** \brief Return a Data with a 1 for -ive values and a 0 for +ive or 0 values. * */ Data whereNegative() const; /** \brief Return a Data with a 1 for +ive or 0 values and a 0 for -ive values. * */ Data whereNonNegative() const; /** \brief Return a Data with a 1 for -ive or 0 values and a 0 for +ive values. * */ Data whereNonPositive() const; /** \brief Return a Data with a 1 for 0 values and a 0 for +ive or -ive values. * */ Data whereZero(DataTypes::real_t tol=0.0) const; /** \brief Return a Data with a 0 for 0 values and a 1 for +ive or -ive values. * */ Data whereNonZero(DataTypes::real_t tol=0.0) const; /** \brief Return the maximum absolute value of this Data object. The method is not const because lazy data needs to be expanded before Lsup can be computed. The _const form can be used when the Data object is const, however this will only work for Data which is not Lazy. For Data which contain no samples (or tagged Data for which no tags in use have a value) zero is returned. */ DataTypes::real_t Lsup(); DataTypes::real_t Lsup_const() const; /** \brief Return the maximum value of this Data object. The method is not const because lazy data needs to be expanded before sup can be computed. The _const form can be used when the Data object is const, however this will only work for Data which is not Lazy. For Data which contain no samples (or tagged Data for which no tags in use have a value) a large negative value is returned. */ DataTypes::real_t sup(); DataTypes::real_t sup_const() const; /** \brief Return the minimum value of this Data object. The method is not const because lazy data needs to be expanded before inf can be computed. The _const form can be used when the Data object is const, however this will only work for Data which is not Lazy. For Data which contain no samples (or tagged Data for which no tags in use have a value) a large positive value is returned. */ DataTypes::real_t inf(); DataTypes::real_t inf_const() const; /** \brief Return the absolute value of each data point of this Data object. * */ Data abs() const; /** \brief Return the phase/arg/angular-part of complex values. * */ Data phase() const; /** \brief Return the maximum value of each data point of this Data object. * */ Data maxval() const; /** \brief Return the minimum value of each data point of this Data object. * */ Data minval() const; /** \brief Return the (sample number, data-point number) of the data point with the minimum component value in this Data object. \note If you are working in python, please consider using Locator instead of manually manipulating process and point IDs. */ const boost::python::tuple minGlobalDataPoint() const; /** \brief Return the (sample number, data-point number) of the data point with the minimum component value in this Data object. \note If you are working in python, please consider using Locator instead of manually manipulating process and point IDs. */ const boost::python::tuple maxGlobalDataPoint() const; /** \brief Return the sign of each data point of this Data object. -1 for negative values, zero for zero values, 1 for positive values. * */ Data sign() const; /** \brief Return the symmetric part of a matrix which is half the matrix plus its transpose. * */ Data symmetric() const; /** \brief Return the antisymmetric part of a matrix which is half the matrix minus its transpose. * */ Data antisymmetric() const; /** \brief Return the hermitian part of a matrix which is half the matrix plus its adjoint. * */ Data hermitian() const; /** \brief Return the anti-hermitian part of a matrix which is half the matrix minus its hermitian. * */ Data antihermitian() const; /** \brief Return the trace of a matrix * */ Data trace(int axis_offset) const; /** \brief Transpose each data point of this Data object around the given axis. * */ Data transpose(int axis_offset) const; /** \brief Return the eigenvalues of the symmetric part at each data point of this Data object in increasing values. Currently this function is restricted to rank 2, square shape, and dimension 3. * */ Data eigenvalues() const; /** \brief Return the eigenvalues and corresponding eigenvcetors of the symmetric part at each data point of this Data object. the eigenvalues are ordered in increasing size where eigenvalues with relative difference less than tol are treated as equal. The eigenvectors are orthogonal, normalized and the sclaed such that the first non-zero entry is positive. Currently this function is restricted to rank 2, square shape, and dimension 3 * */ const boost::python::tuple eigenvalues_and_eigenvectors(const DataTypes::real_t tol=1.e-12) const; /** \brief swaps the components axis0 and axis1 * */ Data swapaxes(const int axis0, const int axis1) const; /** \brief Return the error function erf of each data point of this Data object. * */ Data erf() const; /** \brief For complex values return the conjugate values. For non-complex data return a copy */ Data conjugate() const; Data real() const; Data imag() const; /** \brief Return the sin of each data point of this Data object. * */ Data sin() const; /** \brief Return the cos of each data point of this Data object. * */ Data cos() const; /** \brief Bessel worker function. * */ Data bessel(int order, DataTypes::real_t (*besselfunc) (int,DataTypes::real_t) ); /** \brief Return the Bessel function of the first kind for each data point of this Data object. * */ Data besselFirstKind(int order); /** \brief Return the Bessel function of the second kind for each data point of this Data object. * */ Data besselSecondKind(int order); /** \brief Return the tan of each data point of this Data object. * */ Data tan() const; /** \brief Return the asin of each data point of this Data object. * */ Data asin() const; /** \brief Return the acos of each data point of this Data object. * */ Data acos() const; /** \brief Return the atan of each data point of this Data object. * */ Data atan() const; /** \brief Return the sinh of each data point of this Data object. * */ Data sinh() const; /** \brief Return the cosh of each data point of this Data object. * */ Data cosh() const; /** \brief Return the tanh of each data point of this Data object. * */ Data tanh() const; /** \brief Return the asinh of each data point of this Data object. * */ Data asinh() const; /** \brief Return the acosh of each data point of this Data object. * */ Data acosh() const; /** \brief Return the atanh of each data point of this Data object. * */ Data atanh() const; /** \brief Return the log to base 10 of each data point of this Data object. * */ Data log10() const; /** \brief Return the natural log of each data point of this Data object. * */ Data log() const; /** \brief Return the exponential function of each data point of this Data object. * */ Data exp() const; /** \brief Return the square root of each data point of this Data object. * */ Data sqrt() const; /** \brief Return the negation of each data point of this Data object. * */ Data neg() const; /** \brief Return the identity of each data point of this Data object. Simply returns this object unmodified. * */ Data pos() const; /** \brief Return the given power of each data point of this Data object. \param right Input - the power to raise the object to. * */ Data powD(const Data& right) const; /** \brief Return the given power of each data point of this boost python object. \param right Input - the power to raise the object to. * */ Data powO(const boost::python::object& right) const; /** \brief Return the given power of each data point of this boost python object. \param left Input - the bases * */ Data rpowO(const boost::python::object& left) const; /** \brief Overloaded operator += \param right - Input - The right hand side. * */ Data& operator+=(const Data& right); Data& operator+=(const boost::python::object& right); Data& operator=(const Data& other); /** \brief Overloaded operator -= \param right - Input - The right hand side. * */ Data& operator-=(const Data& right); Data& operator-=(const boost::python::object& right); /** \brief Overloaded operator *= \param right - Input - The right hand side. * */ Data& operator*=(const Data& right); Data& operator*=(const boost::python::object& right); /** \brief Overloaded operator /= \param right - Input - The right hand side. * */ Data& operator/=(const Data& right); Data& operator/=(const boost::python::object& right); /** \brief Newer style division operator for python */ Data truedivD(const Data& right); /** \brief Newer style division operator for python */ Data truedivO(const boost::python::object& right); /** \brief Newer style division operator for python */ Data rtruedivO(const boost::python::object& left); /** \brief wrapper for python add operation */ boost::python::object __add__(const boost::python::object& right); /** \brief wrapper for python subtract operation */ boost::python::object __sub__(const boost::python::object& right); /** \brief wrapper for python reverse subtract operation */ boost::python::object __rsub__(const boost::python::object& right); /** \brief wrapper for python multiply operation */ boost::python::object __mul__(const boost::python::object& right); /** \brief wrapper for python divide operation */ boost::python::object __div__(const boost::python::object& right); /** \brief wrapper for python reverse divide operation */ boost::python::object __rdiv__(const boost::python::object& right); /** \brief return inverse of matricies. */ Data matrixInverse() const; /** \brief Returns true if this can be interpolated to functionspace. */ bool probeInterpolation(const FunctionSpace& functionspace) const; /** Data object slicing methods. */ /** \brief Returns a slice from this Data object. /description Implements the [] get operator in python. Calls getSlice. \param key - Input - python slice tuple specifying slice to return. */ Data getItem(const boost::python::object& key) const; /** \brief Copies slice from value into this Data object. Implements the [] set operator in python. Calls setSlice. \param key - Input - python slice tuple specifying slice to copy from value. \param value - Input - Data object to copy from. */ void setItemD(const boost::python::object& key, const Data& value); void setItemO(const boost::python::object& key, const boost::python::object& value); // These following public methods should be treated as private. /** \brief Perform the given unary operation on every element of every data point in this Data object. */ template <class UnaryFunction> inline void unaryOp2(UnaryFunction operation); /** \brief Return a Data object containing the specified slice of this Data object. \param region - Input - Region to copy. * */ Data getSlice(const DataTypes::RegionType& region) const; /** \brief Copy the specified slice from the given value into this Data object. \param value - Input - Data to copy from. \param region - Input - Region to copy. * */ void setSlice(const Data& value, const DataTypes::RegionType& region); /** \brief print the data values to stdout. Used for debugging */ void print(void); /** \brief return the MPI rank number of the local data MPI_COMM_WORLD is assumed and the result of MPI_Comm_size() is returned */ int get_MPIRank(void) const; /** \brief return the MPI rank number of the local data MPI_COMM_WORLD is assumed and the result of MPI_Comm_rank() is returned */ int get_MPISize(void) const; /** \brief return the MPI rank number of the local data MPI_COMM_WORLD is assumed and returned. */ MPI_Comm get_MPIComm(void) const; /** \brief return the object produced by the factory, which is a DataConstant or DataExpanded TODO Ownership of this object should be explained in doco. */ DataAbstract* borrowData(void) const; DataAbstract_ptr borrowDataPtr(void) const; DataReady_ptr borrowReadyPtr(void) const; /** \brief Return a pointer to the beginning of the datapoint at the specified offset. TODO Eventually these should be inlined. \param i - position(offset) in the underlying datastructure */ DataTypes::RealVectorType::const_reference getDataAtOffsetRO(DataTypes::RealVectorType::size_type i, DataTypes::real_t dummy); DataTypes::RealVectorType::reference getDataAtOffsetRW(DataTypes::RealVectorType::size_type i, DataTypes::real_t dummy); DataTypes::CplxVectorType::const_reference getDataAtOffsetRO(DataTypes::CplxVectorType::size_type i, DataTypes::cplx_t dummy); DataTypes::CplxVectorType::reference getDataAtOffsetRW(DataTypes::CplxVectorType::size_type i, DataTypes::cplx_t dummy); /** \brief Ensures that the Data is expanded and returns its underlying vector Does not check for exclusive write so do that before calling if sharing Is a posibility. \warning For domain implementors only. Using this function will avoid using optimisations like lazy evaluation. It is intended to allow quick initialisation of Data by domain; not as a bypass around escript's other mechanisms. */ DataTypes::RealVectorType& getExpandedVectorReference(DataTypes::real_t dummy=0); DataTypes::CplxVectorType& getExpandedVectorReference(DataTypes::cplx_t dummy); /** * \brief For tagged Data returns the number of tags with values. * For non-tagged data will return 0 (even Data which has been expanded from tagged). */ size_t getNumberOfTaggedValues() const; /* * \brief make the data complex */ void complicate(); protected: private: void init_from_data_and_fs(const Data& inData, const FunctionSpace& functionspace); template <typename S> void maskWorker(Data& other2, Data& mask2, S sentinel); template <class BinaryOp> DataTypes::real_t #ifdef ESYS_MPI lazyAlgWorker(DataTypes::real_t init, MPI_Op mpiop_type); #else lazyAlgWorker(DataTypes::real_t init); #endif DataTypes::real_t LsupWorker() const; DataTypes::real_t supWorker() const; DataTypes::real_t infWorker() const; template<typename Scalar> boost::python::object integrateWorker() const; void calc_minGlobalDataPoint(int& ProcNo, int& DataPointNo) const; void calc_maxGlobalDataPoint(int& ProcNo, int& DataPointNo) const; // For internal use in Data.cpp only! // other uses should call the main entry points and allow laziness Data minval_nonlazy() const; // For internal use in Data.cpp only! Data maxval_nonlazy() const; /** \brief Check *this and the right operand are compatible. Throws an exception if they aren't. \param right - Input - The right hand side. */ inline void operandCheck(const Data& right) const { return m_data->operandCheck(*(right.m_data.get())); } /** \brief Perform the specified reduction algorithm on every element of every data point in this Data object according to the given function and return the single value result. */ template <class BinaryFunction> inline DataTypes::real_t reduction(BinaryFunction operation, DataTypes::real_t initial_value) const; /** \brief Reduce each data-point in this Data object using the given operation. Return a Data object with the same number of data-points, but with each data-point containing only one value - the result of the reduction operation on the corresponding data-point in this Data object */ template <class BinaryFunction> inline Data dp_algorithm(BinaryFunction operation, DataTypes::real_t initial_value) const; /** \brief Convert the data type of the RHS to match this. \param right - Input - data type to match. */ void typeMatchLeft(Data& right) const; /** \brief Convert the data type of this to match the RHS. \param right - Input - data type to match. */ void typeMatchRight(const Data& right); /** \brief Construct a Data object of the appropriate type. */ void initialise(const DataTypes::RealVectorType& value, const DataTypes::ShapeType& shape, const FunctionSpace& what, bool expanded); void initialise(const DataTypes::CplxVectorType& value, const DataTypes::ShapeType& shape, const FunctionSpace& what, bool expanded); void initialise(const WrappedArray& value, const FunctionSpace& what, bool expanded); void initialise(const DataTypes::real_t value, const DataTypes::ShapeType& shape, const FunctionSpace& what, bool expanded); void initialise(const DataTypes::cplx_t value, const DataTypes::ShapeType& shape, const FunctionSpace& what, bool expanded); // // flag to protect the data object against any update bool m_protected; bool m_lazy; // // pointer to the actual data object // boost::shared_ptr<DataAbstract> m_data; DataAbstract_ptr m_data; // If possible please use getReadyPtr instead. // But see warning below. const DataReady* getReady() const { const DataReady* dr=dynamic_cast<const DataReady*>(m_data.get()); ESYS_ASSERT(dr!=0, "error casting to DataReady."); return dr; } DataReady* getReady() { DataReady* dr=dynamic_cast<DataReady*>(m_data.get()); ESYS_ASSERT(dr!=0, "error casting to DataReady."); return dr; } // Be wary of using this for local operations since it (temporarily) increases reference count. // If you are just using this to call a method on DataReady instead of DataAbstract consider using // getReady() instead DataReady_ptr getReadyPtr() { DataReady_ptr dr=REFCOUNTNS::dynamic_pointer_cast<DataReady>(m_data); ESYS_ASSERT(dr.get()!=0, "error casting to DataReady."); return dr; } const_DataReady_ptr getReadyPtr() const { const_DataReady_ptr dr=REFCOUNTNS::dynamic_pointer_cast<const DataReady>(m_data); ESYS_ASSERT(dr.get()!=0, "error casting to DataReady."); return dr; } // In the isShared() method below: // A problem would occur if m_data (the address pointed to) were being modified // while the call m_data->is_shared is being executed. // // Q: So why do I think this code can be thread safe/correct? // A: We need to make some assumptions. // 1. We assume it is acceptable to return true under some conditions when we aren't shared. // 2. We assume that no constructions or assignments which will share previously unshared // will occur while this call is executing. This is consistent with the way Data:: and C are written. // // This means that the only transition we need to consider, is when a previously shared object is // not shared anymore. ie. the other objects have been destroyed or a deep copy has been made. // In those cases the m_shared flag changes to false after m_data has completed changing. // For any threads executing before the flag switches they will assume the object is still shared. bool isShared() const { #ifdef SLOWSHARECHECK return m_data->isShared(); // single threadsafe check for this #else return !m_data.unique(); #endif } void forceResolve() { if (isLazy()) { #ifdef _OPENMP if (omp_in_parallel()) { // Yes this is throwing an exception out of an omp thread which is forbidden. throw DataException("Please do not call forceResolve() in a parallel region."); } #endif resolve(); } } /** \brief if another object is sharing out member data make a copy to work with instead. This code should only be called from single threaded sections of code. */ void exclusiveWrite() { #ifdef _OPENMP if (omp_in_parallel()) { throw DataException("Programming error. Please do not run exclusiveWrite() in multi-threaded sections."); } #endif forceResolve(); if (isShared()) { DataAbstract* t=m_data->deepCopy(); set_m_data(DataAbstract_ptr(t)); } #ifdef EXWRITECHK m_data->exclusivewritecalled=true; #endif } /** \brief checks if caller can have exclusive write to the object */ void checkExclusiveWrite() { if (isLazy() || isShared()) { std::ostringstream oss; oss << "Programming error. ExclusiveWrite required - please call requireWrite() isLazy=" << isLazy() << " isShared()=" << isShared(); throw DataException(oss.str()); } } /** \brief Modify the data abstract hosted by this Data object For internal use only. Passing a pointer to null is permitted (do this in the destructor) \warning Only to be called in single threaded code or inside a single/critical section. This method needs to be atomic. */ void set_m_data(DataAbstract_ptr p); void TensorSelfUpdateBinaryOperation(const Data& right, escript::ES_optype operation); friend class DataAbstract; // To allow calls to updateShareStatus friend class TestDomain; // so its getX will work quickly #ifdef IKNOWWHATIMDOING friend Data applyBinaryCFunction(boost::python::object cfunc, boost::python::tuple shape, escript::Data& d, escript::Data& e); #endif template <typename S> friend Data condEvalWorker(escript::Data& mask, escript::Data& trueval, escript::Data& falseval, S sentinel); friend ESCRIPT_DLL_API Data randomData(const boost::python::tuple& shape, const FunctionSpace& what, long seed, const boost::python::tuple& filter); }; #ifdef IKNOWWHATIMDOING Data applyBinaryCFunction(boost::python::object func, boost::python::tuple shape, escript::Data& d, escript::Data& e); #endif ESCRIPT_DLL_API Data condEval(escript::Data& mask, escript::Data& trueval, escript::Data& falseval); /** \brief Create a new Expanded Data object filled with pseudo-random data. */ ESCRIPT_DLL_API Data randomData(const boost::python::tuple& shape, const FunctionSpace& what, long seed, const boost::python::tuple& filter); } // end namespace escript // No, this is not supposed to be at the top of the file // DataAbstact needs to be declared first, then DataReady needs to be fully declared // so that I can dynamic cast between them below. #include "DataReady.h" #include "DataLazy.h" #include "DataExpanded.h" #include "DataConstant.h" #include "DataTagged.h" namespace escript { inline DataTypes::real_t* Data::getSampleDataRW(DataTypes::RealVectorType::size_type sampleNo, DataTypes::real_t dummy) { if (isLazy()) { throw DataException("Error, attempt to acquire RW access to lazy data. Please call requireWrite() first."); } #ifdef EXWRITECHK if (!getReady()->exclusivewritecalled) { throw DataException("Error, call to Data::getSampleDataRW without a preceeding call to requireWrite/exclusiveWrite."); } #endif return getReady()->getSampleDataRW(sampleNo, dummy); } inline DataTypes::cplx_t* Data::getSampleDataRW(DataTypes::CplxVectorType::size_type sampleNo, DataTypes::cplx_t dummy) { if (isLazy()) { throw DataException("Error, attempt to acquire RW access to lazy data. Please call requireWrite() first."); } #ifdef EXWRITECHK if (!getReady()->exclusivewritecalled) { throw DataException("Error, call to Data::getSampleDataRW without a preceeding call to requireWrite/exclusiveWrite."); } #endif return getReady()->getSampleDataRW(sampleNo, dummy); } inline const DataTypes::real_t* Data::getSampleDataRO(DataTypes::RealVectorType::size_type sampleNo,DataTypes::real_t dummy) const { DataLazy* l=dynamic_cast<DataLazy*>(m_data.get()); if (l!=0) { size_t offset=0; const DataTypes::RealVectorType* res=l->resolveSample(sampleNo,offset); return &((*res)[offset]); } return getReady()->getSampleDataRO(sampleNo, dummy); } inline const DataTypes::cplx_t* Data::getSampleDataRO(DataTypes::RealVectorType::size_type sampleNo, DataTypes::cplx_t dummy) const { DataLazy* l=dynamic_cast<DataLazy*>(m_data.get()); if (l!=0) { throw DataException("Programming error: complex lazy objects are not supported."); } return getReady()->getSampleDataRO(sampleNo, dummy); } inline const DataTypes::real_t* Data::getDataRO(DataTypes::real_t dummy) const { if (isLazy()) { throw DataException("Programmer error - getDataRO must not be called on Lazy Data."); } if (getNumSamples()==0) { return 0; } else { return &(getReady()->getTypedVectorRO(0)[0]); } } inline const DataTypes::cplx_t* Data::getDataRO(DataTypes::cplx_t dummy) const { if (isLazy()) { throw DataException("Programmer error - getDataRO must not be called on Lazy Data."); } if (getNumSamples()==0) { return 0; } else { return &(getReady()->getTypedVectorRO(dummy)[0]); } } /** Binary Data object operators. */ inline DataTypes::real_t rpow(DataTypes::real_t x,DataTypes::real_t y) { return pow(y,x); } /** \brief Operator+ Takes two Data objects. */ ESCRIPT_DLL_API Data operator+(const Data& left, const Data& right); /** \brief Operator- Takes two Data objects. */ ESCRIPT_DLL_API Data operator-(const Data& left, const Data& right); /** \brief Operator* Takes two Data objects. */ ESCRIPT_DLL_API Data operator*(const Data& left, const Data& right); /** \brief Operator/ Takes two Data objects. */ ESCRIPT_DLL_API Data operator/(const Data& left, const Data& right); /** \brief Operator+ Takes LHS Data object and RHS python::object. python::object must be convertable to Data type. */ ESCRIPT_DLL_API Data operator+(const Data& left, const boost::python::object& right); /** \brief Operator- Takes LHS Data object and RHS python::object. python::object must be convertable to Data type. */ ESCRIPT_DLL_API Data operator-(const Data& left, const boost::python::object& right); /** \brief Operator* Takes LHS Data object and RHS python::object. python::object must be convertable to Data type. */ ESCRIPT_DLL_API Data operator*(const Data& left, const boost::python::object& right); /** \brief Operator/ Takes LHS Data object and RHS python::object. python::object must be convertable to Data type. */ ESCRIPT_DLL_API Data operator/(const Data& left, const boost::python::object& right); /** \brief Operator+ Takes LHS python::object and RHS Data object. python::object must be convertable to Data type. */ ESCRIPT_DLL_API Data operator+(const boost::python::object& left, const Data& right); /** \brief Operator- Takes LHS python::object and RHS Data object. python::object must be convertable to Data type. */ ESCRIPT_DLL_API Data operator-(const boost::python::object& left, const Data& right); /** \brief Operator* Takes LHS python::object and RHS Data object. python::object must be convertable to Data type. */ ESCRIPT_DLL_API Data operator*(const boost::python::object& left, const Data& right); /** \brief Operator/ Takes LHS python::object and RHS Data object. python::object must be convertable to Data type. */ ESCRIPT_DLL_API Data operator/(const boost::python::object& left, const Data& right); /** \brief Output operator */ ESCRIPT_DLL_API std::ostream& operator<<(std::ostream& o, const Data& data); /** \brief Compute a tensor product of two Data objects \param arg_0 - Input - Data object \param arg_1 - Input - Data object \param axis_offset - Input - axis offset \param transpose - Input - 0: transpose neither, 1: transpose arg0, 2: transpose arg1 */ ESCRIPT_DLL_API Data C_GeneralTensorProduct(Data& arg_0, Data& arg_1, int axis_offset=0, int transpose=0); /** \brief Operator/ Takes RHS Data object. */ inline Data Data::truedivD(const Data& right) { return *this / right; } /** \brief Operator/ Takes RHS python::object. */ inline Data Data::truedivO(const boost::python::object& right) { Data tmp(right, getFunctionSpace(), false); return truedivD(tmp); } /** \brief Operator/ Takes LHS python::object. */ inline Data Data::rtruedivO(const boost::python::object& left) { Data tmp(left, getFunctionSpace(), false); return tmp.truedivD(*this); } /** \brief Perform the given Data object reduction algorithm on this and return the result. Given operation combines each element of each data point, thus argument object (*this) is a rank n Data object, and returned object is a scalar. Calls escript::algorithm. */ template <class BinaryFunction> inline DataTypes::real_t Data::reduction(BinaryFunction operation, DataTypes::real_t initial_value) const { if (isExpanded()) { DataExpanded* leftC=dynamic_cast<DataExpanded*>(m_data.get()); ESYS_ASSERT(leftC!=0, "Programming error - casting to DataExpanded."); DataExpanded& data=*leftC; int i,j; int numDPPSample=data.getNumDPPSample(); int numSamples=data.getNumSamples(); DataTypes::real_t global_current_value=initial_value; DataTypes::real_t local_current_value; const auto& vec=data.getTypedVectorRO(typename BinaryFunction::first_argument_type(0)); const DataTypes::ShapeType& shape=data.getShape(); // calculate the reduction operation value for each data point // reducing the result for each data-point into the current_value variables #pragma omp parallel private(local_current_value) { local_current_value=initial_value; #pragma omp for private(i,j) schedule(static) for (i=0;i<numSamples;i++) { for (j=0;j<numDPPSample;j++) { local_current_value=operation(local_current_value,escript::reductionOpVector(vec,shape,data.getPointOffset(i,j),operation,initial_value)); } } #pragma omp critical global_current_value=operation(global_current_value,local_current_value); } return global_current_value; } else if (isTagged()) { DataTagged* leftC=dynamic_cast<DataTagged*>(m_data.get()); ESYS_ASSERT(leftC!=0, "Programming error - casting to DataTagged."); DataTagged& data=*leftC; DataTypes::real_t current_value=initial_value; const auto& vec=data.getTypedVectorRO(typename BinaryFunction::first_argument_type(0)); const DataTypes::ShapeType& shape=data.getShape(); const DataTagged::DataMapType& lookup=data.getTagLookup(); const std::list<int> used=data.getFunctionSpace().getListOfTagsSTL(); for (std::list<int>::const_iterator i=used.begin();i!=used.end();++i) { int tag=*i; DataTagged::DataMapType::const_iterator it=lookup.find(tag); if ((tag==0) || (it==lookup.end())) // check for the default tag { current_value=operation(current_value,escript::reductionOpVector(vec,shape,data.getDefaultOffset(),operation,initial_value)); } else { current_value=operation(current_value,escript::reductionOpVector(vec,shape,it->second,operation,initial_value)); } } return current_value; } else if (isConstant()) { DataConstant* leftC=dynamic_cast<DataConstant*>(m_data.get()); ESYS_ASSERT(leftC!=0, "Programming error - casting to DataConstant."); return escript::reductionOpVector(leftC->getTypedVectorRO(typename BinaryFunction::first_argument_type(0)),leftC->getShape(),0,operation,initial_value); } else if (isEmpty()) { throw DataException("Error - Operations (algorithm) not permitted on instances of DataEmpty."); } else if (isLazy()) { throw DataException("Error - Operations not permitted on instances of DataLazy."); } else { throw DataException("Error - Data encapsulates an unknown type."); } } /** \brief Perform the given data point reduction algorithm on data and return the result. Given operation combines each element within each data point into a scalar, thus argument object is a rank n Data object, and returned object is a rank 0 Data object. Calls escript::dp_algorithm. */ template <class BinaryFunction> inline Data Data::dp_algorithm(BinaryFunction operation, DataTypes::real_t initial_value) const { if (isEmpty()) { throw DataException("Error - Operations (dp_algorithm) not permitted on instances of DataEmpty."); } else if (isExpanded()) { Data result(0,DataTypes::ShapeType(),getFunctionSpace(),isExpanded()); DataExpanded* dataE=dynamic_cast<DataExpanded*>(m_data.get()); DataExpanded* resultE=dynamic_cast<DataExpanded*>(result.m_data.get()); ESYS_ASSERT(dataE!=0, "Programming error - casting data to DataExpanded."); ESYS_ASSERT(resultE!=0, "Programming error - casting result to DataExpanded."); int i,j; int numSamples=dataE->getNumSamples(); int numDPPSample=dataE->getNumDPPSample(); // DataArrayView dataView=data.getPointDataView(); // DataArrayView resultView=result.getPointDataView(); const auto& dataVec=dataE->getTypedVectorRO(initial_value); const DataTypes::ShapeType& shape=dataE->getShape(); auto& resultVec=resultE->getTypedVectorRW(initial_value); // perform the operation on each data-point and assign // this to the corresponding element in result #pragma omp parallel for private(i,j) schedule(static) for (i=0;i<numSamples;i++) { for (j=0;j<numDPPSample;j++) { resultVec[resultE->getPointOffset(i,j)] = escript::reductionOpVector(dataVec, shape, dataE->getPointOffset(i,j),operation,initial_value); } } //escript::dp_algorithm(*dataE,*resultE,operation,initial_value); return result; } else if (isTagged()) { DataTagged* dataT=dynamic_cast<DataTagged*>(m_data.get()); ESYS_ASSERT(dataT!=0, "Programming error - casting data to DataTagged."); DataTypes::RealVectorType defval(1); defval[0]=0; DataTagged* resultT=new DataTagged(getFunctionSpace(), DataTypes::scalarShape, defval, dataT); const DataTypes::ShapeType& shape=dataT->getShape(); const auto& vec=dataT->getTypedVectorRO(initial_value); const DataTagged::DataMapType& lookup=dataT->getTagLookup(); for (DataTagged::DataMapType::const_iterator i=lookup.begin(); i!=lookup.end(); i++) { resultT->getDataByTagRW(i->first,0) = escript::reductionOpVector(vec,shape,dataT->getOffsetForTag(i->first),operation,initial_value); } resultT->getTypedVectorRW(initial_value)[resultT->getDefaultOffset()] = escript::reductionOpVector(dataT->getTypedVectorRO(initial_value),dataT->getShape(),dataT->getDefaultOffset(),operation,initial_value); //escript::dp_algorithm(*dataT,*resultT,operation,initial_value); return Data(resultT); // note: the Data object now owns the resultT pointer } else if (isConstant()) { Data result(0,DataTypes::ShapeType(),getFunctionSpace(),isExpanded()); DataConstant* dataC=dynamic_cast<DataConstant*>(m_data.get()); DataConstant* resultC=dynamic_cast<DataConstant*>(result.m_data.get()); ESYS_ASSERT(dataC!=0, "Programming error - casting data to DataConstant."); ESYS_ASSERT(resultC!=0, "Programming error - casting result to DataConstant."); DataConstant& data=*dataC; resultC->getTypedVectorRW(initial_value)[0] = escript::reductionOpVector(data.getTypedVectorRO(initial_value),data.getShape(),0,operation,initial_value); //escript::dp_algorithm(*dataC,*resultC,operation,initial_value); return result; } else if (isLazy()) { throw DataException("Error - Operations not permitted on instances of DataLazy."); } else { throw DataException("Error - Data encapsulates an unknown type."); } } /** \brief Compute a tensor operation with two Data objects \param arg_0 - Input - Data object \param arg_1 - Input - Data object \param operation - Input - Binary op functor */ Data C_TensorBinaryOperation(Data const &arg_0, Data const &arg_1, ES_optype operation); Data C_TensorUnaryOperation(Data const &arg_0, escript::ES_optype operation, DataTypes::real_t tol=0); } // namespace escript #endif // __ESCRIPT_DATA_H__

sculpt.c

/* * $Id: sculpt.c 40597 2011-09-27 09:21:17Z nazgul $ * * ***** BEGIN GPL LICENSE BLOCK ***** * * This program is free software; you can redistribute it and/or * modify it under the terms of the GNU General Public License * as published by the Free Software Foundation; either version 2 * of the License, or (at your option) any later version. * * This program is distributed in the hope that it will be useful, * but WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the * GNU General Public License for more details. * * You should have received a copy of the GNU General Public License * along with this program; if not, write to the Free Software Foundation, * Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301, USA. * * The Original Code is Copyright (C) 2006 by Nicholas Bishop * All rights reserved. * * The Original Code is: all of this file. * * Contributor(s): Jason Wilkins, Tom Musgrove. * * ***** END GPL LICENSE BLOCK ***** * * Implements the Sculpt Mode tools * */ /** \file blender/editors/sculpt_paint/sculpt.c * \ingroup edsculpt */ #include "MEM_guardedalloc.h" #include "BLI_math.h" #include "BLI_blenlib.h" #include "BLI_utildefines.h" #include "BLI_dynstr.h" #include "BLI_ghash.h" #include "BLI_pbvh.h" #include "BLI_threads.h" #include "BLI_editVert.h" #include "BLI_rand.h" #include "DNA_meshdata_types.h" #include "DNA_node_types.h" #include "DNA_object_types.h" #include "DNA_scene_types.h" #include "DNA_brush_types.h" #include "BKE_brush.h" #include "BKE_cdderivedmesh.h" #include "BKE_context.h" #include "BKE_depsgraph.h" #include "BKE_key.h" #include "BKE_library.h" #include "BKE_mesh.h" #include "BKE_modifier.h" #include "BKE_multires.h" #include "BKE_paint.h" #include "BKE_report.h" #include "BKE_lattice.h" /* for armature_deform_verts */ #include "BKE_node.h" #include "BIF_glutil.h" #include "WM_api.h" #include "WM_types.h" #include "ED_sculpt.h" #include "ED_screen.h" #include "ED_view3d.h" #include "ED_util.h" /* for crazyspace correction */ #include "paint_intern.h" #include "sculpt_intern.h" #include "RNA_access.h" #include "RNA_define.h" #include "RE_render_ext.h" #include "GPU_buffers.h" #include <math.h> #include <stdlib.h> #include <string.h> #ifdef _OPENMP #include <omp.h> #endif void ED_sculpt_force_update(bContext *C) { Object *ob= CTX_data_active_object(C); if(ob && (ob->mode & OB_MODE_SCULPT)) multires_force_update(ob); } /* Sculpt mode handles multires differently from regular meshes, but only if it's the last modifier on the stack and it is not on the first level */ struct MultiresModifierData *sculpt_multires_active(Scene *scene, Object *ob) { Mesh *me= (Mesh*)ob->data; ModifierData *md; if(!CustomData_get_layer(&me->fdata, CD_MDISPS)) { /* multires can't work without displacement layer */ return NULL; } for(md= modifiers_getVirtualModifierList(ob); md; md= md->next) { if(md->type == eModifierType_Multires) { MultiresModifierData *mmd= (MultiresModifierData*)md; if(!modifier_isEnabled(scene, md, eModifierMode_Realtime)) continue; if(mmd->sculptlvl > 0) return mmd; else return NULL; } } return NULL; } /* Check if there are any active modifiers in stack (used for flushing updates at enter/exit sculpt mode) */ static int sculpt_has_active_modifiers(Scene *scene, Object *ob) { ModifierData *md; md= modifiers_getVirtualModifierList(ob); /* exception for shape keys because we can edit those */ for(; md; md= md->next) { if(modifier_isEnabled(scene, md, eModifierMode_Realtime)) return 1; } return 0; } /* Checks if there are any supported deformation modifiers active */ static int sculpt_modifiers_active(Scene *scene, Sculpt *sd, Object *ob) { ModifierData *md; Mesh *me= (Mesh*)ob->data; MultiresModifierData *mmd= sculpt_multires_active(scene, ob); if(mmd) return 0; /* non-locked shape keys could be handled in the same way as deformed mesh */ if((ob->shapeflag&OB_SHAPE_LOCK)==0 && me->key && ob->shapenr) return 1; md= modifiers_getVirtualModifierList(ob); /* exception for shape keys because we can edit those */ for(; md; md= md->next) { ModifierTypeInfo *mti = modifierType_getInfo(md->type); if(!modifier_isEnabled(scene, md, eModifierMode_Realtime)) continue; if(md->type==eModifierType_ShapeKey) continue; if(mti->type==eModifierTypeType_OnlyDeform) return 1; else if((sd->flags & SCULPT_ONLY_DEFORM)==0) return 1; } return 0; } typedef enum StrokeFlags { CLIP_X = 1, CLIP_Y = 2, CLIP_Z = 4 } StrokeFlags; /* Cache stroke properties. Used because RNA property lookup isn't particularly fast. For descriptions of these settings, check the operator properties. */ typedef struct StrokeCache { /* Invariants */ float initial_radius; float scale[3]; int flag; float clip_tolerance[3]; float initial_mouse[2]; /* Variants */ float radius; float radius_squared; //float traced_location[3]; float true_location[3]; float location[3]; float pen_flip; float invert; float pressure; float mouse[2]; float bstrength; float tex_mouse[2]; /* The rest is temporary storage that isn't saved as a property */ int first_time; /* Beginning of stroke may do some things special */ bglMats *mats; /* Clean this up! */ ViewContext *vc; Brush *brush; float (*face_norms)[3]; /* Copy of the mesh faces' normals */ float special_rotation; /* Texture rotation (radians) for anchored and rake modes */ int pixel_radius, previous_pixel_radius; float grab_delta[3], grab_delta_symmetry[3]; float old_grab_location[3], orig_grab_location[3]; int symmetry; /* Symmetry index between 0 and 7 bit combo 0 is Brush only; 1 is X mirror; 2 is Y mirror; 3 is XY; 4 is Z; 5 is XZ; 6 is YZ; 7 is XYZ */ int mirror_symmetry_pass; /* the symmetry pass we are currently on between 0 and 7*/ float true_view_normal[3]; float view_normal[3]; float last_area_normal[3]; float last_center[3]; int radial_symmetry_pass; float symm_rot_mat[4][4]; float symm_rot_mat_inv[4][4]; float last_rake[2]; /* Last location of updating rake rotation */ int original; float vertex_rotation; char saved_active_brush_name[24]; int alt_smooth; float plane_trim_squared; rcti previous_r; /* previous redraw rectangle */ } StrokeCache; /*** BVH Tree ***/ /* Get a screen-space rectangle of the modified area */ static int sculpt_get_redraw_rect(ARegion *ar, RegionView3D *rv3d, Object *ob, rcti *rect) { PBVH *pbvh= ob->sculpt->pbvh; float bb_min[3], bb_max[3], pmat[4][4]; int i, j, k; ED_view3d_ob_project_mat_get(rv3d, ob, pmat); if(!pbvh) return 0; BLI_pbvh_redraw_BB(pbvh, bb_min, bb_max); rect->xmin = rect->ymin = INT_MAX; rect->xmax = rect->ymax = INT_MIN; if(bb_min[0] > bb_max[0] || bb_min[1] > bb_max[1] || bb_min[2] > bb_max[2]) return 0; for(i = 0; i < 2; ++i) { for(j = 0; j < 2; ++j) { for(k = 0; k < 2; ++k) { float vec[3], proj[2]; vec[0] = i ? bb_min[0] : bb_max[0]; vec[1] = j ? bb_min[1] : bb_max[1]; vec[2] = k ? bb_min[2] : bb_max[2]; ED_view3d_project_float(ar, vec, proj, pmat); rect->xmin = MIN2(rect->xmin, proj[0]); rect->xmax = MAX2(rect->xmax, proj[0]); rect->ymin = MIN2(rect->ymin, proj[1]); rect->ymax = MAX2(rect->ymax, proj[1]); } } } if (rect->xmin < rect->xmax && rect->ymin < rect->ymax) { /* expand redraw rect with redraw rect from previous step to prevent partial-redraw issues caused by fast strokes. This is needed here (not in sculpt_flush_update) as it was before because redraw rectangle should be the same in both of optimized PBVH draw function and 3d view redraw (if not -- some mesh parts could disapper from screen (sergey) */ SculptSession *ss = ob->sculpt; if (ss->cache) { if (!BLI_rcti_is_empty(&ss->cache->previous_r)) BLI_union_rcti(rect, &ss->cache->previous_r); } return 1; } return 0; } void sculpt_get_redraw_planes(float planes[4][4], ARegion *ar, RegionView3D *rv3d, Object *ob) { PBVH *pbvh= ob->sculpt->pbvh; BoundBox bb; bglMats mats; rcti rect; memset(&bb, 0, sizeof(BoundBox)); view3d_get_transformation(ar, rv3d, ob, &mats); sculpt_get_redraw_rect(ar, rv3d,ob, &rect); #if 1 /* use some extra space just in case */ rect.xmin -= 2; rect.xmax += 2; rect.ymin -= 2; rect.ymax += 2; #else /* it was doing this before, allows to redraw a smaller part of the screen but also gives artifaces .. */ rect.xmin += 2; rect.xmax -= 2; rect.ymin += 2; rect.ymax -= 2; #endif ED_view3d_calc_clipping(&bb, planes, &mats, &rect); mul_m4_fl(planes, -1.0f); /* clear redraw flag from nodes */ if(pbvh) BLI_pbvh_update(pbvh, PBVH_UpdateRedraw, NULL); } /************************ Brush Testing *******************/ typedef struct SculptBrushTest { float radius_squared; float location[3]; float dist; } SculptBrushTest; static void sculpt_brush_test_init(SculptSession *ss, SculptBrushTest *test) { test->radius_squared= ss->cache->radius_squared; copy_v3_v3(test->location, ss->cache->location); test->dist= 0.0f; /* just for initialize */ } static int sculpt_brush_test(SculptBrushTest *test, float co[3]) { float distsq = len_squared_v3v3(co, test->location); if(distsq <= test->radius_squared) { test->dist = sqrt(distsq); return 1; } else { return 0; } } static int sculpt_brush_test_sq(SculptBrushTest *test, float co[3]) { float distsq = len_squared_v3v3(co, test->location); if(distsq <= test->radius_squared) { test->dist = distsq; return 1; } else { return 0; } } static int sculpt_brush_test_fast(SculptBrushTest *test, float co[3]) { return len_squared_v3v3(co, test->location) <= test->radius_squared; } static int sculpt_brush_test_cube(SculptBrushTest *test, float co[3], float local[4][4]) { static const float side = 0.70710678118654752440084436210485; // sqrt(.5); float local_co[3]; mul_v3_m4v3(local_co, local, co); local_co[0] = fabs(local_co[0]); local_co[1] = fabs(local_co[1]); local_co[2] = fabs(local_co[2]); if (local_co[0] <= side && local_co[1] <= side && local_co[2] <= side) { test->dist = MAX3(local_co[0], local_co[1], local_co[2]) / side; return 1; } else { return 0; } } static float frontface(Brush *brush, float sculpt_normal[3], short no[3], float fno[3]) { if (brush->flag & BRUSH_FRONTFACE) { float dot; if (no) { float tmp[3]; normal_short_to_float_v3(tmp, no); dot= dot_v3v3(tmp, sculpt_normal); } else { dot= dot_v3v3(fno, sculpt_normal); } return dot > 0 ? dot : 0; } else { return 1; } } #if 0 static int sculpt_brush_test_cyl(SculptBrushTest *test, float co[3], float location[3], float an[3]) { if (sculpt_brush_test_fast(test, co)) { float t1[3], t2[3], t3[3], dist; sub_v3_v3v3(t1, location, co); sub_v3_v3v3(t2, x2, location); cross_v3_v3v3(t3, an, t1); dist = len_v3(t3)/len_v3(t2); test->dist = dist; return 1; } return 0; } #endif /* ===== Sculpting ===== * */ static float overlapped_curve(Brush* br, float x) { int i; const int n = 100 / br->spacing; const float h = br->spacing / 50.0f; const float x0 = x-1; float sum; sum = 0; for (i= 0; i < n; i++) { float xx; xx = fabs(x0 + i*h); if (xx < 1.0f) sum += brush_curve_strength(br, xx, 1); } return sum; } static float integrate_overlap(Brush* br) { int i; int m= 10; float g = 1.0f/m; float max; max= 0; for(i= 0; i < m; i++) { float overlap= overlapped_curve(br, i*g); if (overlap > max) max = overlap; } return max; } /* Uses symm to selectively flip any axis of a coordinate. */ static void flip_coord(float out[3], float in[3], const char symm) { if(symm & SCULPT_SYMM_X) out[0]= -in[0]; else out[0]= in[0]; if(symm & SCULPT_SYMM_Y) out[1]= -in[1]; else out[1]= in[1]; if(symm & SCULPT_SYMM_Z) out[2]= -in[2]; else out[2]= in[2]; } static float calc_overlap(StrokeCache *cache, const char symm, const char axis, const float angle) { float mirror[3]; float distsq; //flip_coord(mirror, cache->traced_location, symm); flip_coord(mirror, cache->true_location, symm); if(axis != 0) { float mat[4][4]= MAT4_UNITY; rotate_m4(mat, axis, angle); mul_m4_v3(mat, mirror); } //distsq = len_squared_v3v3(mirror, cache->traced_location); distsq = len_squared_v3v3(mirror, cache->true_location); if (distsq <= 4.0f*(cache->radius_squared)) return (2.0f*(cache->radius) - sqrtf(distsq)) / (2.0f*(cache->radius)); else return 0; } static float calc_radial_symmetry_feather(Sculpt *sd, StrokeCache *cache, const char symm, const char axis) { int i; float overlap; overlap = 0; for(i = 1; i < sd->radial_symm[axis-'X']; ++i) { const float angle = 2*M_PI*i/sd->radial_symm[axis-'X']; overlap += calc_overlap(cache, symm, axis, angle); } return overlap; } static float calc_symmetry_feather(Sculpt *sd, StrokeCache* cache) { if (sd->flags & SCULPT_SYMMETRY_FEATHER) { float overlap; int symm = cache->symmetry; int i; overlap = 0; for (i = 0; i <= symm; i++) { if(i == 0 || (symm & i && (symm != 5 || i != 3) && (symm != 6 || (i != 3 && i != 5)))) { overlap += calc_overlap(cache, i, 0, 0); overlap += calc_radial_symmetry_feather(sd, cache, i, 'X'); overlap += calc_radial_symmetry_feather(sd, cache, i, 'Y'); overlap += calc_radial_symmetry_feather(sd, cache, i, 'Z'); } } return 1/overlap; } else { return 1; } } /* Return modified brush strength. Includes the direction of the brush, positive values pull vertices, negative values push. Uses tablet pressure and a special multiplier found experimentally to scale the strength factor. */ static float brush_strength(Sculpt *sd, StrokeCache *cache, float feather) { Brush *brush = paint_brush(&sd->paint); /* Primary strength input; square it to make lower values more sensitive */ const float root_alpha = brush_alpha(brush); float alpha = root_alpha*root_alpha; float dir = brush->flag & BRUSH_DIR_IN ? -1 : 1; float pressure = brush_use_alpha_pressure(brush) ? cache->pressure : 1; float pen_flip = cache->pen_flip ? -1 : 1; float invert = cache->invert ? -1 : 1; float accum = integrate_overlap(brush); float overlap = (brush->flag & BRUSH_SPACE_ATTEN && brush->flag & BRUSH_SPACE && !(brush->flag & BRUSH_ANCHORED)) && (brush->spacing < 100) ? 1.0f/accum : 1; // spacing is integer percentage of radius, divide by 50 to get normalized diameter float flip = dir * invert * pen_flip; switch(brush->sculpt_tool){ case SCULPT_TOOL_CLAY: case SCULPT_TOOL_CLAY_TUBES: case SCULPT_TOOL_DRAW: case SCULPT_TOOL_LAYER: return alpha * flip * pressure * overlap * feather; case SCULPT_TOOL_CREASE: case SCULPT_TOOL_BLOB: return alpha * flip * pressure * overlap * feather; case SCULPT_TOOL_INFLATE: if (flip > 0) { return 0.250f * alpha * flip * pressure * overlap * feather; } else { return 0.125f * alpha * flip * pressure * overlap * feather; } case SCULPT_TOOL_FILL: case SCULPT_TOOL_SCRAPE: case SCULPT_TOOL_FLATTEN: if (flip > 0) { overlap = (1+overlap) / 2; return alpha * flip * pressure * overlap * feather; } else { /* reduce strength for DEEPEN, PEAKS, and CONTRAST */ return 0.5f * alpha * flip * pressure * overlap * feather; } case SCULPT_TOOL_SMOOTH: return alpha * pressure * feather; case SCULPT_TOOL_PINCH: if (flip > 0) { return alpha * flip * pressure * overlap * feather; } else { return 0.25f * alpha * flip * pressure * overlap * feather; } case SCULPT_TOOL_NUDGE: overlap = (1+overlap) / 2; return alpha * pressure * overlap * feather; case SCULPT_TOOL_THUMB: return alpha*pressure*feather; case SCULPT_TOOL_SNAKE_HOOK: return feather; case SCULPT_TOOL_GRAB: case SCULPT_TOOL_ROTATE: return feather; default: return 0; } } /* Return a multiplier for brush strength on a particular vertex. */ static float tex_strength(SculptSession *ss, Brush *br, float *point, const float len) { MTex *mtex = &br->mtex; float avg= 1; if(!mtex->tex) { avg= 1; } else if(mtex->brush_map_mode == MTEX_MAP_MODE_3D) { float jnk; /* Get strength by feeding the vertex location directly into a texture */ externtex(mtex, point, &avg, &jnk, &jnk, &jnk, &jnk, 0); } else if(ss->texcache) { float rotation = -mtex->rot; float x, y, point_2d[3]; float radius; /* if the active area is being applied for symmetry, flip it across the symmetry axis and rotate it back to the orignal position in order to project it. This insures that the brush texture will be oriented correctly. */ flip_coord(point_2d, point, ss->cache->mirror_symmetry_pass); if (ss->cache->radial_symmetry_pass) mul_m4_v3(ss->cache->symm_rot_mat_inv, point_2d); projectf(ss->cache->mats, point_2d, point_2d); /* if fixed mode, keep coordinates relative to mouse */ if(mtex->brush_map_mode == MTEX_MAP_MODE_FIXED) { rotation += ss->cache->special_rotation; point_2d[0] -= ss->cache->tex_mouse[0]; point_2d[1] -= ss->cache->tex_mouse[1]; radius = ss->cache->pixel_radius; // use pressure adjusted size for fixed mode x = point_2d[0]; y = point_2d[1]; } else /* else (mtex->brush_map_mode == MTEX_MAP_MODE_TILED), leave the coordinates relative to the screen */ { radius = brush_size(br); // use unadjusted size for tiled mode x = point_2d[0] - ss->cache->vc->ar->winrct.xmin; y = point_2d[1] - ss->cache->vc->ar->winrct.ymin; } x /= ss->cache->vc->ar->winx; y /= ss->cache->vc->ar->winy; if (mtex->brush_map_mode == MTEX_MAP_MODE_TILED) { x -= 0.5f; y -= 0.5f; } x *= ss->cache->vc->ar->winx / radius; y *= ss->cache->vc->ar->winy / radius; /* it is probably worth optimizing for those cases where the texture is not rotated by skipping the calls to atan2, sqrtf, sin, and cos. */ if (rotation > 0.001f || rotation < -0.001f) { const float angle = atan2f(y, x) + rotation; const float flen = sqrtf(x*x + y*y); x = flen * cosf(angle); y = flen * sinf(angle); } x *= br->mtex.size[0]; y *= br->mtex.size[1]; x += br->mtex.ofs[0]; y += br->mtex.ofs[1]; avg = paint_get_tex_pixel(br, x, y); } avg += br->texture_sample_bias; avg *= brush_curve_strength(br, len, ss->cache->radius); /* Falloff curve */ return avg; } typedef struct { Sculpt *sd; SculptSession *ss; float radius_squared; int original; } SculptSearchSphereData; /* Test AABB against sphere */ static int sculpt_search_sphere_cb(PBVHNode *node, void *data_v) { SculptSearchSphereData *data = data_v; float *center = data->ss->cache->location, nearest[3]; float t[3], bb_min[3], bb_max[3]; int i; if(data->original) BLI_pbvh_node_get_original_BB(node, bb_min, bb_max); else BLI_pbvh_node_get_BB(node, bb_min, bb_max); for(i = 0; i < 3; ++i) { if(bb_min[i] > center[i]) nearest[i] = bb_min[i]; else if(bb_max[i] < center[i]) nearest[i] = bb_max[i]; else nearest[i] = center[i]; } sub_v3_v3v3(t, center, nearest); return dot_v3v3(t, t) < data->radius_squared; } /* Handles clipping against a mirror modifier and SCULPT_LOCK axis flags */ static void sculpt_clip(Sculpt *sd, SculptSession *ss, float *co, const float val[3]) { int i; for(i=0; i<3; ++i) { if(sd->flags & (SCULPT_LOCK_X << i)) continue; if((ss->cache->flag & (CLIP_X << i)) && (fabsf(co[i]) <= ss->cache->clip_tolerance[i])) co[i]= 0.0f; else co[i]= val[i]; } } static void add_norm_if(float view_vec[3], float out[3], float out_flip[3], float fno[3]) { if((dot_v3v3(view_vec, fno)) > 0) { add_v3_v3(out, fno); } else { add_v3_v3(out_flip, fno); /* out_flip is used when out is {0,0,0} */ } } static void calc_area_normal(Sculpt *sd, Object *ob, float an[3], PBVHNode **nodes, int totnode) { SculptSession *ss = ob->sculpt; int n; float out_flip[3] = {0.0f, 0.0f, 0.0f}; (void)sd; /* unused w/o openmp */ zero_v3(an); #pragma omp parallel for schedule(guided) if (sd->flags & SCULPT_USE_OPENMP) for(n=0; n<totnode; n++) { PBVHVertexIter vd; SculptBrushTest test; SculptUndoNode *unode; float private_an[3] = {0.0f, 0.0f, 0.0f}; float private_out_flip[3] = {0.0f, 0.0f, 0.0f}; unode = sculpt_undo_push_node(ob, nodes[n]); sculpt_brush_test_init(ss, &test); if(ss->cache->original) { BLI_pbvh_vertex_iter_begin(ss->pbvh, nodes[n], vd, PBVH_ITER_UNIQUE) { if(sculpt_brush_test_fast(&test, unode->co[vd.i])) { float fno[3]; normal_short_to_float_v3(fno, unode->no[vd.i]); add_norm_if(ss->cache->view_normal, private_an, private_out_flip, fno); } } BLI_pbvh_vertex_iter_end; } else { BLI_pbvh_vertex_iter_begin(ss->pbvh, nodes[n], vd, PBVH_ITER_UNIQUE) { if(sculpt_brush_test_fast(&test, vd.co)) { if(vd.no) { float fno[3]; normal_short_to_float_v3(fno, vd.no); add_norm_if(ss->cache->view_normal, private_an, private_out_flip, fno); } else { add_norm_if(ss->cache->view_normal, private_an, private_out_flip, vd.fno); } } } BLI_pbvh_vertex_iter_end; } #pragma omp critical { add_v3_v3(an, private_an); add_v3_v3(out_flip, private_out_flip); } } if (is_zero_v3(an)) copy_v3_v3(an, out_flip); normalize_v3(an); } /* This initializes the faces to be moved for this sculpt for draw/layer/flatten; then it finds average normal for all active vertices - note that this is called once for each mirroring direction */ static void calc_sculpt_normal(Sculpt *sd, Object *ob, float an[3], PBVHNode **nodes, int totnode) { SculptSession *ss = ob->sculpt; Brush *brush = paint_brush(&sd->paint); if (ss->cache->mirror_symmetry_pass == 0 && ss->cache->radial_symmetry_pass == 0 && (ss->cache->first_time || !(brush->flag & BRUSH_ORIGINAL_NORMAL))) { switch (brush->sculpt_plane) { case SCULPT_DISP_DIR_VIEW: ED_view3d_global_to_vector(ss->cache->vc->rv3d, ss->cache->vc->rv3d->twmat[3], an); break; case SCULPT_DISP_DIR_X: an[1] = 0.0; an[2] = 0.0; an[0] = 1.0; break; case SCULPT_DISP_DIR_Y: an[0] = 0.0; an[2] = 0.0; an[1] = 1.0; break; case SCULPT_DISP_DIR_Z: an[0] = 0.0; an[1] = 0.0; an[2] = 1.0; break; case SCULPT_DISP_DIR_AREA: calc_area_normal(sd, ob, an, nodes, totnode); default: break; } copy_v3_v3(ss->cache->last_area_normal, an); } else { copy_v3_v3(an, ss->cache->last_area_normal); flip_coord(an, an, ss->cache->mirror_symmetry_pass); mul_m4_v3(ss->cache->symm_rot_mat, an); } } /* For the smooth brush, uses the neighboring vertices around vert to calculate a smoothed location for vert. Skips corner vertices (used by only one polygon.) */ static void neighbor_average(SculptSession *ss, float avg[3], const unsigned vert) { int i, skip= -1, total=0; IndexNode *node= ss->fmap[vert].first; char ncount= BLI_countlist(&ss->fmap[vert]); MFace *f; avg[0] = avg[1] = avg[2] = 0; /* Don't modify corner vertices */ if(ncount==1) { if(ss->deform_cos) copy_v3_v3(avg, ss->deform_cos[vert]); else copy_v3_v3(avg, ss->mvert[vert].co); return; } while(node){ f= &ss->mface[node->index]; if(f->v4) { skip= (f->v1==vert?2: f->v2==vert?3: f->v3==vert?0: f->v4==vert?1:-1); } for(i=0; i<(f->v4?4:3); ++i) { if(i != skip && (ncount!=2 || BLI_countlist(&ss->fmap[(&f->v1)[i]]) <= 2)) { if(ss->deform_cos) add_v3_v3(avg, ss->deform_cos[(&f->v1)[i]]); else add_v3_v3(avg, ss->mvert[(&f->v1)[i]].co); ++total; } } node= node->next; } if(total>0) mul_v3_fl(avg, 1.0f / total); else { if(ss->deform_cos) copy_v3_v3(avg, ss->deform_cos[vert]); else copy_v3_v3(avg, ss->mvert[vert].co); } } static void do_mesh_smooth_brush(Sculpt *sd, SculptSession *ss, PBVHNode *node, float bstrength) { Brush *brush = paint_brush(&sd->paint); PBVHVertexIter vd; SculptBrushTest test; CLAMP(bstrength, 0.0f, 1.0f); sculpt_brush_test_init(ss, &test); BLI_pbvh_vertex_iter_begin(ss->pbvh, node, vd, PBVH_ITER_UNIQUE) { if(sculpt_brush_test(&test, vd.co)) { const float fade = bstrength*tex_strength(ss, brush, vd.co, test.dist)*frontface(brush, ss->cache->view_normal, vd.no, vd.fno); float avg[3], val[3]; neighbor_average(ss, avg, vd.vert_indices[vd.i]); sub_v3_v3v3(val, avg, vd.co); mul_v3_fl(val, fade); add_v3_v3(val, vd.co); sculpt_clip(sd, ss, vd.co, val); if(vd.mvert) vd.mvert->flag |= ME_VERT_PBVH_UPDATE; } } BLI_pbvh_vertex_iter_end; } static void do_multires_smooth_brush(Sculpt *sd, SculptSession *ss, PBVHNode *node, float bstrength) { Brush *brush = paint_brush(&sd->paint); SculptBrushTest test; DMGridData **griddata, *data; DMGridAdjacency *gridadj, *adj; float (*tmpgrid)[3], (*tmprow)[3]; int v1, v2, v3, v4; int *grid_indices, totgrid, gridsize, i, x, y; sculpt_brush_test_init(ss, &test); CLAMP(bstrength, 0.0f, 1.0f); BLI_pbvh_node_get_grids(ss->pbvh, node, &grid_indices, &totgrid, NULL, &gridsize, &griddata, &gridadj); #pragma omp critical { tmpgrid= MEM_mallocN(sizeof(float)*3*gridsize*gridsize, "tmpgrid"); tmprow= MEM_mallocN(sizeof(float)*3*gridsize, "tmprow"); } for(i = 0; i < totgrid; ++i) { data = griddata[grid_indices[i]]; adj = &gridadj[grid_indices[i]]; memset(tmpgrid, 0, sizeof(float)*3*gridsize*gridsize); for (y= 0; y < gridsize-1; y++) { float tmp[3]; v1 = y*gridsize; add_v3_v3v3(tmprow[0], data[v1].co, data[v1+gridsize].co); for (x= 0; x < gridsize-1; x++) { v1 = x + y*gridsize; v2 = v1 + 1; v3 = v1 + gridsize; v4 = v3 + 1; add_v3_v3v3(tmprow[x+1], data[v2].co, data[v4].co); add_v3_v3v3(tmp, tmprow[x+1], tmprow[x]); add_v3_v3(tmpgrid[v1], tmp); add_v3_v3(tmpgrid[v2], tmp); add_v3_v3(tmpgrid[v3], tmp); add_v3_v3(tmpgrid[v4], tmp); } } /* blend with existing coordinates */ for(y = 0; y < gridsize; ++y) { for(x = 0; x < gridsize; ++x) { float *co; float *fno; int index; if(x == 0 && adj->index[0] == -1) continue; if(x == gridsize - 1 && adj->index[2] == -1) continue; if(y == 0 && adj->index[3] == -1) continue; if(y == gridsize - 1 && adj->index[1] == -1) continue; index = x + y*gridsize; co= data[index].co; fno= data[index].no; if(sculpt_brush_test(&test, co)) { const float fade = bstrength*tex_strength(ss, brush, co, test.dist)*frontface(brush, ss->cache->view_normal, NULL, fno); float *avg, val[3]; float n; avg = tmpgrid[x + y*gridsize]; n = 1/16.0f; if(x == 0 || x == gridsize - 1) n *= 2; if(y == 0 || y == gridsize - 1) n *= 2; mul_v3_fl(avg, n); sub_v3_v3v3(val, avg, co); mul_v3_fl(val, fade); add_v3_v3(val, co); sculpt_clip(sd, ss, co, val); } } } } #pragma omp critical { MEM_freeN(tmpgrid); MEM_freeN(tmprow); } } static void smooth(Sculpt *sd, Object *ob, PBVHNode **nodes, int totnode, float bstrength) { SculptSession *ss = ob->sculpt; const int max_iterations = 4; const float fract = 1.0f/max_iterations; int iteration, n, count; float last; CLAMP(bstrength, 0, 1); count = (int)(bstrength*max_iterations); last = max_iterations*(bstrength - count*fract); for(iteration = 0; iteration <= count; ++iteration) { #pragma omp parallel for schedule(guided) if (sd->flags & SCULPT_USE_OPENMP) for(n=0; n<totnode; n++) { if(ss->multires) { do_multires_smooth_brush(sd, ss, nodes[n], iteration != count ? 1.0f : last); } else if(ss->fmap) do_mesh_smooth_brush(sd, ss, nodes[n], iteration != count ? 1.0f : last); } if(ss->multires) multires_stitch_grids(ob); } } static void do_smooth_brush(Sculpt *sd, Object *ob, PBVHNode **nodes, int totnode) { SculptSession *ss = ob->sculpt; smooth(sd, ob, nodes, totnode, ss->cache->bstrength); } static void do_draw_brush(Sculpt *sd, Object *ob, PBVHNode **nodes, int totnode) { SculptSession *ss = ob->sculpt; Brush *brush = paint_brush(&sd->paint); float offset[3], area_normal[3]; float bstrength= ss->cache->bstrength; int n; calc_sculpt_normal(sd, ob, area_normal, nodes, totnode); /* offset with as much as possible factored in already */ mul_v3_v3fl(offset, area_normal, ss->cache->radius); mul_v3_v3(offset, ss->cache->scale); mul_v3_fl(offset, bstrength); /* threaded loop over nodes */ #pragma omp parallel for schedule(guided) if (sd->flags & SCULPT_USE_OPENMP) for(n=0; n<totnode; n++) { PBVHVertexIter vd; SculptBrushTest test; float (*proxy)[3]; proxy= BLI_pbvh_node_add_proxy(ss->pbvh, nodes[n])->co; sculpt_brush_test_init(ss, &test); BLI_pbvh_vertex_iter_begin(ss->pbvh, nodes[n], vd, PBVH_ITER_UNIQUE) { if (sculpt_brush_test(&test, vd.co)) { //if(sculpt_brush_test_cyl(&test, vd.co, ss->cache->location, area_normal)) { /* offset vertex */ float fade = tex_strength(ss, brush, vd.co, test.dist)*frontface(brush, area_normal, vd.no, vd.fno); mul_v3_v3fl(proxy[vd.i], offset, fade); if(vd.mvert) vd.mvert->flag |= ME_VERT_PBVH_UPDATE; } } BLI_pbvh_vertex_iter_end; } } static void do_crease_brush(Sculpt *sd, Object *ob, PBVHNode **nodes, int totnode) { SculptSession *ss = ob->sculpt; Brush *brush = paint_brush(&sd->paint); float offset[3], area_normal[3]; float bstrength= ss->cache->bstrength; float flippedbstrength, crease_correction; int n; calc_sculpt_normal(sd, ob, area_normal, nodes, totnode); /* offset with as much as possible factored in already */ mul_v3_v3fl(offset, area_normal, ss->cache->radius); mul_v3_v3(offset, ss->cache->scale); mul_v3_fl(offset, bstrength); /* we divide out the squared alpha and multiply by the squared crease to give us the pinch strength */ if(brush_alpha(brush) > 0.0f) crease_correction = brush->crease_pinch_factor*brush->crease_pinch_factor/(brush_alpha(brush)*brush_alpha(brush)); else crease_correction = brush->crease_pinch_factor*brush->crease_pinch_factor; /* we always want crease to pinch or blob to relax even when draw is negative */ flippedbstrength = (bstrength < 0) ? -crease_correction*bstrength : crease_correction*bstrength; if(brush->sculpt_tool == SCULPT_TOOL_BLOB) flippedbstrength *= -1.0f; /* threaded loop over nodes */ #pragma omp parallel for schedule(guided) if (sd->flags & SCULPT_USE_OPENMP) for(n=0; n<totnode; n++) { PBVHVertexIter vd; SculptBrushTest test; float (*proxy)[3]; proxy= BLI_pbvh_node_add_proxy(ss->pbvh, nodes[n])->co; sculpt_brush_test_init(ss, &test); BLI_pbvh_vertex_iter_begin(ss->pbvh, nodes[n], vd, PBVH_ITER_UNIQUE) { if(sculpt_brush_test(&test, vd.co)) { /* offset vertex */ const float fade = tex_strength(ss, brush, vd.co, test.dist)*frontface(brush, area_normal, vd.no, vd.fno); float val1[3]; float val2[3]; /* first we pinch */ sub_v3_v3v3(val1, test.location, vd.co); //mul_v3_v3(val1, ss->cache->scale); mul_v3_fl(val1, fade*flippedbstrength); /* then we draw */ mul_v3_v3fl(val2, offset, fade); add_v3_v3v3(proxy[vd.i], val1, val2); if(vd.mvert) vd.mvert->flag |= ME_VERT_PBVH_UPDATE; } } BLI_pbvh_vertex_iter_end; } } static void do_pinch_brush(Sculpt *sd, Object *ob, PBVHNode **nodes, int totnode) { SculptSession *ss = ob->sculpt; Brush *brush = paint_brush(&sd->paint); float bstrength= ss->cache->bstrength; int n; #pragma omp parallel for schedule(guided) if (sd->flags & SCULPT_USE_OPENMP) for(n=0; n<totnode; n++) { PBVHVertexIter vd; SculptBrushTest test; float (*proxy)[3]; proxy= BLI_pbvh_node_add_proxy(ss->pbvh, nodes[n])->co; sculpt_brush_test_init(ss, &test); BLI_pbvh_vertex_iter_begin(ss->pbvh, nodes[n], vd, PBVH_ITER_UNIQUE) { if(sculpt_brush_test(&test, vd.co)) { float fade = bstrength*tex_strength(ss, brush, vd.co, test.dist)*frontface(brush, ss->cache->view_normal, vd.no, vd.fno); float val[3]; sub_v3_v3v3(val, test.location, vd.co); mul_v3_v3fl(proxy[vd.i], val, fade); if(vd.mvert) vd.mvert->flag |= ME_VERT_PBVH_UPDATE; } } BLI_pbvh_vertex_iter_end; } } static void do_grab_brush(Sculpt *sd, Object *ob, PBVHNode **nodes, int totnode) { SculptSession *ss = ob->sculpt; Brush *brush= paint_brush(&sd->paint); float bstrength= ss->cache->bstrength; float grab_delta[3], an[3]; int n; float len; if (brush->normal_weight > 0 || brush->flag & BRUSH_FRONTFACE) { int cache= 1; /* grab brush requires to test on original data */ SWAP(int, ss->cache->original, cache); calc_sculpt_normal(sd, ob, an, nodes, totnode); SWAP(int, ss->cache->original, cache); } copy_v3_v3(grab_delta, ss->cache->grab_delta_symmetry); len = len_v3(grab_delta); if (brush->normal_weight > 0) { mul_v3_fl(an, len*brush->normal_weight); mul_v3_fl(grab_delta, 1.0f - brush->normal_weight); add_v3_v3(grab_delta, an); } #pragma omp parallel for schedule(guided) if (sd->flags & SCULPT_USE_OPENMP) for(n=0; n<totnode; n++) { PBVHVertexIter vd; SculptUndoNode* unode; SculptBrushTest test; float (*origco)[3]; short (*origno)[3]; float (*proxy)[3]; unode= sculpt_undo_push_node(ob, nodes[n]); origco= unode->co; origno= unode->no; proxy= BLI_pbvh_node_add_proxy(ss->pbvh, nodes[n])->co; sculpt_brush_test_init(ss, &test); BLI_pbvh_vertex_iter_begin(ss->pbvh, nodes[n], vd, PBVH_ITER_UNIQUE) { if(sculpt_brush_test(&test, origco[vd.i])) { const float fade = bstrength*tex_strength(ss, brush, origco[vd.i], test.dist)*frontface(brush, an, origno[vd.i], NULL); mul_v3_v3fl(proxy[vd.i], grab_delta, fade); if(vd.mvert) vd.mvert->flag |= ME_VERT_PBVH_UPDATE; } } BLI_pbvh_vertex_iter_end; } } static void do_nudge_brush(Sculpt *sd, Object *ob, PBVHNode **nodes, int totnode) { SculptSession *ss = ob->sculpt; Brush *brush = paint_brush(&sd->paint); float bstrength = ss->cache->bstrength; float grab_delta[3]; int n; float an[3]; float tmp[3], cono[3]; copy_v3_v3(grab_delta, ss->cache->grab_delta_symmetry); calc_sculpt_normal(sd, ob, an, nodes, totnode); cross_v3_v3v3(tmp, an, grab_delta); cross_v3_v3v3(cono, tmp, an); #pragma omp parallel for schedule(guided) if (sd->flags & SCULPT_USE_OPENMP) for(n = 0; n < totnode; n++) { PBVHVertexIter vd; SculptBrushTest test; float (*proxy)[3]; proxy= BLI_pbvh_node_add_proxy(ss->pbvh, nodes[n])->co; sculpt_brush_test_init(ss, &test); BLI_pbvh_vertex_iter_begin(ss->pbvh, nodes[n], vd, PBVH_ITER_UNIQUE) { if(sculpt_brush_test(&test, vd.co)) { const float fade = bstrength*tex_strength(ss, brush, vd.co, test.dist)*frontface(brush, an, vd.no, vd.fno); mul_v3_v3fl(proxy[vd.i], cono, fade); if(vd.mvert) vd.mvert->flag |= ME_VERT_PBVH_UPDATE; } } BLI_pbvh_vertex_iter_end; } } static void do_snake_hook_brush(Sculpt *sd, Object *ob, PBVHNode **nodes, int totnode) { SculptSession *ss = ob->sculpt; Brush *brush = paint_brush(&sd->paint); float bstrength = ss->cache->bstrength; float grab_delta[3], an[3]; int n; float len; if (brush->normal_weight > 0 || brush->flag & BRUSH_FRONTFACE) calc_sculpt_normal(sd, ob, an, nodes, totnode); copy_v3_v3(grab_delta, ss->cache->grab_delta_symmetry); len = len_v3(grab_delta); if (bstrength < 0) negate_v3(grab_delta); if (brush->normal_weight > 0) { mul_v3_fl(an, len*brush->normal_weight); mul_v3_fl(grab_delta, 1.0f - brush->normal_weight); add_v3_v3(grab_delta, an); } #pragma omp parallel for schedule(guided) if (sd->flags & SCULPT_USE_OPENMP) for(n = 0; n < totnode; n++) { PBVHVertexIter vd; SculptBrushTest test; float (*proxy)[3]; proxy= BLI_pbvh_node_add_proxy(ss->pbvh, nodes[n])->co; sculpt_brush_test_init(ss, &test); BLI_pbvh_vertex_iter_begin(ss->pbvh, nodes[n], vd, PBVH_ITER_UNIQUE) { if(sculpt_brush_test(&test, vd.co)) { const float fade = bstrength*tex_strength(ss, brush, vd.co, test.dist)*frontface(brush, an, vd.no, vd.fno); mul_v3_v3fl(proxy[vd.i], grab_delta, fade); if(vd.mvert) vd.mvert->flag |= ME_VERT_PBVH_UPDATE; } } BLI_pbvh_vertex_iter_end; } } static void do_thumb_brush(Sculpt *sd, Object *ob, PBVHNode **nodes, int totnode) { SculptSession *ss = ob->sculpt; Brush *brush = paint_brush(&sd->paint); float bstrength = ss->cache->bstrength; float grab_delta[3]; int n; float an[3]; float tmp[3], cono[3]; copy_v3_v3(grab_delta, ss->cache->grab_delta_symmetry); calc_sculpt_normal(sd, ob, an, nodes, totnode); cross_v3_v3v3(tmp, an, grab_delta); cross_v3_v3v3(cono, tmp, an); #pragma omp parallel for schedule(guided) if (sd->flags & SCULPT_USE_OPENMP) for(n = 0; n < totnode; n++) { PBVHVertexIter vd; SculptUndoNode* unode; SculptBrushTest test; float (*origco)[3]; short (*origno)[3]; float (*proxy)[3]; unode= sculpt_undo_push_node(ob, nodes[n]); origco= unode->co; origno= unode->no; proxy= BLI_pbvh_node_add_proxy(ss->pbvh, nodes[n])->co; sculpt_brush_test_init(ss, &test); BLI_pbvh_vertex_iter_begin(ss->pbvh, nodes[n], vd, PBVH_ITER_UNIQUE) { if(sculpt_brush_test(&test, origco[vd.i])) { const float fade = bstrength*tex_strength(ss, brush, origco[vd.i], test.dist)*frontface(brush, an, origno[vd.i], NULL); mul_v3_v3fl(proxy[vd.i], cono, fade); if(vd.mvert) vd.mvert->flag |= ME_VERT_PBVH_UPDATE; } } BLI_pbvh_vertex_iter_end; } } static void do_rotate_brush(Sculpt *sd, Object *ob, PBVHNode **nodes, int totnode) { SculptSession *ss = ob->sculpt; Brush *brush= paint_brush(&sd->paint); float bstrength= ss->cache->bstrength; float an[3]; int n; float m[3][3]; static const int flip[8] = { 1, -1, -1, 1, -1, 1, 1, -1 }; float angle = ss->cache->vertex_rotation * flip[ss->cache->mirror_symmetry_pass]; calc_sculpt_normal(sd, ob, an, nodes, totnode); axis_angle_to_mat3(m, an, angle); #pragma omp parallel for schedule(guided) if (sd->flags & SCULPT_USE_OPENMP) for(n=0; n<totnode; n++) { PBVHVertexIter vd; SculptUndoNode* unode; SculptBrushTest test; float (*origco)[3]; short (*origno)[3]; float (*proxy)[3]; unode= sculpt_undo_push_node(ob, nodes[n]); origco= unode->co; origno= unode->no; proxy= BLI_pbvh_node_add_proxy(ss->pbvh, nodes[n])->co; sculpt_brush_test_init(ss, &test); BLI_pbvh_vertex_iter_begin(ss->pbvh, nodes[n], vd, PBVH_ITER_UNIQUE) { if(sculpt_brush_test(&test, origco[vd.i])) { const float fade = bstrength*tex_strength(ss, brush, origco[vd.i], test.dist)*frontface(brush, an, origno[vd.i], NULL); mul_v3_m3v3(proxy[vd.i], m, origco[vd.i]); sub_v3_v3(proxy[vd.i], origco[vd.i]); mul_v3_fl(proxy[vd.i], fade); if(vd.mvert) vd.mvert->flag |= ME_VERT_PBVH_UPDATE; } } BLI_pbvh_vertex_iter_end; } } static void do_layer_brush(Sculpt *sd, Object *ob, PBVHNode **nodes, int totnode) { SculptSession *ss = ob->sculpt; Brush *brush = paint_brush(&sd->paint); float bstrength= ss->cache->bstrength; float area_normal[3], offset[3]; float lim= brush->height; int n; if(bstrength < 0) lim = -lim; calc_sculpt_normal(sd, ob, area_normal, nodes, totnode); mul_v3_v3v3(offset, ss->cache->scale, area_normal); #pragma omp parallel for schedule(guided) if (sd->flags & SCULPT_USE_OPENMP) for(n=0; n<totnode; n++) { PBVHVertexIter vd; SculptBrushTest test; SculptUndoNode *unode; float (*origco)[3], *layer_disp; //float (*proxy)[3]; // XXX layer brush needs conversion to proxy but its more complicated //proxy= BLI_pbvh_node_add_proxy(ss->pbvh, nodes[n])->co; unode= sculpt_undo_push_node(ob, nodes[n]); origco=unode->co; if(!unode->layer_disp) { #pragma omp critical unode->layer_disp= MEM_callocN(sizeof(float)*unode->totvert, "layer disp"); } layer_disp= unode->layer_disp; sculpt_brush_test_init(ss, &test); BLI_pbvh_vertex_iter_begin(ss->pbvh, nodes[n], vd, PBVH_ITER_UNIQUE) { if(sculpt_brush_test(&test, origco[vd.i])) { const float fade = bstrength*tex_strength(ss, brush, vd.co, test.dist)*frontface(brush, area_normal, vd.no, vd.fno); float *disp= &layer_disp[vd.i]; float val[3]; *disp+= fade; /* Don't let the displacement go past the limit */ if((lim < 0 && *disp < lim) || (lim >= 0 && *disp > lim)) *disp = lim; mul_v3_v3fl(val, offset, *disp); if(ss->layer_co && (brush->flag & BRUSH_PERSISTENT)) { int index= vd.vert_indices[vd.i]; /* persistent base */ add_v3_v3(val, ss->layer_co[index]); } else { add_v3_v3(val, origco[vd.i]); } sculpt_clip(sd, ss, vd.co, val); if(vd.mvert) vd.mvert->flag |= ME_VERT_PBVH_UPDATE; } } BLI_pbvh_vertex_iter_end; } } static void do_inflate_brush(Sculpt *sd, Object *ob, PBVHNode **nodes, int totnode) { SculptSession *ss = ob->sculpt; Brush *brush = paint_brush(&sd->paint); float bstrength= ss->cache->bstrength; int n; #pragma omp parallel for schedule(guided) if (sd->flags & SCULPT_USE_OPENMP) for(n=0; n<totnode; n++) { PBVHVertexIter vd; SculptBrushTest test; float (*proxy)[3]; proxy= BLI_pbvh_node_add_proxy(ss->pbvh, nodes[n])->co; sculpt_brush_test_init(ss, &test); BLI_pbvh_vertex_iter_begin(ss->pbvh, nodes[n], vd, PBVH_ITER_UNIQUE) { if(sculpt_brush_test(&test, vd.co)) { const float fade = bstrength*tex_strength(ss, brush, vd.co, test.dist)*frontface(brush, ss->cache->view_normal, vd.no, vd.fno); float val[3]; if(vd.fno) copy_v3_v3(val, vd.fno); else normal_short_to_float_v3(val, vd.no); mul_v3_fl(val, fade * ss->cache->radius); mul_v3_v3v3(proxy[vd.i], val, ss->cache->scale); if(vd.mvert) vd.mvert->flag |= ME_VERT_PBVH_UPDATE; } } BLI_pbvh_vertex_iter_end; } } static void calc_flatten_center(Sculpt *sd, Object *ob, PBVHNode **nodes, int totnode, float fc[3]) { SculptSession *ss = ob->sculpt; int n; float count = 0; (void)sd; /* unused w/o openmp */ zero_v3(fc); #pragma omp parallel for schedule(guided) if (sd->flags & SCULPT_USE_OPENMP) for(n=0; n<totnode; n++) { PBVHVertexIter vd; SculptBrushTest test; SculptUndoNode *unode; float private_fc[3] = {0.0f, 0.0f, 0.0f}; int private_count = 0; unode = sculpt_undo_push_node(ob, nodes[n]); sculpt_brush_test_init(ss, &test); if(ss->cache->original) { BLI_pbvh_vertex_iter_begin(ss->pbvh, nodes[n], vd, PBVH_ITER_UNIQUE) { if(sculpt_brush_test_fast(&test, unode->co[vd.i])) { add_v3_v3(private_fc, vd.co); private_count++; } } BLI_pbvh_vertex_iter_end; } else { BLI_pbvh_vertex_iter_begin(ss->pbvh, nodes[n], vd, PBVH_ITER_UNIQUE) { if(sculpt_brush_test_fast(&test, vd.co)) { add_v3_v3(private_fc, vd.co); private_count++; } } BLI_pbvh_vertex_iter_end; } #pragma omp critical { add_v3_v3(fc, private_fc); count += private_count; } } mul_v3_fl(fc, 1.0f / count); } /* this calculates flatten center and area normal together, amortizing the memory bandwidth and loop overhead to calculate both at the same time */ static void calc_area_normal_and_flatten_center(Sculpt *sd, Object *ob, PBVHNode **nodes, int totnode, float an[3], float fc[3]) { SculptSession *ss = ob->sculpt; int n; // an float out_flip[3] = {0.0f, 0.0f, 0.0f}; // fc float count = 0; (void)sd; /* unused w/o openmp */ // an zero_v3(an); // fc zero_v3(fc); #pragma omp parallel for schedule(guided) if (sd->flags & SCULPT_USE_OPENMP) for(n=0; n<totnode; n++) { PBVHVertexIter vd; SculptBrushTest test; SculptUndoNode *unode; float private_an[3] = {0.0f, 0.0f, 0.0f}; float private_out_flip[3] = {0.0f, 0.0f, 0.0f}; float private_fc[3] = {0.0f, 0.0f, 0.0f}; int private_count = 0; unode = sculpt_undo_push_node(ob, nodes[n]); sculpt_brush_test_init(ss, &test); if(ss->cache->original) { BLI_pbvh_vertex_iter_begin(ss->pbvh, nodes[n], vd, PBVH_ITER_UNIQUE) { if(sculpt_brush_test_fast(&test, unode->co[vd.i])) { // an float fno[3]; normal_short_to_float_v3(fno, unode->no[vd.i]); add_norm_if(ss->cache->view_normal, private_an, private_out_flip, fno); // fc add_v3_v3(private_fc, vd.co); private_count++; } } BLI_pbvh_vertex_iter_end; } else { BLI_pbvh_vertex_iter_begin(ss->pbvh, nodes[n], vd, PBVH_ITER_UNIQUE) { if(sculpt_brush_test_fast(&test, vd.co)) { // an if(vd.no) { float fno[3]; normal_short_to_float_v3(fno, vd.no); add_norm_if(ss->cache->view_normal, private_an, private_out_flip, fno); } else { add_norm_if(ss->cache->view_normal, private_an, private_out_flip, vd.fno); } // fc add_v3_v3(private_fc, vd.co); private_count++; } } BLI_pbvh_vertex_iter_end; } #pragma omp critical { // an add_v3_v3(an, private_an); add_v3_v3(out_flip, private_out_flip); // fc add_v3_v3(fc, private_fc); count += private_count; } } // an if (is_zero_v3(an)) copy_v3_v3(an, out_flip); normalize_v3(an); // fc if (count != 0) { mul_v3_fl(fc, 1.0f / count); } else { zero_v3(fc); } } static void calc_sculpt_plane(Sculpt *sd, Object *ob, PBVHNode **nodes, int totnode, float an[3], float fc[3]) { SculptSession *ss = ob->sculpt; Brush *brush = paint_brush(&sd->paint); if (ss->cache->mirror_symmetry_pass == 0 && ss->cache->radial_symmetry_pass == 0 && (ss->cache->first_time || !(brush->flag & BRUSH_ORIGINAL_NORMAL))) { switch (brush->sculpt_plane) { case SCULPT_DISP_DIR_VIEW: ED_view3d_global_to_vector(ss->cache->vc->rv3d, ss->cache->vc->rv3d->twmat[3], an); break; case SCULPT_DISP_DIR_X: an[1] = 0.0; an[2] = 0.0; an[0] = 1.0; break; case SCULPT_DISP_DIR_Y: an[0] = 0.0; an[2] = 0.0; an[1] = 1.0; break; case SCULPT_DISP_DIR_Z: an[0] = 0.0; an[1] = 0.0; an[2] = 1.0; break; case SCULPT_DISP_DIR_AREA: calc_area_normal_and_flatten_center(sd, ob, nodes, totnode, an, fc); default: break; } // fc /* flatten center has not been calculated yet if we are not using the area normal */ if (brush->sculpt_plane != SCULPT_DISP_DIR_AREA) calc_flatten_center(sd, ob, nodes, totnode, fc); // an copy_v3_v3(ss->cache->last_area_normal, an); // fc copy_v3_v3(ss->cache->last_center, fc); } else { // an copy_v3_v3(an, ss->cache->last_area_normal); // fc copy_v3_v3(fc, ss->cache->last_center); // an flip_coord(an, an, ss->cache->mirror_symmetry_pass); // fc flip_coord(fc, fc, ss->cache->mirror_symmetry_pass); // an mul_m4_v3(ss->cache->symm_rot_mat, an); // fc mul_m4_v3(ss->cache->symm_rot_mat, fc); } } /* Projects a point onto a plane along the plane's normal */ static void point_plane_project(float intr[3], float co[3], float plane_normal[3], float plane_center[3]) { sub_v3_v3v3(intr, co, plane_center); mul_v3_v3fl(intr, plane_normal, dot_v3v3(plane_normal, intr)); sub_v3_v3v3(intr, co, intr); } static int plane_trim(StrokeCache *cache, Brush *brush, float val[3]) { return !(brush->flag & BRUSH_PLANE_TRIM) || (dot_v3v3(val, val) <= cache->radius_squared*cache->plane_trim_squared); } static int plane_point_side_flip(float co[3], float plane_normal[3], float plane_center[3], int flip) { float delta[3]; float d; sub_v3_v3v3(delta, co, plane_center); d = dot_v3v3(plane_normal, delta); if (flip) d = -d; return d <= 0.0f; } static int plane_point_side(float co[3], float plane_normal[3], float plane_center[3]) { float delta[3]; sub_v3_v3v3(delta, co, plane_center); return dot_v3v3(plane_normal, delta) <= 0.0f; } static float get_offset(Sculpt *sd, SculptSession *ss) { Brush* brush = paint_brush(&sd->paint); float rv = brush->plane_offset; if (brush->flag & BRUSH_OFFSET_PRESSURE) { rv *= ss->cache->pressure; } return rv; } static void do_flatten_brush(Sculpt *sd, Object *ob, PBVHNode **nodes, int totnode) { SculptSession *ss = ob->sculpt; Brush *brush = paint_brush(&sd->paint); float bstrength = ss->cache->bstrength; const float radius = ss->cache->radius; float an[3]; float fc[3]; float offset = get_offset(sd, ss); float displace; int n; float temp[3]; calc_sculpt_plane(sd, ob, nodes, totnode, an, fc); displace = radius*offset; mul_v3_v3v3(temp, an, ss->cache->scale); mul_v3_fl(temp, displace); add_v3_v3(fc, temp); #pragma omp parallel for schedule(guided) if (sd->flags & SCULPT_USE_OPENMP) for(n = 0; n < totnode; n++) { PBVHVertexIter vd; SculptBrushTest test; float (*proxy)[3]; proxy= BLI_pbvh_node_add_proxy(ss->pbvh, nodes[n])->co; sculpt_brush_test_init(ss, &test); BLI_pbvh_vertex_iter_begin(ss->pbvh, nodes[n], vd, PBVH_ITER_UNIQUE) { if (sculpt_brush_test_sq(&test, vd.co)) { float intr[3]; float val[3]; point_plane_project(intr, vd.co, an, fc); sub_v3_v3v3(val, intr, vd.co); if (plane_trim(ss->cache, brush, val)) { const float fade = bstrength*tex_strength(ss, brush, vd.co, sqrt(test.dist))*frontface(brush, an, vd.no, vd.fno); mul_v3_v3fl(proxy[vd.i], val, fade); if(vd.mvert) vd.mvert->flag |= ME_VERT_PBVH_UPDATE; } } } BLI_pbvh_vertex_iter_end; } } static void do_clay_brush(Sculpt *sd, Object *ob, PBVHNode **nodes, int totnode) { SculptSession *ss = ob->sculpt; Brush *brush = paint_brush(&sd->paint); float bstrength = ss->cache->bstrength; float radius = ss->cache->radius; float offset = get_offset(sd, ss); float displace; float an[3]; // area normal float fc[3]; // flatten center int n; float temp[3]; //float p[3]; int flip; calc_sculpt_plane(sd, ob, nodes, totnode, an, fc); flip = bstrength < 0; if (flip) { bstrength = -bstrength; radius = -radius; } displace = radius * (0.25f+offset); mul_v3_v3v3(temp, an, ss->cache->scale); mul_v3_fl(temp, displace); add_v3_v3(fc, temp); //add_v3_v3v3(p, ss->cache->location, an); #pragma omp parallel for schedule(guided) if (sd->flags & SCULPT_USE_OPENMP) for (n = 0; n < totnode; n++) { PBVHVertexIter vd; SculptBrushTest test; float (*proxy)[3]; proxy= BLI_pbvh_node_add_proxy(ss->pbvh, nodes[n])->co; sculpt_brush_test_init(ss, &test); BLI_pbvh_vertex_iter_begin(ss->pbvh, nodes[n], vd, PBVH_ITER_UNIQUE) { if (sculpt_brush_test_sq(&test, vd.co)) { if (plane_point_side_flip(vd.co, an, fc, flip)) { //if (sculpt_brush_test_cyl(&test, vd.co, ss->cache->location, p)) { float intr[3]; float val[3]; point_plane_project(intr, vd.co, an, fc); sub_v3_v3v3(val, intr, vd.co); if (plane_trim(ss->cache, brush, val)) { const float fade = bstrength*tex_strength(ss, brush, vd.co, sqrt(test.dist))*frontface(brush, an, vd.no, vd.fno); mul_v3_v3fl(proxy[vd.i], val, fade); if(vd.mvert) vd.mvert->flag |= ME_VERT_PBVH_UPDATE; } } } } BLI_pbvh_vertex_iter_end; } } static void do_clay_tubes_brush(Sculpt *sd, Object *ob, PBVHNode **nodes, int totnode) { SculptSession *ss = ob->sculpt; Brush *brush = paint_brush(&sd->paint); float bstrength = ss->cache->bstrength; float radius = ss->cache->radius; float offset = get_offset(sd, ss); float displace; float sn[3]; // sculpt normal float an[3]; // area normal float fc[3]; // flatten center int n; float temp[3]; float mat[4][4]; float scale[4][4]; float tmat[4][4]; int flip; calc_sculpt_plane(sd, ob, nodes, totnode, sn, fc); if (brush->sculpt_plane != SCULPT_DISP_DIR_AREA || (brush->flag & BRUSH_ORIGINAL_NORMAL)) calc_area_normal(sd, ob, an, nodes, totnode); else copy_v3_v3(an, sn); if (ss->cache->first_time) return; // delay the first daub because grab delta is not setup flip = bstrength < 0; if (flip) { bstrength = -bstrength; radius = -radius; } displace = radius * (0.25f+offset); mul_v3_v3v3(temp, sn, ss->cache->scale); mul_v3_fl(temp, displace); add_v3_v3(fc, temp); cross_v3_v3v3(mat[0], an, ss->cache->grab_delta_symmetry); mat[0][3] = 0; cross_v3_v3v3(mat[1], an, mat[0]); mat[1][3] = 0; copy_v3_v3(mat[2], an); mat[2][3] = 0; copy_v3_v3(mat[3], ss->cache->location); mat[3][3] = 1; normalize_m4(mat); scale_m4_fl(scale, ss->cache->radius); mul_m4_m4m4(tmat, scale, mat); invert_m4_m4(mat, tmat); #pragma omp parallel for schedule(guided) if (sd->flags & SCULPT_USE_OPENMP) for (n = 0; n < totnode; n++) { PBVHVertexIter vd; SculptBrushTest test; float (*proxy)[3]; proxy= BLI_pbvh_node_add_proxy(ss->pbvh, nodes[n])->co; sculpt_brush_test_init(ss, &test); BLI_pbvh_vertex_iter_begin(ss->pbvh, nodes[n], vd, PBVH_ITER_UNIQUE) { if (sculpt_brush_test_cube(&test, vd.co, mat)) { if (plane_point_side_flip(vd.co, sn, fc, flip)) { float intr[3]; float val[3]; point_plane_project(intr, vd.co, sn, fc); sub_v3_v3v3(val, intr, vd.co); if (plane_trim(ss->cache, brush, val)) { const float fade = bstrength*tex_strength(ss, brush, vd.co, ss->cache->radius*test.dist)*frontface(brush, an, vd.no, vd.fno); mul_v3_v3fl(proxy[vd.i], val, fade); if(vd.mvert) vd.mvert->flag |= ME_VERT_PBVH_UPDATE; } } } } BLI_pbvh_vertex_iter_end; } } static void do_fill_brush(Sculpt *sd, Object *ob, PBVHNode **nodes, int totnode) { SculptSession *ss = ob->sculpt; Brush *brush = paint_brush(&sd->paint); float bstrength = ss->cache->bstrength; const float radius = ss->cache->radius; float an[3]; float fc[3]; float offset = get_offset(sd, ss); float displace; int n; float temp[3]; calc_sculpt_plane(sd, ob, nodes, totnode, an, fc); displace = radius*offset; mul_v3_v3v3(temp, an, ss->cache->scale); mul_v3_fl(temp, displace); add_v3_v3(fc, temp); #pragma omp parallel for schedule(guided) if (sd->flags & SCULPT_USE_OPENMP) for (n = 0; n < totnode; n++) { PBVHVertexIter vd; SculptBrushTest test; float (*proxy)[3]; proxy= BLI_pbvh_node_add_proxy(ss->pbvh, nodes[n])->co; sculpt_brush_test_init(ss, &test); BLI_pbvh_vertex_iter_begin(ss->pbvh, nodes[n], vd, PBVH_ITER_UNIQUE) { if (sculpt_brush_test_sq(&test, vd.co)) { if (plane_point_side(vd.co, an, fc)) { float intr[3]; float val[3]; point_plane_project(intr, vd.co, an, fc); sub_v3_v3v3(val, intr, vd.co); if (plane_trim(ss->cache, brush, val)) { const float fade = bstrength*tex_strength(ss, brush, vd.co, sqrt(test.dist))*frontface(brush, an, vd.no, vd.fno); mul_v3_v3fl(proxy[vd.i], val, fade); if(vd.mvert) vd.mvert->flag |= ME_VERT_PBVH_UPDATE; } } } } BLI_pbvh_vertex_iter_end; } } static void do_scrape_brush(Sculpt *sd, Object *ob, PBVHNode **nodes, int totnode) { SculptSession *ss = ob->sculpt; Brush *brush = paint_brush(&sd->paint); float bstrength = ss->cache->bstrength; const float radius = ss->cache->radius; float an[3]; float fc[3]; float offset = get_offset(sd, ss); float displace; int n; float temp[3]; calc_sculpt_plane(sd, ob, nodes, totnode, an, fc); displace = -radius*offset; mul_v3_v3v3(temp, an, ss->cache->scale); mul_v3_fl(temp, displace); add_v3_v3(fc, temp); #pragma omp parallel for schedule(guided) if (sd->flags & SCULPT_USE_OPENMP) for (n = 0; n < totnode; n++) { PBVHVertexIter vd; SculptBrushTest test; float (*proxy)[3]; proxy= BLI_pbvh_node_add_proxy(ss->pbvh, nodes[n])->co; sculpt_brush_test_init(ss, &test); BLI_pbvh_vertex_iter_begin(ss->pbvh, nodes[n], vd, PBVH_ITER_UNIQUE) { if (sculpt_brush_test_sq(&test, vd.co)) { if (!plane_point_side(vd.co, an, fc)) { float intr[3]; float val[3]; point_plane_project(intr, vd.co, an, fc); sub_v3_v3v3(val, intr, vd.co); if (plane_trim(ss->cache, brush, val)) { const float fade = bstrength*tex_strength(ss, brush, vd.co, sqrt(test.dist))*frontface(brush, an, vd.no, vd.fno); mul_v3_v3fl(proxy[vd.i], val, fade); if(vd.mvert) vd.mvert->flag |= ME_VERT_PBVH_UPDATE; } } } } BLI_pbvh_vertex_iter_end; } } void sculpt_vertcos_to_key(Object *ob, KeyBlock *kb, float (*vertCos)[3]) { Mesh *me= (Mesh*)ob->data; float (*ofs)[3]= NULL; int a, is_basis= 0; KeyBlock *currkey; /* for relative keys editing of base should update other keys */ if (me->key->type == KEY_RELATIVE) for (currkey = me->key->block.first; currkey; currkey= currkey->next) if(ob->shapenr-1 == currkey->relative) { is_basis= 1; break; } if (is_basis) { ofs= key_to_vertcos(ob, kb); /* calculate key coord offsets (from previous location) */ for (a= 0; a < me->totvert; a++) VECSUB(ofs[a], vertCos[a], ofs[a]); /* apply offsets on other keys */ currkey = me->key->block.first; while (currkey) { int apply_offset = ((currkey != kb) && (ob->shapenr-1 == currkey->relative)); if (apply_offset) offset_to_key(ob, currkey, ofs); currkey= currkey->next; } MEM_freeN(ofs); } /* modifying of basis key should update mesh */ if (kb == me->key->refkey) { MVert *mvert= me->mvert; for (a= 0; a < me->totvert; a++, mvert++) VECCOPY(mvert->co, vertCos[a]); mesh_calc_normals(me->mvert, me->totvert, me->mface, me->totface, NULL); } /* apply new coords on active key block */ vertcos_to_key(ob, kb, vertCos); } static void do_brush_action(Sculpt *sd, Object *ob, Brush *brush) { SculptSession *ss = ob->sculpt; SculptSearchSphereData data; PBVHNode **nodes = NULL; int n, totnode; /* Build a list of all nodes that are potentially within the brush's area of influence */ data.ss = ss; data.sd = sd; data.radius_squared = ss->cache->radius_squared; data.original = ELEM4(brush->sculpt_tool, SCULPT_TOOL_GRAB, SCULPT_TOOL_ROTATE, SCULPT_TOOL_THUMB, SCULPT_TOOL_LAYER); BLI_pbvh_search_gather(ss->pbvh, sculpt_search_sphere_cb, &data, &nodes, &totnode); /* Only act if some verts are inside the brush area */ if (totnode) { #pragma omp parallel for schedule(guided) if (sd->flags & SCULPT_USE_OPENMP) for (n= 0; n < totnode; n++) { sculpt_undo_push_node(ob, nodes[n]); BLI_pbvh_node_mark_update(nodes[n]); } /* Apply one type of brush action */ switch(brush->sculpt_tool){ case SCULPT_TOOL_DRAW: do_draw_brush(sd, ob, nodes, totnode); break; case SCULPT_TOOL_SMOOTH: do_smooth_brush(sd, ob, nodes, totnode); break; case SCULPT_TOOL_CREASE: do_crease_brush(sd, ob, nodes, totnode); break; case SCULPT_TOOL_BLOB: do_crease_brush(sd, ob, nodes, totnode); break; case SCULPT_TOOL_PINCH: do_pinch_brush(sd, ob, nodes, totnode); break; case SCULPT_TOOL_INFLATE: do_inflate_brush(sd, ob, nodes, totnode); break; case SCULPT_TOOL_GRAB: do_grab_brush(sd, ob, nodes, totnode); break; case SCULPT_TOOL_ROTATE: do_rotate_brush(sd, ob, nodes, totnode); break; case SCULPT_TOOL_SNAKE_HOOK: do_snake_hook_brush(sd, ob, nodes, totnode); break; case SCULPT_TOOL_NUDGE: do_nudge_brush(sd, ob, nodes, totnode); break; case SCULPT_TOOL_THUMB: do_thumb_brush(sd, ob, nodes, totnode); break; case SCULPT_TOOL_LAYER: do_layer_brush(sd, ob, nodes, totnode); break; case SCULPT_TOOL_FLATTEN: do_flatten_brush(sd, ob, nodes, totnode); break; case SCULPT_TOOL_CLAY: do_clay_brush(sd, ob, nodes, totnode); break; case SCULPT_TOOL_CLAY_TUBES: do_clay_tubes_brush(sd, ob, nodes, totnode); break; case SCULPT_TOOL_FILL: do_fill_brush(sd, ob, nodes, totnode); break; case SCULPT_TOOL_SCRAPE: do_scrape_brush(sd, ob, nodes, totnode); break; } if (brush->sculpt_tool != SCULPT_TOOL_SMOOTH && brush->autosmooth_factor > 0) { if (brush->flag & BRUSH_INVERSE_SMOOTH_PRESSURE) { smooth(sd, ob, nodes, totnode, brush->autosmooth_factor*(1-ss->cache->pressure)); } else { smooth(sd, ob, nodes, totnode, brush->autosmooth_factor); } } MEM_freeN(nodes); } } /* flush displacement from deformed PBVH vertex to original mesh */ static void sculpt_flush_pbvhvert_deform(Object *ob, PBVHVertexIter *vd) { SculptSession *ss = ob->sculpt; Mesh *me= ob->data; float disp[3], newco[3]; int index= vd->vert_indices[vd->i]; sub_v3_v3v3(disp, vd->co, ss->deform_cos[index]); mul_m3_v3(ss->deform_imats[index], disp); add_v3_v3v3(newco, disp, ss->orig_cos[index]); copy_v3_v3(ss->deform_cos[index], vd->co); copy_v3_v3(ss->orig_cos[index], newco); if(!ss->kb) copy_v3_v3(me->mvert[index].co, newco); } static void sculpt_combine_proxies(Sculpt *sd, Object *ob) { SculptSession *ss = ob->sculpt; Brush *brush= paint_brush(&sd->paint); PBVHNode** nodes; int totnode, n; BLI_pbvh_gather_proxies(ss->pbvh, &nodes, &totnode); if(!ELEM(brush->sculpt_tool, SCULPT_TOOL_SMOOTH, SCULPT_TOOL_LAYER)) { /* these brushes start from original coordinates */ const int use_orco = (ELEM3(brush->sculpt_tool, SCULPT_TOOL_GRAB, SCULPT_TOOL_ROTATE, SCULPT_TOOL_THUMB)); #pragma omp parallel for schedule(guided) if (sd->flags & SCULPT_USE_OPENMP) for (n= 0; n < totnode; n++) { PBVHVertexIter vd; PBVHProxyNode* proxies; int proxy_count; float (*orco)[3]; if(use_orco) orco= sculpt_undo_push_node(ob, nodes[n])->co; BLI_pbvh_node_get_proxies(nodes[n], &proxies, &proxy_count); BLI_pbvh_vertex_iter_begin(ss->pbvh, nodes[n], vd, PBVH_ITER_UNIQUE) { float val[3]; int p; if(use_orco) copy_v3_v3(val, orco[vd.i]); else copy_v3_v3(val, vd.co); for (p= 0; p < proxy_count; p++) add_v3_v3(val, proxies[p].co[vd.i]); sculpt_clip(sd, ss, vd.co, val); if(ss->modifiers_active) sculpt_flush_pbvhvert_deform(ob, &vd); } BLI_pbvh_vertex_iter_end; BLI_pbvh_node_free_proxies(nodes[n]); } } if (nodes) MEM_freeN(nodes); } /* copy the modified vertices from bvh to the active key */ static void sculpt_update_keyblock(Object *ob) { SculptSession *ss = ob->sculpt; float (*vertCos)[3]; /* Keyblock update happens after hadning deformation caused by modifiers, so ss->orig_cos would be updated with new stroke */ if(ss->orig_cos) vertCos = ss->orig_cos; else vertCos = BLI_pbvh_get_vertCos(ss->pbvh); if (vertCos) { sculpt_vertcos_to_key(ob, ss->kb, vertCos); if(vertCos != ss->orig_cos) MEM_freeN(vertCos); } } /* flush displacement from deformed PBVH to original layer */ static void sculpt_flush_stroke_deform(Sculpt *sd, Object *ob) { SculptSession *ss = ob->sculpt; Brush *brush= paint_brush(&sd->paint); if(ELEM(brush->sculpt_tool, SCULPT_TOOL_SMOOTH, SCULPT_TOOL_LAYER)) { /* this brushes aren't using proxies, so sculpt_combine_proxies() wouldn't propagate needed deformation to original base */ int n, totnode; Mesh *me= (Mesh*)ob->data; PBVHNode** nodes; float (*vertCos)[3]= NULL; if(ss->kb) vertCos= MEM_callocN(sizeof(*vertCos)*me->totvert, "flushStrokeDeofrm keyVerts"); BLI_pbvh_search_gather(ss->pbvh, NULL, NULL, &nodes, &totnode); #pragma omp parallel for schedule(guided) if (sd->flags & SCULPT_USE_OPENMP) for (n= 0; n < totnode; n++) { PBVHVertexIter vd; BLI_pbvh_vertex_iter_begin(ss->pbvh, nodes[n], vd, PBVH_ITER_UNIQUE) { sculpt_flush_pbvhvert_deform(ob, &vd); if(vertCos) { int index= vd.vert_indices[vd.i]; copy_v3_v3(vertCos[index], ss->orig_cos[index]); } } BLI_pbvh_vertex_iter_end; } if(vertCos) { sculpt_vertcos_to_key(ob, ss->kb, vertCos); MEM_freeN(vertCos); } MEM_freeN(nodes); /* Modifiers could depend on mesh normals, so we should update them/ Note, then if sculpting happens on locked key, normals should be re-calculated after applying coords from keyblock on base mesh */ mesh_calc_normals(me->mvert, me->totvert, me->mface, me->totface, NULL); } else if (ss->kb) sculpt_update_keyblock(ob); } //static int max_overlap_count(Sculpt *sd) //{ // int count[3]; // int i, j; // // for (i= 0; i < 3; i++) { // count[i] = sd->radial_symm[i]; // // for (j= 0; j < 3; j++) { // if (i != j && sd->flags & (SCULPT_SYMM_X<<i)) // count[i] *= 2; // } // } // // return MAX3(count[0], count[1], count[2]); //} /* Flip all the editdata across the axis/axes specified by symm. Used to calculate multiple modifications to the mesh when symmetry is enabled. */ static void calc_brushdata_symm(Sculpt *sd, StrokeCache *cache, const char symm, const char axis, const float angle, const float UNUSED(feather)) { (void)sd; /* unused */ flip_coord(cache->location, cache->true_location, symm); flip_coord(cache->grab_delta_symmetry, cache->grab_delta, symm); flip_coord(cache->view_normal, cache->true_view_normal, symm); // XXX This reduces the length of the grab delta if it approaches the line of symmetry // XXX However, a different approach appears to be needed //if (sd->flags & SCULPT_SYMMETRY_FEATHER) { // float frac = 1.0f/max_overlap_count(sd); // float reduce = (feather-frac)/(1-frac); // printf("feather: %f frac: %f reduce: %f\n", feather, frac, reduce); // if (frac < 1) // mul_v3_fl(cache->grab_delta_symmetry, reduce); //} unit_m4(cache->symm_rot_mat); unit_m4(cache->symm_rot_mat_inv); if(axis) { /* expects XYZ */ rotate_m4(cache->symm_rot_mat, axis, angle); rotate_m4(cache->symm_rot_mat_inv, axis, -angle); } mul_m4_v3(cache->symm_rot_mat, cache->location); mul_m4_v3(cache->symm_rot_mat, cache->grab_delta_symmetry); } static void do_radial_symmetry(Sculpt *sd, Object *ob, Brush *brush, const char symm, const int axis, const float feather) { SculptSession *ss = ob->sculpt; int i; for(i = 1; i < sd->radial_symm[axis-'X']; ++i) { const float angle = 2*M_PI*i/sd->radial_symm[axis-'X']; ss->cache->radial_symmetry_pass= i; calc_brushdata_symm(sd, ss->cache, symm, axis, angle, feather); do_brush_action(sd, ob, brush); } } /* noise texture gives different values for the same input coord; this can tear a multires mesh during sculpting so do a stitch in this case */ static void sculpt_fix_noise_tear(Sculpt *sd, Object *ob) { SculptSession *ss = ob->sculpt; Brush *brush = paint_brush(&sd->paint); MTex *mtex = &brush->mtex; if(ss->multires && mtex->tex && mtex->tex->type == TEX_NOISE) multires_stitch_grids(ob); } static void do_symmetrical_brush_actions(Sculpt *sd, Object *ob) { Brush *brush = paint_brush(&sd->paint); SculptSession *ss = ob->sculpt; StrokeCache *cache = ss->cache; const char symm = sd->flags & 7; int i; float feather = calc_symmetry_feather(sd, ss->cache); cache->bstrength= brush_strength(sd, cache, feather); cache->symmetry= symm; /* symm is a bit combination of XYZ - 1 is mirror X; 2 is Y; 3 is XY; 4 is Z; 5 is XZ; 6 is YZ; 7 is XYZ */ for(i = 0; i <= symm; ++i) { if(i == 0 || (symm & i && (symm != 5 || i != 3) && (symm != 6 || (i != 3 && i != 5)))) { cache->mirror_symmetry_pass= i; cache->radial_symmetry_pass= 0; calc_brushdata_symm(sd, cache, i, 0, 0, feather); do_brush_action(sd, ob, brush); do_radial_symmetry(sd, ob, brush, i, 'X', feather); do_radial_symmetry(sd, ob, brush, i, 'Y', feather); do_radial_symmetry(sd, ob, brush, i, 'Z', feather); } } sculpt_combine_proxies(sd, ob); /* hack to fix noise texture tearing mesh */ sculpt_fix_noise_tear(sd, ob); if (ss->modifiers_active) sculpt_flush_stroke_deform(sd, ob); cache->first_time= 0; } static void sculpt_update_tex(Sculpt *sd, SculptSession *ss) { Brush *brush = paint_brush(&sd->paint); const int radius= brush_size(brush); if(ss->texcache) { MEM_freeN(ss->texcache); ss->texcache= NULL; } /* Need to allocate a bigger buffer for bigger brush size */ ss->texcache_side = 2*radius; if(!ss->texcache || ss->texcache_side > ss->texcache_actual) { ss->texcache = brush_gen_texture_cache(brush, radius); ss->texcache_actual = ss->texcache_side; } } void sculpt_update_mesh_elements(Scene *scene, Sculpt *sd, Object *ob, int need_fmap) { DerivedMesh *dm = mesh_get_derived_final(scene, ob, CD_MASK_BAREMESH); SculptSession *ss = ob->sculpt; MultiresModifierData *mmd= sculpt_multires_active(scene, ob); ss->modifiers_active= sculpt_modifiers_active(scene, sd, ob); if(!mmd) ss->kb= ob_get_keyblock(ob); else ss->kb= NULL; if(mmd) { ss->multires = mmd; ss->totvert = dm->getNumVerts(dm); ss->totface = dm->getNumFaces(dm); ss->mvert= NULL; ss->mface= NULL; ss->face_normals= NULL; } else { Mesh *me = get_mesh(ob); ss->totvert = me->totvert; ss->totface = me->totface; ss->mvert = me->mvert; ss->mface = me->mface; ss->face_normals = NULL; ss->multires = NULL; } ss->pbvh = dm->getPBVH(ob, dm); ss->fmap = (need_fmap && dm->getFaceMap)? dm->getFaceMap(ob, dm): NULL; if(ss->modifiers_active) { if(!ss->orig_cos) { int a; free_sculptsession_deformMats(ss); if(ss->kb) ss->orig_cos = key_to_vertcos(ob, ss->kb); else ss->orig_cos = mesh_getVertexCos(ob->data, NULL); crazyspace_build_sculpt(scene, ob, &ss->deform_imats, &ss->deform_cos); BLI_pbvh_apply_vertCos(ss->pbvh, ss->deform_cos); for(a = 0; a < ((Mesh*)ob->data)->totvert; ++a) invert_m3(ss->deform_imats[a]); } } else free_sculptsession_deformMats(ss); /* if pbvh is deformed, key block is already applied to it */ if (ss->kb && !BLI_pbvh_isDeformed(ss->pbvh)) { float (*vertCos)[3]= key_to_vertcos(ob, ss->kb); if (vertCos) { /* apply shape keys coordinates to PBVH */ BLI_pbvh_apply_vertCos(ss->pbvh, vertCos); MEM_freeN(vertCos); } } } static int sculpt_mode_poll(bContext *C) { Object *ob = CTX_data_active_object(C); return ob && ob->mode & OB_MODE_SCULPT; } int sculpt_poll(bContext *C) { return sculpt_mode_poll(C) && paint_poll(C); } static const char *sculpt_tool_name(Sculpt *sd) { Brush *brush = paint_brush(&sd->paint); switch(brush->sculpt_tool) { case SCULPT_TOOL_DRAW: return "Draw Brush"; break; case SCULPT_TOOL_SMOOTH: return "Smooth Brush"; break; case SCULPT_TOOL_CREASE: return "Crease Brush"; break; case SCULPT_TOOL_BLOB: return "Blob Brush"; break; case SCULPT_TOOL_PINCH: return "Pinch Brush"; break; case SCULPT_TOOL_INFLATE: return "Inflate Brush"; break; case SCULPT_TOOL_GRAB: return "Grab Brush"; break; case SCULPT_TOOL_NUDGE: return "Nudge Brush"; break; case SCULPT_TOOL_THUMB: return "Thumb Brush"; break; case SCULPT_TOOL_LAYER: return "Layer Brush"; break; case SCULPT_TOOL_FLATTEN: return "Flatten Brush"; break; case SCULPT_TOOL_CLAY: return "Clay Brush"; break; case SCULPT_TOOL_CLAY_TUBES: return "Clay Tubes Brush"; break; case SCULPT_TOOL_FILL: return "Fill Brush"; break; case SCULPT_TOOL_SCRAPE: return "Scrape Brush"; break; default: return "Sculpting"; break; } } /**** Operator for applying a stroke (various attributes including mouse path) using the current brush. ****/ static void sculpt_cache_free(StrokeCache *cache) { if(cache->face_norms) MEM_freeN(cache->face_norms); if(cache->mats) MEM_freeN(cache->mats); MEM_freeN(cache); } /* Initialize mirror modifier clipping */ static void sculpt_init_mirror_clipping(Object *ob, SculptSession *ss) { ModifierData *md; int i; for(md= ob->modifiers.first; md; md= md->next) { if(md->type==eModifierType_Mirror && (md->mode & eModifierMode_Realtime)) { MirrorModifierData *mmd = (MirrorModifierData*)md; if(mmd->flag & MOD_MIR_CLIPPING) { /* check each axis for mirroring */ for(i = 0; i < 3; ++i) { if(mmd->flag & (MOD_MIR_AXIS_X << i)) { /* enable sculpt clipping */ ss->cache->flag |= CLIP_X << i; /* update the clip tolerance */ if(mmd->tolerance > ss->cache->clip_tolerance[i]) ss->cache->clip_tolerance[i] = mmd->tolerance; } } } } } } /* Initialize the stroke cache invariants from operator properties */ static void sculpt_update_cache_invariants(bContext* C, Sculpt *sd, SculptSession *ss, wmOperator *op, wmEvent *event) { StrokeCache *cache = MEM_callocN(sizeof(StrokeCache), "stroke cache"); Brush *brush = paint_brush(&sd->paint); ViewContext *vc = paint_stroke_view_context(op->customdata); Object *ob= CTX_data_active_object(C); int i; int mode; ss->cache = cache; /* Set scaling adjustment */ ss->cache->scale[0] = 1.0f / ob->size[0]; ss->cache->scale[1] = 1.0f / ob->size[1]; ss->cache->scale[2] = 1.0f / ob->size[2]; ss->cache->plane_trim_squared = brush->plane_trim * brush->plane_trim; ss->cache->flag = 0; sculpt_init_mirror_clipping(ob, ss); /* Initial mouse location */ if (event) { ss->cache->initial_mouse[0] = event->x; ss->cache->initial_mouse[1] = event->y; } else { ss->cache->initial_mouse[0] = 0; ss->cache->initial_mouse[1] = 0; } mode = RNA_enum_get(op->ptr, "mode"); cache->invert = mode == BRUSH_STROKE_INVERT; cache->alt_smooth = mode == BRUSH_STROKE_SMOOTH; /* not very nice, but with current events system implementation we can't handle brush appearance inversion hotkey separately (sergey) */ if(cache->invert) brush->flag |= BRUSH_INVERTED; else brush->flag &= ~BRUSH_INVERTED; /* Alt-Smooth */ if (ss->cache->alt_smooth) { Paint *p= &sd->paint; Brush *br; BLI_strncpy(cache->saved_active_brush_name, brush->id.name+2, sizeof(cache->saved_active_brush_name)); br= (Brush *)find_id("BR", "Smooth"); if(br) { paint_brush_set(p, br); brush = br; } } copy_v2_v2(cache->mouse, cache->initial_mouse); copy_v2_v2(cache->tex_mouse, cache->initial_mouse); /* Truly temporary data that isn't stored in properties */ cache->vc = vc; cache->brush = brush; cache->mats = MEM_callocN(sizeof(bglMats), "sculpt bglMats"); view3d_get_transformation(vc->ar, vc->rv3d, vc->obact, cache->mats); ED_view3d_global_to_vector(cache->vc->rv3d, cache->vc->rv3d->twmat[3], cache->true_view_normal); /* Initialize layer brush displacements and persistent coords */ if(brush->sculpt_tool == SCULPT_TOOL_LAYER) { /* not supported yet for multires */ if(!ss->multires && !ss->layer_co && (brush->flag & BRUSH_PERSISTENT)) { if(!ss->layer_co) ss->layer_co= MEM_mallocN(sizeof(float) * 3 * ss->totvert, "sculpt mesh vertices copy"); if(ss->deform_cos) memcpy(ss->layer_co, ss->deform_cos, ss->totvert); else { for(i = 0; i < ss->totvert; ++i) { copy_v3_v3(ss->layer_co[i], ss->mvert[i].co); } } } } /* Make copies of the mesh vertex locations and normals for some tools */ if(brush->flag & BRUSH_ANCHORED) { if(ss->face_normals) { float *fn = ss->face_normals; cache->face_norms= MEM_mallocN(sizeof(float) * 3 * ss->totface, "Sculpt face norms"); for(i = 0; i < ss->totface; ++i, fn += 3) copy_v3_v3(cache->face_norms[i], fn); } cache->original = 1; } if(ELEM8(brush->sculpt_tool, SCULPT_TOOL_DRAW, SCULPT_TOOL_CREASE, SCULPT_TOOL_BLOB, SCULPT_TOOL_LAYER, SCULPT_TOOL_INFLATE, SCULPT_TOOL_CLAY, SCULPT_TOOL_CLAY_TUBES, SCULPT_TOOL_ROTATE)) if(!(brush->flag & BRUSH_ACCUMULATE)) cache->original = 1; cache->special_rotation = (brush->flag & BRUSH_RAKE) ? sd->last_angle : 0; //cache->last_rake[0] = sd->last_x; //cache->last_rake[1] = sd->last_y; cache->first_time= 1; cache->vertex_rotation= 0; } static void sculpt_update_brush_delta(Sculpt *sd, Object *ob, Brush *brush) { SculptSession *ss = ob->sculpt; StrokeCache *cache = ss->cache; int tool = brush->sculpt_tool; if(ELEM5(tool, SCULPT_TOOL_GRAB, SCULPT_TOOL_NUDGE, SCULPT_TOOL_CLAY_TUBES, SCULPT_TOOL_SNAKE_HOOK, SCULPT_TOOL_THUMB)) { float grab_location[3], imat[4][4], delta[3], loc[3]; if(cache->first_time) { copy_v3_v3(cache->orig_grab_location, cache->true_location); } else if(tool == SCULPT_TOOL_SNAKE_HOOK) add_v3_v3(cache->true_location, cache->grab_delta); /* compute 3d coordinate at same z from original location + mouse */ mul_v3_m4v3(loc, ob->obmat, cache->orig_grab_location); initgrabz(cache->vc->rv3d, loc[0], loc[1], loc[2]); ED_view3d_win_to_delta(cache->vc->ar, cache->mouse, grab_location); /* compute delta to move verts by */ if(!cache->first_time) { switch(tool) { case SCULPT_TOOL_GRAB: case SCULPT_TOOL_THUMB: sub_v3_v3v3(delta, grab_location, cache->old_grab_location); invert_m4_m4(imat, ob->obmat); mul_mat3_m4_v3(imat, delta); add_v3_v3(cache->grab_delta, delta); break; case SCULPT_TOOL_CLAY_TUBES: case SCULPT_TOOL_NUDGE: sub_v3_v3v3(cache->grab_delta, grab_location, cache->old_grab_location); invert_m4_m4(imat, ob->obmat); mul_mat3_m4_v3(imat, cache->grab_delta); break; case SCULPT_TOOL_SNAKE_HOOK: sub_v3_v3v3(cache->grab_delta, grab_location, cache->old_grab_location); invert_m4_m4(imat, ob->obmat); mul_mat3_m4_v3(imat, cache->grab_delta); break; } } else { zero_v3(cache->grab_delta); } copy_v3_v3(cache->old_grab_location, grab_location); if(tool == SCULPT_TOOL_GRAB) copy_v3_v3(sd->anchored_location, cache->true_location); else if(tool == SCULPT_TOOL_THUMB) copy_v3_v3(sd->anchored_location, cache->orig_grab_location); if(ELEM(tool, SCULPT_TOOL_GRAB, SCULPT_TOOL_THUMB)) { /* location stays the same for finding vertices in brush radius */ copy_v3_v3(cache->true_location, cache->orig_grab_location); sd->draw_anchored = 1; copy_v2_v2(sd->anchored_initial_mouse, cache->initial_mouse); sd->anchored_size = cache->pixel_radius; } } } /* Initialize the stroke cache variants from operator properties */ static void sculpt_update_cache_variants(bContext *C, Sculpt *sd, Object *ob, struct PaintStroke *stroke, PointerRNA *ptr) { SculptSession *ss = ob->sculpt; StrokeCache *cache = ss->cache; Brush *brush = paint_brush(&sd->paint); int dx, dy; //RNA_float_get_array(ptr, "location", cache->traced_location); if (cache->first_time || !((brush->flag & BRUSH_ANCHORED)|| (brush->sculpt_tool == SCULPT_TOOL_SNAKE_HOOK)|| (brush->sculpt_tool == SCULPT_TOOL_ROTATE)) ) { RNA_float_get_array(ptr, "location", cache->true_location); } cache->pen_flip = RNA_boolean_get(ptr, "pen_flip"); RNA_float_get_array(ptr, "mouse", cache->mouse); /* XXX: Use preassure value from first brush step for brushes which don't support strokes (grab, thumb). They depends on initial state and brush coord/pressure/etc. It's more an events design issue, which doesn't split coordinate/pressure/angle changing events. We should avoid this after events system re-design */ if(paint_space_stroke_enabled(brush) || cache->first_time) cache->pressure = RNA_float_get(ptr, "pressure"); /* Truly temporary data that isn't stored in properties */ sd->draw_pressure= 1; sd->pressure_value= cache->pressure; cache->previous_pixel_radius = cache->pixel_radius; cache->pixel_radius = brush_size(brush); if(cache->first_time) { if (!brush_use_locked_size(brush)) { cache->initial_radius= paint_calc_object_space_radius(cache->vc, cache->true_location, brush_size(brush)); brush_set_unprojected_radius(brush, cache->initial_radius); } else { cache->initial_radius= brush_unprojected_radius(brush); } } if(brush_use_size_pressure(brush)) { cache->pixel_radius *= cache->pressure; cache->radius= cache->initial_radius * cache->pressure; } else cache->radius= cache->initial_radius; cache->radius_squared = cache->radius*cache->radius; if(!(brush->flag & BRUSH_ANCHORED || ELEM4(brush->sculpt_tool, SCULPT_TOOL_GRAB, SCULPT_TOOL_SNAKE_HOOK, SCULPT_TOOL_THUMB, SCULPT_TOOL_ROTATE))) { copy_v2_v2(cache->tex_mouse, cache->mouse); if ( (brush->mtex.brush_map_mode == MTEX_MAP_MODE_FIXED) && (brush->flag & BRUSH_RANDOM_ROTATION) && !(brush->flag & BRUSH_RAKE)) { cache->special_rotation = 2.0f*(float)M_PI*BLI_frand(); } } if(brush->flag & BRUSH_ANCHORED) { int hit = 0; dx = cache->mouse[0] - cache->initial_mouse[0]; dy = cache->mouse[1] - cache->initial_mouse[1]; sd->anchored_size = cache->pixel_radius = sqrt(dx*dx + dy*dy); cache->special_rotation = atan2(dx, dy) + M_PI; if (brush->flag & BRUSH_EDGE_TO_EDGE) { float halfway[2]; float out[3]; halfway[0] = (float)dx * 0.5f + cache->initial_mouse[0]; halfway[1] = (float)dy * 0.5f + cache->initial_mouse[1]; if (sculpt_stroke_get_location(C, stroke, out, halfway)) { copy_v3_v3(sd->anchored_location, out); copy_v2_v2(sd->anchored_initial_mouse, halfway); copy_v2_v2(cache->tex_mouse, halfway); copy_v3_v3(cache->true_location, sd->anchored_location); sd->anchored_size /= 2.0f; cache->pixel_radius /= 2.0f; hit = 1; } } if (!hit) copy_v2_v2(sd->anchored_initial_mouse, cache->initial_mouse); cache->radius= paint_calc_object_space_radius(paint_stroke_view_context(stroke), cache->true_location, cache->pixel_radius); cache->radius_squared = cache->radius*cache->radius; copy_v3_v3(sd->anchored_location, cache->true_location); sd->draw_anchored = 1; } else if(brush->flag & BRUSH_RAKE) { const float u = 0.5f; const float v = 1 - u; const float r = 20; const float dx = cache->last_rake[0] - cache->mouse[0]; const float dy = cache->last_rake[1] - cache->mouse[1]; if (cache->first_time) { copy_v2_v2(cache->last_rake, cache->mouse); } else if (dx*dx + dy*dy >= r*r) { cache->special_rotation = atan2(dx, dy); cache->last_rake[0] = u*cache->last_rake[0] + v*cache->mouse[0]; cache->last_rake[1] = u*cache->last_rake[1] + v*cache->mouse[1]; } } sculpt_update_brush_delta(sd, ob, brush); if(brush->sculpt_tool == SCULPT_TOOL_ROTATE) { dx = cache->mouse[0] - cache->initial_mouse[0]; dy = cache->mouse[1] - cache->initial_mouse[1]; cache->vertex_rotation = -atan2(dx, dy); sd->draw_anchored = 1; copy_v2_v2(sd->anchored_initial_mouse, cache->initial_mouse); copy_v3_v3(sd->anchored_location, cache->true_location); sd->anchored_size = cache->pixel_radius; } sd->special_rotation = cache->special_rotation; } static void sculpt_stroke_modifiers_check(bContext *C, Object *ob) { SculptSession *ss = ob->sculpt; if(ss->modifiers_active) { Sculpt *sd = CTX_data_tool_settings(C)->sculpt; Brush *brush = paint_brush(&sd->paint); sculpt_update_mesh_elements(CTX_data_scene(C), sd, ob, brush->sculpt_tool == SCULPT_TOOL_SMOOTH); } } typedef struct { SculptSession *ss; float *ray_start, *ray_normal; int hit; float dist; int original; } SculptRaycastData; static void sculpt_raycast_cb(PBVHNode *node, void *data_v, float* tmin) { if (BLI_pbvh_node_get_tmin(node) < *tmin) { SculptRaycastData *srd = data_v; float (*origco)[3]= NULL; if(srd->original && srd->ss->cache) { /* intersect with coordinates from before we started stroke */ SculptUndoNode *unode= sculpt_undo_get_node(node); origco= (unode)? unode->co: NULL; } if (BLI_pbvh_node_raycast(srd->ss->pbvh, node, origco, srd->ray_start, srd->ray_normal, &srd->dist)) { srd->hit = 1; *tmin = srd->dist; } } } /* Do a raycast in the tree to find the 3d brush location (This allows us to ignore the GL depth buffer) Returns 0 if the ray doesn't hit the mesh, non-zero otherwise */ int sculpt_stroke_get_location(bContext *C, struct PaintStroke *stroke, float out[3], float mouse[2]) { ViewContext *vc = paint_stroke_view_context(stroke); Object *ob = vc->obact; SculptSession *ss= ob->sculpt; StrokeCache *cache= ss->cache; float ray_start[3], ray_end[3], ray_normal[3], dist; float obimat[4][4]; float mval[2]; SculptRaycastData srd; mval[0] = mouse[0] - vc->ar->winrct.xmin; mval[1] = mouse[1] - vc->ar->winrct.ymin; sculpt_stroke_modifiers_check(C, ob); ED_view3d_win_to_segment_clip(vc->ar, vc->v3d, mval, ray_start, ray_end); invert_m4_m4(obimat, ob->obmat); mul_m4_v3(obimat, ray_start); mul_m4_v3(obimat, ray_end); sub_v3_v3v3(ray_normal, ray_end, ray_start); dist= normalize_v3(ray_normal); srd.ss = vc->obact->sculpt; srd.ray_start = ray_start; srd.ray_normal = ray_normal; srd.dist = dist; srd.hit = 0; srd.original = (cache)? cache->original: 0; BLI_pbvh_raycast(ss->pbvh, sculpt_raycast_cb, &srd, ray_start, ray_normal, srd.original); copy_v3_v3(out, ray_normal); mul_v3_fl(out, srd.dist); add_v3_v3(out, ray_start); return srd.hit; } static void sculpt_brush_init_tex(Sculpt *sd, SculptSession *ss) { Brush *brush = paint_brush(&sd->paint); MTex *mtex= &brush->mtex; /* init mtex nodes */ if(mtex->tex && mtex->tex->nodetree) ntreeTexBeginExecTree(mtex->tex->nodetree, 1); /* has internal flag to detect it only does it once */ /* TODO: Shouldn't really have to do this at the start of every stroke, but sculpt would need some sort of notification when changes are made to the texture. */ sculpt_update_tex(sd, ss); } static int sculpt_brush_stroke_init(bContext *C, wmOperator *op) { Scene *scene= CTX_data_scene(C); Object *ob= CTX_data_active_object(C); Sculpt *sd = CTX_data_tool_settings(C)->sculpt; SculptSession *ss = CTX_data_active_object(C)->sculpt; Brush *brush = paint_brush(&sd->paint); int mode= RNA_enum_get(op->ptr, "mode"); int is_smooth= 0; view3d_operator_needs_opengl(C); sculpt_brush_init_tex(sd, ss); is_smooth|= mode == BRUSH_STROKE_SMOOTH; is_smooth|= brush->sculpt_tool == SCULPT_TOOL_SMOOTH; sculpt_update_mesh_elements(scene, sd, ob, is_smooth); return 1; } static void sculpt_restore_mesh(Sculpt *sd, SculptSession *ss) { Brush *brush = paint_brush(&sd->paint); /* Restore the mesh before continuing with anchored stroke */ if((brush->flag & BRUSH_ANCHORED) || (brush->sculpt_tool == SCULPT_TOOL_GRAB && brush_use_size_pressure(brush)) || (brush->flag & BRUSH_RESTORE_MESH)) { StrokeCache *cache = ss->cache; int i; PBVHNode **nodes; int n, totnode; BLI_pbvh_search_gather(ss->pbvh, NULL, NULL, &nodes, &totnode); #pragma omp parallel for schedule(guided) if (sd->flags & SCULPT_USE_OPENMP) for(n=0; n<totnode; n++) { SculptUndoNode *unode; unode= sculpt_undo_get_node(nodes[n]); if(unode) { PBVHVertexIter vd; BLI_pbvh_vertex_iter_begin(ss->pbvh, nodes[n], vd, PBVH_ITER_UNIQUE) { copy_v3_v3(vd.co, unode->co[vd.i]); if(vd.no) copy_v3_v3_short(vd.no, unode->no[vd.i]); else normal_short_to_float_v3(vd.fno, unode->no[vd.i]); if(vd.mvert) vd.mvert->flag |= ME_VERT_PBVH_UPDATE; } BLI_pbvh_vertex_iter_end; BLI_pbvh_node_mark_update(nodes[n]); } } if(ss->face_normals) { float *fn = ss->face_normals; for(i = 0; i < ss->totface; ++i, fn += 3) copy_v3_v3(fn, cache->face_norms[i]); } if(nodes) MEM_freeN(nodes); } } static void sculpt_flush_update(bContext *C) { Object *ob = CTX_data_active_object(C); SculptSession *ss = ob->sculpt; ARegion *ar = CTX_wm_region(C); MultiresModifierData *mmd = ss->multires; if(mmd) multires_mark_as_modified(ob); if(ob->derivedFinal) /* VBO no longer valid */ GPU_drawobject_free(ob->derivedFinal); if(ss->modifiers_active) { DAG_id_tag_update(&ob->id, OB_RECALC_DATA); ED_region_tag_redraw(ar); } else { rcti r; BLI_pbvh_update(ss->pbvh, PBVH_UpdateBB, NULL); if (sculpt_get_redraw_rect(ar, CTX_wm_region_view3d(C), ob, &r)) { if (ss->cache) ss->cache->previous_r= r; r.xmin += ar->winrct.xmin + 1; r.xmax += ar->winrct.xmin - 1; r.ymin += ar->winrct.ymin + 1; r.ymax += ar->winrct.ymin - 1; ss->partial_redraw = 1; ED_region_tag_redraw_partial(ar, &r); } } } /* Returns whether the mouse/stylus is over the mesh (1) or over the background (0) */ static int over_mesh(bContext *C, struct wmOperator *op, float x, float y) { float mouse[2], co[3]; mouse[0] = x; mouse[1] = y; return sculpt_stroke_get_location(C, op->customdata, co, mouse); } static int sculpt_stroke_test_start(bContext *C, struct wmOperator *op, wmEvent *event) { /* Don't start the stroke until mouse goes over the mesh. * note: event will only be null when re-executing the saved stroke. */ if(event==NULL || over_mesh(C, op, event->x, event->y)) { Object *ob = CTX_data_active_object(C); SculptSession *ss = ob->sculpt; Sculpt *sd = CTX_data_tool_settings(C)->sculpt; ED_view3d_init_mats_rv3d(ob, CTX_wm_region_view3d(C)); sculpt_update_cache_invariants(C, sd, ss, op, event); sculpt_undo_push_begin(sculpt_tool_name(sd)); #ifdef _OPENMP /* If using OpenMP then create a number of threads two times the number of processor cores. Justification: Empirically I've found that two threads per processor gives higher throughput. */ if (sd->flags & SCULPT_USE_OPENMP) { int num_procs; num_procs = omp_get_num_procs(); omp_set_num_threads(2*num_procs); } #endif return 1; } else return 0; } static void sculpt_stroke_update_step(bContext *C, struct PaintStroke *stroke, PointerRNA *itemptr) { Sculpt *sd = CTX_data_tool_settings(C)->sculpt; Object *ob = CTX_data_active_object(C); SculptSession *ss = ob->sculpt; sculpt_stroke_modifiers_check(C, ob); sculpt_update_cache_variants(C, sd, ob, stroke, itemptr); sculpt_restore_mesh(sd, ss); do_symmetrical_brush_actions(sd, ob); /* Cleanup */ sculpt_flush_update(C); } static void sculpt_brush_exit_tex(Sculpt *sd) { Brush *brush= paint_brush(&sd->paint); MTex *mtex= &brush->mtex; if(mtex->tex && mtex->tex->nodetree) ntreeTexEndExecTree(mtex->tex->nodetree->execdata, 1); } static void sculpt_stroke_done(bContext *C, struct PaintStroke *UNUSED(stroke)) { Object *ob= CTX_data_active_object(C); SculptSession *ss = ob->sculpt; Sculpt *sd = CTX_data_tool_settings(C)->sculpt; // reset values used to draw brush after completing the stroke sd->draw_anchored= 0; sd->draw_pressure= 0; sd->special_rotation= 0; /* Finished */ if(ss->cache) { Brush *brush= paint_brush(&sd->paint); brush->flag &= ~BRUSH_INVERTED; sculpt_stroke_modifiers_check(C, ob); /* Alt-Smooth */ if (ss->cache->alt_smooth) { Paint *p= &sd->paint; brush= (Brush *)find_id("BR", ss->cache->saved_active_brush_name); if(brush) { paint_brush_set(p, brush); } } sculpt_cache_free(ss->cache); ss->cache = NULL; sculpt_undo_push_end(); BLI_pbvh_update(ss->pbvh, PBVH_UpdateOriginalBB, NULL); /* optimization: if there is locked key and active modifiers present in */ /* the stack, keyblock is updating at each step. otherwise we could update */ /* keyblock only when stroke is finished */ if(ss->kb && !ss->modifiers_active) sculpt_update_keyblock(ob); ss->partial_redraw = 0; /* try to avoid calling this, only for e.g. linked duplicates now */ if(((Mesh*)ob->data)->id.us > 1) DAG_id_tag_update(&ob->id, OB_RECALC_DATA); WM_event_add_notifier(C, NC_OBJECT|ND_DRAW, ob); } sculpt_brush_exit_tex(sd); } static int sculpt_brush_stroke_invoke(bContext *C, wmOperator *op, wmEvent *event) { struct PaintStroke *stroke; int ignore_background_click; if(!sculpt_brush_stroke_init(C, op)) return OPERATOR_CANCELLED; stroke = paint_stroke_new(C, sculpt_stroke_get_location, sculpt_stroke_test_start, sculpt_stroke_update_step, sculpt_stroke_done, event->type); op->customdata = stroke; /* For tablet rotation */ ignore_background_click = RNA_boolean_get(op->ptr, "ignore_background_click"); if(ignore_background_click && !over_mesh(C, op, event->x, event->y)) { paint_stroke_free(stroke); return OPERATOR_PASS_THROUGH; } /* add modal handler */ WM_event_add_modal_handler(C, op); op->type->modal(C, op, event); return OPERATOR_RUNNING_MODAL; } static int sculpt_brush_stroke_exec(bContext *C, wmOperator *op) { if(!sculpt_brush_stroke_init(C, op)) return OPERATOR_CANCELLED; op->customdata = paint_stroke_new(C, sculpt_stroke_get_location, sculpt_stroke_test_start, sculpt_stroke_update_step, sculpt_stroke_done, 0); /* frees op->customdata */ paint_stroke_exec(C, op); return OPERATOR_FINISHED; } static int sculpt_brush_stroke_cancel(bContext *C, wmOperator *op) { Object *ob= CTX_data_active_object(C); SculptSession *ss = ob->sculpt; Sculpt *sd = CTX_data_tool_settings(C)->sculpt; paint_stroke_cancel(C, op); if(ss->cache) { sculpt_cache_free(ss->cache); ss->cache = NULL; } sculpt_brush_exit_tex(sd); return OPERATOR_CANCELLED; } static void SCULPT_OT_brush_stroke(wmOperatorType *ot) { static EnumPropertyItem stroke_mode_items[] = { {BRUSH_STROKE_NORMAL, "NORMAL", 0, "Normal", "Apply brush normally"}, {BRUSH_STROKE_INVERT, "INVERT", 0, "Invert", "Invert action of brush for duration of stroke"}, {BRUSH_STROKE_SMOOTH, "SMOOTH", 0, "Smooth", "Switch brush to smooth mode for duration of stroke"}, {0} }; /* identifiers */ ot->name= "Sculpt Mode"; ot->idname= "SCULPT_OT_brush_stroke"; /* api callbacks */ ot->invoke= sculpt_brush_stroke_invoke; ot->modal= paint_stroke_modal; ot->exec= sculpt_brush_stroke_exec; ot->poll= sculpt_poll; ot->cancel= sculpt_brush_stroke_cancel; /* flags (sculpt does own undo? (ton) */ ot->flag= OPTYPE_BLOCKING; /* properties */ RNA_def_collection_runtime(ot->srna, "stroke", &RNA_OperatorStrokeElement, "Stroke", ""); RNA_def_enum(ot->srna, "mode", stroke_mode_items, BRUSH_STROKE_NORMAL, "Sculpt Stroke Mode", "Action taken when a sculpt stroke is made"); RNA_def_boolean(ot->srna, "ignore_background_click", 0, "Ignore Background Click", "Clicks on the background do not start the stroke"); } /**** Reset the copy of the mesh that is being sculpted on (currently just for the layer brush) ****/ static int sculpt_set_persistent_base(bContext *C, wmOperator *UNUSED(op)) { SculptSession *ss = CTX_data_active_object(C)->sculpt; if(ss) { if(ss->layer_co) MEM_freeN(ss->layer_co); ss->layer_co = NULL; } return OPERATOR_FINISHED; } static void SCULPT_OT_set_persistent_base(wmOperatorType *ot) { /* identifiers */ ot->name= "Set Persistent Base"; ot->idname= "SCULPT_OT_set_persistent_base"; /* api callbacks */ ot->exec= sculpt_set_persistent_base; ot->poll= sculpt_mode_poll; ot->flag= OPTYPE_REGISTER|OPTYPE_UNDO; } /**** Toggle operator for turning sculpt mode on or off ****/ static void sculpt_init_session(Scene *scene, Object *ob) { ob->sculpt = MEM_callocN(sizeof(SculptSession), "sculpt session"); sculpt_update_mesh_elements(scene, scene->toolsettings->sculpt, ob, 0); } static int sculpt_toggle_mode(bContext *C, wmOperator *UNUSED(op)) { Scene *scene = CTX_data_scene(C); ToolSettings *ts = CTX_data_tool_settings(C); Object *ob = CTX_data_active_object(C); MultiresModifierData *mmd= sculpt_multires_active(scene, ob); int flush_recalc= 0; /* multires in sculpt mode could have different from object mode subdivision level */ flush_recalc |= mmd && mmd->sculptlvl != mmd->lvl; /* if object has got active modifiers, it's dm could be different in sculpt mode */ flush_recalc |= sculpt_has_active_modifiers(scene, ob); if(ob->mode & OB_MODE_SCULPT) { if(mmd) multires_force_update(ob); if(flush_recalc) DAG_id_tag_update(&ob->id, OB_RECALC_DATA); /* Leave sculptmode */ ob->mode &= ~OB_MODE_SCULPT; free_sculptsession(ob); } else { /* Enter sculptmode */ ob->mode |= OB_MODE_SCULPT; if(flush_recalc) DAG_id_tag_update(&ob->id, OB_RECALC_DATA); /* Create persistent sculpt mode data */ if(!ts->sculpt) { ts->sculpt = MEM_callocN(sizeof(Sculpt), "sculpt mode data"); /* Turn on X plane mirror symmetry by default */ ts->sculpt->flags |= SCULPT_SYMM_X; } /* Create sculpt mode session data */ if(ob->sculpt) free_sculptsession(ob); sculpt_init_session(scene, ob); paint_init(&ts->sculpt->paint, PAINT_CURSOR_SCULPT); paint_cursor_start(C, sculpt_poll); } WM_event_add_notifier(C, NC_SCENE|ND_MODE, CTX_data_scene(C)); return OPERATOR_FINISHED; } static void SCULPT_OT_sculptmode_toggle(wmOperatorType *ot) { /* identifiers */ ot->name= "Sculpt Mode"; ot->idname= "SCULPT_OT_sculptmode_toggle"; /* api callbacks */ ot->exec= sculpt_toggle_mode; ot->poll= ED_operator_object_active_editable_mesh; ot->flag= OPTYPE_REGISTER|OPTYPE_UNDO; } void ED_operatortypes_sculpt(void) { WM_operatortype_append(SCULPT_OT_brush_stroke); WM_operatortype_append(SCULPT_OT_sculptmode_toggle); WM_operatortype_append(SCULPT_OT_set_persistent_base); }

mmap_spin.c

#include <sys/types.h> #include <sys/stat.h> #include <fcntl.h> #include <stdio.h> #include <stdlib.h> #include <sys/mman.h> #include <unistd.h> #include <string.h> int main() { size_t size = 8294400; int fd = open("/tmp/testmmap", O_RDWR | O_CREAT, S_IRUSR | S_IWUSR); ftruncate(fd, size + 64); char *buf = (char*)mmap(NULL, 64 + size, PROT_READ|PROT_WRITE, MAP_SHARED, fd, 0); char *src = (char*)malloc(size); buf[0] = 1; for (size_t i = 0; i < size; i++) { src[i] = i; } for (int j = 0; j < 100; j++) { printf("send %d\n", j); #pragma omp parallel for for (size_t i = 0; i < size; i += size/4) { memcpy(buf+(i+64), src+i, size/4); } buf[0] = 0; } return 0; }

Network.h

/* * Network.h * * Created by Guido Novati on 30.10.18. * Copyright 2018 ETH Zurich. All rights reserved. * */ #pragma once #include "Layers.h" struct Network { std::mt19937 gen; // Vector of layers, each defines a forward and bckward operation: std::vector<Layer*> layers; // Vector of parameters of each layer (two vectors must have the same size) // Each Params contains the matrices of parameters needed by the corresp layer std::vector<Params*> params; // Vector of grads for each parameter. By definition they have the same size std::vector<Params*> grads; // Memory space where each layer can compute its output and gradient: std::vector<Activation*> workspace; // Number of inputs to the network: int nInputs = 0; // Number of network outputs: int nOutputs = 0; Network(const int seed = 0) : gen(seed) {}; std::vector<std::vector<Real>> forward( // one vector of input for each element in the mini-batch: const std::vector<std::vector<Real>> I, // layer ID at which to start forward operation: const size_t layerStart = 0 // (zero means compute from input to output) ) { if(params.size()==0 || grads.size()==0 || layers.size()==0) { printf("Attempted to access uninitialized network. Aborting\n"); abort(); } // input is a minibatch of datapoints: one vector for each datapoint: const size_t batchSize = I.size(); // allocate workspaces where we can write output of each layer clearWorkspace(); workspace = allocateActivation(batchSize); // User can overwrite the output of any upper layer (marked by layerStart) // in order to see what happens if layer layerStart has a predefined output. // ( this allows visualizing PCA components! ) const int inputLayerSize = workspace[layerStart]->layersSize; //copy input onto output of input layer: #pragma omp parallel for schedule(static) for (size_t b=0; b<batchSize; b++) { assert(I[b].size() == (size_t) inputLayerSize ); // Input to the network is the output of input layer. // Respective workspace is a matrix of size [batchSize]x[nInputs] // Here we use row-major ordering: nInputs is the number of columns. Real* const input_b = workspace[layerStart]->output + b * inputLayerSize; // copy from function argument to workspace: std::copy(I[b].begin(), I[b].end(), input_b); } // Start from layer after input. E.g. Input layer is 0. No need to backprop // input layer has it has no parameters. for (size_t j=layerStart+1; j<layers.size(); j++) layers[j]->forward(workspace, params); // copy output into vector of vectors: one vector for each element of batch std::vector<std::vector<Real>> O(batchSize, std::vector<Real>(nOutputs, 0)); #pragma omp parallel for schedule(static) for (size_t b=0; b<batchSize; b++) { assert(nOutputs == workspace.back()->layersSize); // network output is the output of last layer. // Respective workspace is a matrix of size [batchSize]x[nOutputs] // Here we use row-major ordering: nOutputs is the number of columns. Real* const output_b = workspace.back()->output + b * nOutputs; // copy from function argument to workspace: std::copy(output_b, output_b + nOutputs, O[b].begin()); } return O; } void bckward( // vector of size of mini-batch of gradients of error wrt to network output const std::vector<std::vector<Real>> E, // layer ID at which forward operation was started: const size_t layerStart=0 // (zero means compute from input to output) ) const { //this function assumes that we already called forward propagation if(params.size()==0 || grads.size()==0 || layers.size()==0) { printf("Attempted to access uninitialized network. Aborting\n"); abort(); } // input is a minibatch of datapoints: one vector for each datapoint: const size_t batchSize = E.size(); assert( (size_t) workspace.back()->batchSize == batchSize); // first, clear memory over which we'll write gradients: for(auto& p : workspace) p->clearErrors(); //copy input onto output of input layer: for (size_t b=0; b<batchSize; b++) { assert(E[b].size() == (size_t) nOutputs); // Write d Err / d Out onto last layer of the network. // Respective workspace is a matrix of size [batchSize]x[nOutputs] // Here we use row-major ordering: nOutputs is the number of columns. Real* const errors_b = workspace.back()->dError_dOutput + b * nOutputs; // copy from function argument to workspace: std::copy(E[b].begin(), E[b].end(), errors_b); } // Backprop starts at the last layer, which computes gradient of error wrt // to its parameters and gradient of error wrt to it's input. // Last layer to backprop is the one above input layer. Eg. if layerStart=0 // Then input layer was 0, which has no parametes and has no inputs to // backprp the error grad to, last layer to backprop is layer 1. for (size_t i = layers.size()-1; i >= layerStart + 1; i--) layers[i]->bckward(workspace, params, grads); } // Helper function for forward with batchsize = 1 std::vector<Real> forward(const std::vector<Real>I, const size_t layerStart=0) { std::vector<std::vector<Real>> vecI (1, I); std::vector<std::vector<Real>> vecO = forward(vecI, layerStart); return vecO[0]; } // Helper function for forward with batchsize = 1) void bckward(const std::vector<Real> E, const size_t layerStart = 0) const { std::vector<std::vector<Real>> vecE (1, E); bckward(vecE, layerStart); } void save() const { for(const auto &l : layers) l->save(params); } void restart() const { for(const auto &l : layers) l->restart(params); } ~Network() { for(auto& p : grads) _dispose_object(p); for(auto& p : params) _dispose_object(p); for(auto& p : layers) _dispose_object(p); for(auto& p : workspace) _dispose_object(p); } inline void clearWorkspace() { for(auto& p : workspace) _dispose_object(p); workspace.clear(); } // Function to loop over layers and allocate workspace for network operations: inline std::vector<Activation*> allocateActivation(size_t batchSize) const { std::vector<Activation*> ret(layers.size(), nullptr); for(size_t j=0; j<layers.size(); j++) ret[j] = layers[j]->allocateActivation(batchSize); return ret; } // Function to loop over layers and allocate memory space for parameter grads: inline std::vector<Params*> allocateGrad() const { std::vector<Params*> ret(layers.size(), nullptr); for(size_t j=0; j<layers.size(); j++) ret[j] = layers[j]->allocate_params(); return ret; } ////////////////////////////////////////////////////////////////////////////// /// Functions to build the network are defined in Network_buildFunctions.h /// ////////////////////////////////////////////////////////////////////////////// template<int size> void addInput(); template<int nInputs, int size> void addLinear(const std::string fname = std::string()); template<int size> void addTanh(); }; #include "Network_buildFunctions.h"

deconv_2d.h

// Copyright 2018 Xiaomi, Inc. All rights reserved. // // Licensed under the Apache License, Version 2.0 (the "License"); // you may not use this file except in compliance with the License. // You may obtain a copy of the License at // // http://www.apache.org/licenses/LICENSE-2.0 // // Unless required by applicable law or agreed to in writing, software // distributed under the License is distributed on an "AS IS" BASIS, // WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. // See the License for the specific language governing permissions and // limitations under the License. #ifndef MACE_KERNELS_DECONV_2D_H_ #define MACE_KERNELS_DECONV_2D_H_ #if defined(MACE_ENABLE_NEON) && defined(__aarch64__) #include <arm_neon.h> #endif #include <algorithm> #include <memory> #include <vector> #include "mace/core/future.h" #include "mace/core/tensor.h" #include "mace/kernels/activation.h" #include "mace/kernels/conv_pool_2d_util.h" #include "mace/utils/utils.h" #ifdef MACE_ENABLE_OPENCL #include "mace/core/runtime/opencl/cl2_header.h" #endif // MACE_ENABLE_OPENCL namespace mace { namespace kernels { namespace deconv { template<typename T> void Deconv2dNCHW(const T *input, const T *filter, const T *bias, const index_t *in_shape, const index_t *out_shape, const index_t *kernel_hw, const int *strides, const int *padding, float *output) { #pragma omp parallel for collapse(4) for (index_t b = 0; b < out_shape[0]; ++b) { for (index_t oc = 0; oc < out_shape[1]; ++oc) { for (index_t oh = 0; oh < out_shape[2]; ++oh) { for (index_t ow = 0; ow < out_shape[3]; ++ow) { index_t filter_start_y, filter_start_x; index_t start_x = std::max<int>(0, ow + strides[1] -1 - padding[1]); index_t start_y = std::max<int>(0, oh + strides[0] -1 - padding[0]); start_x /= strides[1]; start_y /= strides[0]; filter_start_x = padding[1] + strides[1] * start_x - ow; filter_start_y = padding[0] + strides[0] * start_y - oh; filter_start_x = kernel_hw[1] - 1 - filter_start_x; filter_start_y = kernel_hw[0] - 1 - filter_start_y; T out_value = 0; index_t out_pos = ((b * out_shape[1] + oc) * out_shape[2] + oh) * out_shape[3] + ow; for (index_t ic = 0; ic < in_shape[1]; ++ic) { for (index_t f_y = filter_start_y, ih = start_y; f_y >= 0 && ih < in_shape[2]; f_y -= strides[0], ++ih) { for (index_t f_x = filter_start_x, iw = start_x; f_x >= 0 && iw < in_shape[3]; f_x -= strides[1], ++iw) { index_t weight_pos = ((oc * in_shape[1] + ic) * kernel_hw[0] + f_y) * kernel_hw[1] + f_x; index_t in_pos = ((b * in_shape[1] + ic) * in_shape[2] + ih) * in_shape[3] + iw; out_value += input[in_pos] * filter[weight_pos]; } } } if (bias != nullptr) out_value += bias[oc]; output[out_pos] = out_value; } } } } } } // namespace deconv struct Deconv2dFunctorBase { Deconv2dFunctorBase(const int *strides, const Padding &padding_type, const std::vector<int> &paddings, const std::vector<index_t> &output_shape, const ActivationType activation, const float relux_max_limit, const bool from_caffe) : strides_(strides), padding_type_(padding_type), paddings_(paddings), output_shape_(output_shape), activation_(activation), relux_max_limit_(relux_max_limit), from_caffe_(from_caffe) {} static void CalcDeconvOutputSize( const index_t *input_shape, // NHWC const index_t *filter_shape, // OIHW const int *strides, index_t *output_shape, const int *padding_size, const bool isNCHW = false) { MACE_CHECK_NOTNULL(output_shape); MACE_CHECK_NOTNULL(padding_size); MACE_CHECK_NOTNULL(input_shape); MACE_CHECK_NOTNULL(filter_shape); MACE_CHECK_NOTNULL(strides); const index_t output_channel = filter_shape[0]; const index_t in_height = isNCHW ? input_shape[2] : input_shape[1]; const index_t in_width = isNCHW ? input_shape[3] : input_shape[2]; const index_t filter_h = filter_shape[2]; const index_t filter_w = filter_shape[3]; index_t out_height = (in_height - 1) * strides[0] + filter_h -padding_size[0]; index_t out_width = (in_width - 1) * strides[1] + filter_w -padding_size[1]; output_shape[0] = input_shape[0]; if (isNCHW) { output_shape[1] = output_channel; output_shape[2] = out_height; output_shape[3] = out_width; } else { output_shape[1] = out_height; output_shape[2] = out_width; output_shape[3] = output_channel; } } static void CalcDeconvPaddingAndInputSize( const index_t *input_shape, // NHWC const index_t *filter_shape, // OIHW const int *strides, Padding padding, const index_t *output_shape, int *padding_size, const bool isNCHW = false) { MACE_CHECK_NOTNULL(output_shape); MACE_CHECK_NOTNULL(padding_size); MACE_CHECK_NOTNULL(input_shape); MACE_CHECK_NOTNULL(filter_shape); MACE_CHECK_NOTNULL(strides); const index_t in_height = isNCHW ? input_shape[2] : input_shape[1]; const index_t in_width = isNCHW ? input_shape[3] : input_shape[2]; const index_t out_height = isNCHW ? output_shape[2] : output_shape[1]; const index_t out_width = isNCHW ? output_shape[3] : output_shape[2]; const index_t extended_input_height = (in_height - 1) * strides[0] + 1; const index_t extended_input_width = (in_width - 1) * strides[1] + 1; const index_t filter_h = filter_shape[2]; const index_t filter_w = filter_shape[3]; index_t expected_input_height = 0, expected_input_width = 0; switch (padding) { case VALID: expected_input_height = (out_height - filter_h + strides[0]) / strides[0]; expected_input_width = (out_width - filter_w + strides[1]) / strides[1]; break; case SAME: expected_input_height = (out_height + strides[0] - 1) / strides[0]; expected_input_width = (out_width + strides[1] - 1) / strides[1]; break; default: MACE_CHECK(false, "Unsupported padding type: ", padding); } MACE_CHECK(expected_input_height == in_height, expected_input_height, "!=", in_height); MACE_CHECK(expected_input_width == in_width, expected_input_width, "!=", in_width); const int p_h = static_cast<int>(out_height + filter_h - 1 - extended_input_height); const int p_w = static_cast<int>(out_width + filter_w - 1 - extended_input_width); padding_size[0] = std::max<int>(0, p_h); padding_size[1] = std::max<int>(0, p_w); } const int *strides_; // [stride_h, stride_w] const Padding padding_type_; std::vector<int> paddings_; std::vector<index_t> output_shape_; const ActivationType activation_; const float relux_max_limit_; const bool from_caffe_; }; template <DeviceType D, typename T> struct Deconv2dFunctor : Deconv2dFunctorBase { Deconv2dFunctor(const int *strides, const Padding &padding_type, const std::vector<int> &paddings, const std::vector<index_t> &output_shape, const ActivationType activation, const float relux_max_limit, const bool from_caffe) : Deconv2dFunctorBase(strides, padding_type, paddings, output_shape, activation, relux_max_limit, from_caffe) {} MaceStatus operator()(const Tensor *input, // NCHW const Tensor *filter, // OIHW const Tensor *bias, const Tensor *output_shape_tensor, Tensor *output, StatsFuture *future) { MACE_UNUSED(future); MACE_CHECK_NOTNULL(input); MACE_CHECK_NOTNULL(filter); MACE_CHECK_NOTNULL(output); if (!from_caffe_) { // tensorflow std::vector<index_t> output_shape(4); if (output_shape_.size() == 4) { output_shape[0] = output_shape_[0]; output_shape[1] = output_shape_[3]; output_shape[2] = output_shape_[1]; output_shape[3] = output_shape_[2]; } else { MACE_CHECK_NOTNULL(output_shape_tensor); MACE_CHECK(output_shape_tensor->size() == 4); Tensor::MappingGuard output_shape_mapper(output_shape_tensor); auto output_shape_data = output_shape_tensor->data<int32_t>(); output_shape = std::vector<index_t>(output_shape_data, output_shape_data + 4); } paddings_.clear(); paddings_ = std::vector<int>(2, 0); CalcDeconvPaddingAndInputSize( input->shape().data(), filter->shape().data(), strides_, padding_type_, output_shape.data(), paddings_.data(), true); MACE_RETURN_IF_ERROR(output->Resize(output_shape)); } else { // caffe output_shape_.clear(); output_shape_ = std::vector<index_t>(4, 0); CalcDeconvOutputSize(input->shape().data(), filter->shape().data(), strides_, output_shape_.data(), paddings_.data(), true); MACE_RETURN_IF_ERROR(output->Resize(output_shape_)); } index_t kernel_h = filter->dim(2); index_t kernel_w = filter->dim(3); const index_t *in_shape = input->shape().data(); const index_t *out_shape = output->shape().data(); const index_t kernel_hw[2] = {kernel_h, kernel_w}; MACE_CHECK(filter->dim(0) == out_shape[1], filter->dim(0), " != ", out_shape[1]); MACE_CHECK(filter->dim(1) == in_shape[1], filter->dim(1), " != ", in_shape[1]); MACE_CHECK(in_shape[0] == out_shape[0], "Input/Output batch size mismatch"); Tensor::MappingGuard input_mapper(input); Tensor::MappingGuard filter_mapper(filter); Tensor::MappingGuard bias_mapper(bias); Tensor::MappingGuard output_mapper(output); auto input_data = input->data<T>(); auto filter_data = filter->data<T>(); auto bias_data = bias == nullptr ? nullptr : bias->data<T>(); auto output_data = output->mutable_data<T>(); int padding[2]; padding[0] = (paddings_[0] + 1) >> 1; padding[1] = (paddings_[1] + 1) >> 1; deconv::Deconv2dNCHW(input_data, filter_data, bias_data, in_shape, out_shape, kernel_hw, strides_, padding, output_data); DoActivation(output_data, output_data, output->size(), activation_, relux_max_limit_); return MACE_SUCCESS; } }; #ifdef MACE_ENABLE_OPENCL template <typename T> struct Deconv2dFunctor<DeviceType::GPU, T> : Deconv2dFunctorBase { Deconv2dFunctor(const int *strides, const Padding &padding_type, const std::vector<int> &paddings, const std::vector<index_t> &output_shape, const ActivationType activation, const float relux_max_limit, const bool from_caffe) : Deconv2dFunctorBase(strides, padding_type, paddings, output_shape, activation, relux_max_limit, from_caffe) {} MaceStatus operator()(const Tensor *input, const Tensor *filter, const Tensor *bias, const Tensor *output_shape_tensor, Tensor *output, StatsFuture *future); cl::Kernel kernel_; uint32_t kwg_size_; std::unique_ptr<BufferBase> kernel_error_; std::vector<index_t> input_shape_; }; #endif // MACE_ENABLE_OPENCL } // namespace kernels } // namespace mace #endif // MACE_KERNELS_DECONV_2D_H_

dds.c

/* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % DDDD DDDD SSSSS % % D D D D SS % % D D D D SSS % % D D D D SS % % DDDD DDDD SSSSS % % % % % % Read/Write Microsoft Direct Draw Surface Image Format % % % % Software Design % % Bianca van Schaik % % March 2008 % % Dirk Lemstra % % September 2013 % % % % % % Copyright 1999-2021 ImageMagick Studio LLC, a non-profit organization % % dedicated to making software imaging solutions freely available. % % % % You may not use this file except in compliance with the License. You may % % obtain a copy of the License at % % % % https://imagemagick.org/script/license.php % % % % Unless required by applicable law or agreed to in writing, software % % distributed under the License is distributed on an "AS IS" BASIS, % % WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. % % See the License for the specific language governing permissions and % % limitations under the License. % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % */ /* Include declarations. */ #include "MagickCore/studio.h" #include "MagickCore/attribute.h" #include "MagickCore/blob.h" #include "MagickCore/blob-private.h" #include "MagickCore/cache.h" #include "MagickCore/colorspace.h" #include "MagickCore/colorspace-private.h" #include "MagickCore/exception.h" #include "MagickCore/exception-private.h" #include "MagickCore/image.h" #include "MagickCore/image-private.h" #include "MagickCore/list.h" #include "MagickCore/log.h" #include "MagickCore/magick.h" #include "MagickCore/memory_.h" #include "MagickCore/monitor.h" #include "MagickCore/monitor-private.h" #include "MagickCore/option.h" #include "MagickCore/pixel-accessor.h" #include "MagickCore/profile.h" #include "MagickCore/quantum.h" #include "MagickCore/quantum-private.h" #include "MagickCore/resource_.h" #include "MagickCore/static.h" #include "MagickCore/string_.h" #include "MagickCore/string-private.h" #include "MagickCore/module.h" #include "MagickCore/transform.h" /* Definitions */ #define DDSD_CAPS 0x00000001 #define DDSD_HEIGHT 0x00000002 #define DDSD_WIDTH 0x00000004 #define DDSD_PITCH 0x00000008 #define DDSD_PIXELFORMAT 0x00001000 #define DDSD_MIPMAPCOUNT 0x00020000 #define DDSD_LINEARSIZE 0x00080000 #define DDSD_DEPTH 0x00800000 #define DDPF_ALPHAPIXELS 0x00000001 #define DDPF_FOURCC 0x00000004 #define DDPF_RGB 0x00000040 #define DDPF_LUMINANCE 0x00020000 #define FOURCC_DXT1 0x31545844 #define FOURCC_DXT3 0x33545844 #define FOURCC_DXT5 0x35545844 #define FOURCC_DX10 0x30315844 #define DDSCAPS_COMPLEX 0x00000008 #define DDSCAPS_TEXTURE 0x00001000 #define DDSCAPS_MIPMAP 0x00400000 #define DDSCAPS2_CUBEMAP 0x00000200 #define DDSCAPS2_CUBEMAP_POSITIVEX 0x00000400 #define DDSCAPS2_CUBEMAP_NEGATIVEX 0x00000800 #define DDSCAPS2_CUBEMAP_POSITIVEY 0x00001000 #define DDSCAPS2_CUBEMAP_NEGATIVEY 0x00002000 #define DDSCAPS2_CUBEMAP_POSITIVEZ 0x00004000 #define DDSCAPS2_CUBEMAP_NEGATIVEZ 0x00008000 #define DDSCAPS2_VOLUME 0x00200000 #define DDSEXT_DIMENSION_TEX2D 0x00000003 #define DDSEXTFLAGS_CUBEMAP 0x00000004 typedef enum DXGI_FORMAT { DXGI_FORMAT_UNKNOWN, DXGI_FORMAT_R32G32B32A32_TYPELESS, DXGI_FORMAT_R32G32B32A32_FLOAT, DXGI_FORMAT_R32G32B32A32_UINT, DXGI_FORMAT_R32G32B32A32_SINT, DXGI_FORMAT_R32G32B32_TYPELESS, DXGI_FORMAT_R32G32B32_FLOAT, DXGI_FORMAT_R32G32B32_UINT, DXGI_FORMAT_R32G32B32_SINT, DXGI_FORMAT_R16G16B16A16_TYPELESS, DXGI_FORMAT_R16G16B16A16_FLOAT, DXGI_FORMAT_R16G16B16A16_UNORM, DXGI_FORMAT_R16G16B16A16_UINT, DXGI_FORMAT_R16G16B16A16_SNORM, DXGI_FORMAT_R16G16B16A16_SINT, DXGI_FORMAT_R32G32_TYPELESS, DXGI_FORMAT_R32G32_FLOAT, DXGI_FORMAT_R32G32_UINT, DXGI_FORMAT_R32G32_SINT, DXGI_FORMAT_R32G8X24_TYPELESS, DXGI_FORMAT_D32_FLOAT_S8X24_UINT, DXGI_FORMAT_R32_FLOAT_X8X24_TYPELESS, DXGI_FORMAT_X32_TYPELESS_G8X24_UINT, DXGI_FORMAT_R10G10B10A2_TYPELESS, DXGI_FORMAT_R10G10B10A2_UNORM, DXGI_FORMAT_R10G10B10A2_UINT, DXGI_FORMAT_R11G11B10_FLOAT, DXGI_FORMAT_R8G8B8A8_TYPELESS, DXGI_FORMAT_R8G8B8A8_UNORM, DXGI_FORMAT_R8G8B8A8_UNORM_SRGB, DXGI_FORMAT_R8G8B8A8_UINT, DXGI_FORMAT_R8G8B8A8_SNORM, DXGI_FORMAT_R8G8B8A8_SINT, DXGI_FORMAT_R16G16_TYPELESS, DXGI_FORMAT_R16G16_FLOAT, DXGI_FORMAT_R16G16_UNORM, DXGI_FORMAT_R16G16_UINT, DXGI_FORMAT_R16G16_SNORM, DXGI_FORMAT_R16G16_SINT, DXGI_FORMAT_R32_TYPELESS, DXGI_FORMAT_D32_FLOAT, DXGI_FORMAT_R32_FLOAT, DXGI_FORMAT_R32_UINT, DXGI_FORMAT_R32_SINT, DXGI_FORMAT_R24G8_TYPELESS, DXGI_FORMAT_D24_UNORM_S8_UINT, DXGI_FORMAT_R24_UNORM_X8_TYPELESS, DXGI_FORMAT_X24_TYPELESS_G8_UINT, DXGI_FORMAT_R8G8_TYPELESS, DXGI_FORMAT_R8G8_UNORM, DXGI_FORMAT_R8G8_UINT, DXGI_FORMAT_R8G8_SNORM, DXGI_FORMAT_R8G8_SINT, DXGI_FORMAT_R16_TYPELESS, DXGI_FORMAT_R16_FLOAT, DXGI_FORMAT_D16_UNORM, DXGI_FORMAT_R16_UNORM, DXGI_FORMAT_R16_UINT, DXGI_FORMAT_R16_SNORM, DXGI_FORMAT_R16_SINT, DXGI_FORMAT_R8_TYPELESS, DXGI_FORMAT_R8_UNORM, DXGI_FORMAT_R8_UINT, DXGI_FORMAT_R8_SNORM, DXGI_FORMAT_R8_SINT, DXGI_FORMAT_A8_UNORM, DXGI_FORMAT_R1_UNORM, DXGI_FORMAT_R9G9B9E5_SHAREDEXP, DXGI_FORMAT_R8G8_B8G8_UNORM, DXGI_FORMAT_G8R8_G8B8_UNORM, DXGI_FORMAT_BC1_TYPELESS, DXGI_FORMAT_BC1_UNORM, DXGI_FORMAT_BC1_UNORM_SRGB, DXGI_FORMAT_BC2_TYPELESS, DXGI_FORMAT_BC2_UNORM, DXGI_FORMAT_BC2_UNORM_SRGB, DXGI_FORMAT_BC3_TYPELESS, DXGI_FORMAT_BC3_UNORM, DXGI_FORMAT_BC3_UNORM_SRGB, DXGI_FORMAT_BC4_TYPELESS, DXGI_FORMAT_BC4_UNORM, DXGI_FORMAT_BC4_SNORM, DXGI_FORMAT_BC5_TYPELESS, DXGI_FORMAT_BC5_UNORM, DXGI_FORMAT_BC5_SNORM, DXGI_FORMAT_B5G6R5_UNORM, DXGI_FORMAT_B5G5R5A1_UNORM, DXGI_FORMAT_B8G8R8A8_UNORM, DXGI_FORMAT_B8G8R8X8_UNORM, DXGI_FORMAT_R10G10B10_XR_BIAS_A2_UNORM, DXGI_FORMAT_B8G8R8A8_TYPELESS, DXGI_FORMAT_B8G8R8A8_UNORM_SRGB, DXGI_FORMAT_B8G8R8X8_TYPELESS, DXGI_FORMAT_B8G8R8X8_UNORM_SRGB, DXGI_FORMAT_BC6H_TYPELESS, DXGI_FORMAT_BC6H_UF16, DXGI_FORMAT_BC6H_SF16, DXGI_FORMAT_BC7_TYPELESS, DXGI_FORMAT_BC7_UNORM, DXGI_FORMAT_BC7_UNORM_SRGB, DXGI_FORMAT_AYUV, DXGI_FORMAT_Y410, DXGI_FORMAT_Y416, DXGI_FORMAT_NV12, DXGI_FORMAT_P010, DXGI_FORMAT_P016, DXGI_FORMAT_420_OPAQUE, DXGI_FORMAT_YUY2, DXGI_FORMAT_Y210, DXGI_FORMAT_Y216, DXGI_FORMAT_NV11, DXGI_FORMAT_AI44, DXGI_FORMAT_IA44, DXGI_FORMAT_P8, DXGI_FORMAT_A8P8, DXGI_FORMAT_B4G4R4A4_UNORM, DXGI_FORMAT_P208, DXGI_FORMAT_V208, DXGI_FORMAT_V408, DXGI_FORMAT_SAMPLER_FEEDBACK_MIN_MIP_OPAQUE, DXGI_FORMAT_SAMPLER_FEEDBACK_MIP_REGION_USED_OPAQUE, DXGI_FORMAT_FORCE_UINT } DXGI_FORMAT; #ifndef SIZE_MAX #define SIZE_MAX ((size_t) -1) #endif /* Structure declarations. */ typedef struct _DDSPixelFormat { size_t flags, fourcc, rgb_bitcount, r_bitmask, g_bitmask, b_bitmask, alpha_bitmask; } DDSPixelFormat; typedef struct _DDSInfo { size_t flags, height, width, pitchOrLinearSize, depth, mipmapcount, ddscaps1, ddscaps2, extFormat, extDimension, extFlags, extArraySize, extFlags2; DDSPixelFormat pixelformat; } DDSInfo; typedef struct _DDSColors { unsigned char r[4], g[4], b[4], a[4]; } DDSColors; typedef struct _BC7Colors { unsigned char r[6], g[6], b[6], a[6]; } BC7Colors; typedef struct _DDSVector4 { float x, y, z, w; } DDSVector4; typedef struct _DDSVector3 { float x, y, z; } DDSVector3; typedef struct _DDSSourceBlock { unsigned char start, end, error; } DDSSourceBlock; typedef struct _DDSSingleColorLookup { DDSSourceBlock sources[2]; } DDSSingleColorLookup; typedef struct _BC7ModeInfo { unsigned char partition_bits, num_subsets, color_precision, alpha_precision, num_pbits, index_precision, index2_precision; } BC7ModeInfo; typedef MagickBooleanType DDSDecoder(const ImageInfo *,Image *,const DDSInfo *,const MagickBooleanType, ExceptionInfo *); typedef MagickBooleanType DDSPixelDecoder(Image *,const DDSInfo *,ExceptionInfo *); static const DDSSingleColorLookup DDSLookup_5_4[] = { { { { 0, 0, 0 }, { 0, 0, 0 } } }, { { { 0, 0, 1 }, { 0, 1, 1 } } }, { { { 0, 0, 2 }, { 0, 1, 0 } } }, { { { 0, 0, 3 }, { 0, 1, 1 } } }, { { { 0, 0, 4 }, { 0, 2, 1 } } }, { { { 1, 0, 3 }, { 0, 2, 0 } } }, { { { 1, 0, 2 }, { 0, 2, 1 } } }, { { { 1, 0, 1 }, { 0, 3, 1 } } }, { { { 1, 0, 0 }, { 0, 3, 0 } } }, { { { 1, 0, 1 }, { 1, 2, 1 } } }, { { { 1, 0, 2 }, { 1, 2, 0 } } }, { { { 1, 0, 3 }, { 0, 4, 0 } } }, { { { 1, 0, 4 }, { 0, 5, 1 } } }, { { { 2, 0, 3 }, { 0, 5, 0 } } }, { { { 2, 0, 2 }, { 0, 5, 1 } } }, { { { 2, 0, 1 }, { 0, 6, 1 } } }, { { { 2, 0, 0 }, { 0, 6, 0 } } }, { { { 2, 0, 1 }, { 2, 3, 1 } } }, { { { 2, 0, 2 }, { 2, 3, 0 } } }, { { { 2, 0, 3 }, { 0, 7, 0 } } }, { { { 2, 0, 4 }, { 1, 6, 1 } } }, { { { 3, 0, 3 }, { 1, 6, 0 } } }, { { { 3, 0, 2 }, { 0, 8, 0 } } }, { { { 3, 0, 1 }, { 0, 9, 1 } } }, { { { 3, 0, 0 }, { 0, 9, 0 } } }, { { { 3, 0, 1 }, { 0, 9, 1 } } }, { { { 3, 0, 2 }, { 0, 10, 1 } } }, { { { 3, 0, 3 }, { 0, 10, 0 } } }, { { { 3, 0, 4 }, { 2, 7, 1 } } }, { { { 4, 0, 4 }, { 2, 7, 0 } } }, { { { 4, 0, 3 }, { 0, 11, 0 } } }, { { { 4, 0, 2 }, { 1, 10, 1 } } }, { { { 4, 0, 1 }, { 1, 10, 0 } } }, { { { 4, 0, 0 }, { 0, 12, 0 } } }, { { { 4, 0, 1 }, { 0, 13, 1 } } }, { { { 4, 0, 2 }, { 0, 13, 0 } } }, { { { 4, 0, 3 }, { 0, 13, 1 } } }, { { { 4, 0, 4 }, { 0, 14, 1 } } }, { { { 5, 0, 3 }, { 0, 14, 0 } } }, { { { 5, 0, 2 }, { 2, 11, 1 } } }, { { { 5, 0, 1 }, { 2, 11, 0 } } }, { { { 5, 0, 0 }, { 0, 15, 0 } } }, { { { 5, 0, 1 }, { 1, 14, 1 } } }, { { { 5, 0, 2 }, { 1, 14, 0 } } }, { { { 5, 0, 3 }, { 0, 16, 0 } } }, { { { 5, 0, 4 }, { 0, 17, 1 } } }, { { { 6, 0, 3 }, { 0, 17, 0 } } }, { { { 6, 0, 2 }, { 0, 17, 1 } } }, { { { 6, 0, 1 }, { 0, 18, 1 } } }, { { { 6, 0, 0 }, { 0, 18, 0 } } }, { { { 6, 0, 1 }, { 2, 15, 1 } } }, { { { 6, 0, 2 }, { 2, 15, 0 } } }, { { { 6, 0, 3 }, { 0, 19, 0 } } }, { { { 6, 0, 4 }, { 1, 18, 1 } } }, { { { 7, 0, 3 }, { 1, 18, 0 } } }, { { { 7, 0, 2 }, { 0, 20, 0 } } }, { { { 7, 0, 1 }, { 0, 21, 1 } } }, { { { 7, 0, 0 }, { 0, 21, 0 } } }, { { { 7, 0, 1 }, { 0, 21, 1 } } }, { { { 7, 0, 2 }, { 0, 22, 1 } } }, { { { 7, 0, 3 }, { 0, 22, 0 } } }, { { { 7, 0, 4 }, { 2, 19, 1 } } }, { { { 8, 0, 4 }, { 2, 19, 0 } } }, { { { 8, 0, 3 }, { 0, 23, 0 } } }, { { { 8, 0, 2 }, { 1, 22, 1 } } }, { { { 8, 0, 1 }, { 1, 22, 0 } } }, { { { 8, 0, 0 }, { 0, 24, 0 } } }, { { { 8, 0, 1 }, { 0, 25, 1 } } }, { { { 8, 0, 2 }, { 0, 25, 0 } } }, { { { 8, 0, 3 }, { 0, 25, 1 } } }, { { { 8, 0, 4 }, { 0, 26, 1 } } }, { { { 9, 0, 3 }, { 0, 26, 0 } } }, { { { 9, 0, 2 }, { 2, 23, 1 } } }, { { { 9, 0, 1 }, { 2, 23, 0 } } }, { { { 9, 0, 0 }, { 0, 27, 0 } } }, { { { 9, 0, 1 }, { 1, 26, 1 } } }, { { { 9, 0, 2 }, { 1, 26, 0 } } }, { { { 9, 0, 3 }, { 0, 28, 0 } } }, { { { 9, 0, 4 }, { 0, 29, 1 } } }, { { { 10, 0, 3 }, { 0, 29, 0 } } }, { { { 10, 0, 2 }, { 0, 29, 1 } } }, { { { 10, 0, 1 }, { 0, 30, 1 } } }, { { { 10, 0, 0 }, { 0, 30, 0 } } }, { { { 10, 0, 1 }, { 2, 27, 1 } } }, { { { 10, 0, 2 }, { 2, 27, 0 } } }, { { { 10, 0, 3 }, { 0, 31, 0 } } }, { { { 10, 0, 4 }, { 1, 30, 1 } } }, { { { 11, 0, 3 }, { 1, 30, 0 } } }, { { { 11, 0, 2 }, { 4, 24, 0 } } }, { { { 11, 0, 1 }, { 1, 31, 1 } } }, { { { 11, 0, 0 }, { 1, 31, 0 } } }, { { { 11, 0, 1 }, { 1, 31, 1 } } }, { { { 11, 0, 2 }, { 2, 30, 1 } } }, { { { 11, 0, 3 }, { 2, 30, 0 } } }, { { { 11, 0, 4 }, { 2, 31, 1 } } }, { { { 12, 0, 4 }, { 2, 31, 0 } } }, { { { 12, 0, 3 }, { 4, 27, 0 } } }, { { { 12, 0, 2 }, { 3, 30, 1 } } }, { { { 12, 0, 1 }, { 3, 30, 0 } } }, { { { 12, 0, 0 }, { 4, 28, 0 } } }, { { { 12, 0, 1 }, { 3, 31, 1 } } }, { { { 12, 0, 2 }, { 3, 31, 0 } } }, { { { 12, 0, 3 }, { 3, 31, 1 } } }, { { { 12, 0, 4 }, { 4, 30, 1 } } }, { { { 13, 0, 3 }, { 4, 30, 0 } } }, { { { 13, 0, 2 }, { 6, 27, 1 } } }, { { { 13, 0, 1 }, { 6, 27, 0 } } }, { { { 13, 0, 0 }, { 4, 31, 0 } } }, { { { 13, 0, 1 }, { 5, 30, 1 } } }, { { { 13, 0, 2 }, { 5, 30, 0 } } }, { { { 13, 0, 3 }, { 8, 24, 0 } } }, { { { 13, 0, 4 }, { 5, 31, 1 } } }, { { { 14, 0, 3 }, { 5, 31, 0 } } }, { { { 14, 0, 2 }, { 5, 31, 1 } } }, { { { 14, 0, 1 }, { 6, 30, 1 } } }, { { { 14, 0, 0 }, { 6, 30, 0 } } }, { { { 14, 0, 1 }, { 6, 31, 1 } } }, { { { 14, 0, 2 }, { 6, 31, 0 } } }, { { { 14, 0, 3 }, { 8, 27, 0 } } }, { { { 14, 0, 4 }, { 7, 30, 1 } } }, { { { 15, 0, 3 }, { 7, 30, 0 } } }, { { { 15, 0, 2 }, { 8, 28, 0 } } }, { { { 15, 0, 1 }, { 7, 31, 1 } } }, { { { 15, 0, 0 }, { 7, 31, 0 } } }, { { { 15, 0, 1 }, { 7, 31, 1 } } }, { { { 15, 0, 2 }, { 8, 30, 1 } } }, { { { 15, 0, 3 }, { 8, 30, 0 } } }, { { { 15, 0, 4 }, { 10, 27, 1 } } }, { { { 16, 0, 4 }, { 10, 27, 0 } } }, { { { 16, 0, 3 }, { 8, 31, 0 } } }, { { { 16, 0, 2 }, { 9, 30, 1 } } }, { { { 16, 0, 1 }, { 9, 30, 0 } } }, { { { 16, 0, 0 }, { 12, 24, 0 } } }, { { { 16, 0, 1 }, { 9, 31, 1 } } }, { { { 16, 0, 2 }, { 9, 31, 0 } } }, { { { 16, 0, 3 }, { 9, 31, 1 } } }, { { { 16, 0, 4 }, { 10, 30, 1 } } }, { { { 17, 0, 3 }, { 10, 30, 0 } } }, { { { 17, 0, 2 }, { 10, 31, 1 } } }, { { { 17, 0, 1 }, { 10, 31, 0 } } }, { { { 17, 0, 0 }, { 12, 27, 0 } } }, { { { 17, 0, 1 }, { 11, 30, 1 } } }, { { { 17, 0, 2 }, { 11, 30, 0 } } }, { { { 17, 0, 3 }, { 12, 28, 0 } } }, { { { 17, 0, 4 }, { 11, 31, 1 } } }, { { { 18, 0, 3 }, { 11, 31, 0 } } }, { { { 18, 0, 2 }, { 11, 31, 1 } } }, { { { 18, 0, 1 }, { 12, 30, 1 } } }, { { { 18, 0, 0 }, { 12, 30, 0 } } }, { { { 18, 0, 1 }, { 14, 27, 1 } } }, { { { 18, 0, 2 }, { 14, 27, 0 } } }, { { { 18, 0, 3 }, { 12, 31, 0 } } }, { { { 18, 0, 4 }, { 13, 30, 1 } } }, { { { 19, 0, 3 }, { 13, 30, 0 } } }, { { { 19, 0, 2 }, { 16, 24, 0 } } }, { { { 19, 0, 1 }, { 13, 31, 1 } } }, { { { 19, 0, 0 }, { 13, 31, 0 } } }, { { { 19, 0, 1 }, { 13, 31, 1 } } }, { { { 19, 0, 2 }, { 14, 30, 1 } } }, { { { 19, 0, 3 }, { 14, 30, 0 } } }, { { { 19, 0, 4 }, { 14, 31, 1 } } }, { { { 20, 0, 4 }, { 14, 31, 0 } } }, { { { 20, 0, 3 }, { 16, 27, 0 } } }, { { { 20, 0, 2 }, { 15, 30, 1 } } }, { { { 20, 0, 1 }, { 15, 30, 0 } } }, { { { 20, 0, 0 }, { 16, 28, 0 } } }, { { { 20, 0, 1 }, { 15, 31, 1 } } }, { { { 20, 0, 2 }, { 15, 31, 0 } } }, { { { 20, 0, 3 }, { 15, 31, 1 } } }, { { { 20, 0, 4 }, { 16, 30, 1 } } }, { { { 21, 0, 3 }, { 16, 30, 0 } } }, { { { 21, 0, 2 }, { 18, 27, 1 } } }, { { { 21, 0, 1 }, { 18, 27, 0 } } }, { { { 21, 0, 0 }, { 16, 31, 0 } } }, { { { 21, 0, 1 }, { 17, 30, 1 } } }, { { { 21, 0, 2 }, { 17, 30, 0 } } }, { { { 21, 0, 3 }, { 20, 24, 0 } } }, { { { 21, 0, 4 }, { 17, 31, 1 } } }, { { { 22, 0, 3 }, { 17, 31, 0 } } }, { { { 22, 0, 2 }, { 17, 31, 1 } } }, { { { 22, 0, 1 }, { 18, 30, 1 } } }, { { { 22, 0, 0 }, { 18, 30, 0 } } }, { { { 22, 0, 1 }, { 18, 31, 1 } } }, { { { 22, 0, 2 }, { 18, 31, 0 } } }, { { { 22, 0, 3 }, { 20, 27, 0 } } }, { { { 22, 0, 4 }, { 19, 30, 1 } } }, { { { 23, 0, 3 }, { 19, 30, 0 } } }, { { { 23, 0, 2 }, { 20, 28, 0 } } }, { { { 23, 0, 1 }, { 19, 31, 1 } } }, { { { 23, 0, 0 }, { 19, 31, 0 } } }, { { { 23, 0, 1 }, { 19, 31, 1 } } }, { { { 23, 0, 2 }, { 20, 30, 1 } } }, { { { 23, 0, 3 }, { 20, 30, 0 } } }, { { { 23, 0, 4 }, { 22, 27, 1 } } }, { { { 24, 0, 4 }, { 22, 27, 0 } } }, { { { 24, 0, 3 }, { 20, 31, 0 } } }, { { { 24, 0, 2 }, { 21, 30, 1 } } }, { { { 24, 0, 1 }, { 21, 30, 0 } } }, { { { 24, 0, 0 }, { 24, 24, 0 } } }, { { { 24, 0, 1 }, { 21, 31, 1 } } }, { { { 24, 0, 2 }, { 21, 31, 0 } } }, { { { 24, 0, 3 }, { 21, 31, 1 } } }, { { { 24, 0, 4 }, { 22, 30, 1 } } }, { { { 25, 0, 3 }, { 22, 30, 0 } } }, { { { 25, 0, 2 }, { 22, 31, 1 } } }, { { { 25, 0, 1 }, { 22, 31, 0 } } }, { { { 25, 0, 0 }, { 24, 27, 0 } } }, { { { 25, 0, 1 }, { 23, 30, 1 } } }, { { { 25, 0, 2 }, { 23, 30, 0 } } }, { { { 25, 0, 3 }, { 24, 28, 0 } } }, { { { 25, 0, 4 }, { 23, 31, 1 } } }, { { { 26, 0, 3 }, { 23, 31, 0 } } }, { { { 26, 0, 2 }, { 23, 31, 1 } } }, { { { 26, 0, 1 }, { 24, 30, 1 } } }, { { { 26, 0, 0 }, { 24, 30, 0 } } }, { { { 26, 0, 1 }, { 26, 27, 1 } } }, { { { 26, 0, 2 }, { 26, 27, 0 } } }, { { { 26, 0, 3 }, { 24, 31, 0 } } }, { { { 26, 0, 4 }, { 25, 30, 1 } } }, { { { 27, 0, 3 }, { 25, 30, 0 } } }, { { { 27, 0, 2 }, { 28, 24, 0 } } }, { { { 27, 0, 1 }, { 25, 31, 1 } } }, { { { 27, 0, 0 }, { 25, 31, 0 } } }, { { { 27, 0, 1 }, { 25, 31, 1 } } }, { { { 27, 0, 2 }, { 26, 30, 1 } } }, { { { 27, 0, 3 }, { 26, 30, 0 } } }, { { { 27, 0, 4 }, { 26, 31, 1 } } }, { { { 28, 0, 4 }, { 26, 31, 0 } } }, { { { 28, 0, 3 }, { 28, 27, 0 } } }, { { { 28, 0, 2 }, { 27, 30, 1 } } }, { { { 28, 0, 1 }, { 27, 30, 0 } } }, { { { 28, 0, 0 }, { 28, 28, 0 } } }, { { { 28, 0, 1 }, { 27, 31, 1 } } }, { { { 28, 0, 2 }, { 27, 31, 0 } } }, { { { 28, 0, 3 }, { 27, 31, 1 } } }, { { { 28, 0, 4 }, { 28, 30, 1 } } }, { { { 29, 0, 3 }, { 28, 30, 0 } } }, { { { 29, 0, 2 }, { 30, 27, 1 } } }, { { { 29, 0, 1 }, { 30, 27, 0 } } }, { { { 29, 0, 0 }, { 28, 31, 0 } } }, { { { 29, 0, 1 }, { 29, 30, 1 } } }, { { { 29, 0, 2 }, { 29, 30, 0 } } }, { { { 29, 0, 3 }, { 29, 30, 1 } } }, { { { 29, 0, 4 }, { 29, 31, 1 } } }, { { { 30, 0, 3 }, { 29, 31, 0 } } }, { { { 30, 0, 2 }, { 29, 31, 1 } } }, { { { 30, 0, 1 }, { 30, 30, 1 } } }, { { { 30, 0, 0 }, { 30, 30, 0 } } }, { { { 30, 0, 1 }, { 30, 31, 1 } } }, { { { 30, 0, 2 }, { 30, 31, 0 } } }, { { { 30, 0, 3 }, { 30, 31, 1 } } }, { { { 30, 0, 4 }, { 31, 30, 1 } } }, { { { 31, 0, 3 }, { 31, 30, 0 } } }, { { { 31, 0, 2 }, { 31, 30, 1 } } }, { { { 31, 0, 1 }, { 31, 31, 1 } } }, { { { 31, 0, 0 }, { 31, 31, 0 } } } }; static const DDSSingleColorLookup DDSLookup_6_4[] = { { { { 0, 0, 0 }, { 0, 0, 0 } } }, { { { 0, 0, 1 }, { 0, 1, 0 } } }, { { { 0, 0, 2 }, { 0, 2, 0 } } }, { { { 1, 0, 1 }, { 0, 3, 1 } } }, { { { 1, 0, 0 }, { 0, 3, 0 } } }, { { { 1, 0, 1 }, { 0, 4, 0 } } }, { { { 1, 0, 2 }, { 0, 5, 0 } } }, { { { 2, 0, 1 }, { 0, 6, 1 } } }, { { { 2, 0, 0 }, { 0, 6, 0 } } }, { { { 2, 0, 1 }, { 0, 7, 0 } } }, { { { 2, 0, 2 }, { 0, 8, 0 } } }, { { { 3, 0, 1 }, { 0, 9, 1 } } }, { { { 3, 0, 0 }, { 0, 9, 0 } } }, { { { 3, 0, 1 }, { 0, 10, 0 } } }, { { { 3, 0, 2 }, { 0, 11, 0 } } }, { { { 4, 0, 1 }, { 0, 12, 1 } } }, { { { 4, 0, 0 }, { 0, 12, 0 } } }, { { { 4, 0, 1 }, { 0, 13, 0 } } }, { { { 4, 0, 2 }, { 0, 14, 0 } } }, { { { 5, 0, 1 }, { 0, 15, 1 } } }, { { { 5, 0, 0 }, { 0, 15, 0 } } }, { { { 5, 0, 1 }, { 0, 16, 0 } } }, { { { 5, 0, 2 }, { 1, 15, 0 } } }, { { { 6, 0, 1 }, { 0, 17, 0 } } }, { { { 6, 0, 0 }, { 0, 18, 0 } } }, { { { 6, 0, 1 }, { 0, 19, 0 } } }, { { { 6, 0, 2 }, { 3, 14, 0 } } }, { { { 7, 0, 1 }, { 0, 20, 0 } } }, { { { 7, 0, 0 }, { 0, 21, 0 } } }, { { { 7, 0, 1 }, { 0, 22, 0 } } }, { { { 7, 0, 2 }, { 4, 15, 0 } } }, { { { 8, 0, 1 }, { 0, 23, 0 } } }, { { { 8, 0, 0 }, { 0, 24, 0 } } }, { { { 8, 0, 1 }, { 0, 25, 0 } } }, { { { 8, 0, 2 }, { 6, 14, 0 } } }, { { { 9, 0, 1 }, { 0, 26, 0 } } }, { { { 9, 0, 0 }, { 0, 27, 0 } } }, { { { 9, 0, 1 }, { 0, 28, 0 } } }, { { { 9, 0, 2 }, { 7, 15, 0 } } }, { { { 10, 0, 1 }, { 0, 29, 0 } } }, { { { 10, 0, 0 }, { 0, 30, 0 } } }, { { { 10, 0, 1 }, { 0, 31, 0 } } }, { { { 10, 0, 2 }, { 9, 14, 0 } } }, { { { 11, 0, 1 }, { 0, 32, 0 } } }, { { { 11, 0, 0 }, { 0, 33, 0 } } }, { { { 11, 0, 1 }, { 2, 30, 0 } } }, { { { 11, 0, 2 }, { 0, 34, 0 } } }, { { { 12, 0, 1 }, { 0, 35, 0 } } }, { { { 12, 0, 0 }, { 0, 36, 0 } } }, { { { 12, 0, 1 }, { 3, 31, 0 } } }, { { { 12, 0, 2 }, { 0, 37, 0 } } }, { { { 13, 0, 1 }, { 0, 38, 0 } } }, { { { 13, 0, 0 }, { 0, 39, 0 } } }, { { { 13, 0, 1 }, { 5, 30, 0 } } }, { { { 13, 0, 2 }, { 0, 40, 0 } } }, { { { 14, 0, 1 }, { 0, 41, 0 } } }, { { { 14, 0, 0 }, { 0, 42, 0 } } }, { { { 14, 0, 1 }, { 6, 31, 0 } } }, { { { 14, 0, 2 }, { 0, 43, 0 } } }, { { { 15, 0, 1 }, { 0, 44, 0 } } }, { { { 15, 0, 0 }, { 0, 45, 0 } } }, { { { 15, 0, 1 }, { 8, 30, 0 } } }, { { { 15, 0, 2 }, { 0, 46, 0 } } }, { { { 16, 0, 2 }, { 0, 47, 0 } } }, { { { 16, 0, 1 }, { 1, 46, 0 } } }, { { { 16, 0, 0 }, { 0, 48, 0 } } }, { { { 16, 0, 1 }, { 0, 49, 0 } } }, { { { 16, 0, 2 }, { 0, 50, 0 } } }, { { { 17, 0, 1 }, { 2, 47, 0 } } }, { { { 17, 0, 0 }, { 0, 51, 0 } } }, { { { 17, 0, 1 }, { 0, 52, 0 } } }, { { { 17, 0, 2 }, { 0, 53, 0 } } }, { { { 18, 0, 1 }, { 4, 46, 0 } } }, { { { 18, 0, 0 }, { 0, 54, 0 } } }, { { { 18, 0, 1 }, { 0, 55, 0 } } }, { { { 18, 0, 2 }, { 0, 56, 0 } } }, { { { 19, 0, 1 }, { 5, 47, 0 } } }, { { { 19, 0, 0 }, { 0, 57, 0 } } }, { { { 19, 0, 1 }, { 0, 58, 0 } } }, { { { 19, 0, 2 }, { 0, 59, 0 } } }, { { { 20, 0, 1 }, { 7, 46, 0 } } }, { { { 20, 0, 0 }, { 0, 60, 0 } } }, { { { 20, 0, 1 }, { 0, 61, 0 } } }, { { { 20, 0, 2 }, { 0, 62, 0 } } }, { { { 21, 0, 1 }, { 8, 47, 0 } } }, { { { 21, 0, 0 }, { 0, 63, 0 } } }, { { { 21, 0, 1 }, { 1, 62, 0 } } }, { { { 21, 0, 2 }, { 1, 63, 0 } } }, { { { 22, 0, 1 }, { 10, 46, 0 } } }, { { { 22, 0, 0 }, { 2, 62, 0 } } }, { { { 22, 0, 1 }, { 2, 63, 0 } } }, { { { 22, 0, 2 }, { 3, 62, 0 } } }, { { { 23, 0, 1 }, { 11, 47, 0 } } }, { { { 23, 0, 0 }, { 3, 63, 0 } } }, { { { 23, 0, 1 }, { 4, 62, 0 } } }, { { { 23, 0, 2 }, { 4, 63, 0 } } }, { { { 24, 0, 1 }, { 13, 46, 0 } } }, { { { 24, 0, 0 }, { 5, 62, 0 } } }, { { { 24, 0, 1 }, { 5, 63, 0 } } }, { { { 24, 0, 2 }, { 6, 62, 0 } } }, { { { 25, 0, 1 }, { 14, 47, 0 } } }, { { { 25, 0, 0 }, { 6, 63, 0 } } }, { { { 25, 0, 1 }, { 7, 62, 0 } } }, { { { 25, 0, 2 }, { 7, 63, 0 } } }, { { { 26, 0, 1 }, { 16, 45, 0 } } }, { { { 26, 0, 0 }, { 8, 62, 0 } } }, { { { 26, 0, 1 }, { 8, 63, 0 } } }, { { { 26, 0, 2 }, { 9, 62, 0 } } }, { { { 27, 0, 1 }, { 16, 48, 0 } } }, { { { 27, 0, 0 }, { 9, 63, 0 } } }, { { { 27, 0, 1 }, { 10, 62, 0 } } }, { { { 27, 0, 2 }, { 10, 63, 0 } } }, { { { 28, 0, 1 }, { 16, 51, 0 } } }, { { { 28, 0, 0 }, { 11, 62, 0 } } }, { { { 28, 0, 1 }, { 11, 63, 0 } } }, { { { 28, 0, 2 }, { 12, 62, 0 } } }, { { { 29, 0, 1 }, { 16, 54, 0 } } }, { { { 29, 0, 0 }, { 12, 63, 0 } } }, { { { 29, 0, 1 }, { 13, 62, 0 } } }, { { { 29, 0, 2 }, { 13, 63, 0 } } }, { { { 30, 0, 1 }, { 16, 57, 0 } } }, { { { 30, 0, 0 }, { 14, 62, 0 } } }, { { { 30, 0, 1 }, { 14, 63, 0 } } }, { { { 30, 0, 2 }, { 15, 62, 0 } } }, { { { 31, 0, 1 }, { 16, 60, 0 } } }, { { { 31, 0, 0 }, { 15, 63, 0 } } }, { { { 31, 0, 1 }, { 24, 46, 0 } } }, { { { 31, 0, 2 }, { 16, 62, 0 } } }, { { { 32, 0, 2 }, { 16, 63, 0 } } }, { { { 32, 0, 1 }, { 17, 62, 0 } } }, { { { 32, 0, 0 }, { 25, 47, 0 } } }, { { { 32, 0, 1 }, { 17, 63, 0 } } }, { { { 32, 0, 2 }, { 18, 62, 0 } } }, { { { 33, 0, 1 }, { 18, 63, 0 } } }, { { { 33, 0, 0 }, { 27, 46, 0 } } }, { { { 33, 0, 1 }, { 19, 62, 0 } } }, { { { 33, 0, 2 }, { 19, 63, 0 } } }, { { { 34, 0, 1 }, { 20, 62, 0 } } }, { { { 34, 0, 0 }, { 28, 47, 0 } } }, { { { 34, 0, 1 }, { 20, 63, 0 } } }, { { { 34, 0, 2 }, { 21, 62, 0 } } }, { { { 35, 0, 1 }, { 21, 63, 0 } } }, { { { 35, 0, 0 }, { 30, 46, 0 } } }, { { { 35, 0, 1 }, { 22, 62, 0 } } }, { { { 35, 0, 2 }, { 22, 63, 0 } } }, { { { 36, 0, 1 }, { 23, 62, 0 } } }, { { { 36, 0, 0 }, { 31, 47, 0 } } }, { { { 36, 0, 1 }, { 23, 63, 0 } } }, { { { 36, 0, 2 }, { 24, 62, 0 } } }, { { { 37, 0, 1 }, { 24, 63, 0 } } }, { { { 37, 0, 0 }, { 32, 47, 0 } } }, { { { 37, 0, 1 }, { 25, 62, 0 } } }, { { { 37, 0, 2 }, { 25, 63, 0 } } }, { { { 38, 0, 1 }, { 26, 62, 0 } } }, { { { 38, 0, 0 }, { 32, 50, 0 } } }, { { { 38, 0, 1 }, { 26, 63, 0 } } }, { { { 38, 0, 2 }, { 27, 62, 0 } } }, { { { 39, 0, 1 }, { 27, 63, 0 } } }, { { { 39, 0, 0 }, { 32, 53, 0 } } }, { { { 39, 0, 1 }, { 28, 62, 0 } } }, { { { 39, 0, 2 }, { 28, 63, 0 } } }, { { { 40, 0, 1 }, { 29, 62, 0 } } }, { { { 40, 0, 0 }, { 32, 56, 0 } } }, { { { 40, 0, 1 }, { 29, 63, 0 } } }, { { { 40, 0, 2 }, { 30, 62, 0 } } }, { { { 41, 0, 1 }, { 30, 63, 0 } } }, { { { 41, 0, 0 }, { 32, 59, 0 } } }, { { { 41, 0, 1 }, { 31, 62, 0 } } }, { { { 41, 0, 2 }, { 31, 63, 0 } } }, { { { 42, 0, 1 }, { 32, 61, 0 } } }, { { { 42, 0, 0 }, { 32, 62, 0 } } }, { { { 42, 0, 1 }, { 32, 63, 0 } } }, { { { 42, 0, 2 }, { 41, 46, 0 } } }, { { { 43, 0, 1 }, { 33, 62, 0 } } }, { { { 43, 0, 0 }, { 33, 63, 0 } } }, { { { 43, 0, 1 }, { 34, 62, 0 } } }, { { { 43, 0, 2 }, { 42, 47, 0 } } }, { { { 44, 0, 1 }, { 34, 63, 0 } } }, { { { 44, 0, 0 }, { 35, 62, 0 } } }, { { { 44, 0, 1 }, { 35, 63, 0 } } }, { { { 44, 0, 2 }, { 44, 46, 0 } } }, { { { 45, 0, 1 }, { 36, 62, 0 } } }, { { { 45, 0, 0 }, { 36, 63, 0 } } }, { { { 45, 0, 1 }, { 37, 62, 0 } } }, { { { 45, 0, 2 }, { 45, 47, 0 } } }, { { { 46, 0, 1 }, { 37, 63, 0 } } }, { { { 46, 0, 0 }, { 38, 62, 0 } } }, { { { 46, 0, 1 }, { 38, 63, 0 } } }, { { { 46, 0, 2 }, { 47, 46, 0 } } }, { { { 47, 0, 1 }, { 39, 62, 0 } } }, { { { 47, 0, 0 }, { 39, 63, 0 } } }, { { { 47, 0, 1 }, { 40, 62, 0 } } }, { { { 47, 0, 2 }, { 48, 46, 0 } } }, { { { 48, 0, 2 }, { 40, 63, 0 } } }, { { { 48, 0, 1 }, { 41, 62, 0 } } }, { { { 48, 0, 0 }, { 41, 63, 0 } } }, { { { 48, 0, 1 }, { 48, 49, 0 } } }, { { { 48, 0, 2 }, { 42, 62, 0 } } }, { { { 49, 0, 1 }, { 42, 63, 0 } } }, { { { 49, 0, 0 }, { 43, 62, 0 } } }, { { { 49, 0, 1 }, { 48, 52, 0 } } }, { { { 49, 0, 2 }, { 43, 63, 0 } } }, { { { 50, 0, 1 }, { 44, 62, 0 } } }, { { { 50, 0, 0 }, { 44, 63, 0 } } }, { { { 50, 0, 1 }, { 48, 55, 0 } } }, { { { 50, 0, 2 }, { 45, 62, 0 } } }, { { { 51, 0, 1 }, { 45, 63, 0 } } }, { { { 51, 0, 0 }, { 46, 62, 0 } } }, { { { 51, 0, 1 }, { 48, 58, 0 } } }, { { { 51, 0, 2 }, { 46, 63, 0 } } }, { { { 52, 0, 1 }, { 47, 62, 0 } } }, { { { 52, 0, 0 }, { 47, 63, 0 } } }, { { { 52, 0, 1 }, { 48, 61, 0 } } }, { { { 52, 0, 2 }, { 48, 62, 0 } } }, { { { 53, 0, 1 }, { 56, 47, 0 } } }, { { { 53, 0, 0 }, { 48, 63, 0 } } }, { { { 53, 0, 1 }, { 49, 62, 0 } } }, { { { 53, 0, 2 }, { 49, 63, 0 } } }, { { { 54, 0, 1 }, { 58, 46, 0 } } }, { { { 54, 0, 0 }, { 50, 62, 0 } } }, { { { 54, 0, 1 }, { 50, 63, 0 } } }, { { { 54, 0, 2 }, { 51, 62, 0 } } }, { { { 55, 0, 1 }, { 59, 47, 0 } } }, { { { 55, 0, 0 }, { 51, 63, 0 } } }, { { { 55, 0, 1 }, { 52, 62, 0 } } }, { { { 55, 0, 2 }, { 52, 63, 0 } } }, { { { 56, 0, 1 }, { 61, 46, 0 } } }, { { { 56, 0, 0 }, { 53, 62, 0 } } }, { { { 56, 0, 1 }, { 53, 63, 0 } } }, { { { 56, 0, 2 }, { 54, 62, 0 } } }, { { { 57, 0, 1 }, { 62, 47, 0 } } }, { { { 57, 0, 0 }, { 54, 63, 0 } } }, { { { 57, 0, 1 }, { 55, 62, 0 } } }, { { { 57, 0, 2 }, { 55, 63, 0 } } }, { { { 58, 0, 1 }, { 56, 62, 1 } } }, { { { 58, 0, 0 }, { 56, 62, 0 } } }, { { { 58, 0, 1 }, { 56, 63, 0 } } }, { { { 58, 0, 2 }, { 57, 62, 0 } } }, { { { 59, 0, 1 }, { 57, 63, 1 } } }, { { { 59, 0, 0 }, { 57, 63, 0 } } }, { { { 59, 0, 1 }, { 58, 62, 0 } } }, { { { 59, 0, 2 }, { 58, 63, 0 } } }, { { { 60, 0, 1 }, { 59, 62, 1 } } }, { { { 60, 0, 0 }, { 59, 62, 0 } } }, { { { 60, 0, 1 }, { 59, 63, 0 } } }, { { { 60, 0, 2 }, { 60, 62, 0 } } }, { { { 61, 0, 1 }, { 60, 63, 1 } } }, { { { 61, 0, 0 }, { 60, 63, 0 } } }, { { { 61, 0, 1 }, { 61, 62, 0 } } }, { { { 61, 0, 2 }, { 61, 63, 0 } } }, { { { 62, 0, 1 }, { 62, 62, 1 } } }, { { { 62, 0, 0 }, { 62, 62, 0 } } }, { { { 62, 0, 1 }, { 62, 63, 0 } } }, { { { 62, 0, 2 }, { 63, 62, 0 } } }, { { { 63, 0, 1 }, { 63, 63, 1 } } }, { { { 63, 0, 0 }, { 63, 63, 0 } } } }; static const DDSSingleColorLookup* DDS_LOOKUP[] = { DDSLookup_5_4, DDSLookup_6_4, DDSLookup_5_4 }; static const unsigned char BC7_weight2[] = { 0, 21, 43, 64 }; static const unsigned char BC7_weight3[] = { 0, 9, 18, 27, 37, 46, 55, 64 }; static const unsigned char BC7_weight4[] = { 0, 4, 9, 13, 17, 21, 26, 30, 34, 38, 43, 47, 51, 55, 60, 64 }; /* stores info for each mode of BC7 */ static const BC7ModeInfo BC7_mode_info[8] = { { 4, 3, 4, 0, 6, 3, 0 }, /* mode 0 */ { 6, 2, 6, 0, 2, 3, 0 }, /* mode 1 */ { 6, 3, 5, 0, 0, 2, 0 }, /* mode 2 */ { 6, 2, 7, 0, 4, 2, 0 }, /* mode 3 */ { 0, 1, 5, 6, 0, 2, 3 }, /* mode 4 */ { 0, 1, 7, 8, 0, 2, 2 }, /* mode 5 */ { 0, 1, 7, 7, 2, 4, 0 }, /* mode 6 */ { 6, 2, 5, 5, 4, 2, 0 }, /* mode 7 */ }; static const unsigned char BC7_partition_table[2][64][16] = { { /* BC7 Partition Set for 2 Subsets */ { 0, 0, 1, 1, 0, 0, 1, 1, 0, 0, 1, 1, 0, 0, 1, 1 }, { 0, 0, 0, 1, 0, 0, 0, 1, 0, 0, 0, 1, 0, 0, 0, 1 }, { 0, 1, 1, 1, 0, 1, 1, 1, 0, 1, 1, 1, 0, 1, 1, 1 }, { 0, 0, 0, 1, 0, 0, 1, 1, 0, 0, 1, 1, 0, 1, 1, 1 }, { 0, 0, 0, 0, 0, 0, 0, 1, 0, 0, 0, 1, 0, 0, 1, 1 }, { 0, 0, 1, 1, 0, 1, 1, 1, 0, 1, 1, 1, 1, 1, 1, 1 }, { 0, 0, 0, 1, 0, 0, 1, 1, 0, 1, 1, 1, 1, 1, 1, 1 }, { 0, 0, 0, 0, 0, 0, 0, 1, 0, 0, 1, 1, 0, 1, 1, 1 }, { 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 1, 0, 0, 1, 1 }, { 0, 0, 1, 1, 0, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1 }, { 0, 0, 0, 0, 0, 0, 0, 1, 0, 1, 1, 1, 1, 1, 1, 1 }, { 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 1, 0, 1, 1, 1 }, { 0, 0, 0, 1, 0, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1 }, { 0, 0, 0, 0, 0, 0, 0, 0, 1, 1, 1, 1, 1, 1, 1, 1 }, { 0, 0, 0, 0, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1 }, { 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 1, 1, 1, 1 }, { 0, 0, 0, 0, 1, 0, 0, 0, 1, 1, 1, 0, 1, 1, 1, 1 }, { 0, 1, 1, 1, 0, 0, 0, 1, 0, 0, 0, 0, 0, 0, 0, 0 }, { 0, 0, 0, 0, 0, 0, 0, 0, 1, 0, 0, 0, 1, 1, 1, 0 }, { 0, 1, 1, 1, 0, 0, 1, 1, 0, 0, 0, 1, 0, 0, 0, 0 }, { 0, 0, 1, 1, 0, 0, 0, 1, 0, 0, 0, 0, 0, 0, 0, 0 }, { 0, 0, 0, 0, 1, 0, 0, 0, 1, 1, 0, 0, 1, 1, 1, 0 }, { 0, 0, 0, 0, 0, 0, 0, 0, 1, 0, 0, 0, 1, 1, 0, 0 }, { 0, 1, 1, 1, 0, 0, 1, 1, 0, 0, 1, 1, 0, 0, 0, 1 }, { 0, 0, 1, 1, 0, 0, 0, 1, 0, 0, 0, 1, 0, 0, 0, 0 }, { 0, 0, 0, 0, 1, 0, 0, 0, 1, 0, 0, 0, 1, 1, 0, 0 }, { 0, 1, 1, 0, 0, 1, 1, 0, 0, 1, 1, 0, 0, 1, 1, 0 }, { 0, 0, 1, 1, 0, 1, 1, 0, 0, 1, 1, 0, 1, 1, 0, 0 }, { 0, 0, 0, 1, 0, 1, 1, 1, 1, 1, 1, 0, 1, 0, 0, 0 }, { 0, 0, 0, 0, 1, 1, 1, 1, 1, 1, 1, 1, 0, 0, 0, 0 }, { 0, 1, 1, 1, 0, 0, 0, 1, 1, 0, 0, 0, 1, 1, 1, 0 }, { 0, 0, 1, 1, 1, 0, 0, 1, 1, 0, 0, 1, 1, 1, 0, 0 }, { 0, 1, 0, 1, 0, 1, 0, 1, 0, 1, 0, 1, 0, 1, 0, 1 }, { 0, 0, 0, 0, 1, 1, 1, 1, 0, 0, 0, 0, 1, 1, 1, 1 }, { 0, 1, 0, 1, 1, 0, 1, 0, 0, 1, 0, 1, 1, 0, 1, 0 }, { 0, 0, 1, 1, 0, 0, 1, 1, 1, 1, 0, 0, 1, 1, 0, 0 }, { 0, 0, 1, 1, 1, 1, 0, 0, 0, 0, 1, 1, 1, 1, 0, 0 }, { 0, 1, 0, 1, 0, 1, 0, 1, 1, 0, 1, 0, 1, 0, 1, 0 }, { 0, 1, 1, 0, 1, 0, 0, 1, 0, 1, 1, 0, 1, 0, 0, 1 }, { 0, 1, 0, 1, 1, 0, 1, 0, 1, 0, 1, 0, 0, 1, 0, 1 }, { 0, 1, 1, 1, 0, 0, 1, 1, 1, 1, 0, 0, 1, 1, 1, 0 }, { 0, 0, 0, 1, 0, 0, 1, 1, 1, 1, 0, 0, 1, 0, 0, 0 }, { 0, 0, 1, 1, 0, 0, 1, 0, 0, 1, 0, 0, 1, 1, 0, 0 }, { 0, 0, 1, 1, 1, 0, 1, 1, 1, 1, 0, 1, 1, 1, 0, 0 }, { 0, 1, 1, 0, 1, 0, 0, 1, 1, 0, 0, 1, 0, 1, 1, 0 }, { 0, 0, 1, 1, 1, 1, 0, 0, 1, 1, 0, 0, 0, 0, 1, 1 }, { 0, 1, 1, 0, 0, 1, 1, 0, 1, 0, 0, 1, 1, 0, 0, 1 }, { 0, 0, 0, 0, 0, 1, 1, 0, 0, 1, 1, 0, 0, 0, 0, 0 }, { 0, 1, 0, 0, 1, 1, 1, 0, 0, 1, 0, 0, 0, 0, 0, 0 }, { 0, 0, 1, 0, 0, 1, 1, 1, 0, 0, 1, 0, 0, 0, 0, 0 }, { 0, 0, 0, 0, 0, 0, 1, 0, 0, 1, 1, 1, 0, 0, 1, 0 }, { 0, 0, 0, 0, 0, 1, 0, 0, 1, 1, 1, 0, 0, 1, 0, 0 }, { 0, 1, 1, 0, 1, 1, 0, 0, 1, 0, 0, 1, 0, 0, 1, 1 }, { 0, 0, 1, 1, 0, 1, 1, 0, 1, 1, 0, 0, 1, 0, 0, 1 }, { 0, 1, 1, 0, 0, 0, 1, 1, 1, 0, 0, 1, 1, 1, 0, 0 }, { 0, 0, 1, 1, 1, 0, 0, 1, 1, 1, 0, 0, 0, 1, 1, 0 }, { 0, 1, 1, 0, 1, 1, 0, 0, 1, 1, 0, 0, 1, 0, 0, 1 }, { 0, 1, 1, 0, 0, 0, 1, 1, 0, 0, 1, 1, 1, 0, 0, 1 }, { 0, 1, 1, 1, 1, 1, 1, 0, 1, 0, 0, 0, 0, 0, 0, 1 }, { 0, 0, 0, 1, 1, 0, 0, 0, 1, 1, 1, 0, 0, 1, 1, 1 }, { 0, 0, 0, 0, 1, 1, 1, 1, 0, 0, 1, 1, 0, 0, 1, 1 }, { 0, 0, 1, 1, 0, 0, 1, 1, 1, 1, 1, 1, 0, 0, 0, 0 }, { 0, 0, 1, 0, 0, 0, 1, 0, 1, 1, 1, 0, 1, 1, 1, 0 }, { 0, 1, 0, 0, 0, 1, 0, 0, 0, 1, 1, 1, 0, 1, 1, 1 } }, { /* BC7 Partition Set for 3 Subsets */ { 0, 0, 1, 1, 0, 0, 1, 1, 0, 2, 2, 1, 2, 2, 2, 2 }, { 0, 0, 0, 1, 0, 0, 1, 1, 2, 2, 1, 1, 2, 2, 2, 1 }, { 0, 0, 0, 0, 2, 0, 0, 1, 2, 2, 1, 1, 2, 2, 1, 1 }, { 0, 2, 2, 2, 0, 0, 2, 2, 0, 0, 1, 1, 0, 1, 1, 1 }, { 0, 0, 0, 0, 0, 0, 0, 0, 1, 1, 2, 2, 1, 1, 2, 2 }, { 0, 0, 1, 1, 0, 0, 1, 1, 0, 0, 2, 2, 0, 0, 2, 2 }, { 0, 0, 2, 2, 0, 0, 2, 2, 1, 1, 1, 1, 1, 1, 1, 1 }, { 0, 0, 1, 1, 0, 0, 1, 1, 2, 2, 1, 1, 2, 2, 1, 1 }, { 0, 0, 0, 0, 0, 0, 0, 0, 1, 1, 1, 1, 2, 2, 2, 2 }, { 0, 0, 0, 0, 1, 1, 1, 1, 1, 1, 1, 1, 2, 2, 2, 2 }, { 0, 0, 0, 0, 1, 1, 1, 1, 2, 2, 2, 2, 2, 2, 2, 2 }, { 0, 0, 1, 2, 0, 0, 1, 2, 0, 0, 1, 2, 0, 0, 1, 2 }, { 0, 1, 1, 2, 0, 1, 1, 2, 0, 1, 1, 2, 0, 1, 1, 2 }, { 0, 1, 2, 2, 0, 1, 2, 2, 0, 1, 2, 2, 0, 1, 2, 2 }, { 0, 0, 1, 1, 0, 1, 1, 2, 1, 1, 2, 2, 1, 2, 2, 2 }, { 0, 0, 1, 1, 2, 0, 0, 1, 2, 2, 0, 0, 2, 2, 2, 0 }, { 0, 0, 0, 1, 0, 0, 1, 1, 0, 1, 1, 2, 1, 1, 2, 2 }, { 0, 1, 1, 1, 0, 0, 1, 1, 2, 0, 0, 1, 2, 2, 0, 0 }, { 0, 0, 0, 0, 1, 1, 2, 2, 1, 1, 2, 2, 1, 1, 2, 2 }, { 0, 0, 2, 2, 0, 0, 2, 2, 0, 0, 2, 2, 1, 1, 1, 1 }, { 0, 1, 1, 1, 0, 1, 1, 1, 0, 2, 2, 2, 0, 2, 2, 2 }, { 0, 0, 0, 1, 0, 0, 0, 1, 2, 2, 2, 1, 2, 2, 2, 1 }, { 0, 0, 0, 0, 0, 0, 1, 1, 0, 1, 2, 2, 0, 1, 2, 2 }, { 0, 0, 0, 0, 1, 1, 0, 0, 2, 2, 1, 0, 2, 2, 1, 0 }, { 0, 1, 2, 2, 0, 1, 2, 2, 0, 0, 1, 1, 0, 0, 0, 0 }, { 0, 0, 1, 2, 0, 0, 1, 2, 1, 1, 2, 2, 2, 2, 2, 2 }, { 0, 1, 1, 0, 1, 2, 2, 1, 1, 2, 2, 1, 0, 1, 1, 0 }, { 0, 0, 0, 0, 0, 1, 1, 0, 1, 2, 2, 1, 1, 2, 2, 1 }, { 0, 0, 2, 2, 1, 1, 0, 2, 1, 1, 0, 2, 0, 0, 2, 2 }, { 0, 1, 1, 0, 0, 1, 1, 0, 2, 0, 0, 2, 2, 2, 2, 2 }, { 0, 0, 1, 1, 0, 1, 2, 2, 0, 1, 2, 2, 0, 0, 1, 1 }, { 0, 0, 0, 0, 2, 0, 0, 0, 2, 2, 1, 1, 2, 2, 2, 1 }, { 0, 0, 0, 0, 0, 0, 0, 2, 1, 1, 2, 2, 1, 2, 2, 2 }, { 0, 2, 2, 2, 0, 0, 2, 2, 0, 0, 1, 2, 0, 0, 1, 1 }, { 0, 0, 1, 1, 0, 0, 1, 2, 0, 0, 2, 2, 0, 2, 2, 2 }, { 0, 1, 2, 0, 0, 1, 2, 0, 0, 1, 2, 0, 0, 1, 2, 0 }, { 0, 0, 0, 0, 1, 1, 1, 1, 2, 2, 2, 2, 0, 0, 0, 0 }, { 0, 1, 2, 0, 1, 2, 0, 1, 2, 0, 1, 2, 0, 1, 2, 0 }, { 0, 1, 2, 0, 2, 0, 1, 2, 1, 2, 0, 1, 0, 1, 2, 0 }, { 0, 0, 1, 1, 2, 2, 0, 0, 1, 1, 2, 2, 0, 0, 1, 1 }, { 0, 0, 1, 1, 1, 1, 2, 2, 2, 2, 0, 0, 0, 0, 1, 1 }, { 0, 1, 0, 1, 0, 1, 0, 1, 2, 2, 2, 2, 2, 2, 2, 2 }, { 0, 0, 0, 0, 0, 0, 0, 0, 2, 1, 2, 1, 2, 1, 2, 1 }, { 0, 0, 2, 2, 1, 1, 2, 2, 0, 0, 2, 2, 1, 1, 2, 2 }, { 0, 0, 2, 2, 0, 0, 1, 1, 0, 0, 2, 2, 0, 0, 1, 1 }, { 0, 2, 2, 0, 1, 2, 2, 1, 0, 2, 2, 0, 1, 2, 2, 1 }, { 0, 1, 0, 1, 2, 2, 2, 2, 2, 2, 2, 2, 0, 1, 0, 1 }, { 0, 0, 0, 0, 2, 1, 2, 1, 2, 1, 2, 1, 2, 1, 2, 1 }, { 0, 1, 0, 1, 0, 1, 0, 1, 0, 1, 0, 1, 2, 2, 2, 2 }, { 0, 2, 2, 2, 0, 1, 1, 1, 0, 2, 2, 2, 0, 1, 1, 1 }, { 0, 0, 0, 2, 1, 1, 1, 2, 0, 0, 0, 2, 1, 1, 1, 2 }, { 0, 0, 0, 0, 2, 1, 1, 2, 2, 1, 1, 2, 2, 1, 1, 2 }, { 0, 2, 2, 2, 0, 1, 1, 1, 0, 1, 1, 1, 0, 2, 2, 2 }, { 0, 0, 0, 2, 1, 1, 1, 2, 1, 1, 1, 2, 0, 0, 0, 2 }, { 0, 1, 1, 0, 0, 1, 1, 0, 0, 1, 1, 0, 2, 2, 2, 2 }, { 0, 0, 0, 0, 0, 0, 0, 0, 2, 1, 1, 2, 2, 1, 1, 2 }, { 0, 1, 1, 0, 0, 1, 1, 0, 2, 2, 2, 2, 2, 2, 2, 2 }, { 0, 0, 2, 2, 0, 0, 1, 1, 0, 0, 1, 1, 0, 0, 2, 2 }, { 0, 0, 2, 2, 1, 1, 2, 2, 1, 1, 2, 2, 0, 0, 2, 2 }, { 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 2, 1, 1, 2 }, { 0, 0, 0, 2, 0, 0, 0, 1, 0, 0, 0, 2, 0, 0, 0, 1 }, { 0, 2, 2, 2, 1, 2, 2, 2, 0, 2, 2, 2, 1, 2, 2, 2 }, { 0, 1, 0, 1, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2, 2 }, { 0, 1, 1, 1, 2, 0, 1, 1, 2, 2, 0, 1, 2, 2, 2, 0 } } }; static const unsigned char BC7_anchor_index_table[4][64] = { /* Anchor index values for the first subset */ { 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0, 0 }, /* Anchor index values for the second subset of two-subset partitioning */ { 15,15,15,15,15,15,15,15, 15,15,15,15,15,15,15,15, 15, 2, 8, 2, 2, 8, 8,15, 2, 8, 2, 2, 8, 8, 2, 2, 15,15, 6, 8, 2, 8,15,15, 2, 8, 2, 2, 2,15,15, 6, 6, 2, 6, 8,15,15, 2, 2, 15,15,15,15,15, 2, 2,15 }, /* Anchor index values for the second subset of three-subset partitioning */ { 3, 3,15,15, 8, 3,15,15, 8, 8, 6, 6, 6, 5, 3, 3, 3, 3, 8,15, 3, 3, 6,10, 5, 8, 8, 6, 8, 5,15,15, 8,15, 3, 5, 6,10, 8,15, 15, 3,15, 5,15,15,15,15, 3,15, 5, 5, 5, 8, 5,10, 5,10, 8,13,15,12, 3, 3 }, /* Anchor index values for the third subset of three-subset partitioning */ { 15, 8, 8, 3,15,15, 3, 8, 15,15,15,15,15,15,15, 8, 15, 8,15, 3,15, 8,15, 8, 3,15, 6,10,15,15,10, 8, 15, 3,15,10,10, 8, 9,10, 6,15, 8,15, 3, 6, 6, 8, 15, 3,15,15,15,15,15,15, 15,15,15,15, 3,15,15, 8 } }; /* Macros */ #define C565_r(x) (((x) & 0xF800) >> 11) #define C565_g(x) (((x) & 0x07E0) >> 5) #define C565_b(x) ((x) & 0x001F) #define C565_red(x) ( (C565_r(x) << 3 | C565_r(x) >> 2)) #define C565_green(x) ( (C565_g(x) << 2 | C565_g(x) >> 4)) #define C565_blue(x) ( (C565_b(x) << 3 | C565_b(x) >> 2)) #define DIV2(x) ((x) > 1 ? ((x) >> 1) : 1) #define FixRange(min, max, steps) \ if (min > max) \ min = max; \ if ((ssize_t) max - min < steps) \ max = MagickMin(min + steps, 255); \ if ((ssize_t) max - min < steps) \ min = MagickMax(0, (ssize_t) max - steps) #define Dot(left, right) (left.x*right.x) + (left.y*right.y) + (left.z*right.z) #define VectorInit(vector, value) vector.x = vector.y = vector.z = vector.w \ = value #define VectorInit3(vector, value) vector.x = vector.y = vector.z = value #define IsBitMask(mask, r, g, b, a) (mask.r_bitmask == r && mask.g_bitmask == \ g && mask.b_bitmask == b && mask.alpha_bitmask == a) /* Forward declarations */ static MagickBooleanType WriteDDSImage(const ImageInfo *,Image *,ExceptionInfo *); static inline void VectorAdd(const DDSVector4 left, const DDSVector4 right, DDSVector4 *destination) { destination->x = left.x + right.x; destination->y = left.y + right.y; destination->z = left.z + right.z; destination->w = left.w + right.w; } static inline void VectorClamp(DDSVector4 *value) { value->x = MagickMin(1.0f,MagickMax(0.0f,value->x)); value->y = MagickMin(1.0f,MagickMax(0.0f,value->y)); value->z = MagickMin(1.0f,MagickMax(0.0f,value->z)); value->w = MagickMin(1.0f,MagickMax(0.0f,value->w)); } static inline void VectorClamp3(DDSVector3 *value) { value->x = MagickMin(1.0f,MagickMax(0.0f,value->x)); value->y = MagickMin(1.0f,MagickMax(0.0f,value->y)); value->z = MagickMin(1.0f,MagickMax(0.0f,value->z)); } static inline void VectorCopy43(const DDSVector4 source, DDSVector3 *destination) { destination->x = source.x; destination->y = source.y; destination->z = source.z; } static inline void VectorCopy44(const DDSVector4 source, DDSVector4 *destination) { destination->x = source.x; destination->y = source.y; destination->z = source.z; destination->w = source.w; } static inline void VectorNegativeMultiplySubtract(const DDSVector4 a, const DDSVector4 b, const DDSVector4 c, DDSVector4 *destination) { destination->x = c.x - (a.x * b.x); destination->y = c.y - (a.y * b.y); destination->z = c.z - (a.z * b.z); destination->w = c.w - (a.w * b.w); } static inline void VectorMultiply(const DDSVector4 left, const DDSVector4 right, DDSVector4 *destination) { destination->x = left.x * right.x; destination->y = left.y * right.y; destination->z = left.z * right.z; destination->w = left.w * right.w; } static inline void VectorMultiply3(const DDSVector3 left, const DDSVector3 right, DDSVector3 *destination) { destination->x = left.x * right.x; destination->y = left.y * right.y; destination->z = left.z * right.z; } static inline void VectorMultiplyAdd(const DDSVector4 a, const DDSVector4 b, const DDSVector4 c, DDSVector4 *destination) { destination->x = (a.x * b.x) + c.x; destination->y = (a.y * b.y) + c.y; destination->z = (a.z * b.z) + c.z; destination->w = (a.w * b.w) + c.w; } static inline void VectorMultiplyAdd3(const DDSVector3 a, const DDSVector3 b, const DDSVector3 c, DDSVector3 *destination) { destination->x = (a.x * b.x) + c.x; destination->y = (a.y * b.y) + c.y; destination->z = (a.z * b.z) + c.z; } static inline void VectorReciprocal(const DDSVector4 value, DDSVector4 *destination) { destination->x = 1.0f / value.x; destination->y = 1.0f / value.y; destination->z = 1.0f / value.z; destination->w = 1.0f / value.w; } static inline void VectorSubtract(const DDSVector4 left, const DDSVector4 right, DDSVector4 *destination) { destination->x = left.x - right.x; destination->y = left.y - right.y; destination->z = left.z - right.z; destination->w = left.w - right.w; } static inline void VectorSubtract3(const DDSVector3 left, const DDSVector3 right, DDSVector3 *destination) { destination->x = left.x - right.x; destination->y = left.y - right.y; destination->z = left.z - right.z; } static inline void VectorTruncate(DDSVector4 *value) { value->x = value->x > 0.0f ? floor(value->x) : ceil(value->x); value->y = value->y > 0.0f ? floor(value->y) : ceil(value->y); value->z = value->z > 0.0f ? floor(value->z) : ceil(value->z); value->w = value->w > 0.0f ? floor(value->w) : ceil(value->w); } static inline void VectorTruncate3(DDSVector3 *value) { value->x = value->x > 0.0f ? floor(value->x) : ceil(value->x); value->y = value->y > 0.0f ? floor(value->y) : ceil(value->y); value->z = value->z > 0.0f ? floor(value->z) : ceil(value->z); } static inline size_t ClampToLimit(const float value, const size_t limit) { size_t result = (int) (value + 0.5f); if (result < 0.0f) return(0); if (result > limit) return(limit); return result; } static inline size_t ColorTo565(const DDSVector3 point) { size_t r = ClampToLimit(31.0f*point.x,31); size_t g = ClampToLimit(63.0f*point.y,63); size_t b = ClampToLimit(31.0f*point.z,31); return (r << 11) | (g << 5) | b; } static inline unsigned char GetSubsetIndex(unsigned char numSubsets, unsigned char partition_id,size_t pixelIndex) { if (numSubsets == 2) return BC7_partition_table[0][partition_id][pixelIndex]; if (numSubsets == 3) return BC7_partition_table[1][partition_id][pixelIndex]; return 0; } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % I s D D S % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % IsDDS() returns MagickTrue if the image format type, identified by the % magick string, is DDS. % % The format of the IsDDS method is: % % MagickBooleanType IsDDS(const unsigned char *magick,const size_t length) % % A description of each parameter follows: % % o magick: compare image format pattern against these bytes. % % o length: Specifies the length of the magick string. % */ static MagickBooleanType IsDDS(const unsigned char *magick, const size_t length) { if (length < 4) return(MagickFalse); if (LocaleNCompare((char *) magick,"DDS ", 4) == 0) return(MagickTrue); return(MagickFalse); } static MagickBooleanType ReadDDSInfo(Image *image, DDSInfo *dds_info) { size_t hdr_size, required; /* Seek to start of header */ (void) SeekBlob(image, 4, SEEK_SET); /* Check header field */ hdr_size = ReadBlobLSBLong(image); if (hdr_size != 124) return MagickFalse; /* Fill in DDS info struct */ dds_info->flags = ReadBlobLSBLong(image); /* Check required flags */ required=(size_t) (DDSD_CAPS | DDSD_WIDTH | DDSD_HEIGHT | DDSD_PIXELFORMAT); if ((dds_info->flags & required) != required) return MagickFalse; dds_info->height = ReadBlobLSBLong(image); dds_info->width = ReadBlobLSBLong(image); dds_info->pitchOrLinearSize = ReadBlobLSBLong(image); dds_info->depth = ReadBlobLSBLong(image); dds_info->mipmapcount = ReadBlobLSBLong(image); (void) SeekBlob(image, 44, SEEK_CUR); /* reserved region of 11 DWORDs */ /* Read pixel format structure */ hdr_size = ReadBlobLSBLong(image); if (hdr_size != 32) return MagickFalse; dds_info->pixelformat.flags = ReadBlobLSBLong(image); dds_info->pixelformat.fourcc = ReadBlobLSBLong(image); dds_info->pixelformat.rgb_bitcount = ReadBlobLSBLong(image); dds_info->pixelformat.r_bitmask = ReadBlobLSBLong(image); dds_info->pixelformat.g_bitmask = ReadBlobLSBLong(image); dds_info->pixelformat.b_bitmask = ReadBlobLSBLong(image); dds_info->pixelformat.alpha_bitmask = ReadBlobLSBLong(image); dds_info->ddscaps1 = ReadBlobLSBLong(image); dds_info->ddscaps2 = ReadBlobLSBLong(image); (void) SeekBlob(image, 12, SEEK_CUR); /* 3 reserved DWORDs */ /* Read optional DX10 header if available */ if ((dds_info->pixelformat.flags & DDPF_FOURCC) && (dds_info->pixelformat.fourcc == FOURCC_DX10)) { dds_info->extFormat = ReadBlobLSBLong(image); dds_info->extDimension = ReadBlobLSBLong(image); dds_info->extFlags = ReadBlobLSBLong(image); dds_info->extArraySize = ReadBlobLSBLong(image); dds_info->extFlags2 = ReadBlobLSBLong(image); } else { dds_info->extFormat = 0; dds_info->extDimension = 0; dds_info->extFlags = 0; dds_info->extArraySize = 0; dds_info->extFlags2 = 0; } return(MagickTrue); } static MagickBooleanType SetDXT1Pixels(Image *image,ssize_t x,ssize_t y, DDSColors colors,size_t bits,Quantum *q) { ssize_t i; ssize_t j; unsigned char code; for (j = 0; j < 4; j++) { for (i = 0; i < 4; i++) { if ((x + i) < (ssize_t) image->columns && (y + j) < (ssize_t) image->rows) { code=(unsigned char) ((bits >> ((j*4+i)*2)) & 0x3); SetPixelRed(image,ScaleCharToQuantum(colors.r[code]),q); SetPixelGreen(image,ScaleCharToQuantum(colors.g[code]),q); SetPixelBlue(image,ScaleCharToQuantum(colors.b[code]),q); SetPixelOpacity(image,ScaleCharToQuantum(colors.a[code]),q); if ((colors.a[code] != 0) && (image->alpha_trait == UndefinedPixelTrait)) return(MagickFalse); q+=GetPixelChannels(image); } } } return(MagickTrue); } static MagickBooleanType ReadMipmaps(const ImageInfo *image_info,Image *image, const DDSInfo *dds_info,DDSPixelDecoder decoder,ExceptionInfo *exception) { MagickBooleanType status; /* Only skip mipmaps for textures and cube maps */ if (EOFBlob(image) != MagickFalse) { ThrowFileException(exception,CorruptImageWarning,"UnexpectedEndOfFile", image->filename); return(MagickFalse); } status=MagickTrue; if (dds_info->ddscaps1 & DDSCAPS_MIPMAP && (dds_info->ddscaps1 & DDSCAPS_TEXTURE || dds_info->ddscaps2 & DDSCAPS2_CUBEMAP)) { ssize_t i; size_t h, w; w=DIV2(dds_info->width); h=DIV2(dds_info->height); /* Mipmapcount includes the main image, so start from one */ for (i = 1; (i < (ssize_t) dds_info->mipmapcount) && w && h; i++) { AcquireNextImage(image_info,image,exception); if (image->next == (Image *) NULL) return(MagickFalse); image->next->alpha_trait=image->alpha_trait; image=SyncNextImageInList(image); status=SetImageExtent(image,w,h,exception); if (status == MagickFalse) break; status=decoder(image,dds_info,exception); if (status == MagickFalse) break; if ((w == 1) && (h == 1)) break; w=DIV2(w); h=DIV2(h); } } return(status); } static void CalculateColors(unsigned short c0, unsigned short c1, DDSColors *c, MagickBooleanType ignoreAlpha) { c->a[0] = c->a[1] = c->a[2] = c->a[3] = 0; c->r[0] = (unsigned char) C565_red(c0); c->g[0] = (unsigned char) C565_green(c0); c->b[0] = (unsigned char) C565_blue(c0); c->r[1] = (unsigned char) C565_red(c1); c->g[1] = (unsigned char) C565_green(c1); c->b[1] = (unsigned char) C565_blue(c1); if (ignoreAlpha != MagickFalse || c0 > c1) { c->r[2] = (unsigned char) ((2 * c->r[0] + c->r[1]) / 3); c->g[2] = (unsigned char) ((2 * c->g[0] + c->g[1]) / 3); c->b[2] = (unsigned char) ((2 * c->b[0] + c->b[1]) / 3); c->r[3] = (unsigned char) ((c->r[0] + 2 * c->r[1]) / 3); c->g[3] = (unsigned char) ((c->g[0] + 2 * c->g[1]) / 3); c->b[3] = (unsigned char) ((c->b[0] + 2 * c->b[1]) / 3); } else { c->r[2] = (unsigned char) ((c->r[0] + c->r[1]) / 2); c->g[2] = (unsigned char) ((c->g[0] + c->g[1]) / 2); c->b[2] = (unsigned char) ((c->b[0] + c->b[1]) / 2); c->r[3] = c->g[3] = c->b[3] = 0; c->a[3] = 255; } } static MagickBooleanType ReadDXT1Pixels(Image *image, const DDSInfo *magick_unused(dds_info),ExceptionInfo *exception) { DDSColors colors; Quantum *q; ssize_t x; size_t bits; ssize_t y; unsigned short c0, c1; magick_unreferenced(dds_info); for (y = 0; y < (ssize_t) image->rows; y += 4) { for (x = 0; x < (ssize_t) image->columns; x += 4) { /* Get 4x4 patch of pixels to write on */ q=QueueAuthenticPixels(image,x,y,MagickMin(4,image->columns-x), MagickMin(4,image->rows-y),exception); if (q == (Quantum *) NULL) return(MagickFalse); /* Read 8 bytes of data from the image */ c0=ReadBlobLSBShort(image); c1=ReadBlobLSBShort(image); bits=ReadBlobLSBLong(image); CalculateColors(c0,c1,&colors,MagickFalse); if (EOFBlob(image) != MagickFalse) return(MagickFalse); /* Write the pixels */ if (SetDXT1Pixels(image,x,y,colors,bits,q) == MagickFalse) { /* Correct alpha */ SetImageAlpha(image,QuantumRange,exception); q=QueueAuthenticPixels(image,x,y,MagickMin(4,image->columns-x), MagickMin(4,image->rows-y),exception); if (q != (Quantum *) NULL) SetDXT1Pixels(image,x,y,colors,bits,q); } if (SyncAuthenticPixels(image,exception) == MagickFalse) return(MagickFalse); } if (EOFBlob(image) != MagickFalse) return(MagickFalse); } return(MagickTrue); } /* Skip the mipmap images for compressed (DXTn) dds files */ static MagickBooleanType SkipDXTMipmaps(Image *image,const DDSInfo *dds_info, int texel_size,ExceptionInfo *exception) { /* Only skip mipmaps for textures and cube maps */ if (EOFBlob(image) != MagickFalse) { ThrowFileException(exception,CorruptImageWarning,"UnexpectedEndOfFile", image->filename); return(MagickFalse); } if (dds_info->ddscaps1 & DDSCAPS_MIPMAP && (dds_info->ddscaps1 & DDSCAPS_TEXTURE || dds_info->ddscaps2 & DDSCAPS2_CUBEMAP)) { MagickOffsetType offset; ssize_t i; size_t h, w; w=DIV2(dds_info->width); h=DIV2(dds_info->height); /* Mipmapcount includes the main image, so start from one */ for (i = 1; (i < (ssize_t) dds_info->mipmapcount) && w && h; i++) { offset=(MagickOffsetType)((w+3)/4)*((h+3)/4)*texel_size; if (SeekBlob(image,offset,SEEK_CUR) < 0) break; w=DIV2(w); h=DIV2(h); if ((w == 1) && (h == 1)) break; } } return(MagickTrue); } static MagickBooleanType ReadDXT1(const ImageInfo *image_info,Image *image, const DDSInfo *dds_info,const MagickBooleanType read_mipmaps, ExceptionInfo *exception) { if (ReadDXT1Pixels(image,dds_info,exception) == MagickFalse) return(MagickFalse); if (read_mipmaps != MagickFalse) return(ReadMipmaps(image_info,image,dds_info,ReadDXT1Pixels,exception)); else return(SkipDXTMipmaps(image,dds_info,8,exception)); } static MagickBooleanType ReadDXT3Pixels(Image *image, const DDSInfo *magick_unused(dds_info),ExceptionInfo *exception) { DDSColors colors; Quantum *q; ssize_t i, x; unsigned char alpha; size_t a0, a1, bits, code; ssize_t j, y; unsigned short c0, c1; magick_unreferenced(dds_info); for (y = 0; y < (ssize_t) image->rows; y += 4) { for (x = 0; x < (ssize_t) image->columns; x += 4) { /* Get 4x4 patch of pixels to write on */ q = QueueAuthenticPixels(image, x, y, MagickMin(4, image->columns - x), MagickMin(4, image->rows - y),exception); if (q == (Quantum *) NULL) return(MagickFalse); /* Read alpha values (8 bytes) */ a0 = ReadBlobLSBLong(image); a1 = ReadBlobLSBLong(image); /* Read 8 bytes of data from the image */ c0 = ReadBlobLSBShort(image); c1 = ReadBlobLSBShort(image); bits = ReadBlobLSBLong(image); CalculateColors(c0, c1, &colors, MagickTrue); if (EOFBlob(image) != MagickFalse) return(MagickFalse); /* Write the pixels */ for (j = 0; j < 4; j++) { for (i = 0; i < 4; i++) { if ((x + i) < (ssize_t) image->columns && (y + j) < (ssize_t) image->rows) { code = (bits >> ((4*j+i)*2)) & 0x3; SetPixelRed(image,ScaleCharToQuantum(colors.r[code]),q); SetPixelGreen(image,ScaleCharToQuantum(colors.g[code]),q); SetPixelBlue(image,ScaleCharToQuantum(colors.b[code]),q); /* Extract alpha value: multiply 0..15 by 17 to get range 0..255 */ if (j < 2) alpha = 17U * (unsigned char) ((a0 >> (4*(4*j+i))) & 0xf); else alpha = 17U * (unsigned char) ((a1 >> (4*(4*(j-2)+i))) & 0xf); SetPixelAlpha(image,ScaleCharToQuantum((unsigned char) alpha),q); q+=GetPixelChannels(image); } } } if (SyncAuthenticPixels(image,exception) == MagickFalse) return(MagickFalse); } if (EOFBlob(image) != MagickFalse) return(MagickFalse); } return(MagickTrue); } static MagickBooleanType ReadDXT3(const ImageInfo *image_info,Image *image, const DDSInfo *dds_info,const MagickBooleanType read_mipmaps, ExceptionInfo *exception) { if (ReadDXT3Pixels(image,dds_info,exception) == MagickFalse) return(MagickFalse); if (read_mipmaps != MagickFalse) return(ReadMipmaps(image_info,image,dds_info,ReadDXT3Pixels,exception)); else return(SkipDXTMipmaps(image,dds_info,16,exception)); } static MagickBooleanType ReadDXT5Pixels(Image *image, const DDSInfo *magick_unused(dds_info),ExceptionInfo *exception) { DDSColors colors; MagickSizeType alpha_bits; Quantum *q; ssize_t i, x; unsigned char a0, a1; size_t alpha, bits, code, alpha_code; ssize_t j, y; unsigned short c0, c1; magick_unreferenced(dds_info); for (y = 0; y < (ssize_t) image->rows; y += 4) { for (x = 0; x < (ssize_t) image->columns; x += 4) { /* Get 4x4 patch of pixels to write on */ q = QueueAuthenticPixels(image, x, y, MagickMin(4, image->columns - x), MagickMin(4, image->rows - y),exception); if (q == (Quantum *) NULL) return(MagickFalse); /* Read alpha values (8 bytes) */ a0 = (unsigned char) ReadBlobByte(image); a1 = (unsigned char) ReadBlobByte(image); alpha_bits = (MagickSizeType)ReadBlobLSBLong(image); alpha_bits = alpha_bits | ((MagickSizeType)ReadBlobLSBShort(image) << 32); /* Read 8 bytes of data from the image */ c0 = ReadBlobLSBShort(image); c1 = ReadBlobLSBShort(image); bits = ReadBlobLSBLong(image); CalculateColors(c0, c1, &colors, MagickTrue); if (EOFBlob(image) != MagickFalse) return(MagickFalse); /* Write the pixels */ for (j = 0; j < 4; j++) { for (i = 0; i < 4; i++) { if ((x + i) < (ssize_t) image->columns && (y + j) < (ssize_t) image->rows) { code = (bits >> ((4*j+i)*2)) & 0x3; SetPixelRed(image,ScaleCharToQuantum(colors.r[code]),q); SetPixelGreen(image,ScaleCharToQuantum(colors.g[code]),q); SetPixelBlue(image,ScaleCharToQuantum(colors.b[code]),q); /* Extract alpha value */ alpha_code = (size_t) (alpha_bits >> (3*(4*j+i))) & 0x7; if (alpha_code == 0) alpha = a0; else if (alpha_code == 1) alpha = a1; else if (a0 > a1) alpha = ((8-alpha_code) * a0 + (alpha_code-1) * a1) / 7; else if (alpha_code == 6) alpha = 0; else if (alpha_code == 7) alpha = 255; else alpha = (((6-alpha_code) * a0 + (alpha_code-1) * a1) / 5); SetPixelAlpha(image,ScaleCharToQuantum((unsigned char) alpha),q); q+=GetPixelChannels(image); } } } if (SyncAuthenticPixels(image,exception) == MagickFalse) return(MagickFalse); } if (EOFBlob(image) != MagickFalse) return(MagickFalse); } return(MagickTrue); } static MagickBooleanType ReadDXT5(const ImageInfo *image_info,Image *image, const DDSInfo *dds_info,const MagickBooleanType read_mipmaps, ExceptionInfo *exception) { if (ReadDXT5Pixels(image,dds_info,exception) == MagickFalse) return(MagickFalse); if (read_mipmaps != MagickFalse) return(ReadMipmaps(image_info,image,dds_info,ReadDXT5Pixels,exception)); else return(SkipDXTMipmaps(image,dds_info,16,exception)); } static unsigned char GetBit(const unsigned char *block,size_t *start_bit) { size_t base, index; index=(*start_bit) >> 3; base=(*start_bit) - (index << 3); (*start_bit)++; if (index > 15) return(0); return((block[index] >> base) & 0x01); } static unsigned char GetBits(const unsigned char *block,size_t *start_bit, unsigned char num_bits) { size_t base, first_bits, index, next_bits; unsigned char ret; index=(*start_bit) >> 3; base=(*start_bit)-(index << 3); if (index > 15) return(0); if (base + num_bits > 8) { first_bits=8-base; next_bits=num_bits-first_bits; ret=((block[index] >> base) | (((block[index + 1]) & ((1u << next_bits) - 1)) << first_bits)); } else { ret=((block[index] >> base) & ((1 << num_bits) - 1)); } (*start_bit)+=num_bits; return(ret); } static MagickBooleanType IsPixelAnchorIndex(unsigned char subset_index, unsigned char num_subsets,size_t pixelIndex,unsigned char partition_id) { size_t table_index; /* for first subset */ if (subset_index == 0) table_index=0; /* for second subset of two subset partitioning */ else if ((subset_index == 1) && (num_subsets == 2)) table_index=1; /* for second subset of three subset partitioning */ else if ((subset_index == 1) && (num_subsets == 3)) table_index=2; /* for third subset of three subset partitioning */ else table_index=3; if (BC7_anchor_index_table[table_index][partition_id] == pixelIndex) return(MagickTrue); else return(MagickFalse); } static void ReadEndpoints(BC7Colors *endpoints,const unsigned char *block, size_t mode,size_t *start_bit) { MagickBooleanType has_alpha, has_pbits; unsigned char alpha_bits, color_bits, pbit, pbit0, pbit1; size_t num_subsets, i; num_subsets=(size_t) BC7_mode_info[mode].num_subsets; color_bits=BC7_mode_info[mode].color_precision; /* red */ for (i=0; i < num_subsets * 2; i++) endpoints->r[i]=GetBits(block,start_bit,color_bits); /* green */ for (i=0; i < num_subsets * 2; i++) endpoints->g[i]=GetBits(block,start_bit,color_bits); /* blue */ for (i=0; i < num_subsets * 2; i++) endpoints->b[i]=GetBits(block,start_bit,color_bits); /* alpha */ alpha_bits=BC7_mode_info[mode].alpha_precision; has_alpha=mode >= 4 ? MagickTrue : MagickFalse; if (has_alpha != MagickFalse) { for (i=0; i < num_subsets * 2; i++) endpoints->a[i]=GetBits(block,start_bit,alpha_bits); } /* handle modes that have p bits */ has_pbits=(mode == 0) || (mode == 1) || (mode == 3) || (mode == 6) || (mode == 7) ? MagickTrue : MagickFalse; if (has_pbits != MagickFalse) { for (i=0; i < num_subsets * 2; i++) { endpoints->r[i] <<= 1; endpoints->g[i] <<= 1; endpoints->b[i] <<= 1; endpoints->a[i] <<= 1; } /* mode 1 shares a p-bit for both endpoints */ if (mode == 1) { pbit0=GetBit(block,start_bit); pbit1=GetBit(block,start_bit); endpoints->r[0] |= pbit0; endpoints->g[0] |= pbit0; endpoints->b[0] |= pbit0; endpoints->r[1] |= pbit0; endpoints->g[1] |= pbit0; endpoints->b[1] |= pbit0; endpoints->r[2] |= pbit1; endpoints->g[2] |= pbit1; endpoints->b[2] |= pbit1; endpoints->r[3] |= pbit1; endpoints->g[3] |= pbit1; endpoints->b[3] |= pbit1; } else { for (i=0; i < num_subsets * 2; i++) { pbit=GetBit(block,start_bit); endpoints->r[i] |= pbit; endpoints->g[i] |= pbit; endpoints->b[i] |= pbit; endpoints->a[i] |= pbit; } } } /* 1 bit increased due to the pbit */ if (has_pbits != MagickFalse) { color_bits++; alpha_bits++; } /* color and alpha bit shifting so that MSB lies in bit 7 */ for (i=0; i < num_subsets * 2; i++) { endpoints->r[i] <<= (8 - color_bits); endpoints->g[i] <<= (8 - color_bits); endpoints->b[i] <<= (8 - color_bits); endpoints->a[i] <<= (8 - alpha_bits); endpoints->r[i]=endpoints->r[i] | (endpoints->r[i] >> color_bits); endpoints->g[i]=endpoints->g[i] | (endpoints->g[i] >> color_bits); endpoints->b[i]=endpoints->b[i] | (endpoints->b[i] >> color_bits); endpoints->a[i]=endpoints->a[i] | (endpoints->a[i] >> alpha_bits); } if (has_alpha == MagickFalse) { for (i=0; i < num_subsets * 2; i++) endpoints->a[i]=255; } } static MagickBooleanType ReadBC7Pixels(Image *image, const DDSInfo *magick_unused(dds_info),ExceptionInfo *exception) { BC7Colors colors; Quantum *q; size_t mode, start_bit; ssize_t count, i, x, y; unsigned char a, alpha_indices[16], b, block[16], c0, c1, color_indices[16], g, index_prec, index2_prec, num_bits, num_subsets, partition_id, r, rotation, selector_bit, subset_indices[16], weight; magick_unreferenced(dds_info); memset(alpha_indices,0,sizeof(alpha_indices)); memset(block,0,sizeof(block)); memset(color_indices,0,sizeof(color_indices)); memset(subset_indices,0,sizeof(subset_indices)); for (y = 0; y < (ssize_t) image->rows; y += 4) { for (x = 0; x < (ssize_t) image->columns; x += 4) { size_t area; /* Get 4x4 patch of pixels to write on */ q=QueueAuthenticPixels(image,x,y,MagickMin(4,image->columns-x), MagickMin(4,image->rows-y),exception); if (q == (Quantum *) NULL) return(MagickFalse); /* Read 16 bytes of data from the image */ count=ReadBlob(image,16,block); if (count != 16) return(MagickFalse); if (EOFBlob(image) != MagickFalse) return(MagickFalse); /* Get the mode of the block */ start_bit=0; while (start_bit <= 8 && !GetBit(block, &start_bit)) {} mode=start_bit-1; if (mode > 7) return(MagickFalse); num_subsets=BC7_mode_info[mode].num_subsets; partition_id=0; /* only these modes have more than 1 subset */ if ((mode == 0) || (mode == 1) || (mode == 2) || (mode == 3) || (mode == 7)) { partition_id=GetBits(block,&start_bit,BC7_mode_info[mode].partition_bits); if (partition_id > 63) return(MagickFalse); } rotation=0; if ((mode == 4) || (mode == 5)) rotation=GetBits(block,&start_bit,2); selector_bit=0; if (mode == 4) selector_bit=GetBit(block, &start_bit); ReadEndpoints(&colors,block,mode,&start_bit); index_prec=BC7_mode_info[mode].index_precision; index2_prec=BC7_mode_info[mode].index2_precision; if ((mode == 4) && (selector_bit == 1)) { index_prec=3; alpha_indices[0]=GetBit(block,&start_bit); for (i = 1; i < 16; i++) alpha_indices[i]=GetBits(block,&start_bit,2); } /* get color and subset indices */ for (i=0; i < 16; i++) { subset_indices[i]=GetSubsetIndex(num_subsets,partition_id,i); num_bits=index_prec; if (IsPixelAnchorIndex(subset_indices[i],num_subsets,i,partition_id)) num_bits--; color_indices[i]=GetBits(block,&start_bit,num_bits); } /* get alpha indices if the block has it */ if ((mode == 5) || ((mode == 4) && (selector_bit == 0))) { alpha_indices[0]=GetBits(block,&start_bit,index2_prec - 1); for (i=1; i < 16; i++) alpha_indices[i]=GetBits(block,&start_bit,index2_prec); } /* Write the pixels */ area=MagickMin(MagickMin(4,image->columns-x)*MagickMin(4,image->rows-y), 16); for (i=0; i < (ssize_t) area; i++) { unsigned char c2; c0=2 * subset_indices[i]; c1=(2 * subset_indices[i]) + 1; c2=color_indices[i]; weight=64; /* Color Interpolation */ switch(index_prec) { case 2: if (c2 < sizeof(BC7_weight2)) weight=BC7_weight2[c2]; break; case 3: if (c2 < sizeof(BC7_weight3)) weight=BC7_weight3[c2]; break; default: if (c2 < sizeof(BC7_weight4)) weight=BC7_weight4[c2]; } r=((64 - weight) * colors.r[c0] + weight * colors.r[c1] + 32) >> 6; g=((64 - weight) * colors.g[c0] + weight * colors.g[c1] + 32) >> 6; b=((64 - weight) * colors.b[c0] + weight * colors.b[c1] + 32) >> 6; a=((64 - weight) * colors.a[c0] + weight * colors.a[c1] + 32) >> 6; /* Interpolate alpha for mode 4 and 5 blocks */ if (mode == 4 || mode == 5) { unsigned char a0; a0=alpha_indices[i]; if (a0 < sizeof(BC7_weight2)) weight=BC7_weight2[a0]; if ((mode == 4) && (selector_bit == 0) && (a0 < sizeof(BC7_weight3))) weight=BC7_weight3[a0]; if ((c0 < sizeof(colors.a)) && (c1 < sizeof(colors.a))) a=((64 - weight) * colors.a[c0] + weight * colors.a[c1] + 32) >> 6; } switch (rotation) { case 1: Swap(a,r); break; case 2: Swap(a,g); break; case 3: Swap(a,b); break; } SetPixelRed(image,ScaleCharToQuantum((unsigned char)r),q); SetPixelGreen(image,ScaleCharToQuantum((unsigned char)g),q); SetPixelBlue(image,ScaleCharToQuantum((unsigned char)b),q); SetPixelAlpha(image,ScaleCharToQuantum((unsigned char)a),q); q+=GetPixelChannels(image); } if (SyncAuthenticPixels(image,exception) == MagickFalse) return(MagickFalse); } if (EOFBlob(image) != MagickFalse) return(MagickFalse); } return(MagickTrue); } static MagickBooleanType ReadBC7(const ImageInfo *image_info,Image *image, const DDSInfo *dds_info,const MagickBooleanType read_mipmaps, ExceptionInfo *exception) { if (ReadBC7Pixels(image,dds_info,exception) == MagickFalse) return(MagickFalse); if (read_mipmaps != MagickFalse) return(ReadMipmaps(image_info,image,dds_info,ReadBC7Pixels,exception)); else return(SkipDXTMipmaps(image,dds_info,16,exception)); } static MagickBooleanType ReadUncompressedRGBPixels(Image *image, const DDSInfo *dds_info,ExceptionInfo *exception) { Quantum *q; ssize_t x, y; unsigned short color; for (y = 0; y < (ssize_t) image->rows; y++) { q=QueueAuthenticPixels(image,0,y,image->columns,1,exception); if (q == (Quantum *) NULL) return(MagickFalse); for (x = 0; x < (ssize_t) image->columns; x++) { if (dds_info->pixelformat.rgb_bitcount == 8 || dds_info->extFormat == DXGI_FORMAT_R8_UNORM) SetPixelGray(image,ScaleCharToQuantum(ReadBlobByte(image)),q); else if (dds_info->pixelformat.rgb_bitcount == 16 || dds_info->extFormat == DXGI_FORMAT_B5G6R5_UNORM) { color=ReadBlobShort(image); SetPixelRed(image,ScaleCharToQuantum((unsigned char) (((color >> 11)/31.0)*255)),q); SetPixelGreen(image,ScaleCharToQuantum((unsigned char) ((((unsigned short)(color << 5) >> 10)/63.0)*255)),q); SetPixelBlue(image,ScaleCharToQuantum((unsigned char) ((((unsigned short)(color << 11) >> 11)/31.0)*255)),q); } else { SetPixelBlue(image,ScaleCharToQuantum((unsigned char) ReadBlobByte(image)),q); SetPixelGreen(image,ScaleCharToQuantum((unsigned char) ReadBlobByte(image)),q); SetPixelRed(image,ScaleCharToQuantum((unsigned char) ReadBlobByte(image)),q); if (dds_info->pixelformat.rgb_bitcount == 32 || dds_info->extFormat == DXGI_FORMAT_B8G8R8X8_UNORM) (void) ReadBlobByte(image); } q+=GetPixelChannels(image); } if (SyncAuthenticPixels(image,exception) == MagickFalse) return(MagickFalse); if (EOFBlob(image) != MagickFalse) return(MagickFalse); } return(MagickTrue); } /* Skip the mipmap images for uncompressed (RGB or RGBA) dds files */ static MagickBooleanType SkipRGBMipmaps(Image *image,const DDSInfo *dds_info, int pixel_size,ExceptionInfo *exception) { /* Only skip mipmaps for textures and cube maps */ if (EOFBlob(image) != MagickFalse) { ThrowFileException(exception,CorruptImageError,"UnexpectedEndOfFile", image->filename); return(MagickFalse); } if (dds_info->ddscaps1 & DDSCAPS_MIPMAP && (dds_info->ddscaps1 & DDSCAPS_TEXTURE || dds_info->ddscaps2 & DDSCAPS2_CUBEMAP)) { MagickOffsetType offset; ssize_t i; size_t h, w; w=DIV2(dds_info->width); h=DIV2(dds_info->height); /* Mipmapcount includes the main image, so start from one */ for (i=1; (i < (ssize_t) dds_info->mipmapcount) && w && h; i++) { offset=(MagickOffsetType)w*h*pixel_size; if (SeekBlob(image,offset,SEEK_CUR) < 0) break; w=DIV2(w); h=DIV2(h); if ((w == 1) && (h == 1)) break; } } return(MagickTrue); } static MagickBooleanType ReadUncompressedRGB(const ImageInfo *image_info, Image *image,const DDSInfo *dds_info,const MagickBooleanType read_mipmaps, ExceptionInfo *exception) { if (dds_info->pixelformat.rgb_bitcount == 8 || dds_info->extFormat == DXGI_FORMAT_R8_UNORM) (void) SetImageType(image,GrayscaleType,exception); else if (dds_info->pixelformat.rgb_bitcount == 16 && !IsBitMask( dds_info->pixelformat,0xf800,0x07e0,0x001f,0x0000)) ThrowBinaryException(CorruptImageError,"ImageTypeNotSupported", image->filename); if (ReadUncompressedRGBPixels(image,dds_info,exception) == MagickFalse) return(MagickFalse); if (read_mipmaps != MagickFalse) return(ReadMipmaps(image_info,image,dds_info,ReadUncompressedRGBPixels, exception)); else return(SkipRGBMipmaps(image,dds_info,3,exception)); } static MagickBooleanType ReadUncompressedRGBAPixels(Image *image, const DDSInfo *dds_info,ExceptionInfo *exception) { Quantum *q; ssize_t alphaBits, x, y; unsigned short color; alphaBits=0; if (dds_info->pixelformat.rgb_bitcount == 16) { if (IsBitMask(dds_info->pixelformat,0x7c00,0x03e0,0x001f,0x8000)) alphaBits=1; else if (IsBitMask(dds_info->pixelformat,0x00ff,0x00ff,0x00ff,0xff00)) { alphaBits=2; (void) SetImageType(image,GrayscaleAlphaType,exception); } else if (IsBitMask(dds_info->pixelformat,0x0f00,0x00f0,0x000f,0xf000)) alphaBits=4; else ThrowBinaryException(CorruptImageError,"ImageTypeNotSupported", image->filename); } if (dds_info->extFormat == DXGI_FORMAT_B5G5R5A1_UNORM) alphaBits=1; for (y = 0; y < (ssize_t) image->rows; y++) { q = QueueAuthenticPixels(image, 0, y, image->columns, 1,exception); if (q == (Quantum *) NULL) return(MagickFalse); for (x = 0; x < (ssize_t) image->columns; x++) { if (dds_info->pixelformat.rgb_bitcount == 16 || dds_info->extFormat == DXGI_FORMAT_B5G5R5A1_UNORM) { color=ReadBlobShort(image); if (alphaBits == 1) { SetPixelAlpha(image,(color & (1 << 15)) ? QuantumRange : 0,q); SetPixelRed(image,ScaleCharToQuantum((unsigned char) ((((unsigned short)(color << 1) >> 11)/31.0)*255)),q); SetPixelGreen(image,ScaleCharToQuantum((unsigned char) ((((unsigned short)(color << 6) >> 11)/31.0)*255)),q); SetPixelBlue(image,ScaleCharToQuantum((unsigned char) ((((unsigned short)(color << 11) >> 11)/31.0)*255)),q); } else if (alphaBits == 2) { SetPixelAlpha(image,ScaleCharToQuantum((unsigned char) (color >> 8)),q); SetPixelGray(image,ScaleCharToQuantum((unsigned char)color),q); } else { SetPixelAlpha(image,ScaleCharToQuantum((unsigned char) (((color >> 12)/15.0)*255)),q); SetPixelRed(image,ScaleCharToQuantum((unsigned char) ((((unsigned short)(color << 4) >> 12)/15.0)*255)),q); SetPixelGreen(image,ScaleCharToQuantum((unsigned char) ((((unsigned short)(color << 8) >> 12)/15.0)*255)),q); SetPixelBlue(image,ScaleCharToQuantum((unsigned char) ((((unsigned short)(color << 12) >> 12)/15.0)*255)),q); } } else if (dds_info->extFormat == DXGI_FORMAT_R8G8B8A8_UNORM || IsBitMask(dds_info->pixelformat,0x000000ff,0x0000ff00,0x00ff0000,0xff000000)) { SetPixelRed(image,ScaleCharToQuantum((unsigned char) ReadBlobByte(image)),q); SetPixelGreen(image,ScaleCharToQuantum((unsigned char) ReadBlobByte(image)),q); SetPixelBlue(image,ScaleCharToQuantum((unsigned char) ReadBlobByte(image)),q); SetPixelAlpha(image,ScaleCharToQuantum((unsigned char) ReadBlobByte(image)),q); } else { SetPixelBlue(image,ScaleCharToQuantum((unsigned char) ReadBlobByte(image)),q); SetPixelGreen(image,ScaleCharToQuantum((unsigned char) ReadBlobByte(image)),q); SetPixelRed(image,ScaleCharToQuantum((unsigned char) ReadBlobByte(image)),q); SetPixelAlpha(image,ScaleCharToQuantum((unsigned char) ReadBlobByte(image)),q); } q+=GetPixelChannels(image); } if (SyncAuthenticPixels(image,exception) == MagickFalse) return(MagickFalse); if (EOFBlob(image) != MagickFalse) return(MagickFalse); } return(MagickTrue); } static MagickBooleanType ReadUncompressedRGBA(const ImageInfo *image_info, Image *image,const DDSInfo *dds_info,const MagickBooleanType read_mipmaps, ExceptionInfo *exception) { if (ReadUncompressedRGBAPixels(image,dds_info,exception) == MagickFalse) return(MagickFalse); if (read_mipmaps != MagickFalse) return(ReadMipmaps(image_info,image,dds_info,ReadUncompressedRGBAPixels, exception)); else return(SkipRGBMipmaps(image,dds_info,4,exception)); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % R e a d D D S I m a g e % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % ReadDDSImage() reads a DirectDraw Surface image file and returns it. It % allocates the memory necessary for the new Image structure and returns a % pointer to the new image. % % The format of the ReadDDSImage method is: % % Image *ReadDDSImage(const ImageInfo *image_info,ExceptionInfo *exception) % % A description of each parameter follows: % % o image_info: The image info. % % o exception: return any errors or warnings in this structure. % */ static Image *ReadDDSImage(const ImageInfo *image_info,ExceptionInfo *exception) { const char *option; CompressionType compression; DDSInfo dds_info; DDSDecoder *decoder; Image *image; MagickBooleanType status, cubemap, volume, read_mipmaps; PixelTrait alpha_trait; size_t n, num_images; /* Open image file. */ assert(image_info != (const ImageInfo *) NULL); assert(image_info->signature == MagickCoreSignature); if (image_info->debug != MagickFalse) (void) LogMagickEvent(TraceEvent,GetMagickModule(),"%s", image_info->filename); assert(exception != (ExceptionInfo *) NULL); assert(exception->signature == MagickCoreSignature); cubemap=MagickFalse, volume=MagickFalse, read_mipmaps=MagickFalse; image=AcquireImage(image_info,exception); status=OpenBlob(image_info,image,ReadBinaryBlobMode,exception); if (status == MagickFalse) { image=DestroyImageList(image); return((Image *) NULL); } /* Initialize image structure. */ if (ReadDDSInfo(image, &dds_info) != MagickTrue) ThrowReaderException(CorruptImageError,"ImproperImageHeader"); if (dds_info.ddscaps2 & DDSCAPS2_CUBEMAP) cubemap = MagickTrue; if (dds_info.ddscaps2 & DDSCAPS2_VOLUME && dds_info.depth > 0) volume = MagickTrue; /* Determine pixel format */ if (dds_info.pixelformat.flags & DDPF_RGB) { compression = NoCompression; if (dds_info.pixelformat.flags & DDPF_ALPHAPIXELS) { alpha_trait = BlendPixelTrait; decoder = ReadUncompressedRGBA; } else { alpha_trait = UndefinedPixelTrait; decoder = ReadUncompressedRGB; } } else if (dds_info.pixelformat.flags & DDPF_LUMINANCE) { compression = NoCompression; if (dds_info.pixelformat.flags & DDPF_ALPHAPIXELS) { /* Not sure how to handle this */ ThrowReaderException(CorruptImageError, "ImageTypeNotSupported"); } else { alpha_trait = UndefinedPixelTrait; decoder = ReadUncompressedRGB; } } else if (dds_info.pixelformat.flags & DDPF_FOURCC) { switch (dds_info.pixelformat.fourcc) { case FOURCC_DXT1: { alpha_trait = UndefinedPixelTrait; compression = DXT1Compression; decoder = ReadDXT1; break; } case FOURCC_DXT3: { alpha_trait = BlendPixelTrait; compression = DXT3Compression; decoder = ReadDXT3; break; } case FOURCC_DXT5: { alpha_trait = BlendPixelTrait; compression = DXT5Compression; decoder = ReadDXT5; break; } case FOURCC_DX10: { if (dds_info.extDimension != DDSEXT_DIMENSION_TEX2D) { ThrowReaderException(CorruptImageError, "ImageTypeNotSupported"); } switch (dds_info.extFormat) { case DXGI_FORMAT_R8_UNORM: { compression = NoCompression; alpha_trait = UndefinedPixelTrait; decoder = ReadUncompressedRGB; break; } case DXGI_FORMAT_B5G6R5_UNORM: { compression = NoCompression; alpha_trait = UndefinedPixelTrait; decoder = ReadUncompressedRGB; break; } case DXGI_FORMAT_B5G5R5A1_UNORM: { compression = NoCompression; alpha_trait = BlendPixelTrait; decoder = ReadUncompressedRGBA; break; } case DXGI_FORMAT_B8G8R8A8_UNORM: { compression = NoCompression; alpha_trait = BlendPixelTrait; decoder = ReadUncompressedRGBA; break; } case DXGI_FORMAT_R8G8B8A8_UNORM: { compression = NoCompression; alpha_trait = BlendPixelTrait; decoder = ReadUncompressedRGBA; break; } case DXGI_FORMAT_B8G8R8X8_UNORM: { compression = NoCompression; alpha_trait = UndefinedPixelTrait; decoder = ReadUncompressedRGB; break; } case DXGI_FORMAT_BC1_UNORM: { alpha_trait = UndefinedPixelTrait; compression = DXT1Compression; decoder = ReadDXT1; break; } case DXGI_FORMAT_BC2_UNORM: { alpha_trait = BlendPixelTrait; compression = DXT3Compression; decoder = ReadDXT3; break; } case DXGI_FORMAT_BC3_UNORM: { alpha_trait = BlendPixelTrait; compression = DXT5Compression; decoder = ReadDXT5; break; } case DXGI_FORMAT_BC7_UNORM: case DXGI_FORMAT_BC7_UNORM_SRGB: { alpha_trait = BlendPixelTrait; compression = BC7Compression; decoder = ReadBC7; break; } default: { /* Unknown format */ ThrowReaderException(CorruptImageError, "ImageTypeNotSupported"); } } if (dds_info.extFlags & DDSEXTFLAGS_CUBEMAP) cubemap = MagickTrue; num_images = dds_info.extArraySize; break; } default: { /* Unknown FOURCC */ ThrowReaderException(CorruptImageError, "ImageTypeNotSupported"); } } } else { /* Neither compressed nor uncompressed... thus unsupported */ ThrowReaderException(CorruptImageError, "ImageTypeNotSupported"); } num_images = 1; if (cubemap) { /* Determine number of faces defined in the cubemap */ num_images = 0; if (dds_info.ddscaps2 & DDSCAPS2_CUBEMAP_POSITIVEX) num_images++; if (dds_info.ddscaps2 & DDSCAPS2_CUBEMAP_NEGATIVEX) num_images++; if (dds_info.ddscaps2 & DDSCAPS2_CUBEMAP_POSITIVEY) num_images++; if (dds_info.ddscaps2 & DDSCAPS2_CUBEMAP_NEGATIVEY) num_images++; if (dds_info.ddscaps2 & DDSCAPS2_CUBEMAP_POSITIVEZ) num_images++; if (dds_info.ddscaps2 & DDSCAPS2_CUBEMAP_NEGATIVEZ) num_images++; } if (volume) num_images = dds_info.depth; if ((num_images == 0) || (num_images > GetBlobSize(image))) ThrowReaderException(CorruptImageError,"ImproperImageHeader"); if (AcquireMagickResource(ListLengthResource,num_images) == MagickFalse) ThrowReaderException(ResourceLimitError,"ListLengthExceedsLimit"); option=GetImageOption(image_info,"dds:skip-mipmaps"); if (IsStringFalse(option) != MagickFalse) read_mipmaps=MagickTrue; for (n = 0; n < num_images; n++) { if (n != 0) { /* Start a new image */ if (EOFBlob(image) != MagickFalse) ThrowReaderException(CorruptImageError,"UnexpectedEndOfFile"); AcquireNextImage(image_info,image,exception); if (GetNextImageInList(image) == (Image *) NULL) return(DestroyImageList(image)); image=SyncNextImageInList(image); } image->alpha_trait=alpha_trait; image->compression=compression; image->columns=dds_info.width; image->rows=dds_info.height; image->storage_class=DirectClass; image->endian=LSBEndian; image->depth=8; if (image_info->ping != MagickFalse) { (void) CloseBlob(image); return(GetFirstImageInList(image)); } status=SetImageExtent(image,image->columns,image->rows,exception); if (status == MagickFalse) return(DestroyImageList(image)); (void) SetImageBackgroundColor(image,exception); status=(decoder)(image_info,image,&dds_info,read_mipmaps,exception); if (status == MagickFalse) { (void) CloseBlob(image); if (n == 0) return(DestroyImageList(image)); return(GetFirstImageInList(image)); } } (void) CloseBlob(image); return(GetFirstImageInList(image)); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % R e g i s t e r D D S I m a g e % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % RegisterDDSImage() adds attributes for the DDS image format to % the list of supported formats. The attributes include the image format % tag, a method to read and/or write the format, whether the format % supports the saving of more than one frame to the same file or blob, % whether the format supports native in-memory I/O, and a brief % description of the format. % % The format of the RegisterDDSImage method is: % % RegisterDDSImage(void) % */ ModuleExport size_t RegisterDDSImage(void) { MagickInfo *entry; entry = AcquireMagickInfo("DDS","DDS","Microsoft DirectDraw Surface"); entry->decoder = (DecodeImageHandler *) ReadDDSImage; entry->encoder = (EncodeImageHandler *) WriteDDSImage; entry->magick = (IsImageFormatHandler *) IsDDS; entry->flags|=CoderDecoderSeekableStreamFlag; (void) RegisterMagickInfo(entry); entry = AcquireMagickInfo("DDS","DXT1","Microsoft DirectDraw Surface"); entry->decoder = (DecodeImageHandler *) ReadDDSImage; entry->encoder = (EncodeImageHandler *) WriteDDSImage; entry->magick = (IsImageFormatHandler *) IsDDS; entry->flags|=CoderDecoderSeekableStreamFlag; (void) RegisterMagickInfo(entry); entry = AcquireMagickInfo("DDS","DXT5","Microsoft DirectDraw Surface"); entry->decoder = (DecodeImageHandler *) ReadDDSImage; entry->encoder = (EncodeImageHandler *) WriteDDSImage; entry->magick = (IsImageFormatHandler *) IsDDS; entry->flags|=CoderDecoderSeekableStreamFlag; (void) RegisterMagickInfo(entry); return(MagickImageCoderSignature); } static void RemapIndices(const ssize_t *map, const unsigned char *source, unsigned char *target) { ssize_t i; for (i = 0; i < 16; i++) { if (map[i] == -1) target[i] = 3; else target[i] = source[map[i]]; } } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % U n r e g i s t e r D D S I m a g e % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % UnregisterDDSImage() removes format registrations made by the % DDS module from the list of supported formats. % % The format of the UnregisterDDSImage method is: % % UnregisterDDSImage(void) % */ ModuleExport void UnregisterDDSImage(void) { (void) UnregisterMagickInfo("DDS"); (void) UnregisterMagickInfo("DXT1"); (void) UnregisterMagickInfo("DXT5"); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % W r i t e D D S I m a g e % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % WriteDDSImage() writes a DirectDraw Surface image file in the DXT5 format. % % The format of the WriteDDSImage method is: % % MagickBooleanType WriteDDSImage(const ImageInfo *image_info,Image *image) % % A description of each parameter follows. % % o image_info: the image info. % % o image: The image. % */ static size_t CompressAlpha(const size_t min, const size_t max, const size_t steps, const ssize_t *alphas, unsigned char* indices) { unsigned char codes[8]; ssize_t i; size_t error, index, j, least, value; codes[0] = (unsigned char) min; codes[1] = (unsigned char) max; codes[6] = 0; codes[7] = 255; for (i=1; i < (ssize_t) steps; i++) codes[i+1] = (unsigned char) (((steps-i)*min + i*max) / steps); error = 0; for (i=0; i<16; i++) { if (alphas[i] == -1) { indices[i] = 0; continue; } value = alphas[i]; least = SIZE_MAX; index = 0; for (j=0; j<8; j++) { size_t dist; dist = value - (size_t)codes[j]; dist *= dist; if (dist < least) { least = dist; index = j; } } indices[i] = (unsigned char)index; error += least; } return error; } static MagickBooleanType ConstructOrdering(const size_t count, const DDSVector4 *points, const DDSVector3 axis, DDSVector4 *pointsWeights, DDSVector4 *xSumwSum, unsigned char *order, size_t iteration) { float dps[16], f; ssize_t i; size_t j; unsigned char c, *o, *p; o = order + (16*iteration); for (i=0; i < (ssize_t) count; i++) { dps[i] = Dot(points[i],axis); o[i] = (unsigned char)i; } for (i=0; i < (ssize_t) count; i++) { for (j=i; j > 0 && dps[j] < dps[j - 1]; j--) { f = dps[j]; dps[j] = dps[j - 1]; dps[j - 1] = f; c = o[j]; o[j] = o[j - 1]; o[j - 1] = c; } } for (i=0; i < (ssize_t) iteration; i++) { MagickBooleanType same; p = order + (16*i); same = MagickTrue; for (j=0; j < count; j++) { if (o[j] != p[j]) { same = MagickFalse; break; } } if (same != MagickFalse) return MagickFalse; } xSumwSum->x = 0; xSumwSum->y = 0; xSumwSum->z = 0; xSumwSum->w = 0; for (i=0; i < (ssize_t) count; i++) { DDSVector4 v; j = (size_t) o[i]; v.x = points[j].w * points[j].x; v.y = points[j].w * points[j].y; v.z = points[j].w * points[j].z; v.w = points[j].w * 1.0f; VectorCopy44(v,&pointsWeights[i]); VectorAdd(*xSumwSum,v,xSumwSum); } return MagickTrue; } static void CompressClusterFit(const size_t count, const DDSVector4 *points, const ssize_t *map, const DDSVector3 principle, const DDSVector4 metric, DDSVector3 *start, DDSVector3* end, unsigned char *indices) { DDSVector3 axis; DDSVector4 grid, gridrcp, half, onethird_onethird2, pointsWeights[16], two, twonineths, twothirds_twothirds2, xSumwSum; float bestError = 1e+37f; size_t bestIteration = 0, besti = 0, bestj = 0, bestk = 0, iterationIndex; ssize_t i; unsigned char *o, order[128], unordered[16]; VectorInit(half,0.5f); VectorInit(two,2.0f); VectorInit(onethird_onethird2,1.0f/3.0f); onethird_onethird2.w = 1.0f/9.0f; VectorInit(twothirds_twothirds2,2.0f/3.0f); twothirds_twothirds2.w = 4.0f/9.0f; VectorInit(twonineths,2.0f/9.0f); grid.x = 31.0f; grid.y = 63.0f; grid.z = 31.0f; grid.w = 0.0f; gridrcp.x = 1.0f/31.0f; gridrcp.y = 1.0f/63.0f; gridrcp.z = 1.0f/31.0f; gridrcp.w = 0.0f; xSumwSum.x = 0.0f; xSumwSum.y = 0.0f; xSumwSum.z = 0.0f; xSumwSum.w = 0.0f; ConstructOrdering(count,points,principle,pointsWeights,&xSumwSum,order,0); for (iterationIndex = 0;;) { #if defined(MAGICKCORE_OPENMP_SUPPORT) #pragma omp parallel for schedule(dynamic,1) \ num_threads(GetMagickResourceLimit(ThreadResource)) #endif for (i=0; i < (ssize_t) count; i++) { DDSVector4 part0, part1, part2; size_t ii, j, k, kmin; VectorInit(part0,0.0f); for(ii=0; ii < (size_t) i; ii++) VectorAdd(pointsWeights[ii],part0,&part0); VectorInit(part1,0.0f); for (j=(size_t) i;;) { if (j == 0) { VectorCopy44(pointsWeights[0],&part2); kmin = 1; } else { VectorInit(part2,0.0f); kmin = j; } for (k=kmin;;) { DDSVector4 a, alpha2_sum, alphax_sum, alphabeta_sum, b, beta2_sum, betax_sum, e1, e2, factor, part3; float error; VectorSubtract(xSumwSum,part2,&part3); VectorSubtract(part3,part1,&part3); VectorSubtract(part3,part0,&part3); VectorMultiplyAdd(part1,twothirds_twothirds2,part0,&alphax_sum); VectorMultiplyAdd(part2,onethird_onethird2,alphax_sum,&alphax_sum); VectorInit(alpha2_sum,alphax_sum.w); VectorMultiplyAdd(part2,twothirds_twothirds2,part3,&betax_sum); VectorMultiplyAdd(part1,onethird_onethird2,betax_sum,&betax_sum); VectorInit(beta2_sum,betax_sum.w); VectorAdd(part1,part2,&alphabeta_sum); VectorInit(alphabeta_sum,alphabeta_sum.w); VectorMultiply(twonineths,alphabeta_sum,&alphabeta_sum); VectorMultiply(alpha2_sum,beta2_sum,&factor); VectorNegativeMultiplySubtract(alphabeta_sum,alphabeta_sum,factor, &factor); VectorReciprocal(factor,&factor); VectorMultiply(alphax_sum,beta2_sum,&a); VectorNegativeMultiplySubtract(betax_sum,alphabeta_sum,a,&a); VectorMultiply(a,factor,&a); VectorMultiply(betax_sum,alpha2_sum,&b); VectorNegativeMultiplySubtract(alphax_sum,alphabeta_sum,b,&b); VectorMultiply(b,factor,&b); VectorClamp(&a); VectorMultiplyAdd(grid,a,half,&a); VectorTruncate(&a); VectorMultiply(a,gridrcp,&a); VectorClamp(&b); VectorMultiplyAdd(grid,b,half,&b); VectorTruncate(&b); VectorMultiply(b,gridrcp,&b); VectorMultiply(b,b,&e1); VectorMultiply(e1,beta2_sum,&e1); VectorMultiply(a,a,&e2); VectorMultiplyAdd(e2,alpha2_sum,e1,&e1); VectorMultiply(a,b,&e2); VectorMultiply(e2,alphabeta_sum,&e2); VectorNegativeMultiplySubtract(a,alphax_sum,e2,&e2); VectorNegativeMultiplySubtract(b,betax_sum,e2,&e2); VectorMultiplyAdd(two,e2,e1,&e2); VectorMultiply(e2,metric,&e2); error = e2.x + e2.y + e2.z; if (error < bestError) { #if defined(MAGICKCORE_OPENMP_SUPPORT) #pragma omp critical (DDS_CompressClusterFit) #endif { if (error < bestError) { VectorCopy43(a,start); VectorCopy43(b,end); bestError = error; besti = i; bestj = j; bestk = k; bestIteration = iterationIndex; } } } if (k == count) break; VectorAdd(pointsWeights[k],part2,&part2); k++; } if (j == count) break; VectorAdd(pointsWeights[j],part1,&part1); j++; } } if (bestIteration != iterationIndex) break; iterationIndex++; if (iterationIndex == 8) break; VectorSubtract3(*end,*start,&axis); if (ConstructOrdering(count,points,axis,pointsWeights,&xSumwSum,order, iterationIndex) == MagickFalse) break; } o = order + (16*bestIteration); for (i=0; i < (ssize_t) besti; i++) unordered[o[i]] = 0; for (i=besti; i < (ssize_t) bestj; i++) unordered[o[i]] = 2; for (i=bestj; i < (ssize_t) bestk; i++) unordered[o[i]] = 3; for (i=bestk; i < (ssize_t) count; i++) unordered[o[i]] = 1; RemapIndices(map,unordered,indices); } static void CompressRangeFit(const size_t count, const DDSVector4* points, const ssize_t *map, const DDSVector3 principle, const DDSVector4 metric, DDSVector3 *start, DDSVector3 *end, unsigned char *indices) { float d, bestDist, max, min, val; DDSVector3 codes[4], grid, gridrcp, half, dist; ssize_t i; size_t bestj, j; unsigned char closest[16]; VectorInit3(half,0.5f); grid.x = 31.0f; grid.y = 63.0f; grid.z = 31.0f; gridrcp.x = 1.0f/31.0f; gridrcp.y = 1.0f/63.0f; gridrcp.z = 1.0f/31.0f; if (count > 0) { VectorCopy43(points[0],start); VectorCopy43(points[0],end); min = max = Dot(points[0],principle); for (i=1; i < (ssize_t) count; i++) { val = Dot(points[i],principle); if (val < min) { VectorCopy43(points[i],start); min = val; } else if (val > max) { VectorCopy43(points[i],end); max = val; } } } VectorClamp3(start); VectorMultiplyAdd3(grid,*start,half,start); VectorTruncate3(start); VectorMultiply3(*start,gridrcp,start); VectorClamp3(end); VectorMultiplyAdd3(grid,*end,half,end); VectorTruncate3(end); VectorMultiply3(*end,gridrcp,end); codes[0] = *start; codes[1] = *end; codes[2].x = (start->x * (2.0f/3.0f)) + (end->x * (1.0f/3.0f)); codes[2].y = (start->y * (2.0f/3.0f)) + (end->y * (1.0f/3.0f)); codes[2].z = (start->z * (2.0f/3.0f)) + (end->z * (1.0f/3.0f)); codes[3].x = (start->x * (1.0f/3.0f)) + (end->x * (2.0f/3.0f)); codes[3].y = (start->y * (1.0f/3.0f)) + (end->y * (2.0f/3.0f)); codes[3].z = (start->z * (1.0f/3.0f)) + (end->z * (2.0f/3.0f)); for (i=0; i < (ssize_t) count; i++) { bestDist = 1e+37f; bestj = 0; for (j=0; j < 4; j++) { dist.x = (points[i].x - codes[j].x) * metric.x; dist.y = (points[i].y - codes[j].y) * metric.y; dist.z = (points[i].z - codes[j].z) * metric.z; d = Dot(dist,dist); if (d < bestDist) { bestDist = d; bestj = j; } } closest[i] = (unsigned char) bestj; } RemapIndices(map, closest, indices); } static void ComputeEndPoints(const DDSSingleColorLookup *lookup[], const unsigned char *color, DDSVector3 *start, DDSVector3 *end, unsigned char *index) { ssize_t i; size_t c, maxError = SIZE_MAX; for (i=0; i < 2; i++) { const DDSSourceBlock* sources[3]; size_t error = 0; for (c=0; c < 3; c++) { sources[c] = &lookup[c][color[c]].sources[i]; error += ((size_t) sources[c]->error) * ((size_t) sources[c]->error); } if (error > maxError) continue; start->x = (float) sources[0]->start / 31.0f; start->y = (float) sources[1]->start / 63.0f; start->z = (float) sources[2]->start / 31.0f; end->x = (float) sources[0]->end / 31.0f; end->y = (float) sources[1]->end / 63.0f; end->z = (float) sources[2]->end / 31.0f; *index = (unsigned char) (2*i); maxError = error; } } static void ComputePrincipleComponent(const float *covariance, DDSVector3 *principle) { DDSVector4 row0, row1, row2, v; ssize_t i; row0.x = covariance[0]; row0.y = covariance[1]; row0.z = covariance[2]; row0.w = 0.0f; row1.x = covariance[1]; row1.y = covariance[3]; row1.z = covariance[4]; row1.w = 0.0f; row2.x = covariance[2]; row2.y = covariance[4]; row2.z = covariance[5]; row2.w = 0.0f; VectorInit(v,1.0f); for (i=0; i < 8; i++) { DDSVector4 w; float a; w.x = row0.x * v.x; w.y = row0.y * v.x; w.z = row0.z * v.x; w.w = row0.w * v.x; w.x = (row1.x * v.y) + w.x; w.y = (row1.y * v.y) + w.y; w.z = (row1.z * v.y) + w.z; w.w = (row1.w * v.y) + w.w; w.x = (row2.x * v.z) + w.x; w.y = (row2.y * v.z) + w.y; w.z = (row2.z * v.z) + w.z; w.w = (row2.w * v.z) + w.w; a = (float) PerceptibleReciprocal(MagickMax(w.x,MagickMax(w.y,w.z))); v.x = w.x * a; v.y = w.y * a; v.z = w.z * a; v.w = w.w * a; } VectorCopy43(v,principle); } static void ComputeWeightedCovariance(const size_t count, const DDSVector4 *points, float *covariance) { DDSVector3 centroid; float total; size_t i; total = 0.0f; VectorInit3(centroid,0.0f); for (i=0; i < count; i++) { total += points[i].w; centroid.x += (points[i].x * points[i].w); centroid.y += (points[i].y * points[i].w); centroid.z += (points[i].z * points[i].w); } if( total > 1.192092896e-07F) { centroid.x /= total; centroid.y /= total; centroid.z /= total; } for (i=0; i < 6; i++) covariance[i] = 0.0f; for (i = 0; i < count; i++) { DDSVector3 a, b; a.x = points[i].x - centroid.x; a.y = points[i].y - centroid.y; a.z = points[i].z - centroid.z; b.x = points[i].w * a.x; b.y = points[i].w * a.y; b.z = points[i].w * a.z; covariance[0] += a.x*b.x; covariance[1] += a.x*b.y; covariance[2] += a.x*b.z; covariance[3] += a.y*b.y; covariance[4] += a.y*b.z; covariance[5] += a.z*b.z; } } static void WriteAlphas(Image *image, const ssize_t *alphas, size_t min5, size_t max5, size_t min7, size_t max7) { ssize_t i; size_t err5, err7, j; unsigned char indices5[16], indices7[16]; FixRange(min5,max5,5); err5 = CompressAlpha(min5,max5,5,alphas,indices5); FixRange(min7,max7,7); err7 = CompressAlpha(min7,max7,7,alphas,indices7); if (err7 < err5) { for (i=0; i < 16; i++) { unsigned char index; index = indices7[i]; if( index == 0 ) indices5[i] = 1; else if (index == 1) indices5[i] = 0; else indices5[i] = 9 - index; } min5 = max7; max5 = min7; } (void) WriteBlobByte(image,(unsigned char) min5); (void) WriteBlobByte(image,(unsigned char) max5); for(i=0; i < 2; i++) { size_t value = 0; for (j=0; j < 8; j++) { size_t index = (size_t) indices5[j + i*8]; value |= ( index << 3*j ); } for (j=0; j < 3; j++) { size_t byte = (value >> 8*j) & 0xff; (void) WriteBlobByte(image,(unsigned char) byte); } } } static void WriteIndices(Image *image, const DDSVector3 start, const DDSVector3 end, unsigned char *indices) { ssize_t i; size_t a, b; unsigned char remapped[16]; const unsigned char *ind; a = ColorTo565(start); b = ColorTo565(end); for (i=0; i<16; i++) { if( a < b ) remapped[i] = (indices[i] ^ 0x1) & 0x3; else if( a == b ) remapped[i] = 0; else remapped[i] = indices[i]; } if( a < b ) Swap(a,b); (void) WriteBlobByte(image,(unsigned char) (a & 0xff)); (void) WriteBlobByte(image,(unsigned char) (a >> 8)); (void) WriteBlobByte(image,(unsigned char) (b & 0xff)); (void) WriteBlobByte(image,(unsigned char) (b >> 8)); for (i=0; i<4; i++) { ind = remapped + 4*i; (void) WriteBlobByte(image,ind[0] | (ind[1] << 2) | (ind[2] << 4) | (ind[3] << 6)); } } static void WriteCompressed(Image *image, const size_t count, DDSVector4 *points, const ssize_t *map, const MagickBooleanType clusterFit) { float covariance[16]; DDSVector3 end, principle, start; DDSVector4 metric; unsigned char indices[16]; VectorInit(metric,1.0f); VectorInit3(start,0.0f); VectorInit3(end,0.0f); ComputeWeightedCovariance(count,points,covariance); ComputePrincipleComponent(covariance,&principle); if ((clusterFit == MagickFalse) || (count == 0)) CompressRangeFit(count,points,map,principle,metric,&start,&end,indices); else CompressClusterFit(count,points,map,principle,metric,&start,&end,indices); WriteIndices(image,start,end,indices); } static void WriteSingleColorFit(Image *image, const DDSVector4 *points, const ssize_t *map) { DDSVector3 start, end; ssize_t i; unsigned char color[3], index, indexes[16], indices[16]; color[0] = (unsigned char) ClampToLimit(255.0f*points->x,255); color[1] = (unsigned char) ClampToLimit(255.0f*points->y,255); color[2] = (unsigned char) ClampToLimit(255.0f*points->z,255); index=0; ComputeEndPoints(DDS_LOOKUP,color,&start,&end,&index); for (i=0; i< 16; i++) indexes[i]=index; RemapIndices(map,indexes,indices); WriteIndices(image,start,end,indices); } static void WriteFourCC(Image *image, const size_t compression, const MagickBooleanType clusterFit, const MagickBooleanType weightByAlpha, ExceptionInfo *exception) { ssize_t x; ssize_t i, y, bx, by; const Quantum *p; for (y=0; y < (ssize_t) image->rows; y+=4) { for (x=0; x < (ssize_t) image->columns; x+=4) { MagickBooleanType match; DDSVector4 point, points[16]; size_t count = 0, max5 = 0, max7 = 0, min5 = 255, min7 = 255, columns = 4, rows = 4; ssize_t alphas[16], map[16]; unsigned char alpha; if (x + columns >= image->columns) columns = image->columns - x; if (y + rows >= image->rows) rows = image->rows - y; p=GetVirtualPixels(image,x,y,columns,rows,exception); if (p == (const Quantum *) NULL) break; for (i=0; i<16; i++) { map[i] = -1; alphas[i] = -1; } for (by=0; by < (ssize_t) rows; by++) { for (bx=0; bx < (ssize_t) columns; bx++) { if (compression == FOURCC_DXT5) alpha = ScaleQuantumToChar(GetPixelAlpha(image,p)); else alpha = 255; if (compression == FOURCC_DXT5) { if (alpha < min7) min7 = alpha; if (alpha > max7) max7 = alpha; if (alpha != 0 && alpha < min5) min5 = alpha; if (alpha != 255 && alpha > max5) max5 = alpha; } alphas[4*by + bx] = (size_t)alpha; point.x = (float)ScaleQuantumToChar(GetPixelRed(image,p)) / 255.0f; point.y = (float)ScaleQuantumToChar(GetPixelGreen(image,p)) / 255.0f; point.z = (float)ScaleQuantumToChar(GetPixelBlue(image,p)) / 255.0f; point.w = weightByAlpha ? (float)(alpha + 1) / 256.0f : 1.0f; p+=GetPixelChannels(image); match = MagickFalse; for (i=0; i < (ssize_t) count; i++) { if ((points[i].x == point.x) && (points[i].y == point.y) && (points[i].z == point.z) && (alpha >= 128 || compression == FOURCC_DXT5)) { points[i].w += point.w; map[4*by + bx] = i; match = MagickTrue; break; } } if (match != MagickFalse) continue; points[count].x = point.x; points[count].y = point.y; points[count].z = point.z; points[count].w = point.w; map[4*by + bx] = count; count++; } } for (i=0; i < (ssize_t) count; i++) points[i].w = sqrt(points[i].w); if (compression == FOURCC_DXT5) WriteAlphas(image,alphas,min5,max5,min7,max7); if (count == 1) WriteSingleColorFit(image,points,map); else WriteCompressed(image,count,points,map,clusterFit); } } } static void WriteUncompressed(Image *image, ExceptionInfo *exception) { const Quantum *p; ssize_t x; ssize_t y; for (y=0; y < (ssize_t) image->rows; y++) { p=GetVirtualPixels(image,0,y,image->columns,1,exception); if (p == (const Quantum *) NULL) break; for (x=0; x < (ssize_t) image->columns; x++) { (void) WriteBlobByte(image,ScaleQuantumToChar(GetPixelBlue(image,p))); (void) WriteBlobByte(image,ScaleQuantumToChar(GetPixelGreen(image,p))); (void) WriteBlobByte(image,ScaleQuantumToChar(GetPixelRed(image,p))); if (image->alpha_trait != UndefinedPixelTrait) (void) WriteBlobByte(image,ScaleQuantumToChar(GetPixelAlpha(image,p))); p+=GetPixelChannels(image); } } } static void WriteImageData(Image *image, const size_t pixelFormat, const size_t compression,const MagickBooleanType clusterFit, const MagickBooleanType weightByAlpha, ExceptionInfo *exception) { if (pixelFormat == DDPF_FOURCC) WriteFourCC(image,compression,clusterFit,weightByAlpha,exception); else WriteUncompressed(image,exception); } static MagickBooleanType WriteMipmaps(Image *image,const ImageInfo *image_info, const size_t pixelFormat,const size_t compression,const size_t mipmaps, const MagickBooleanType fromlist,const MagickBooleanType clusterFit, const MagickBooleanType weightByAlpha,ExceptionInfo *exception) { const char *option; Image *mipmap_image, *resize_image; MagickBooleanType fast_mipmaps, status; ssize_t i; size_t columns, rows; columns=DIV2(image->columns); rows=DIV2(image->rows); option=GetImageOption(image_info,"dds:fast-mipmaps"); fast_mipmaps=IsStringTrue(option); mipmap_image=image; resize_image=image; status=MagickTrue; for (i=0; i < (ssize_t) mipmaps; i++) { if (fromlist == MagickFalse) { mipmap_image=ResizeImage(resize_image,columns,rows,TriangleFilter, exception); if (mipmap_image == (Image *) NULL) { status=MagickFalse; break; } } else { mipmap_image=mipmap_image->next; if ((mipmap_image->columns != columns) || (mipmap_image->rows != rows)) ThrowBinaryException(CoderError,"ImageColumnOrRowSizeIsNotSupported", image->filename); } DestroyBlob(mipmap_image); mipmap_image->blob=ReferenceBlob(image->blob); WriteImageData(mipmap_image,pixelFormat,compression,weightByAlpha, clusterFit,exception); if (fromlist == MagickFalse) { if (fast_mipmaps == MagickFalse) mipmap_image=DestroyImage(mipmap_image); else { if (resize_image != image) resize_image=DestroyImage(resize_image); resize_image=mipmap_image; } } columns=DIV2(columns); rows=DIV2(rows); } if (resize_image != image) resize_image=DestroyImage(resize_image); return(status); } static void WriteDDSInfo(Image *image, const size_t pixelFormat, const size_t compression, const size_t mipmaps) { char software[MagickPathExtent]; ssize_t i; unsigned int format, caps, flags; flags=(unsigned int) (DDSD_CAPS | DDSD_WIDTH | DDSD_HEIGHT | DDSD_PIXELFORMAT); caps=(unsigned int) DDSCAPS_TEXTURE; format=(unsigned int) pixelFormat; if (format == DDPF_FOURCC) flags=flags | DDSD_LINEARSIZE; else flags=flags | DDSD_PITCH; if (mipmaps > 0) { flags=flags | (unsigned int) DDSD_MIPMAPCOUNT; caps=caps | (unsigned int) (DDSCAPS_MIPMAP | DDSCAPS_COMPLEX); } if (format != DDPF_FOURCC && image->alpha_trait != UndefinedPixelTrait) format=format | DDPF_ALPHAPIXELS; (void) WriteBlob(image,4,(unsigned char *) "DDS "); (void) WriteBlobLSBLong(image,124); (void) WriteBlobLSBLong(image,flags); (void) WriteBlobLSBLong(image,(unsigned int) image->rows); (void) WriteBlobLSBLong(image,(unsigned int) image->columns); if (pixelFormat == DDPF_FOURCC) { /* Compressed DDS requires linear compressed size of first image */ if (compression == FOURCC_DXT1) (void) WriteBlobLSBLong(image,(unsigned int) (MagickMax(1, (image->columns+3)/4)*MagickMax(1,(image->rows+3)/4)*8)); else /* DXT5 */ (void) WriteBlobLSBLong(image,(unsigned int) (MagickMax(1, (image->columns+3)/4)*MagickMax(1,(image->rows+3)/4)*16)); } else { /* Uncompressed DDS requires byte pitch of first image */ if (image->alpha_trait != UndefinedPixelTrait) (void) WriteBlobLSBLong(image,(unsigned int) (image->columns * 4)); else (void) WriteBlobLSBLong(image,(unsigned int) (image->columns * 3)); } (void) WriteBlobLSBLong(image,0x00); (void) WriteBlobLSBLong(image,(unsigned int) mipmaps+1); (void) memset(software,0,sizeof(software)); (void) CopyMagickString(software,"IMAGEMAGICK",MagickPathExtent); (void) WriteBlob(image,44,(unsigned char *) software); (void) WriteBlobLSBLong(image,32); (void) WriteBlobLSBLong(image,format); if (pixelFormat == DDPF_FOURCC) { (void) WriteBlobLSBLong(image,(unsigned int) compression); for(i=0;i < 5;i++) /* bitcount / masks */ (void) WriteBlobLSBLong(image,0x00); } else { (void) WriteBlobLSBLong(image,0x00); if (image->alpha_trait != UndefinedPixelTrait) { (void) WriteBlobLSBLong(image,32); (void) WriteBlobLSBLong(image,0xff0000); (void) WriteBlobLSBLong(image,0xff00); (void) WriteBlobLSBLong(image,0xff); (void) WriteBlobLSBLong(image,0xff000000); } else { (void) WriteBlobLSBLong(image,24); (void) WriteBlobLSBLong(image,0xff0000); (void) WriteBlobLSBLong(image,0xff00); (void) WriteBlobLSBLong(image,0xff); (void) WriteBlobLSBLong(image,0x00); } } (void) WriteBlobLSBLong(image,caps); for(i=0;i < 4;i++) /* ddscaps2 + reserved region */ (void) WriteBlobLSBLong(image,0x00); } static MagickBooleanType WriteDDSImage(const ImageInfo *image_info, Image *image, ExceptionInfo *exception) { const char *option; size_t compression, columns, maxMipmaps, mipmaps, pixelFormat, rows; MagickBooleanType clusterFit, fromlist, status, weightByAlpha; assert(image_info != (const ImageInfo *) NULL); assert(image_info->signature == MagickCoreSignature); assert(image != (Image *) NULL); assert(image->signature == MagickCoreSignature); if (image->debug != MagickFalse) (void) LogMagickEvent(TraceEvent,GetMagickModule(),"%s",image->filename); status=OpenBlob(image_info,image,WriteBinaryBlobMode,exception); if (status == MagickFalse) return(status); if (IssRGBCompatibleColorspace(image->colorspace) == MagickFalse) (void) TransformImageColorspace(image,sRGBColorspace,exception); pixelFormat=DDPF_FOURCC; compression=FOURCC_DXT5; if (image->alpha_trait == UndefinedPixelTrait) compression=FOURCC_DXT1; if (LocaleCompare(image_info->magick,"dxt1") == 0) compression=FOURCC_DXT1; if (image_info->compression == DXT1Compression) compression=FOURCC_DXT1; else if (image_info->compression == NoCompression) pixelFormat=DDPF_RGB; option=GetImageOption(image_info,"dds:compression"); if (option != (char *) NULL) { if (LocaleCompare(option,"dxt1") == 0) compression=FOURCC_DXT1; if (LocaleCompare(option,"none") == 0) pixelFormat=DDPF_RGB; } clusterFit=MagickFalse; weightByAlpha=MagickFalse; if (pixelFormat == DDPF_FOURCC) { option=GetImageOption(image_info,"dds:cluster-fit"); if (IsStringTrue(option) != MagickFalse) { clusterFit=MagickTrue; if (compression != FOURCC_DXT1) { option=GetImageOption(image_info,"dds:weight-by-alpha"); if (IsStringTrue(option) != MagickFalse) weightByAlpha=MagickTrue; } } } mipmaps=0; fromlist=MagickFalse; option=GetImageOption(image_info,"dds:mipmaps"); if (option != (char *) NULL) { if (LocaleNCompare(option,"fromlist",8) == 0) { Image *next; fromlist=MagickTrue; next=image->next; while(next != (Image *) NULL) { mipmaps++; next=next->next; } } } if ((mipmaps == 0) && ((image->columns & (image->columns - 1)) == 0) && ((image->rows & (image->rows - 1)) == 0)) { maxMipmaps=SIZE_MAX; if (option != (char *) NULL) maxMipmaps=StringToUnsignedLong(option); if (maxMipmaps != 0) { columns=image->columns; rows=image->rows; while ((columns != 1 || rows != 1) && mipmaps != maxMipmaps) { columns=DIV2(columns); rows=DIV2(rows); mipmaps++; } } } option=GetImageOption(image_info,"dds:raw"); if (IsStringTrue(option) == MagickFalse) WriteDDSInfo(image,pixelFormat,compression,mipmaps); else mipmaps=0; WriteImageData(image,pixelFormat,compression,clusterFit,weightByAlpha, exception); if ((mipmaps > 0) && (WriteMipmaps(image,image_info,pixelFormat,compression, mipmaps,fromlist,clusterFit,weightByAlpha,exception) == MagickFalse)) return(MagickFalse); (void) CloseBlob(image); return(MagickTrue); }

crop_and_resize.c

#include <TH/TH.h> #include <THC/THC.h> #include <stdio.h> #include <math.h> // symbol to be automatically resolved by PyTorch libs extern THCState *state; void CropAndResizePerBox( const float * image_data, const int batch_size, const int depth, const int image_height, const int image_width, const float * boxes_data, const int * box_index_data, const int start_box, const int limit_box, float * corps_data, const int crop_height, const int crop_width, const float extrapolation_value ) { const int image_channel_elements = image_height * image_width; const int image_elements = depth * image_channel_elements; const int channel_elements = crop_height * crop_width; const int crop_elements = depth * channel_elements; int b; #pragma omp parallel for for (b = start_box; b < limit_box; ++b) { const float * box = boxes_data + b * 4; const float y1 = box[0]; const float x1 = box[1]; const float y2 = box[2]; const float x2 = box[3]; const int b_in = box_index_data[b]; if (b_in < 0 || b_in >= batch_size) { printf("Error: batch_index %d out of range [0, %d)\n", b_in, batch_size); exit(-1); } const float height_scale = (crop_height > 1) ? (y2 - y1) * (image_height - 1) / (crop_height - 1) : 0; const float width_scale = (crop_width > 1) ? (x2 - x1) * (image_width - 1) / (crop_width - 1) : 0; for (int y = 0; y < crop_height; ++y) { const float in_y = (crop_height > 1) ? y1 * (image_height - 1) + y * height_scale : 0.5 * (y1 + y2) * (image_height - 1); if (in_y < 0 || in_y > image_height - 1) { for (int x = 0; x < crop_width; ++x) { for (int d = 0; d < depth; ++d) { // crops(b, y, x, d) = extrapolation_value; corps_data[crop_elements * b + channel_elements * d + y * crop_width + x] = extrapolation_value; } } continue; } const int top_y_index = floorf(in_y); const int bottom_y_index = ceilf(in_y); const float y_lerp = in_y - top_y_index; for (int x = 0; x < crop_width; ++x) { const float in_x = (crop_width > 1) ? x1 * (image_width - 1) + x * width_scale : 0.5 * (x1 + x2) * (image_width - 1); if (in_x < 0 || in_x > image_width - 1) { for (int d = 0; d < depth; ++d) { corps_data[crop_elements * b + channel_elements * d + y * crop_width + x] = extrapolation_value; } continue; } const int left_x_index = floorf(in_x); const int right_x_index = ceilf(in_x); const float x_lerp = in_x - left_x_index; for (int d = 0; d < depth; ++d) { const float *pimage = image_data + b_in * image_elements + d * image_channel_elements; const float top_left = pimage[top_y_index * image_width + left_x_index]; const float top_right = pimage[top_y_index * image_width + right_x_index]; const float bottom_left = pimage[bottom_y_index * image_width + left_x_index]; const float bottom_right = pimage[bottom_y_index * image_width + right_x_index]; const float top = top_left + (top_right - top_left) * x_lerp; const float bottom = bottom_left + (bottom_right - bottom_left) * x_lerp; corps_data[crop_elements * b + channel_elements * d + y * crop_width + x] = top + (bottom - top) * y_lerp; } } // end for x } // end for y } // end for b } void crop_and_resize_forward( THFloatTensor * image, THFloatTensor * boxes, // [y1, x1, y2, x2] THIntTensor * box_index, // range in [0, batch_size) const float extrapolation_value, const int crop_height, const int crop_width, THFloatTensor * crops ) { //const int batch_size = image->size[0]; //const int depth = image->size[1]; //const int image_height = image->size[2]; //const int image_width = image->size[3]; //const int num_boxes = boxes->size[0]; const int batch_size = THCudaTensor_size(state, image, 0); const int depth = THCudaTensor_size(state, image, 1); const int image_height = THCudaTensor_size(state, image, 2); const int image_width = THCudaTensor_size(state, image, 3); const int num_boxes = THCudaTensor_size(state, boxes, 0); // init output space THFloatTensor_resize4d(crops, num_boxes, depth, crop_height, crop_width); THFloatTensor_zero(crops); // crop_and_resize for each box CropAndResizePerBox( THFloatTensor_data(image), batch_size, depth, image_height, image_width, THFloatTensor_data(boxes), THIntTensor_data(box_index), 0, num_boxes, THFloatTensor_data(crops), crop_height, crop_width, extrapolation_value ); } void crop_and_resize_backward( THFloatTensor * grads, THFloatTensor * boxes, // [y1, x1, y2, x2] THIntTensor * box_index, // range in [0, batch_size) THFloatTensor * grads_image // resize to [bsize, c, hc, wc] ) { // shape //const int batch_size = grads_image->size[0]; //const int depth = grads_image->size[1]; //const int image_height = grads_image->size[2]; //const int image_width = grads_image->size[3]; //const int num_boxes = grads->size[0]; //const int crop_height = grads->size[2]; //const int crop_width = grads->size[3]; const int batch_size = THCudaTensor_size(state, grads_image, 0); const int depth = THCudaTensor_size(state, grads_image, 1); const int image_height = THCudaTensor_size(state, grads_image, 2); const int image_width = THCudaTensor_size(state, grads_image, 3); const int num_boxes = THCudaTensor_size(state, grads, 0); const int crop_height = THCudaTensor_size(state, grads,2); const int crop_width = THCudaTensor_size(state,grads,3); // n_elements const int image_channel_elements = image_height * image_width; const int image_elements = depth * image_channel_elements; const int channel_elements = crop_height * crop_width; const int crop_elements = depth * channel_elements; // init output space THFloatTensor_zero(grads_image); // data pointer const float * grads_data = THFloatTensor_data(grads); const float * boxes_data = THFloatTensor_data(boxes); const int * box_index_data = THIntTensor_data(box_index); float * grads_image_data = THFloatTensor_data(grads_image); for (int b = 0; b < num_boxes; ++b) { const float * box = boxes_data + b * 4; const float y1 = box[0]; const float x1 = box[1]; const float y2 = box[2]; const float x2 = box[3]; const int b_in = box_index_data[b]; if (b_in < 0 || b_in >= batch_size) { printf("Error: batch_index %d out of range [0, %d)\n", b_in, batch_size); exit(-1); } const float height_scale = (crop_height > 1) ? (y2 - y1) * (image_height - 1) / (crop_height - 1) : 0; const float width_scale = (crop_width > 1) ? (x2 - x1) * (image_width - 1) / (crop_width - 1) : 0; for (int y = 0; y < crop_height; ++y) { const float in_y = (crop_height > 1) ? y1 * (image_height - 1) + y * height_scale : 0.5 * (y1 + y2) * (image_height - 1); if (in_y < 0 || in_y > image_height - 1) { continue; } const int top_y_index = floorf(in_y); const int bottom_y_index = ceilf(in_y); const float y_lerp = in_y - top_y_index; for (int x = 0; x < crop_width; ++x) { const float in_x = (crop_width > 1) ? x1 * (image_width - 1) + x * width_scale : 0.5 * (x1 + x2) * (image_width - 1); if (in_x < 0 || in_x > image_width - 1) { continue; } const int left_x_index = floorf(in_x); const int right_x_index = ceilf(in_x); const float x_lerp = in_x - left_x_index; for (int d = 0; d < depth; ++d) { float *pimage = grads_image_data + b_in * image_elements + d * image_channel_elements; const float grad_val = grads_data[crop_elements * b + channel_elements * d + y * crop_width + x]; const float dtop = (1 - y_lerp) * grad_val; pimage[top_y_index * image_width + left_x_index] += (1 - x_lerp) * dtop; pimage[top_y_index * image_width + right_x_index] += x_lerp * dtop; const float dbottom = y_lerp * grad_val; pimage[bottom_y_index * image_width + left_x_index] += (1 - x_lerp) * dbottom; pimage[bottom_y_index * image_width + right_x_index] += x_lerp * dbottom; } // end d } // end x } // end y } // end b }

symm_x_dia_n_hi_col.c

#include "alphasparse/kernel.h" #include "alphasparse/util.h" #include "alphasparse/opt.h" #ifdef _OPENMP #include <omp.h> #endif alphasparse_status_t ONAME(const ALPHA_Number alpha, const ALPHA_SPMAT_DIA *mat, const ALPHA_Number *x, const ALPHA_INT columns, const ALPHA_INT ldx, const ALPHA_Number beta, ALPHA_Number *y, const ALPHA_INT ldy) { ALPHA_INT num_threads = alpha_get_thread_num(); #ifdef _OPENMP #pragma omp parallel for num_threads(num_threads) #endif for (ALPHA_INT cc = 0; cc < columns; ++cc) { ALPHA_Number* Y = &y[index2(cc,0,ldy)]; for (ALPHA_INT i = 0; i < mat->rows; i++) alpha_mul(Y[i],Y[i],beta); const ALPHA_Number* X = &x[index2(cc,0,ldx)]; for(ALPHA_INT di = 0; di < mat->ndiag;++di){ ALPHA_INT d = mat->distance[di]; if(d > 0){ ALPHA_INT ars = alpha_max(0,-d); ALPHA_INT acs = alpha_max(0,d); ALPHA_INT an = alpha_min(mat->rows - ars,mat->cols - acs); for(ALPHA_INT i = 0; i < an; ++i){ ALPHA_INT ar = ars + i; ALPHA_INT ac = acs + i; ALPHA_Number val; alpha_mul(val,mat->values[index2(di,ar,mat->lval)],alpha); alpha_madde(Y[ar],val,X[ac]); alpha_madde(Y[ac],val,X[ar]); } } if(d == 0){ for(ALPHA_INT r = 0; r < mat->rows; ++r){ ALPHA_Number val; alpha_mul(val,mat->values[index2(di,r,mat->lval)],alpha); alpha_madde(Y[r],val,X[r]); } } } } return ALPHA_SPARSE_STATUS_SUCCESS; }

par_vector.c

/****************************************************************************** * Copyright (c) 1998 Lawrence Livermore National Security, LLC and other * HYPRE Project Developers. See the top-level COPYRIGHT file for details. * * SPDX-License-Identifier: (Apache-2.0 OR MIT) ******************************************************************************/ /****************************************************************************** * * Member functions for hypre_Vector class. * *****************************************************************************/ #include "_hypre_parcsr_mv.h" HYPRE_Int hypre_FillResponseParToVectorAll(void*, HYPRE_Int, HYPRE_Int, void*, MPI_Comm, void**, HYPRE_Int*); /*-------------------------------------------------------------------------- * hypre_ParVectorCreate *--------------------------------------------------------------------------*/ /* If create is called and partitioning is NOT null, then it is assumed that it is array of length 2 containing the start row of the calling processor followed by the start row of the next processor - AHB 6/05 */ hypre_ParVector * hypre_ParVectorCreate( MPI_Comm comm, HYPRE_BigInt global_size, HYPRE_BigInt *partitioning_in ) { hypre_ParVector *vector; HYPRE_Int num_procs, my_id, local_size; HYPRE_BigInt partitioning[2]; if (global_size < 0) { hypre_error_in_arg(2); return NULL; } vector = hypre_CTAlloc(hypre_ParVector, 1, HYPRE_MEMORY_HOST); hypre_MPI_Comm_rank(comm, &my_id); if (!partitioning_in) { hypre_MPI_Comm_size(comm, &num_procs); hypre_GenerateLocalPartitioning(global_size, num_procs, my_id, partitioning); } else { partitioning[0] = partitioning_in[0]; partitioning[1] = partitioning_in[1]; } local_size = (HYPRE_Int) (partitioning[1] - partitioning[0]); hypre_ParVectorAssumedPartition(vector) = NULL; hypre_ParVectorComm(vector) = comm; hypre_ParVectorGlobalSize(vector) = global_size; hypre_ParVectorPartitioning(vector)[0] = partitioning[0]; hypre_ParVectorPartitioning(vector)[1] = partitioning[1]; hypre_ParVectorFirstIndex(vector) = hypre_ParVectorPartitioning(vector)[0]; hypre_ParVectorLastIndex(vector) = hypre_ParVectorPartitioning(vector)[1] - 1; hypre_ParVectorLocalVector(vector) = hypre_SeqVectorCreate(local_size); /* set defaults */ hypre_ParVectorOwnsData(vector) = 1; hypre_ParVectorActualLocalSize(vector) = 0; return vector; } /*-------------------------------------------------------------------------- * hypre_ParMultiVectorCreate *--------------------------------------------------------------------------*/ hypre_ParVector * hypre_ParMultiVectorCreate( MPI_Comm comm, HYPRE_BigInt global_size, HYPRE_BigInt *partitioning, HYPRE_Int num_vectors ) { /* note that global_size is the global length of a single vector */ hypre_ParVector *vector = hypre_ParVectorCreate( comm, global_size, partitioning ); hypre_ParVectorNumVectors(vector) = num_vectors; return vector; } /*-------------------------------------------------------------------------- * hypre_ParVectorDestroy *--------------------------------------------------------------------------*/ HYPRE_Int hypre_ParVectorDestroy( hypre_ParVector *vector ) { if (vector) { if ( hypre_ParVectorOwnsData(vector) ) { hypre_SeqVectorDestroy(hypre_ParVectorLocalVector(vector)); } if (hypre_ParVectorAssumedPartition(vector)) { hypre_AssumedPartitionDestroy(hypre_ParVectorAssumedPartition(vector)); } hypre_TFree(vector, HYPRE_MEMORY_HOST); } return hypre_error_flag; } /*-------------------------------------------------------------------------- * hypre_ParVectorInitialize *--------------------------------------------------------------------------*/ HYPRE_Int hypre_ParVectorInitialize_v2( hypre_ParVector *vector, HYPRE_MemoryLocation memory_location ) { if (!vector) { hypre_error_in_arg(1); return hypre_error_flag; } hypre_SeqVectorInitialize_v2(hypre_ParVectorLocalVector(vector), memory_location); hypre_ParVectorActualLocalSize(vector) = hypre_VectorSize(hypre_ParVectorLocalVector(vector)); return hypre_error_flag; } HYPRE_Int hypre_ParVectorInitialize( hypre_ParVector *vector ) { return hypre_ParVectorInitialize_v2(vector, hypre_ParVectorMemoryLocation(vector)); } /*-------------------------------------------------------------------------- * hypre_ParVectorSetDataOwner *--------------------------------------------------------------------------*/ HYPRE_Int hypre_ParVectorSetDataOwner( hypre_ParVector *vector, HYPRE_Int owns_data ) { if (!vector) { hypre_error_in_arg(1); return hypre_error_flag; } hypre_ParVectorOwnsData(vector) = owns_data; return hypre_error_flag; } /*-------------------------------------------------------------------------- * hypre_ParVectorSetNumVectors * call before calling hypre_ParVectorInitialize * probably this will do more harm than good, use hypre_ParMultiVectorCreate *--------------------------------------------------------------------------*/ #if 0 HYPRE_Int hypre_ParVectorSetNumVectors( hypre_ParVector *vector, HYPRE_Int num_vectors ) { HYPRE_Int ierr = 0; hypre_Vector *local_vector = hypre_ParVectorLocalVector(v); hypre_SeqVectorSetNumVectors( local_vector, num_vectors ); return ierr; } #endif /*-------------------------------------------------------------------------- * hypre_ParVectorRead *--------------------------------------------------------------------------*/ hypre_ParVector* hypre_ParVectorRead( MPI_Comm comm, const char *file_name ) { char new_file_name[80]; hypre_ParVector *par_vector; HYPRE_Int my_id; HYPRE_BigInt partitioning[2]; HYPRE_BigInt global_size; FILE *fp; hypre_MPI_Comm_rank(comm, &my_id); hypre_sprintf(new_file_name, "%s.INFO.%d", file_name, my_id); fp = fopen(new_file_name, "r"); hypre_fscanf(fp, "%b\n", &global_size); hypre_fscanf(fp, "%b\n", &partitioning[0]); hypre_fscanf(fp, "%b\n", &partitioning[1]); fclose (fp); par_vector = hypre_CTAlloc(hypre_ParVector, 1, HYPRE_MEMORY_HOST); hypre_ParVectorComm(par_vector) = comm; hypre_ParVectorGlobalSize(par_vector) = global_size; hypre_ParVectorFirstIndex(par_vector) = partitioning[0]; hypre_ParVectorLastIndex(par_vector) = partitioning[1] - 1; hypre_ParVectorPartitioning(par_vector)[0] = partitioning[0]; hypre_ParVectorPartitioning(par_vector)[1] = partitioning[1]; hypre_ParVectorOwnsData(par_vector) = 1; hypre_sprintf(new_file_name, "%s.%d", file_name, my_id); hypre_ParVectorLocalVector(par_vector) = hypre_SeqVectorRead(new_file_name); /* multivector code not written yet */ hypre_assert( hypre_ParVectorNumVectors(par_vector) == 1 ); return par_vector; } /*-------------------------------------------------------------------------- * hypre_ParVectorPrint *--------------------------------------------------------------------------*/ HYPRE_Int hypre_ParVectorPrint( hypre_ParVector *vector, const char *file_name ) { char new_file_name[80]; hypre_Vector *local_vector; MPI_Comm comm; HYPRE_Int my_id; HYPRE_BigInt *partitioning; HYPRE_BigInt global_size; FILE *fp; if (!vector) { hypre_error_in_arg(1); return hypre_error_flag; } local_vector = hypre_ParVectorLocalVector(vector); comm = hypre_ParVectorComm(vector); partitioning = hypre_ParVectorPartitioning(vector); global_size = hypre_ParVectorGlobalSize(vector); hypre_MPI_Comm_rank(comm, &my_id); hypre_sprintf(new_file_name, "%s.%d", file_name, my_id); hypre_SeqVectorPrint(local_vector, new_file_name); hypre_sprintf(new_file_name, "%s.INFO.%d", file_name, my_id); fp = fopen(new_file_name, "w"); hypre_fprintf(fp, "%b\n", global_size); hypre_fprintf(fp, "%b\n", partitioning[0]); hypre_fprintf(fp, "%b\n", partitioning[1]); fclose(fp); return hypre_error_flag; } /*-------------------------------------------------------------------------- * hypre_ParVectorSetConstantValues *--------------------------------------------------------------------------*/ HYPRE_Int hypre_ParVectorSetConstantValues( hypre_ParVector *v, HYPRE_Complex value ) { hypre_Vector *v_local = hypre_ParVectorLocalVector(v); return hypre_SeqVectorSetConstantValues(v_local, value); } /*-------------------------------------------------------------------------- * hypre_ParVectorSetRandomValues *--------------------------------------------------------------------------*/ HYPRE_Int hypre_ParVectorSetRandomValues( hypre_ParVector *v, HYPRE_Int seed ) { HYPRE_Int my_id; hypre_Vector *v_local = hypre_ParVectorLocalVector(v); MPI_Comm comm = hypre_ParVectorComm(v); hypre_MPI_Comm_rank(comm, &my_id); seed *= (my_id + 1); return hypre_SeqVectorSetRandomValues(v_local, seed); } /*-------------------------------------------------------------------------- * hypre_ParVectorCopy *--------------------------------------------------------------------------*/ HYPRE_Int hypre_ParVectorCopy( hypre_ParVector *x, hypre_ParVector *y ) { hypre_Vector *x_local = hypre_ParVectorLocalVector(x); hypre_Vector *y_local = hypre_ParVectorLocalVector(y); return hypre_SeqVectorCopy(x_local, y_local); } /*-------------------------------------------------------------------------- * hypre_ParVectorCloneShallow * returns a complete copy of a hypre_ParVector x - a shallow copy, re-using * the partitioning and data arrays of x *--------------------------------------------------------------------------*/ hypre_ParVector * hypre_ParVectorCloneShallow( hypre_ParVector *x ) { hypre_ParVector * y = hypre_ParVectorCreate(hypre_ParVectorComm(x), hypre_ParVectorGlobalSize(x), hypre_ParVectorPartitioning(x)); hypre_ParVectorOwnsData(y) = 1; /* ...This vector owns its local vector, although the local vector doesn't * own _its_ data */ hypre_SeqVectorDestroy( hypre_ParVectorLocalVector(y) ); hypre_ParVectorLocalVector(y) = hypre_SeqVectorCloneShallow(hypre_ParVectorLocalVector(x) ); hypre_ParVectorFirstIndex(y) = hypre_ParVectorFirstIndex(x); return y; } hypre_ParVector * hypre_ParVectorCloneDeep_v2( hypre_ParVector *x, HYPRE_MemoryLocation memory_location ) { hypre_ParVector *y = hypre_ParVectorCreate(hypre_ParVectorComm(x), hypre_ParVectorGlobalSize(x), hypre_ParVectorPartitioning(x)); hypre_ParVectorOwnsData(y) = 1; hypre_SeqVectorDestroy( hypre_ParVectorLocalVector(y) ); hypre_ParVectorLocalVector(y) = hypre_SeqVectorCloneDeep_v2( hypre_ParVectorLocalVector(x), memory_location ); hypre_ParVectorFirstIndex(y) = hypre_ParVectorFirstIndex(x); //RL: WHY HERE? return y; } HYPRE_Int hypre_ParVectorMigrate(hypre_ParVector *x, HYPRE_MemoryLocation memory_location) { if (!x) { return hypre_error_flag; } if ( hypre_GetActualMemLocation(memory_location) != hypre_GetActualMemLocation(hypre_ParVectorMemoryLocation(x)) ) { hypre_Vector *x_local = hypre_SeqVectorCloneDeep_v2(hypre_ParVectorLocalVector(x), memory_location); hypre_SeqVectorDestroy(hypre_ParVectorLocalVector(x)); hypre_ParVectorLocalVector(x) = x_local; } else { hypre_VectorMemoryLocation(hypre_ParVectorLocalVector(x)) = memory_location; } return hypre_error_flag; } /*-------------------------------------------------------------------------- * hypre_ParVectorScale *--------------------------------------------------------------------------*/ HYPRE_Int hypre_ParVectorScale( HYPRE_Complex alpha, hypre_ParVector *y ) { hypre_Vector *y_local = hypre_ParVectorLocalVector(y); return hypre_SeqVectorScale( alpha, y_local); } /*-------------------------------------------------------------------------- * hypre_ParVectorAxpy *--------------------------------------------------------------------------*/ HYPRE_Int hypre_ParVectorAxpy( HYPRE_Complex alpha, hypre_ParVector *x, hypre_ParVector *y ) { hypre_Vector *x_local = hypre_ParVectorLocalVector(x); hypre_Vector *y_local = hypre_ParVectorLocalVector(y); return hypre_SeqVectorAxpy( alpha, x_local, y_local); } /*-------------------------------------------------------------------------- * hypre_ParVectorInnerProd *--------------------------------------------------------------------------*/ HYPRE_Real hypre_ParVectorInnerProd( hypre_ParVector *x, hypre_ParVector *y ) { MPI_Comm comm = hypre_ParVectorComm(x); hypre_Vector *x_local = hypre_ParVectorLocalVector(x); hypre_Vector *y_local = hypre_ParVectorLocalVector(y); HYPRE_Real result = 0.0; HYPRE_Real local_result = hypre_SeqVectorInnerProd(x_local, y_local); #ifdef HYPRE_PROFILE hypre_profile_times[HYPRE_TIMER_ID_ALL_REDUCE] -= hypre_MPI_Wtime(); #endif hypre_MPI_Allreduce(&local_result, &result, 1, HYPRE_MPI_REAL, hypre_MPI_SUM, comm); #ifdef HYPRE_PROFILE hypre_profile_times[HYPRE_TIMER_ID_ALL_REDUCE] += hypre_MPI_Wtime(); #endif return result; } /*-------------------------------------------------------------------------- * hypre_ParVectorElmdivpy * y = y + x ./ b [MATLAB Notation] *--------------------------------------------------------------------------*/ HYPRE_Int hypre_ParVectorElmdivpy( hypre_ParVector *x, hypre_ParVector *b, hypre_ParVector *y ) { hypre_Vector *x_local = hypre_ParVectorLocalVector(x); hypre_Vector *b_local = hypre_ParVectorLocalVector(b); hypre_Vector *y_local = hypre_ParVectorLocalVector(y); return hypre_SeqVectorElmdivpy(x_local, b_local, y_local); } /*-------------------------------------------------------------------------- * hypre_ParVectorElmdivpyMarked * y[i] += x[i] / b[i] where marker[i] == marker_val *--------------------------------------------------------------------------*/ HYPRE_Int hypre_ParVectorElmdivpyMarked( hypre_ParVector *x, hypre_ParVector *b, hypre_ParVector *y, HYPRE_Int *marker, HYPRE_Int marker_val ) { hypre_Vector *x_local = hypre_ParVectorLocalVector(x); hypre_Vector *b_local = hypre_ParVectorLocalVector(b); hypre_Vector *y_local = hypre_ParVectorLocalVector(y); return hypre_SeqVectorElmdivpyMarked(x_local, b_local, y_local, marker, marker_val); } /*-------------------------------------------------------------------------- * hypre_VectorToParVector: * generates a ParVector from a Vector on proc 0 and distributes the pieces * to the other procs in comm *--------------------------------------------------------------------------*/ hypre_ParVector * hypre_VectorToParVector ( MPI_Comm comm, hypre_Vector *v, HYPRE_BigInt *vec_starts ) { HYPRE_BigInt global_size; HYPRE_BigInt *global_vec_starts = NULL; HYPRE_BigInt first_index; HYPRE_BigInt last_index; HYPRE_Int local_size; HYPRE_Int num_vectors; HYPRE_Int num_procs, my_id; HYPRE_Int global_vecstride, vecstride, idxstride; hypre_ParVector *par_vector; hypre_Vector *local_vector; HYPRE_Complex *v_data; HYPRE_Complex *local_data; hypre_MPI_Request *requests; hypre_MPI_Status *status, status0; HYPRE_Int i, j, k, p; hypre_MPI_Comm_size(comm, &num_procs); hypre_MPI_Comm_rank(comm, &my_id); if (my_id == 0) { global_size = (HYPRE_BigInt)hypre_VectorSize(v); v_data = hypre_VectorData(v); num_vectors = hypre_VectorNumVectors(v); /* for multivectors */ global_vecstride = hypre_VectorVectorStride(v); } hypre_MPI_Bcast(&global_size, 1, HYPRE_MPI_INT, 0, comm); hypre_MPI_Bcast(&num_vectors, 1, HYPRE_MPI_INT, 0, comm); hypre_MPI_Bcast(&global_vecstride, 1, HYPRE_MPI_INT, 0, comm); if (num_vectors == 1) { par_vector = hypre_ParVectorCreate(comm, global_size, vec_starts); } else { par_vector = hypre_ParMultiVectorCreate(comm, global_size, vec_starts, num_vectors); } vec_starts = hypre_ParVectorPartitioning(par_vector); first_index = hypre_ParVectorFirstIndex(par_vector); last_index = hypre_ParVectorLastIndex(par_vector); local_size = (HYPRE_Int)(last_index - first_index) + 1; if (my_id == 0) { global_vec_starts = hypre_CTAlloc(HYPRE_BigInt, num_procs + 1, HYPRE_MEMORY_HOST); } hypre_MPI_Gather(&first_index, 1, HYPRE_MPI_BIG_INT, global_vec_starts, 1, HYPRE_MPI_BIG_INT, 0, comm); if (my_id == 0) { global_vec_starts[num_procs] = hypre_ParVectorGlobalSize(par_vector); } hypre_ParVectorInitialize(par_vector); local_vector = hypre_ParVectorLocalVector(par_vector); local_data = hypre_VectorData(local_vector); vecstride = hypre_VectorVectorStride(local_vector); idxstride = hypre_VectorIndexStride(local_vector); /* so far the only implemented multivector StorageMethod is 0 */ hypre_assert( idxstride == 1 ); if (my_id == 0) { requests = hypre_CTAlloc(hypre_MPI_Request, num_vectors * (num_procs - 1), HYPRE_MEMORY_HOST); status = hypre_CTAlloc(hypre_MPI_Status, num_vectors * (num_procs - 1), HYPRE_MEMORY_HOST); k = 0; for (p = 1; p < num_procs; p++) for (j = 0; j < num_vectors; ++j) { hypre_MPI_Isend( &v_data[(HYPRE_Int) global_vec_starts[p]] + j * global_vecstride, (HYPRE_Int)(global_vec_starts[p + 1] - global_vec_starts[p]), HYPRE_MPI_COMPLEX, p, 0, comm, &requests[k++] ); } if (num_vectors == 1) { for (i = 0; i < local_size; i++) { local_data[i] = v_data[i]; } } else { for (j = 0; j < num_vectors; ++j) { for (i = 0; i < local_size; i++) { local_data[i + j * vecstride] = v_data[i + j * global_vecstride]; } } } hypre_MPI_Waitall(num_procs - 1, requests, status); hypre_TFree(requests, HYPRE_MEMORY_HOST); hypre_TFree(status, HYPRE_MEMORY_HOST); } else { for ( j = 0; j < num_vectors; ++j ) hypre_MPI_Recv( local_data + j * vecstride, local_size, HYPRE_MPI_COMPLEX, 0, 0, comm, &status0 ); } if (global_vec_starts) { hypre_TFree(global_vec_starts, HYPRE_MEMORY_HOST); } return par_vector; } /*-------------------------------------------------------------------------- * hypre_ParVectorToVectorAll: * generates a Vector on every proc which has a piece of the data * from a ParVector on several procs in comm, * vec_starts needs to contain the partitioning across all procs in comm *--------------------------------------------------------------------------*/ hypre_Vector * hypre_ParVectorToVectorAll( hypre_ParVector *par_v ) { MPI_Comm comm = hypre_ParVectorComm(par_v); HYPRE_BigInt global_size = hypre_ParVectorGlobalSize(par_v); hypre_Vector *local_vector = hypre_ParVectorLocalVector(par_v); HYPRE_Int num_procs, my_id; HYPRE_Int num_vectors = hypre_ParVectorNumVectors(par_v); hypre_Vector *vector; HYPRE_Complex *vector_data; HYPRE_Complex *local_data; HYPRE_Int local_size; hypre_MPI_Request *requests; hypre_MPI_Status *status; HYPRE_Int i, j; HYPRE_Int *used_procs; HYPRE_Int num_types, num_requests; HYPRE_Int vec_len, proc_id; HYPRE_Int *new_vec_starts; HYPRE_Int num_contacts; HYPRE_Int contact_proc_list[1]; HYPRE_Int contact_send_buf[1]; HYPRE_Int contact_send_buf_starts[2]; HYPRE_Int max_response_size; HYPRE_Int *response_recv_buf = NULL; HYPRE_Int *response_recv_buf_starts = NULL; hypre_DataExchangeResponse response_obj; hypre_ProcListElements send_proc_obj; HYPRE_Int *send_info = NULL; hypre_MPI_Status status1; HYPRE_Int count, tag1 = 112, tag2 = 223; HYPRE_Int start; hypre_MPI_Comm_size(comm, &num_procs); hypre_MPI_Comm_rank(comm, &my_id); local_size = (HYPRE_Int)(hypre_ParVectorLastIndex(par_v) - hypre_ParVectorFirstIndex(par_v) + 1); /* determine procs which hold data of par_v and store ids in used_procs */ /* we need to do an exchange data for this. If I own row then I will contact processor 0 with the endpoint of my local range */ if (local_size > 0) { num_contacts = 1; contact_proc_list[0] = 0; contact_send_buf[0] = hypre_ParVectorLastIndex(par_v); contact_send_buf_starts[0] = 0; contact_send_buf_starts[1] = 1; } else { num_contacts = 0; contact_send_buf_starts[0] = 0; contact_send_buf_starts[1] = 0; } /*build the response object*/ /*send_proc_obj will be for saving info from contacts */ send_proc_obj.length = 0; send_proc_obj.storage_length = 10; send_proc_obj.id = hypre_CTAlloc(HYPRE_Int, send_proc_obj.storage_length, HYPRE_MEMORY_HOST); send_proc_obj.vec_starts = hypre_CTAlloc(HYPRE_Int, send_proc_obj.storage_length + 1, HYPRE_MEMORY_HOST); send_proc_obj.vec_starts[0] = 0; send_proc_obj.element_storage_length = 10; send_proc_obj.elements = hypre_CTAlloc(HYPRE_BigInt, send_proc_obj.element_storage_length, HYPRE_MEMORY_HOST); max_response_size = 0; /* each response is null */ response_obj.fill_response = hypre_FillResponseParToVectorAll; response_obj.data1 = NULL; response_obj.data2 = &send_proc_obj; /*this is where we keep info from contacts*/ hypre_DataExchangeList(num_contacts, contact_proc_list, contact_send_buf, contact_send_buf_starts, sizeof(HYPRE_Int), //0, &response_obj, sizeof(HYPRE_Int), &response_obj, max_response_size, 1, comm, (void**) &response_recv_buf, &response_recv_buf_starts); /* now processor 0 should have a list of ranges for processors that have rows - these are in send_proc_obj - it needs to create the new list of processors and also an array of vec starts - and send to those who own row*/ if (my_id) { if (local_size) { /* look for a message from processor 0 */ hypre_MPI_Probe(0, tag1, comm, &status1); hypre_MPI_Get_count(&status1, HYPRE_MPI_INT, &count); send_info = hypre_CTAlloc(HYPRE_Int, count, HYPRE_MEMORY_HOST); hypre_MPI_Recv(send_info, count, HYPRE_MPI_INT, 0, tag1, comm, &status1); /* now unpack */ num_types = send_info[0]; used_procs = hypre_CTAlloc(HYPRE_Int, num_types, HYPRE_MEMORY_HOST); new_vec_starts = hypre_CTAlloc(HYPRE_Int, num_types + 1, HYPRE_MEMORY_HOST); for (i = 1; i <= num_types; i++) { used_procs[i - 1] = (HYPRE_Int)send_info[i]; } for (i = num_types + 1; i < count; i++) { new_vec_starts[i - num_types - 1] = send_info[i] ; } } else /* clean up and exit */ { hypre_TFree(send_proc_obj.vec_starts, HYPRE_MEMORY_HOST); hypre_TFree(send_proc_obj.id, HYPRE_MEMORY_HOST); hypre_TFree(send_proc_obj.elements, HYPRE_MEMORY_HOST); if (response_recv_buf) { hypre_TFree(response_recv_buf, HYPRE_MEMORY_HOST); } if (response_recv_buf_starts) { hypre_TFree(response_recv_buf_starts, HYPRE_MEMORY_HOST); } return NULL; } } else /* my_id ==0 */ { num_types = send_proc_obj.length; used_procs = hypre_CTAlloc(HYPRE_Int, num_types, HYPRE_MEMORY_HOST); new_vec_starts = hypre_CTAlloc(HYPRE_Int, num_types + 1, HYPRE_MEMORY_HOST); new_vec_starts[0] = 0; for (i = 0; i < num_types; i++) { used_procs[i] = send_proc_obj.id[i]; new_vec_starts[i + 1] = send_proc_obj.elements[i] + 1; } hypre_qsort0(used_procs, 0, num_types - 1); hypre_qsort0(new_vec_starts, 0, num_types); /*now we need to put into an array to send */ count = 2 * num_types + 2; send_info = hypre_CTAlloc(HYPRE_Int, count, HYPRE_MEMORY_HOST); send_info[0] = num_types; for (i = 1; i <= num_types; i++) { send_info[i] = (HYPRE_Int)used_procs[i - 1]; } for (i = num_types + 1; i < count; i++) { send_info[i] = new_vec_starts[i - num_types - 1]; } requests = hypre_CTAlloc(hypre_MPI_Request, num_types, HYPRE_MEMORY_HOST); status = hypre_CTAlloc(hypre_MPI_Status, num_types, HYPRE_MEMORY_HOST); /* don't send to myself - these are sorted so my id would be first*/ start = 0; if (used_procs[0] == 0) { start = 1; } for (i = start; i < num_types; i++) { hypre_MPI_Isend(send_info, count, HYPRE_MPI_INT, used_procs[i], tag1, comm, &requests[i - start]); } hypre_MPI_Waitall(num_types - start, requests, status); hypre_TFree(status, HYPRE_MEMORY_HOST); hypre_TFree(requests, HYPRE_MEMORY_HOST); } /* clean up */ hypre_TFree(send_proc_obj.vec_starts, HYPRE_MEMORY_HOST); hypre_TFree(send_proc_obj.id, HYPRE_MEMORY_HOST); hypre_TFree(send_proc_obj.elements, HYPRE_MEMORY_HOST); hypre_TFree(send_info, HYPRE_MEMORY_HOST); if (response_recv_buf) { hypre_TFree(response_recv_buf, HYPRE_MEMORY_HOST); } if (response_recv_buf_starts) { hypre_TFree(response_recv_buf_starts, HYPRE_MEMORY_HOST); } /* now proc 0 can exit if it has no rows */ if (!local_size) { hypre_TFree(used_procs, HYPRE_MEMORY_HOST); hypre_TFree(new_vec_starts, HYPRE_MEMORY_HOST); return NULL; } /* everyone left has rows and knows: new_vec_starts, num_types, and used_procs */ /* this vector should be rather small */ local_data = hypre_VectorData(local_vector); vector = hypre_SeqVectorCreate((HYPRE_Int)global_size); hypre_VectorNumVectors(vector) = num_vectors; hypre_SeqVectorInitialize(vector); vector_data = hypre_VectorData(vector); num_requests = 2 * num_types; requests = hypre_CTAlloc(hypre_MPI_Request, num_requests, HYPRE_MEMORY_HOST); status = hypre_CTAlloc(hypre_MPI_Status, num_requests, HYPRE_MEMORY_HOST); /* initialize data exchange among used_procs and generate vector - here we send to ourself also*/ j = 0; for (i = 0; i < num_types; i++) { proc_id = used_procs[i]; vec_len = (HYPRE_Int)(new_vec_starts[i + 1] - new_vec_starts[i]); hypre_MPI_Irecv(&vector_data[(HYPRE_Int)new_vec_starts[i]], num_vectors * vec_len, HYPRE_MPI_COMPLEX, proc_id, tag2, comm, &requests[j++]); } for (i = 0; i < num_types; i++) { hypre_MPI_Isend(local_data, num_vectors * local_size, HYPRE_MPI_COMPLEX, used_procs[i], tag2, comm, &requests[j++]); } hypre_MPI_Waitall(num_requests, requests, status); if (num_requests) { hypre_TFree(requests, HYPRE_MEMORY_HOST); hypre_TFree(status, HYPRE_MEMORY_HOST); hypre_TFree(used_procs, HYPRE_MEMORY_HOST); } hypre_TFree(new_vec_starts, HYPRE_MEMORY_HOST); return vector; } /*-------------------------------------------------------------------------- * hypre_ParVectorPrintIJ *--------------------------------------------------------------------------*/ HYPRE_Int hypre_ParVectorPrintIJ( hypre_ParVector *vector, HYPRE_Int base_j, const char *filename ) { MPI_Comm comm; HYPRE_BigInt global_size, j; HYPRE_BigInt *partitioning; HYPRE_Complex *local_data; HYPRE_Int myid, num_procs, i, part0; char new_filename[255]; FILE *file; if (!vector) { hypre_error_in_arg(1); return hypre_error_flag; } comm = hypre_ParVectorComm(vector); global_size = hypre_ParVectorGlobalSize(vector); partitioning = hypre_ParVectorPartitioning(vector); /* multivector code not written yet */ hypre_assert( hypre_ParVectorNumVectors(vector) == 1 ); if ( hypre_ParVectorNumVectors(vector) != 1 ) { hypre_error_in_arg(1); } hypre_MPI_Comm_rank(comm, &myid); hypre_MPI_Comm_size(comm, &num_procs); hypre_sprintf(new_filename, "%s.%05d", filename, myid); if ((file = fopen(new_filename, "w")) == NULL) { hypre_error_w_msg(HYPRE_ERROR_GENERIC, "Error: can't open output file %s\n"); return hypre_error_flag; } local_data = hypre_VectorData(hypre_ParVectorLocalVector(vector)); hypre_fprintf(file, "%b \n", global_size); for (i = 0; i < 2; i++) { hypre_fprintf(file, "%b ", partitioning[i] + base_j); } hypre_fprintf(file, "\n"); part0 = partitioning[0]; for (j = part0; j < partitioning[1]; j++) { hypre_fprintf(file, "%b %.14e\n", j + base_j, local_data[(HYPRE_Int)(j - part0)]); } fclose(file); return hypre_error_flag; } /*-------------------------------------------------------------------------- * hypre_ParVectorReadIJ * Warning: wrong base for assumed partition if base > 0 *--------------------------------------------------------------------------*/ HYPRE_Int hypre_ParVectorReadIJ( MPI_Comm comm, const char *filename, HYPRE_Int *base_j_ptr, hypre_ParVector **vector_ptr ) { HYPRE_BigInt global_size, J; hypre_ParVector *vector; hypre_Vector *local_vector; HYPRE_Complex *local_data; HYPRE_BigInt partitioning[2]; HYPRE_Int base_j; HYPRE_Int myid, num_procs, i, j; char new_filename[255]; FILE *file; hypre_MPI_Comm_size(comm, &num_procs); hypre_MPI_Comm_rank(comm, &myid); hypre_sprintf(new_filename, "%s.%05d", filename, myid); if ((file = fopen(new_filename, "r")) == NULL) { hypre_error_w_msg(HYPRE_ERROR_GENERIC, "Error: can't open output file %s\n"); return hypre_error_flag; } hypre_fscanf(file, "%b", &global_size); /* this may need to be changed so that the base is available in the file! */ hypre_fscanf(file, "%b", partitioning); for (i = 0; i < 2; i++) { hypre_fscanf(file, "%b", partitioning + i); } /* This is not yet implemented correctly! */ base_j = 0; vector = hypre_ParVectorCreate(comm, global_size, partitioning); hypre_ParVectorInitialize(vector); local_vector = hypre_ParVectorLocalVector(vector); local_data = hypre_VectorData(local_vector); for (j = 0; j < (HYPRE_Int)(partitioning[1] - partitioning[0]); j++) { hypre_fscanf(file, "%b %le", &J, local_data + j); } fclose(file); *base_j_ptr = base_j; *vector_ptr = vector; /* multivector code not written yet */ hypre_assert( hypre_ParVectorNumVectors(vector) == 1 ); if ( hypre_ParVectorNumVectors(vector) != 1 ) { hypre_error(HYPRE_ERROR_GENERIC); } return hypre_error_flag; } /*-------------------------------------------------------------------- * hypre_FillResponseParToVectorAll * Fill response function for determining the send processors * data exchange *--------------------------------------------------------------------*/ HYPRE_Int hypre_FillResponseParToVectorAll( void *p_recv_contact_buf, HYPRE_Int contact_size, HYPRE_Int contact_proc, void *ro, MPI_Comm comm, void **p_send_response_buf, HYPRE_Int *response_message_size ) { HYPRE_Int myid; HYPRE_Int i, index, count, elength; HYPRE_BigInt *recv_contact_buf = (HYPRE_BigInt * ) p_recv_contact_buf; hypre_DataExchangeResponse *response_obj = (hypre_DataExchangeResponse*)ro; hypre_ProcListElements *send_proc_obj = (hypre_ProcListElements*)response_obj->data2; hypre_MPI_Comm_rank(comm, &myid ); /*check to see if we need to allocate more space in send_proc_obj for ids*/ if (send_proc_obj->length == send_proc_obj->storage_length) { send_proc_obj->storage_length += 10; /*add space for 10 more processors*/ send_proc_obj->id = hypre_TReAlloc(send_proc_obj->id, HYPRE_Int, send_proc_obj->storage_length, HYPRE_MEMORY_HOST); send_proc_obj->vec_starts = hypre_TReAlloc(send_proc_obj->vec_starts, HYPRE_Int, send_proc_obj->storage_length + 1, HYPRE_MEMORY_HOST); } /*initialize*/ count = send_proc_obj->length; index = send_proc_obj->vec_starts[count]; /*this is the number of elements*/ /*send proc*/ send_proc_obj->id[count] = contact_proc; /*do we need more storage for the elements?*/ if (send_proc_obj->element_storage_length < index + contact_size) { elength = hypre_max(contact_size, 10); elength += index; send_proc_obj->elements = hypre_TReAlloc(send_proc_obj->elements, HYPRE_BigInt, elength, HYPRE_MEMORY_HOST); send_proc_obj->element_storage_length = elength; } /*populate send_proc_obj*/ for (i = 0; i < contact_size; i++) { send_proc_obj->elements[index++] = recv_contact_buf[i]; } send_proc_obj->vec_starts[count + 1] = index; send_proc_obj->length++; /*output - no message to return (confirmation) */ *response_message_size = 0; return hypre_error_flag; } /* ----------------------------------------------------------------------------- * return the sum of all local elements of the vector * ----------------------------------------------------------------------------- */ HYPRE_Complex hypre_ParVectorLocalSumElts( hypre_ParVector * vector ) { return hypre_SeqVectorSumElts( hypre_ParVectorLocalVector(vector) ); } HYPRE_Int hypre_ParVectorGetValuesHost(hypre_ParVector *vector, HYPRE_Int num_values, HYPRE_BigInt *indices, HYPRE_BigInt base, HYPRE_Complex *values) { HYPRE_Int i, ierr = 0; HYPRE_BigInt first_index = hypre_ParVectorFirstIndex(vector); HYPRE_BigInt last_index = hypre_ParVectorLastIndex(vector); hypre_Vector *local_vector = hypre_ParVectorLocalVector(vector); HYPRE_Complex *data = hypre_VectorData(local_vector); /* if (hypre_VectorOwnsData(local_vector) == 0) { hypre_error_w_msg(HYPRE_ERROR_GENERIC,"Vector does not own data! -- hypre_ParVectorGetValues."); return hypre_error_flag; } */ if (indices) { #ifdef HYPRE_USING_OPENMP #pragma omp parallel for private(i) reduction(+:ierr) HYPRE_SMP_SCHEDULE #endif for (i = 0; i < num_values; i++) { HYPRE_BigInt index = indices[i] - base; if (index < first_index || index > last_index) { ierr ++; } else { HYPRE_Int local_index = (HYPRE_Int) (index - first_index); values[i] = data[local_index]; } } if (ierr) { hypre_error_in_arg(3); hypre_error_w_msg(HYPRE_ERROR_GENERIC, "Index out of range! -- hypre_ParVectorGetValues."); hypre_printf("Index out of range! -- hypre_ParVectorGetValues\n"); } } else { if (num_values > hypre_VectorSize(local_vector)) { hypre_error_in_arg(2); return hypre_error_flag; } #ifdef HYPRE_USING_OPENMP #pragma omp parallel for private(i) HYPRE_SMP_SCHEDULE #endif for (i = 0; i < num_values; i++) { values[i] = data[i]; } } return hypre_error_flag; } HYPRE_Int hypre_ParVectorGetValues2(hypre_ParVector *vector, HYPRE_Int num_values, HYPRE_BigInt *indices, HYPRE_BigInt base, HYPRE_Complex *values) { #if defined(HYPRE_USING_CUDA) || defined(HYPRE_USING_HIP) if (HYPRE_EXEC_DEVICE == hypre_GetExecPolicy1( hypre_ParVectorMemoryLocation(vector) )) { hypre_ParVectorGetValuesDevice(vector, num_values, indices, base, values); } else #endif { hypre_ParVectorGetValuesHost(vector, num_values, indices, base, values); } return hypre_error_flag; } HYPRE_Int hypre_ParVectorGetValues(hypre_ParVector *vector, HYPRE_Int num_values, HYPRE_BigInt *indices, HYPRE_Complex *values) { return hypre_ParVectorGetValues2(vector, num_values, indices, 0, values); }

feature.c

/* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % FFFFF EEEEE AAA TTTTT U U RRRR EEEEE % % F E A A T U U R R E % % FFF EEE AAAAA T U U RRRR EEE % % F E A A T U U R R E % % F EEEEE A A T UUU R R EEEEE % % % % % % MagickCore Image Feature Methods % % % % Software Design % % Cristy % % July 1992 % % % % % % Copyright 1999-2020 ImageMagick Studio LLC, a non-profit organization % % dedicated to making software imaging solutions freely available. % % % % You may not use this file except in compliance with the License. You may % % obtain a copy of the License at % % % % https://imagemagick.org/script/license.php % % % % Unless required by applicable law or agreed to in writing, software % % distributed under the License is distributed on an "AS IS" BASIS, % % WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. % % See the License for the specific language governing permissions and % % limitations under the License. % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % */ /* Include declarations. */ #include "MagickCore/studio.h" #include "MagickCore/animate.h" #include "MagickCore/artifact.h" #include "MagickCore/blob.h" #include "MagickCore/blob-private.h" #include "MagickCore/cache.h" #include "MagickCore/cache-private.h" #include "MagickCore/cache-view.h" #include "MagickCore/channel.h" #include "MagickCore/client.h" #include "MagickCore/color.h" #include "MagickCore/color-private.h" #include "MagickCore/colorspace.h" #include "MagickCore/colorspace-private.h" #include "MagickCore/composite.h" #include "MagickCore/composite-private.h" #include "MagickCore/compress.h" #include "MagickCore/constitute.h" #include "MagickCore/display.h" #include "MagickCore/draw.h" #include "MagickCore/enhance.h" #include "MagickCore/exception.h" #include "MagickCore/exception-private.h" #include "MagickCore/feature.h" #include "MagickCore/gem.h" #include "MagickCore/geometry.h" #include "MagickCore/list.h" #include "MagickCore/image-private.h" #include "MagickCore/magic.h" #include "MagickCore/magick.h" #include "MagickCore/matrix.h" #include "MagickCore/memory_.h" #include "MagickCore/module.h" #include "MagickCore/monitor.h" #include "MagickCore/monitor-private.h" #include "MagickCore/morphology-private.h" #include "MagickCore/option.h" #include "MagickCore/paint.h" #include "MagickCore/pixel-accessor.h" #include "MagickCore/profile.h" #include "MagickCore/property.h" #include "MagickCore/quantize.h" #include "MagickCore/quantum-private.h" #include "MagickCore/random_.h" #include "MagickCore/resource_.h" #include "MagickCore/segment.h" #include "MagickCore/semaphore.h" #include "MagickCore/signature-private.h" #include "MagickCore/string_.h" #include "MagickCore/thread-private.h" #include "MagickCore/timer.h" #include "MagickCore/utility.h" #include "MagickCore/version.h" /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % C a n n y E d g e I m a g e % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % CannyEdgeImage() uses a multi-stage algorithm to detect a wide range of % edges in images. % % The format of the CannyEdgeImage method is: % % Image *CannyEdgeImage(const Image *image,const double radius, % const double sigma,const double lower_percent, % const double upper_percent,ExceptionInfo *exception) % % A description of each parameter follows: % % o image: the image. % % o radius: the radius of the gaussian smoothing filter. % % o sigma: the sigma of the gaussian smoothing filter. % % o lower_percent: percentage of edge pixels in the lower threshold. % % o upper_percent: percentage of edge pixels in the upper threshold. % % o exception: return any errors or warnings in this structure. % */ typedef struct _CannyInfo { double magnitude, intensity; int orientation; ssize_t x, y; } CannyInfo; static inline MagickBooleanType IsAuthenticPixel(const Image *image, const ssize_t x,const ssize_t y) { if ((x < 0) || (x >= (ssize_t) image->columns)) return(MagickFalse); if ((y < 0) || (y >= (ssize_t) image->rows)) return(MagickFalse); return(MagickTrue); } static MagickBooleanType TraceEdges(Image *edge_image,CacheView *edge_view, MatrixInfo *canny_cache,const ssize_t x,const ssize_t y, const double lower_threshold,ExceptionInfo *exception) { CannyInfo edge, pixel; MagickBooleanType status; register Quantum *q; register ssize_t i; q=GetCacheViewAuthenticPixels(edge_view,x,y,1,1,exception); if (q == (Quantum *) NULL) return(MagickFalse); *q=QuantumRange; status=SyncCacheViewAuthenticPixels(edge_view,exception); if (status == MagickFalse) return(MagickFalse); if (GetMatrixElement(canny_cache,0,0,&edge) == MagickFalse) return(MagickFalse); edge.x=x; edge.y=y; if (SetMatrixElement(canny_cache,0,0,&edge) == MagickFalse) return(MagickFalse); for (i=1; i != 0; ) { ssize_t v; i--; status=GetMatrixElement(canny_cache,i,0,&edge); if (status == MagickFalse) return(MagickFalse); for (v=(-1); v <= 1; v++) { ssize_t u; for (u=(-1); u <= 1; u++) { if ((u == 0) && (v == 0)) continue; if (IsAuthenticPixel(edge_image,edge.x+u,edge.y+v) == MagickFalse) continue; /* Not an edge if gradient value is below the lower threshold. */ q=GetCacheViewAuthenticPixels(edge_view,edge.x+u,edge.y+v,1,1, exception); if (q == (Quantum *) NULL) return(MagickFalse); status=GetMatrixElement(canny_cache,edge.x+u,edge.y+v,&pixel); if (status == MagickFalse) return(MagickFalse); if ((GetPixelIntensity(edge_image,q) == 0.0) && (pixel.intensity >= lower_threshold)) { *q=QuantumRange; status=SyncCacheViewAuthenticPixels(edge_view,exception); if (status == MagickFalse) return(MagickFalse); edge.x+=u; edge.y+=v; status=SetMatrixElement(canny_cache,i,0,&edge); if (status == MagickFalse) return(MagickFalse); i++; } } } } return(MagickTrue); } MagickExport Image *CannyEdgeImage(const Image *image,const double radius, const double sigma,const double lower_percent,const double upper_percent, ExceptionInfo *exception) { #define CannyEdgeImageTag "CannyEdge/Image" CacheView *edge_view; CannyInfo element; char geometry[MagickPathExtent]; double lower_threshold, max, min, upper_threshold; Image *edge_image; KernelInfo *kernel_info; MagickBooleanType status; MagickOffsetType progress; MatrixInfo *canny_cache; ssize_t y; assert(image != (const Image *) NULL); assert(image->signature == MagickCoreSignature); if (image->debug != MagickFalse) (void) LogMagickEvent(TraceEvent,GetMagickModule(),"%s",image->filename); assert(exception != (ExceptionInfo *) NULL); assert(exception->signature == MagickCoreSignature); /* Filter out noise. */ (void) FormatLocaleString(geometry,MagickPathExtent, "blur:%.20gx%.20g;blur:%.20gx%.20g+90",radius,sigma,radius,sigma); kernel_info=AcquireKernelInfo(geometry,exception); if (kernel_info == (KernelInfo *) NULL) ThrowImageException(ResourceLimitError,"MemoryAllocationFailed"); edge_image=MorphologyImage(image,ConvolveMorphology,1,kernel_info,exception); kernel_info=DestroyKernelInfo(kernel_info); if (edge_image == (Image *) NULL) return((Image *) NULL); if (TransformImageColorspace(edge_image,GRAYColorspace,exception) == MagickFalse) { edge_image=DestroyImage(edge_image); return((Image *) NULL); } (void) SetImageAlphaChannel(edge_image,OffAlphaChannel,exception); /* Find the intensity gradient of the image. */ canny_cache=AcquireMatrixInfo(edge_image->columns,edge_image->rows, sizeof(CannyInfo),exception); if (canny_cache == (MatrixInfo *) NULL) { edge_image=DestroyImage(edge_image); return((Image *) NULL); } status=MagickTrue; edge_view=AcquireVirtualCacheView(edge_image,exception); #if defined(MAGICKCORE_OPENMP_SUPPORT) #pragma omp parallel for schedule(static) shared(status) \ magick_number_threads(edge_image,edge_image,edge_image->rows,1) #endif for (y=0; y < (ssize_t) edge_image->rows; y++) { register const Quantum *magick_restrict p; register ssize_t x; if (status == MagickFalse) continue; p=GetCacheViewVirtualPixels(edge_view,0,y,edge_image->columns+1,2, exception); if (p == (const Quantum *) NULL) { status=MagickFalse; continue; } for (x=0; x < (ssize_t) edge_image->columns; x++) { CannyInfo pixel; double dx, dy; register const Quantum *magick_restrict kernel_pixels; ssize_t v; static double Gx[2][2] = { { -1.0, +1.0 }, { -1.0, +1.0 } }, Gy[2][2] = { { +1.0, +1.0 }, { -1.0, -1.0 } }; (void) memset(&pixel,0,sizeof(pixel)); dx=0.0; dy=0.0; kernel_pixels=p; for (v=0; v < 2; v++) { ssize_t u; for (u=0; u < 2; u++) { double intensity; intensity=GetPixelIntensity(edge_image,kernel_pixels+u); dx+=0.5*Gx[v][u]*intensity; dy+=0.5*Gy[v][u]*intensity; } kernel_pixels+=edge_image->columns+1; } pixel.magnitude=hypot(dx,dy); pixel.orientation=0; if (fabs(dx) > MagickEpsilon) { double slope; slope=dy/dx; if (slope < 0.0) { if (slope < -2.41421356237) pixel.orientation=0; else if (slope < -0.414213562373) pixel.orientation=1; else pixel.orientation=2; } else { if (slope > 2.41421356237) pixel.orientation=0; else if (slope > 0.414213562373) pixel.orientation=3; else pixel.orientation=2; } } if (SetMatrixElement(canny_cache,x,y,&pixel) == MagickFalse) continue; p+=GetPixelChannels(edge_image); } } edge_view=DestroyCacheView(edge_view); /* Non-maxima suppression, remove pixels that are not considered to be part of an edge. */ progress=0; (void) GetMatrixElement(canny_cache,0,0,&element); max=element.intensity; min=element.intensity; edge_view=AcquireAuthenticCacheView(edge_image,exception); #if defined(MAGICKCORE_OPENMP_SUPPORT) #pragma omp parallel for schedule(static) shared(status) \ magick_number_threads(edge_image,edge_image,edge_image->rows,1) #endif for (y=0; y < (ssize_t) edge_image->rows; y++) { register Quantum *magick_restrict q; register ssize_t x; if (status == MagickFalse) continue; q=GetCacheViewAuthenticPixels(edge_view,0,y,edge_image->columns,1, exception); if (q == (Quantum *) NULL) { status=MagickFalse; continue; } for (x=0; x < (ssize_t) edge_image->columns; x++) { CannyInfo alpha_pixel, beta_pixel, pixel; (void) GetMatrixElement(canny_cache,x,y,&pixel); switch (pixel.orientation) { case 0: default: { /* 0 degrees, north and south. */ (void) GetMatrixElement(canny_cache,x,y-1,&alpha_pixel); (void) GetMatrixElement(canny_cache,x,y+1,&beta_pixel); break; } case 1: { /* 45 degrees, northwest and southeast. */ (void) GetMatrixElement(canny_cache,x-1,y-1,&alpha_pixel); (void) GetMatrixElement(canny_cache,x+1,y+1,&beta_pixel); break; } case 2: { /* 90 degrees, east and west. */ (void) GetMatrixElement(canny_cache,x-1,y,&alpha_pixel); (void) GetMatrixElement(canny_cache,x+1,y,&beta_pixel); break; } case 3: { /* 135 degrees, northeast and southwest. */ (void) GetMatrixElement(canny_cache,x+1,y-1,&beta_pixel); (void) GetMatrixElement(canny_cache,x-1,y+1,&alpha_pixel); break; } } pixel.intensity=pixel.magnitude; if ((pixel.magnitude < alpha_pixel.magnitude) || (pixel.magnitude < beta_pixel.magnitude)) pixel.intensity=0; (void) SetMatrixElement(canny_cache,x,y,&pixel); #if defined(MAGICKCORE_OPENMP_SUPPORT) #pragma omp critical (MagickCore_CannyEdgeImage) #endif { if (pixel.intensity < min) min=pixel.intensity; if (pixel.intensity > max) max=pixel.intensity; } *q=0; q+=GetPixelChannels(edge_image); } if (SyncCacheViewAuthenticPixels(edge_view,exception) == MagickFalse) status=MagickFalse; } edge_view=DestroyCacheView(edge_view); /* Estimate hysteresis threshold. */ lower_threshold=lower_percent*(max-min)+min; upper_threshold=upper_percent*(max-min)+min; /* Hysteresis threshold. */ edge_view=AcquireAuthenticCacheView(edge_image,exception); for (y=0; y < (ssize_t) edge_image->rows; y++) { register ssize_t x; if (status == MagickFalse) continue; for (x=0; x < (ssize_t) edge_image->columns; x++) { CannyInfo pixel; register const Quantum *magick_restrict p; /* Edge if pixel gradient higher than upper threshold. */ p=GetCacheViewVirtualPixels(edge_view,x,y,1,1,exception); if (p == (const Quantum *) NULL) continue; status=GetMatrixElement(canny_cache,x,y,&pixel); if (status == MagickFalse) continue; if ((GetPixelIntensity(edge_image,p) == 0.0) && (pixel.intensity >= upper_threshold)) status=TraceEdges(edge_image,edge_view,canny_cache,x,y,lower_threshold, exception); } if (image->progress_monitor != (MagickProgressMonitor) NULL) { MagickBooleanType proceed; #if defined(MAGICKCORE_OPENMP_SUPPORT) #pragma omp atomic #endif progress++; proceed=SetImageProgress(image,CannyEdgeImageTag,progress,image->rows); if (proceed == MagickFalse) status=MagickFalse; } } edge_view=DestroyCacheView(edge_view); /* Free resources. */ canny_cache=DestroyMatrixInfo(canny_cache); return(edge_image); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % G e t I m a g e F e a t u r e s % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % GetImageFeatures() returns features for each channel in the image in % each of four directions (horizontal, vertical, left and right diagonals) % for the specified distance. The features include the angular second % moment, contrast, correlation, sum of squares: variance, inverse difference % moment, sum average, sum varience, sum entropy, entropy, difference variance, % difference entropy, information measures of correlation 1, information % measures of correlation 2, and maximum correlation coefficient. You can % access the red channel contrast, for example, like this: % % channel_features=GetImageFeatures(image,1,exception); % contrast=channel_features[RedPixelChannel].contrast[0]; % % Use MagickRelinquishMemory() to free the features buffer. % % The format of the GetImageFeatures method is: % % ChannelFeatures *GetImageFeatures(const Image *image, % const size_t distance,ExceptionInfo *exception) % % A description of each parameter follows: % % o image: the image. % % o distance: the distance. % % o exception: return any errors or warnings in this structure. % */ static inline double MagickLog10(const double x) { #define Log10Epsilon (1.0e-11) if (fabs(x) < Log10Epsilon) return(log10(Log10Epsilon)); return(log10(fabs(x))); } MagickExport ChannelFeatures *GetImageFeatures(const Image *image, const size_t distance,ExceptionInfo *exception) { typedef struct _ChannelStatistics { PixelInfo direction[4]; /* horizontal, vertical, left and right diagonals */ } ChannelStatistics; CacheView *image_view; ChannelFeatures *channel_features; ChannelStatistics **cooccurrence, correlation, *density_x, *density_xy, *density_y, entropy_x, entropy_xy, entropy_xy1, entropy_xy2, entropy_y, mean, **Q, *sum, sum_squares, variance; PixelPacket gray, *grays; MagickBooleanType status; register ssize_t i, r; size_t length; unsigned int number_grays; assert(image != (Image *) NULL); assert(image->signature == MagickCoreSignature); if (image->debug != MagickFalse) (void) LogMagickEvent(TraceEvent,GetMagickModule(),"%s",image->filename); if ((image->columns < (distance+1)) || (image->rows < (distance+1))) return((ChannelFeatures *) NULL); length=MaxPixelChannels+1UL; channel_features=(ChannelFeatures *) AcquireQuantumMemory(length, sizeof(*channel_features)); if (channel_features == (ChannelFeatures *) NULL) ThrowFatalException(ResourceLimitFatalError,"MemoryAllocationFailed"); (void) memset(channel_features,0,length* sizeof(*channel_features)); /* Form grays. */ grays=(PixelPacket *) AcquireQuantumMemory(MaxMap+1UL,sizeof(*grays)); if (grays == (PixelPacket *) NULL) { channel_features=(ChannelFeatures *) RelinquishMagickMemory( channel_features); (void) ThrowMagickException(exception,GetMagickModule(), ResourceLimitError,"MemoryAllocationFailed","`%s'",image->filename); return(channel_features); } for (i=0; i <= (ssize_t) MaxMap; i++) { grays[i].red=(~0U); grays[i].green=(~0U); grays[i].blue=(~0U); grays[i].alpha=(~0U); grays[i].black=(~0U); } status=MagickTrue; image_view=AcquireVirtualCacheView(image,exception); #if defined(MAGICKCORE_OPENMP_SUPPORT) #pragma omp parallel for schedule(static) shared(status) \ magick_number_threads(image,image,image->rows,1) #endif for (r=0; r < (ssize_t) image->rows; r++) { register const Quantum *magick_restrict p; register ssize_t x; if (status == MagickFalse) continue; p=GetCacheViewVirtualPixels(image_view,0,r,image->columns,1,exception); if (p == (const Quantum *) NULL) { status=MagickFalse; continue; } for (x=0; x < (ssize_t) image->columns; x++) { grays[ScaleQuantumToMap(GetPixelRed(image,p))].red= ScaleQuantumToMap(GetPixelRed(image,p)); grays[ScaleQuantumToMap(GetPixelGreen(image,p))].green= ScaleQuantumToMap(GetPixelGreen(image,p)); grays[ScaleQuantumToMap(GetPixelBlue(image,p))].blue= ScaleQuantumToMap(GetPixelBlue(image,p)); if (image->colorspace == CMYKColorspace) grays[ScaleQuantumToMap(GetPixelBlack(image,p))].black= ScaleQuantumToMap(GetPixelBlack(image,p)); if (image->alpha_trait != UndefinedPixelTrait) grays[ScaleQuantumToMap(GetPixelAlpha(image,p))].alpha= ScaleQuantumToMap(GetPixelAlpha(image,p)); p+=GetPixelChannels(image); } } image_view=DestroyCacheView(image_view); if (status == MagickFalse) { grays=(PixelPacket *) RelinquishMagickMemory(grays); channel_features=(ChannelFeatures *) RelinquishMagickMemory( channel_features); return(channel_features); } (void) memset(&gray,0,sizeof(gray)); for (i=0; i <= (ssize_t) MaxMap; i++) { if (grays[i].red != ~0U) grays[gray.red++].red=grays[i].red; if (grays[i].green != ~0U) grays[gray.green++].green=grays[i].green; if (grays[i].blue != ~0U) grays[gray.blue++].blue=grays[i].blue; if (image->colorspace == CMYKColorspace) if (grays[i].black != ~0U) grays[gray.black++].black=grays[i].black; if (image->alpha_trait != UndefinedPixelTrait) if (grays[i].alpha != ~0U) grays[gray.alpha++].alpha=grays[i].alpha; } /* Allocate spatial dependence matrix. */ number_grays=gray.red; if (gray.green > number_grays) number_grays=gray.green; if (gray.blue > number_grays) number_grays=gray.blue; if (image->colorspace == CMYKColorspace) if (gray.black > number_grays) number_grays=gray.black; if (image->alpha_trait != UndefinedPixelTrait) if (gray.alpha > number_grays) number_grays=gray.alpha; cooccurrence=(ChannelStatistics **) AcquireQuantumMemory(number_grays, sizeof(*cooccurrence)); density_x=(ChannelStatistics *) AcquireQuantumMemory(2*(number_grays+1), sizeof(*density_x)); density_xy=(ChannelStatistics *) AcquireQuantumMemory(2*(number_grays+1), sizeof(*density_xy)); density_y=(ChannelStatistics *) AcquireQuantumMemory(2*(number_grays+1), sizeof(*density_y)); Q=(ChannelStatistics **) AcquireQuantumMemory(number_grays,sizeof(*Q)); sum=(ChannelStatistics *) AcquireQuantumMemory(number_grays,sizeof(*sum)); if ((cooccurrence == (ChannelStatistics **) NULL) || (density_x == (ChannelStatistics *) NULL) || (density_xy == (ChannelStatistics *) NULL) || (density_y == (ChannelStatistics *) NULL) || (Q == (ChannelStatistics **) NULL) || (sum == (ChannelStatistics *) NULL)) { if (Q != (ChannelStatistics **) NULL) { for (i=0; i < (ssize_t) number_grays; i++) Q[i]=(ChannelStatistics *) RelinquishMagickMemory(Q[i]); Q=(ChannelStatistics **) RelinquishMagickMemory(Q); } if (sum != (ChannelStatistics *) NULL) sum=(ChannelStatistics *) RelinquishMagickMemory(sum); if (density_y != (ChannelStatistics *) NULL) density_y=(ChannelStatistics *) RelinquishMagickMemory(density_y); if (density_xy != (ChannelStatistics *) NULL) density_xy=(ChannelStatistics *) RelinquishMagickMemory(density_xy); if (density_x != (ChannelStatistics *) NULL) density_x=(ChannelStatistics *) RelinquishMagickMemory(density_x); if (cooccurrence != (ChannelStatistics **) NULL) { for (i=0; i < (ssize_t) number_grays; i++) cooccurrence[i]=(ChannelStatistics *) RelinquishMagickMemory(cooccurrence[i]); cooccurrence=(ChannelStatistics **) RelinquishMagickMemory( cooccurrence); } grays=(PixelPacket *) RelinquishMagickMemory(grays); channel_features=(ChannelFeatures *) RelinquishMagickMemory( channel_features); (void) ThrowMagickException(exception,GetMagickModule(), ResourceLimitError,"MemoryAllocationFailed","`%s'",image->filename); return(channel_features); } (void) memset(&correlation,0,sizeof(correlation)); (void) memset(density_x,0,2*(number_grays+1)*sizeof(*density_x)); (void) memset(density_xy,0,2*(number_grays+1)*sizeof(*density_xy)); (void) memset(density_y,0,2*(number_grays+1)*sizeof(*density_y)); (void) memset(&mean,0,sizeof(mean)); (void) memset(sum,0,number_grays*sizeof(*sum)); (void) memset(&sum_squares,0,sizeof(sum_squares)); (void) memset(density_xy,0,2*number_grays*sizeof(*density_xy)); (void) memset(&entropy_x,0,sizeof(entropy_x)); (void) memset(&entropy_xy,0,sizeof(entropy_xy)); (void) memset(&entropy_xy1,0,sizeof(entropy_xy1)); (void) memset(&entropy_xy2,0,sizeof(entropy_xy2)); (void) memset(&entropy_y,0,sizeof(entropy_y)); (void) memset(&variance,0,sizeof(variance)); for (i=0; i < (ssize_t) number_grays; i++) { cooccurrence[i]=(ChannelStatistics *) AcquireQuantumMemory(number_grays, sizeof(**cooccurrence)); Q[i]=(ChannelStatistics *) AcquireQuantumMemory(number_grays,sizeof(**Q)); if ((cooccurrence[i] == (ChannelStatistics *) NULL) || (Q[i] == (ChannelStatistics *) NULL)) break; (void) memset(cooccurrence[i],0,number_grays* sizeof(**cooccurrence)); (void) memset(Q[i],0,number_grays*sizeof(**Q)); } if (i < (ssize_t) number_grays) { for (i--; i >= 0; i--) { if (Q[i] != (ChannelStatistics *) NULL) Q[i]=(ChannelStatistics *) RelinquishMagickMemory(Q[i]); if (cooccurrence[i] != (ChannelStatistics *) NULL) cooccurrence[i]=(ChannelStatistics *) RelinquishMagickMemory(cooccurrence[i]); } Q=(ChannelStatistics **) RelinquishMagickMemory(Q); cooccurrence=(ChannelStatistics **) RelinquishMagickMemory(cooccurrence); sum=(ChannelStatistics *) RelinquishMagickMemory(sum); density_y=(ChannelStatistics *) RelinquishMagickMemory(density_y); density_xy=(ChannelStatistics *) RelinquishMagickMemory(density_xy); density_x=(ChannelStatistics *) RelinquishMagickMemory(density_x); grays=(PixelPacket *) RelinquishMagickMemory(grays); channel_features=(ChannelFeatures *) RelinquishMagickMemory( channel_features); (void) ThrowMagickException(exception,GetMagickModule(), ResourceLimitError,"MemoryAllocationFailed","`%s'",image->filename); return(channel_features); } /* Initialize spatial dependence matrix. */ status=MagickTrue; image_view=AcquireVirtualCacheView(image,exception); for (r=0; r < (ssize_t) image->rows; r++) { register const Quantum *magick_restrict p; register ssize_t x; ssize_t offset, u, v; if (status == MagickFalse) continue; p=GetCacheViewVirtualPixels(image_view,-(ssize_t) distance,r,image->columns+ 2*distance,distance+2,exception); if (p == (const Quantum *) NULL) { status=MagickFalse; continue; } p+=distance*GetPixelChannels(image);; for (x=0; x < (ssize_t) image->columns; x++) { for (i=0; i < 4; i++) { switch (i) { case 0: default: { /* Horizontal adjacency. */ offset=(ssize_t) distance; break; } case 1: { /* Vertical adjacency. */ offset=(ssize_t) (image->columns+2*distance); break; } case 2: { /* Right diagonal adjacency. */ offset=(ssize_t) ((image->columns+2*distance)-distance); break; } case 3: { /* Left diagonal adjacency. */ offset=(ssize_t) ((image->columns+2*distance)+distance); break; } } u=0; v=0; while (grays[u].red != ScaleQuantumToMap(GetPixelRed(image,p))) u++; while (grays[v].red != ScaleQuantumToMap(GetPixelRed(image,p+offset*GetPixelChannels(image)))) v++; cooccurrence[u][v].direction[i].red++; cooccurrence[v][u].direction[i].red++; u=0; v=0; while (grays[u].green != ScaleQuantumToMap(GetPixelGreen(image,p))) u++; while (grays[v].green != ScaleQuantumToMap(GetPixelGreen(image,p+offset*GetPixelChannels(image)))) v++; cooccurrence[u][v].direction[i].green++; cooccurrence[v][u].direction[i].green++; u=0; v=0; while (grays[u].blue != ScaleQuantumToMap(GetPixelBlue(image,p))) u++; while (grays[v].blue != ScaleQuantumToMap(GetPixelBlue(image,p+offset*GetPixelChannels(image)))) v++; cooccurrence[u][v].direction[i].blue++; cooccurrence[v][u].direction[i].blue++; if (image->colorspace == CMYKColorspace) { u=0; v=0; while (grays[u].black != ScaleQuantumToMap(GetPixelBlack(image,p))) u++; while (grays[v].black != ScaleQuantumToMap(GetPixelBlack(image,p+offset*GetPixelChannels(image)))) v++; cooccurrence[u][v].direction[i].black++; cooccurrence[v][u].direction[i].black++; } if (image->alpha_trait != UndefinedPixelTrait) { u=0; v=0; while (grays[u].alpha != ScaleQuantumToMap(GetPixelAlpha(image,p))) u++; while (grays[v].alpha != ScaleQuantumToMap(GetPixelAlpha(image,p+offset*GetPixelChannels(image)))) v++; cooccurrence[u][v].direction[i].alpha++; cooccurrence[v][u].direction[i].alpha++; } } p+=GetPixelChannels(image); } } grays=(PixelPacket *) RelinquishMagickMemory(grays); image_view=DestroyCacheView(image_view); if (status == MagickFalse) { for (i=0; i < (ssize_t) number_grays; i++) cooccurrence[i]=(ChannelStatistics *) RelinquishMagickMemory(cooccurrence[i]); cooccurrence=(ChannelStatistics **) RelinquishMagickMemory(cooccurrence); channel_features=(ChannelFeatures *) RelinquishMagickMemory( channel_features); (void) ThrowMagickException(exception,GetMagickModule(), ResourceLimitError,"MemoryAllocationFailed","`%s'",image->filename); return(channel_features); } /* Normalize spatial dependence matrix. */ for (i=0; i < 4; i++) { double normalize; register ssize_t y; switch (i) { case 0: default: { /* Horizontal adjacency. */ normalize=2.0*image->rows*(image->columns-distance); break; } case 1: { /* Vertical adjacency. */ normalize=2.0*(image->rows-distance)*image->columns; break; } case 2: { /* Right diagonal adjacency. */ normalize=2.0*(image->rows-distance)*(image->columns-distance); break; } case 3: { /* Left diagonal adjacency. */ normalize=2.0*(image->rows-distance)*(image->columns-distance); break; } } normalize=PerceptibleReciprocal(normalize); for (y=0; y < (ssize_t) number_grays; y++) { register ssize_t x; for (x=0; x < (ssize_t) number_grays; x++) { cooccurrence[x][y].direction[i].red*=normalize; cooccurrence[x][y].direction[i].green*=normalize; cooccurrence[x][y].direction[i].blue*=normalize; if (image->colorspace == CMYKColorspace) cooccurrence[x][y].direction[i].black*=normalize; if (image->alpha_trait != UndefinedPixelTrait) cooccurrence[x][y].direction[i].alpha*=normalize; } } } /* Compute texture features. */ #if defined(MAGICKCORE_OPENMP_SUPPORT) #pragma omp parallel for schedule(static) shared(status) \ magick_number_threads(image,image,number_grays,1) #endif for (i=0; i < 4; i++) { register ssize_t y; for (y=0; y < (ssize_t) number_grays; y++) { register ssize_t x; for (x=0; x < (ssize_t) number_grays; x++) { /* Angular second moment: measure of homogeneity of the image. */ channel_features[RedPixelChannel].angular_second_moment[i]+= cooccurrence[x][y].direction[i].red* cooccurrence[x][y].direction[i].red; channel_features[GreenPixelChannel].angular_second_moment[i]+= cooccurrence[x][y].direction[i].green* cooccurrence[x][y].direction[i].green; channel_features[BluePixelChannel].angular_second_moment[i]+= cooccurrence[x][y].direction[i].blue* cooccurrence[x][y].direction[i].blue; if (image->colorspace == CMYKColorspace) channel_features[BlackPixelChannel].angular_second_moment[i]+= cooccurrence[x][y].direction[i].black* cooccurrence[x][y].direction[i].black; if (image->alpha_trait != UndefinedPixelTrait) channel_features[AlphaPixelChannel].angular_second_moment[i]+= cooccurrence[x][y].direction[i].alpha* cooccurrence[x][y].direction[i].alpha; /* Correlation: measure of linear-dependencies in the image. */ sum[y].direction[i].red+=cooccurrence[x][y].direction[i].red; sum[y].direction[i].green+=cooccurrence[x][y].direction[i].green; sum[y].direction[i].blue+=cooccurrence[x][y].direction[i].blue; if (image->colorspace == CMYKColorspace) sum[y].direction[i].black+=cooccurrence[x][y].direction[i].black; if (image->alpha_trait != UndefinedPixelTrait) sum[y].direction[i].alpha+=cooccurrence[x][y].direction[i].alpha; correlation.direction[i].red+=x*y*cooccurrence[x][y].direction[i].red; correlation.direction[i].green+=x*y* cooccurrence[x][y].direction[i].green; correlation.direction[i].blue+=x*y* cooccurrence[x][y].direction[i].blue; if (image->colorspace == CMYKColorspace) correlation.direction[i].black+=x*y* cooccurrence[x][y].direction[i].black; if (image->alpha_trait != UndefinedPixelTrait) correlation.direction[i].alpha+=x*y* cooccurrence[x][y].direction[i].alpha; /* Inverse Difference Moment. */ channel_features[RedPixelChannel].inverse_difference_moment[i]+= cooccurrence[x][y].direction[i].red/((y-x)*(y-x)+1); channel_features[GreenPixelChannel].inverse_difference_moment[i]+= cooccurrence[x][y].direction[i].green/((y-x)*(y-x)+1); channel_features[BluePixelChannel].inverse_difference_moment[i]+= cooccurrence[x][y].direction[i].blue/((y-x)*(y-x)+1); if (image->colorspace == CMYKColorspace) channel_features[BlackPixelChannel].inverse_difference_moment[i]+= cooccurrence[x][y].direction[i].black/((y-x)*(y-x)+1); if (image->alpha_trait != UndefinedPixelTrait) channel_features[AlphaPixelChannel].inverse_difference_moment[i]+= cooccurrence[x][y].direction[i].alpha/((y-x)*(y-x)+1); /* Sum average. */ density_xy[y+x+2].direction[i].red+= cooccurrence[x][y].direction[i].red; density_xy[y+x+2].direction[i].green+= cooccurrence[x][y].direction[i].green; density_xy[y+x+2].direction[i].blue+= cooccurrence[x][y].direction[i].blue; if (image->colorspace == CMYKColorspace) density_xy[y+x+2].direction[i].black+= cooccurrence[x][y].direction[i].black; if (image->alpha_trait != UndefinedPixelTrait) density_xy[y+x+2].direction[i].alpha+= cooccurrence[x][y].direction[i].alpha; /* Entropy. */ channel_features[RedPixelChannel].entropy[i]-= cooccurrence[x][y].direction[i].red* MagickLog10(cooccurrence[x][y].direction[i].red); channel_features[GreenPixelChannel].entropy[i]-= cooccurrence[x][y].direction[i].green* MagickLog10(cooccurrence[x][y].direction[i].green); channel_features[BluePixelChannel].entropy[i]-= cooccurrence[x][y].direction[i].blue* MagickLog10(cooccurrence[x][y].direction[i].blue); if (image->colorspace == CMYKColorspace) channel_features[BlackPixelChannel].entropy[i]-= cooccurrence[x][y].direction[i].black* MagickLog10(cooccurrence[x][y].direction[i].black); if (image->alpha_trait != UndefinedPixelTrait) channel_features[AlphaPixelChannel].entropy[i]-= cooccurrence[x][y].direction[i].alpha* MagickLog10(cooccurrence[x][y].direction[i].alpha); /* Information Measures of Correlation. */ density_x[x].direction[i].red+=cooccurrence[x][y].direction[i].red; density_x[x].direction[i].green+=cooccurrence[x][y].direction[i].green; density_x[x].direction[i].blue+=cooccurrence[x][y].direction[i].blue; if (image->alpha_trait != UndefinedPixelTrait) density_x[x].direction[i].alpha+= cooccurrence[x][y].direction[i].alpha; if (image->colorspace == CMYKColorspace) density_x[x].direction[i].black+= cooccurrence[x][y].direction[i].black; density_y[y].direction[i].red+=cooccurrence[x][y].direction[i].red; density_y[y].direction[i].green+=cooccurrence[x][y].direction[i].green; density_y[y].direction[i].blue+=cooccurrence[x][y].direction[i].blue; if (image->colorspace == CMYKColorspace) density_y[y].direction[i].black+= cooccurrence[x][y].direction[i].black; if (image->alpha_trait != UndefinedPixelTrait) density_y[y].direction[i].alpha+= cooccurrence[x][y].direction[i].alpha; } mean.direction[i].red+=y*sum[y].direction[i].red; sum_squares.direction[i].red+=y*y*sum[y].direction[i].red; mean.direction[i].green+=y*sum[y].direction[i].green; sum_squares.direction[i].green+=y*y*sum[y].direction[i].green; mean.direction[i].blue+=y*sum[y].direction[i].blue; sum_squares.direction[i].blue+=y*y*sum[y].direction[i].blue; if (image->colorspace == CMYKColorspace) { mean.direction[i].black+=y*sum[y].direction[i].black; sum_squares.direction[i].black+=y*y*sum[y].direction[i].black; } if (image->alpha_trait != UndefinedPixelTrait) { mean.direction[i].alpha+=y*sum[y].direction[i].alpha; sum_squares.direction[i].alpha+=y*y*sum[y].direction[i].alpha; } } /* Correlation: measure of linear-dependencies in the image. */ channel_features[RedPixelChannel].correlation[i]= (correlation.direction[i].red-mean.direction[i].red* mean.direction[i].red)/(sqrt(sum_squares.direction[i].red- (mean.direction[i].red*mean.direction[i].red))*sqrt( sum_squares.direction[i].red-(mean.direction[i].red* mean.direction[i].red))); channel_features[GreenPixelChannel].correlation[i]= (correlation.direction[i].green-mean.direction[i].green* mean.direction[i].green)/(sqrt(sum_squares.direction[i].green- (mean.direction[i].green*mean.direction[i].green))*sqrt( sum_squares.direction[i].green-(mean.direction[i].green* mean.direction[i].green))); channel_features[BluePixelChannel].correlation[i]= (correlation.direction[i].blue-mean.direction[i].blue* mean.direction[i].blue)/(sqrt(sum_squares.direction[i].blue- (mean.direction[i].blue*mean.direction[i].blue))*sqrt( sum_squares.direction[i].blue-(mean.direction[i].blue* mean.direction[i].blue))); if (image->colorspace == CMYKColorspace) channel_features[BlackPixelChannel].correlation[i]= (correlation.direction[i].black-mean.direction[i].black* mean.direction[i].black)/(sqrt(sum_squares.direction[i].black- (mean.direction[i].black*mean.direction[i].black))*sqrt( sum_squares.direction[i].black-(mean.direction[i].black* mean.direction[i].black))); if (image->alpha_trait != UndefinedPixelTrait) channel_features[AlphaPixelChannel].correlation[i]= (correlation.direction[i].alpha-mean.direction[i].alpha* mean.direction[i].alpha)/(sqrt(sum_squares.direction[i].alpha- (mean.direction[i].alpha*mean.direction[i].alpha))*sqrt( sum_squares.direction[i].alpha-(mean.direction[i].alpha* mean.direction[i].alpha))); } /* Compute more texture features. */ #if defined(MAGICKCORE_OPENMP_SUPPORT) #pragma omp parallel for schedule(static) shared(status) \ magick_number_threads(image,image,number_grays,1) #endif for (i=0; i < 4; i++) { register ssize_t x; for (x=2; x < (ssize_t) (2*number_grays); x++) { /* Sum average. */ channel_features[RedPixelChannel].sum_average[i]+= x*density_xy[x].direction[i].red; channel_features[GreenPixelChannel].sum_average[i]+= x*density_xy[x].direction[i].green; channel_features[BluePixelChannel].sum_average[i]+= x*density_xy[x].direction[i].blue; if (image->colorspace == CMYKColorspace) channel_features[BlackPixelChannel].sum_average[i]+= x*density_xy[x].direction[i].black; if (image->alpha_trait != UndefinedPixelTrait) channel_features[AlphaPixelChannel].sum_average[i]+= x*density_xy[x].direction[i].alpha; /* Sum entropy. */ channel_features[RedPixelChannel].sum_entropy[i]-= density_xy[x].direction[i].red* MagickLog10(density_xy[x].direction[i].red); channel_features[GreenPixelChannel].sum_entropy[i]-= density_xy[x].direction[i].green* MagickLog10(density_xy[x].direction[i].green); channel_features[BluePixelChannel].sum_entropy[i]-= density_xy[x].direction[i].blue* MagickLog10(density_xy[x].direction[i].blue); if (image->colorspace == CMYKColorspace) channel_features[BlackPixelChannel].sum_entropy[i]-= density_xy[x].direction[i].black* MagickLog10(density_xy[x].direction[i].black); if (image->alpha_trait != UndefinedPixelTrait) channel_features[AlphaPixelChannel].sum_entropy[i]-= density_xy[x].direction[i].alpha* MagickLog10(density_xy[x].direction[i].alpha); /* Sum variance. */ channel_features[RedPixelChannel].sum_variance[i]+= (x-channel_features[RedPixelChannel].sum_entropy[i])* (x-channel_features[RedPixelChannel].sum_entropy[i])* density_xy[x].direction[i].red; channel_features[GreenPixelChannel].sum_variance[i]+= (x-channel_features[GreenPixelChannel].sum_entropy[i])* (x-channel_features[GreenPixelChannel].sum_entropy[i])* density_xy[x].direction[i].green; channel_features[BluePixelChannel].sum_variance[i]+= (x-channel_features[BluePixelChannel].sum_entropy[i])* (x-channel_features[BluePixelChannel].sum_entropy[i])* density_xy[x].direction[i].blue; if (image->colorspace == CMYKColorspace) channel_features[BlackPixelChannel].sum_variance[i]+= (x-channel_features[BlackPixelChannel].sum_entropy[i])* (x-channel_features[BlackPixelChannel].sum_entropy[i])* density_xy[x].direction[i].black; if (image->alpha_trait != UndefinedPixelTrait) channel_features[AlphaPixelChannel].sum_variance[i]+= (x-channel_features[AlphaPixelChannel].sum_entropy[i])* (x-channel_features[AlphaPixelChannel].sum_entropy[i])* density_xy[x].direction[i].alpha; } } /* Compute more texture features. */ #if defined(MAGICKCORE_OPENMP_SUPPORT) #pragma omp parallel for schedule(static) shared(status) \ magick_number_threads(image,image,number_grays,1) #endif for (i=0; i < 4; i++) { register ssize_t y; for (y=0; y < (ssize_t) number_grays; y++) { register ssize_t x; for (x=0; x < (ssize_t) number_grays; x++) { /* Sum of Squares: Variance */ variance.direction[i].red+=(y-mean.direction[i].red+1)* (y-mean.direction[i].red+1)*cooccurrence[x][y].direction[i].red; variance.direction[i].green+=(y-mean.direction[i].green+1)* (y-mean.direction[i].green+1)*cooccurrence[x][y].direction[i].green; variance.direction[i].blue+=(y-mean.direction[i].blue+1)* (y-mean.direction[i].blue+1)*cooccurrence[x][y].direction[i].blue; if (image->colorspace == CMYKColorspace) variance.direction[i].black+=(y-mean.direction[i].black+1)* (y-mean.direction[i].black+1)*cooccurrence[x][y].direction[i].black; if (image->alpha_trait != UndefinedPixelTrait) variance.direction[i].alpha+=(y-mean.direction[i].alpha+1)* (y-mean.direction[i].alpha+1)* cooccurrence[x][y].direction[i].alpha; /* Sum average / Difference Variance. */ density_xy[MagickAbsoluteValue(y-x)].direction[i].red+= cooccurrence[x][y].direction[i].red; density_xy[MagickAbsoluteValue(y-x)].direction[i].green+= cooccurrence[x][y].direction[i].green; density_xy[MagickAbsoluteValue(y-x)].direction[i].blue+= cooccurrence[x][y].direction[i].blue; if (image->colorspace == CMYKColorspace) density_xy[MagickAbsoluteValue(y-x)].direction[i].black+= cooccurrence[x][y].direction[i].black; if (image->alpha_trait != UndefinedPixelTrait) density_xy[MagickAbsoluteValue(y-x)].direction[i].alpha+= cooccurrence[x][y].direction[i].alpha; /* Information Measures of Correlation. */ entropy_xy.direction[i].red-=cooccurrence[x][y].direction[i].red* MagickLog10(cooccurrence[x][y].direction[i].red); entropy_xy.direction[i].green-=cooccurrence[x][y].direction[i].green* MagickLog10(cooccurrence[x][y].direction[i].green); entropy_xy.direction[i].blue-=cooccurrence[x][y].direction[i].blue* MagickLog10(cooccurrence[x][y].direction[i].blue); if (image->colorspace == CMYKColorspace) entropy_xy.direction[i].black-=cooccurrence[x][y].direction[i].black* MagickLog10(cooccurrence[x][y].direction[i].black); if (image->alpha_trait != UndefinedPixelTrait) entropy_xy.direction[i].alpha-= cooccurrence[x][y].direction[i].alpha*MagickLog10( cooccurrence[x][y].direction[i].alpha); entropy_xy1.direction[i].red-=(cooccurrence[x][y].direction[i].red* MagickLog10(density_x[x].direction[i].red*density_y[y].direction[i].red)); entropy_xy1.direction[i].green-=(cooccurrence[x][y].direction[i].green* MagickLog10(density_x[x].direction[i].green* density_y[y].direction[i].green)); entropy_xy1.direction[i].blue-=(cooccurrence[x][y].direction[i].blue* MagickLog10(density_x[x].direction[i].blue*density_y[y].direction[i].blue)); if (image->colorspace == CMYKColorspace) entropy_xy1.direction[i].black-=( cooccurrence[x][y].direction[i].black*MagickLog10( density_x[x].direction[i].black*density_y[y].direction[i].black)); if (image->alpha_trait != UndefinedPixelTrait) entropy_xy1.direction[i].alpha-=( cooccurrence[x][y].direction[i].alpha*MagickLog10( density_x[x].direction[i].alpha*density_y[y].direction[i].alpha)); entropy_xy2.direction[i].red-=(density_x[x].direction[i].red* density_y[y].direction[i].red*MagickLog10(density_x[x].direction[i].red* density_y[y].direction[i].red)); entropy_xy2.direction[i].green-=(density_x[x].direction[i].green* density_y[y].direction[i].green*MagickLog10(density_x[x].direction[i].green* density_y[y].direction[i].green)); entropy_xy2.direction[i].blue-=(density_x[x].direction[i].blue* density_y[y].direction[i].blue*MagickLog10(density_x[x].direction[i].blue* density_y[y].direction[i].blue)); if (image->colorspace == CMYKColorspace) entropy_xy2.direction[i].black-=(density_x[x].direction[i].black* density_y[y].direction[i].black*MagickLog10( density_x[x].direction[i].black*density_y[y].direction[i].black)); if (image->alpha_trait != UndefinedPixelTrait) entropy_xy2.direction[i].alpha-=(density_x[x].direction[i].alpha* density_y[y].direction[i].alpha*MagickLog10( density_x[x].direction[i].alpha*density_y[y].direction[i].alpha)); } } channel_features[RedPixelChannel].variance_sum_of_squares[i]= variance.direction[i].red; channel_features[GreenPixelChannel].variance_sum_of_squares[i]= variance.direction[i].green; channel_features[BluePixelChannel].variance_sum_of_squares[i]= variance.direction[i].blue; if (image->colorspace == CMYKColorspace) channel_features[BlackPixelChannel].variance_sum_of_squares[i]= variance.direction[i].black; if (image->alpha_trait != UndefinedPixelTrait) channel_features[AlphaPixelChannel].variance_sum_of_squares[i]= variance.direction[i].alpha; } /* Compute more texture features. */ (void) memset(&variance,0,sizeof(variance)); (void) memset(&sum_squares,0,sizeof(sum_squares)); #if defined(MAGICKCORE_OPENMP_SUPPORT) #pragma omp parallel for schedule(static) shared(status) \ magick_number_threads(image,image,number_grays,1) #endif for (i=0; i < 4; i++) { register ssize_t x; for (x=0; x < (ssize_t) number_grays; x++) { /* Difference variance. */ variance.direction[i].red+=density_xy[x].direction[i].red; variance.direction[i].green+=density_xy[x].direction[i].green; variance.direction[i].blue+=density_xy[x].direction[i].blue; if (image->colorspace == CMYKColorspace) variance.direction[i].black+=density_xy[x].direction[i].black; if (image->alpha_trait != UndefinedPixelTrait) variance.direction[i].alpha+=density_xy[x].direction[i].alpha; sum_squares.direction[i].red+=density_xy[x].direction[i].red* density_xy[x].direction[i].red; sum_squares.direction[i].green+=density_xy[x].direction[i].green* density_xy[x].direction[i].green; sum_squares.direction[i].blue+=density_xy[x].direction[i].blue* density_xy[x].direction[i].blue; if (image->colorspace == CMYKColorspace) sum_squares.direction[i].black+=density_xy[x].direction[i].black* density_xy[x].direction[i].black; if (image->alpha_trait != UndefinedPixelTrait) sum_squares.direction[i].alpha+=density_xy[x].direction[i].alpha* density_xy[x].direction[i].alpha; /* Difference entropy. */ channel_features[RedPixelChannel].difference_entropy[i]-= density_xy[x].direction[i].red* MagickLog10(density_xy[x].direction[i].red); channel_features[GreenPixelChannel].difference_entropy[i]-= density_xy[x].direction[i].green* MagickLog10(density_xy[x].direction[i].green); channel_features[BluePixelChannel].difference_entropy[i]-= density_xy[x].direction[i].blue* MagickLog10(density_xy[x].direction[i].blue); if (image->colorspace == CMYKColorspace) channel_features[BlackPixelChannel].difference_entropy[i]-= density_xy[x].direction[i].black* MagickLog10(density_xy[x].direction[i].black); if (image->alpha_trait != UndefinedPixelTrait) channel_features[AlphaPixelChannel].difference_entropy[i]-= density_xy[x].direction[i].alpha* MagickLog10(density_xy[x].direction[i].alpha); /* Information Measures of Correlation. */ entropy_x.direction[i].red-=(density_x[x].direction[i].red* MagickLog10(density_x[x].direction[i].red)); entropy_x.direction[i].green-=(density_x[x].direction[i].green* MagickLog10(density_x[x].direction[i].green)); entropy_x.direction[i].blue-=(density_x[x].direction[i].blue* MagickLog10(density_x[x].direction[i].blue)); if (image->colorspace == CMYKColorspace) entropy_x.direction[i].black-=(density_x[x].direction[i].black* MagickLog10(density_x[x].direction[i].black)); if (image->alpha_trait != UndefinedPixelTrait) entropy_x.direction[i].alpha-=(density_x[x].direction[i].alpha* MagickLog10(density_x[x].direction[i].alpha)); entropy_y.direction[i].red-=(density_y[x].direction[i].red* MagickLog10(density_y[x].direction[i].red)); entropy_y.direction[i].green-=(density_y[x].direction[i].green* MagickLog10(density_y[x].direction[i].green)); entropy_y.direction[i].blue-=(density_y[x].direction[i].blue* MagickLog10(density_y[x].direction[i].blue)); if (image->colorspace == CMYKColorspace) entropy_y.direction[i].black-=(density_y[x].direction[i].black* MagickLog10(density_y[x].direction[i].black)); if (image->alpha_trait != UndefinedPixelTrait) entropy_y.direction[i].alpha-=(density_y[x].direction[i].alpha* MagickLog10(density_y[x].direction[i].alpha)); } /* Difference variance. */ channel_features[RedPixelChannel].difference_variance[i]= (((double) number_grays*number_grays*sum_squares.direction[i].red)- (variance.direction[i].red*variance.direction[i].red))/ ((double) number_grays*number_grays*number_grays*number_grays); channel_features[GreenPixelChannel].difference_variance[i]= (((double) number_grays*number_grays*sum_squares.direction[i].green)- (variance.direction[i].green*variance.direction[i].green))/ ((double) number_grays*number_grays*number_grays*number_grays); channel_features[BluePixelChannel].difference_variance[i]= (((double) number_grays*number_grays*sum_squares.direction[i].blue)- (variance.direction[i].blue*variance.direction[i].blue))/ ((double) number_grays*number_grays*number_grays*number_grays); if (image->colorspace == CMYKColorspace) channel_features[BlackPixelChannel].difference_variance[i]= (((double) number_grays*number_grays*sum_squares.direction[i].black)- (variance.direction[i].black*variance.direction[i].black))/ ((double) number_grays*number_grays*number_grays*number_grays); if (image->alpha_trait != UndefinedPixelTrait) channel_features[AlphaPixelChannel].difference_variance[i]= (((double) number_grays*number_grays*sum_squares.direction[i].alpha)- (variance.direction[i].alpha*variance.direction[i].alpha))/ ((double) number_grays*number_grays*number_grays*number_grays); /* Information Measures of Correlation. */ channel_features[RedPixelChannel].measure_of_correlation_1[i]= (entropy_xy.direction[i].red-entropy_xy1.direction[i].red)/ (entropy_x.direction[i].red > entropy_y.direction[i].red ? entropy_x.direction[i].red : entropy_y.direction[i].red); channel_features[GreenPixelChannel].measure_of_correlation_1[i]= (entropy_xy.direction[i].green-entropy_xy1.direction[i].green)/ (entropy_x.direction[i].green > entropy_y.direction[i].green ? entropy_x.direction[i].green : entropy_y.direction[i].green); channel_features[BluePixelChannel].measure_of_correlation_1[i]= (entropy_xy.direction[i].blue-entropy_xy1.direction[i].blue)/ (entropy_x.direction[i].blue > entropy_y.direction[i].blue ? entropy_x.direction[i].blue : entropy_y.direction[i].blue); if (image->colorspace == CMYKColorspace) channel_features[BlackPixelChannel].measure_of_correlation_1[i]= (entropy_xy.direction[i].black-entropy_xy1.direction[i].black)/ (entropy_x.direction[i].black > entropy_y.direction[i].black ? entropy_x.direction[i].black : entropy_y.direction[i].black); if (image->alpha_trait != UndefinedPixelTrait) channel_features[AlphaPixelChannel].measure_of_correlation_1[i]= (entropy_xy.direction[i].alpha-entropy_xy1.direction[i].alpha)/ (entropy_x.direction[i].alpha > entropy_y.direction[i].alpha ? entropy_x.direction[i].alpha : entropy_y.direction[i].alpha); channel_features[RedPixelChannel].measure_of_correlation_2[i]= (sqrt(fabs(1.0-exp(-2.0*(double) (entropy_xy2.direction[i].red- entropy_xy.direction[i].red))))); channel_features[GreenPixelChannel].measure_of_correlation_2[i]= (sqrt(fabs(1.0-exp(-2.0*(double) (entropy_xy2.direction[i].green- entropy_xy.direction[i].green))))); channel_features[BluePixelChannel].measure_of_correlation_2[i]= (sqrt(fabs(1.0-exp(-2.0*(double) (entropy_xy2.direction[i].blue- entropy_xy.direction[i].blue))))); if (image->colorspace == CMYKColorspace) channel_features[BlackPixelChannel].measure_of_correlation_2[i]= (sqrt(fabs(1.0-exp(-2.0*(double) (entropy_xy2.direction[i].black- entropy_xy.direction[i].black))))); if (image->alpha_trait != UndefinedPixelTrait) channel_features[AlphaPixelChannel].measure_of_correlation_2[i]= (sqrt(fabs(1.0-exp(-2.0*(double) (entropy_xy2.direction[i].alpha- entropy_xy.direction[i].alpha))))); } /* Compute more texture features. */ #if defined(MAGICKCORE_OPENMP_SUPPORT) #pragma omp parallel for schedule(static) shared(status) \ magick_number_threads(image,image,number_grays,1) #endif for (i=0; i < 4; i++) { ssize_t z; for (z=0; z < (ssize_t) number_grays; z++) { register ssize_t y; ChannelStatistics pixel; (void) memset(&pixel,0,sizeof(pixel)); for (y=0; y < (ssize_t) number_grays; y++) { register ssize_t x; for (x=0; x < (ssize_t) number_grays; x++) { /* Contrast: amount of local variations present in an image. */ if (((y-x) == z) || ((x-y) == z)) { pixel.direction[i].red+=cooccurrence[x][y].direction[i].red; pixel.direction[i].green+=cooccurrence[x][y].direction[i].green; pixel.direction[i].blue+=cooccurrence[x][y].direction[i].blue; if (image->colorspace == CMYKColorspace) pixel.direction[i].black+=cooccurrence[x][y].direction[i].black; if (image->alpha_trait != UndefinedPixelTrait) pixel.direction[i].alpha+= cooccurrence[x][y].direction[i].alpha; } /* Maximum Correlation Coefficient. */ if ((fabs(density_x[z].direction[i].red) > MagickEpsilon) && (fabs(density_y[x].direction[i].red) > MagickEpsilon)) Q[z][y].direction[i].red+=cooccurrence[z][x].direction[i].red* cooccurrence[y][x].direction[i].red/density_x[z].direction[i].red/ density_y[x].direction[i].red; if ((fabs(density_x[z].direction[i].green) > MagickEpsilon) && (fabs(density_y[x].direction[i].red) > MagickEpsilon)) Q[z][y].direction[i].green+=cooccurrence[z][x].direction[i].green* cooccurrence[y][x].direction[i].green/ density_x[z].direction[i].green/density_y[x].direction[i].red; if ((fabs(density_x[z].direction[i].blue) > MagickEpsilon) && (fabs(density_y[x].direction[i].blue) > MagickEpsilon)) Q[z][y].direction[i].blue+=cooccurrence[z][x].direction[i].blue* cooccurrence[y][x].direction[i].blue/ density_x[z].direction[i].blue/density_y[x].direction[i].blue; if (image->colorspace == CMYKColorspace) if ((fabs(density_x[z].direction[i].black) > MagickEpsilon) && (fabs(density_y[x].direction[i].black) > MagickEpsilon)) Q[z][y].direction[i].black+=cooccurrence[z][x].direction[i].black* cooccurrence[y][x].direction[i].black/ density_x[z].direction[i].black/density_y[x].direction[i].black; if (image->alpha_trait != UndefinedPixelTrait) if ((fabs(density_x[z].direction[i].alpha) > MagickEpsilon) && (fabs(density_y[x].direction[i].alpha) > MagickEpsilon)) Q[z][y].direction[i].alpha+= cooccurrence[z][x].direction[i].alpha* cooccurrence[y][x].direction[i].alpha/ density_x[z].direction[i].alpha/ density_y[x].direction[i].alpha; } } channel_features[RedPixelChannel].contrast[i]+=z*z* pixel.direction[i].red; channel_features[GreenPixelChannel].contrast[i]+=z*z* pixel.direction[i].green; channel_features[BluePixelChannel].contrast[i]+=z*z* pixel.direction[i].blue; if (image->colorspace == CMYKColorspace) channel_features[BlackPixelChannel].contrast[i]+=z*z* pixel.direction[i].black; if (image->alpha_trait != UndefinedPixelTrait) channel_features[AlphaPixelChannel].contrast[i]+=z*z* pixel.direction[i].alpha; } /* Maximum Correlation Coefficient. Future: return second largest eigenvalue of Q. */ channel_features[RedPixelChannel].maximum_correlation_coefficient[i]= sqrt((double) -1.0); channel_features[GreenPixelChannel].maximum_correlation_coefficient[i]= sqrt((double) -1.0); channel_features[BluePixelChannel].maximum_correlation_coefficient[i]= sqrt((double) -1.0); if (image->colorspace == CMYKColorspace) channel_features[BlackPixelChannel].maximum_correlation_coefficient[i]= sqrt((double) -1.0); if (image->alpha_trait != UndefinedPixelTrait) channel_features[AlphaPixelChannel].maximum_correlation_coefficient[i]= sqrt((double) -1.0); } /* Relinquish resources. */ sum=(ChannelStatistics *) RelinquishMagickMemory(sum); for (i=0; i < (ssize_t) number_grays; i++) Q[i]=(ChannelStatistics *) RelinquishMagickMemory(Q[i]); Q=(ChannelStatistics **) RelinquishMagickMemory(Q); density_y=(ChannelStatistics *) RelinquishMagickMemory(density_y); density_xy=(ChannelStatistics *) RelinquishMagickMemory(density_xy); density_x=(ChannelStatistics *) RelinquishMagickMemory(density_x); for (i=0; i < (ssize_t) number_grays; i++) cooccurrence[i]=(ChannelStatistics *) RelinquishMagickMemory(cooccurrence[i]); cooccurrence=(ChannelStatistics **) RelinquishMagickMemory(cooccurrence); return(channel_features); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % H o u g h L i n e I m a g e % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % Use HoughLineImage() in conjunction with any binary edge extracted image (we % recommand Canny) to identify lines in the image. The algorithm accumulates % counts for every white pixel for every possible orientation (for angles from % 0 to 179 in 1 degree increments) and distance from the center of the image to % the corner (in 1 px increments) and stores the counts in an accumulator % matrix of angle vs distance. The size of the accumulator is 180x(diagonal/2). % Next it searches this space for peaks in counts and converts the locations % of the peaks to slope and intercept in the normal x,y input image space. Use % the slope/intercepts to find the endpoints clipped to the bounds of the % image. The lines are then drawn. The counts are a measure of the length of % the lines. % % The format of the HoughLineImage method is: % % Image *HoughLineImage(const Image *image,const size_t width, % const size_t height,const size_t threshold,ExceptionInfo *exception) % % A description of each parameter follows: % % o image: the image. % % o width, height: find line pairs as local maxima in this neighborhood. % % o threshold: the line count threshold. % % o exception: return any errors or warnings in this structure. % */ static inline double MagickRound(double x) { /* Round the fraction to nearest integer. */ if ((x-floor(x)) < (ceil(x)-x)) return(floor(x)); return(ceil(x)); } static Image *RenderHoughLines(const ImageInfo *image_info,const size_t columns, const size_t rows,ExceptionInfo *exception) { #define BoundingBox "viewbox" DrawInfo *draw_info; Image *image; MagickBooleanType status; /* Open image. */ image=AcquireImage(image_info,exception); status=OpenBlob(image_info,image,ReadBinaryBlobMode,exception); if (status == MagickFalse) { image=DestroyImageList(image); return((Image *) NULL); } image->columns=columns; image->rows=rows; draw_info=CloneDrawInfo(image_info,(DrawInfo *) NULL); draw_info->affine.sx=image->resolution.x == 0.0 ? 1.0 : image->resolution.x/ DefaultResolution; draw_info->affine.sy=image->resolution.y == 0.0 ? 1.0 : image->resolution.y/ DefaultResolution; image->columns=(size_t) (draw_info->affine.sx*image->columns); image->rows=(size_t) (draw_info->affine.sy*image->rows); status=SetImageExtent(image,image->columns,image->rows,exception); if (status == MagickFalse) return(DestroyImageList(image)); if (SetImageBackgroundColor(image,exception) == MagickFalse) { image=DestroyImageList(image); return((Image *) NULL); } /* Render drawing. */ if (GetBlobStreamData(image) == (unsigned char *) NULL) draw_info->primitive=FileToString(image->filename,~0UL,exception); else { draw_info->primitive=(char *) AcquireQuantumMemory(1,(size_t) GetBlobSize(image)+1); if (draw_info->primitive != (char *) NULL) { (void) memcpy(draw_info->primitive,GetBlobStreamData(image), (size_t) GetBlobSize(image)); draw_info->primitive[GetBlobSize(image)]='\0'; } } (void) DrawImage(image,draw_info,exception); draw_info=DestroyDrawInfo(draw_info); (void) CloseBlob(image); return(GetFirstImageInList(image)); } MagickExport Image *HoughLineImage(const Image *image,const size_t width, const size_t height,const size_t threshold,ExceptionInfo *exception) { #define HoughLineImageTag "HoughLine/Image" CacheView *image_view; char message[MagickPathExtent], path[MagickPathExtent]; const char *artifact; double hough_height; Image *lines_image = NULL; ImageInfo *image_info; int file; MagickBooleanType status; MagickOffsetType progress; MatrixInfo *accumulator; PointInfo center; register ssize_t y; size_t accumulator_height, accumulator_width, line_count; /* Create the accumulator. */ assert(image != (const Image *) NULL); assert(image->signature == MagickCoreSignature); if (image->debug != MagickFalse) (void) LogMagickEvent(TraceEvent,GetMagickModule(),"%s",image->filename); assert(exception != (ExceptionInfo *) NULL); assert(exception->signature == MagickCoreSignature); accumulator_width=180; hough_height=((sqrt(2.0)*(double) (image->rows > image->columns ? image->rows : image->columns))/2.0); accumulator_height=(size_t) (2.0*hough_height); accumulator=AcquireMatrixInfo(accumulator_width,accumulator_height, sizeof(double),exception); if (accumulator == (MatrixInfo *) NULL) ThrowImageException(ResourceLimitError,"MemoryAllocationFailed"); if (NullMatrix(accumulator) == MagickFalse) { accumulator=DestroyMatrixInfo(accumulator); ThrowImageException(ResourceLimitError,"MemoryAllocationFailed"); } /* Populate the accumulator. */ status=MagickTrue; progress=0; center.x=(double) image->columns/2.0; center.y=(double) image->rows/2.0; image_view=AcquireVirtualCacheView(image,exception); for (y=0; y < (ssize_t) image->rows; y++) { register const Quantum *magick_restrict p; register ssize_t x; if (status == MagickFalse) continue; p=GetCacheViewVirtualPixels(image_view,0,y,image->columns,1,exception); if (p == (Quantum *) NULL) { status=MagickFalse; continue; } for (x=0; x < (ssize_t) image->columns; x++) { if (GetPixelIntensity(image,p) > (QuantumRange/2.0)) { register ssize_t i; for (i=0; i < 180; i++) { double count, radius; radius=(((double) x-center.x)*cos(DegreesToRadians((double) i)))+ (((double) y-center.y)*sin(DegreesToRadians((double) i))); (void) GetMatrixElement(accumulator,i,(ssize_t) MagickRound(radius+hough_height),&count); count++; (void) SetMatrixElement(accumulator,i,(ssize_t) MagickRound(radius+hough_height),&count); } } p+=GetPixelChannels(image); } if (image->progress_monitor != (MagickProgressMonitor) NULL) { MagickBooleanType proceed; #if defined(MAGICKCORE_OPENMP_SUPPORT) #pragma omp atomic #endif progress++; proceed=SetImageProgress(image,CannyEdgeImageTag,progress,image->rows); if (proceed == MagickFalse) status=MagickFalse; } } image_view=DestroyCacheView(image_view); if (status == MagickFalse) { accumulator=DestroyMatrixInfo(accumulator); return((Image *) NULL); } /* Generate line segments from accumulator. */ file=AcquireUniqueFileResource(path); if (file == -1) { accumulator=DestroyMatrixInfo(accumulator); return((Image *) NULL); } (void) FormatLocaleString(message,MagickPathExtent, "# Hough line transform: %.20gx%.20g%+.20g\n",(double) width, (double) height,(double) threshold); if (write(file,message,strlen(message)) != (ssize_t) strlen(message)) status=MagickFalse; (void) FormatLocaleString(message,MagickPathExtent, "viewbox 0 0 %.20g %.20g\n",(double) image->columns,(double) image->rows); if (write(file,message,strlen(message)) != (ssize_t) strlen(message)) status=MagickFalse; (void) FormatLocaleString(message,MagickPathExtent, "# x1,y1 x2,y2 # count angle distance\n"); if (write(file,message,strlen(message)) != (ssize_t) strlen(message)) status=MagickFalse; line_count=image->columns > image->rows ? image->columns/4 : image->rows/4; if (threshold != 0) line_count=threshold; for (y=0; y < (ssize_t) accumulator_height; y++) { register ssize_t x; for (x=0; x < (ssize_t) accumulator_width; x++) { double count; (void) GetMatrixElement(accumulator,x,y,&count); if (count >= (double) line_count) { double maxima; SegmentInfo line; ssize_t v; /* Is point a local maxima? */ maxima=count; for (v=(-((ssize_t) height/2)); v <= (((ssize_t) height/2)); v++) { ssize_t u; for (u=(-((ssize_t) width/2)); u <= (((ssize_t) width/2)); u++) { if ((u != 0) || (v !=0)) { (void) GetMatrixElement(accumulator,x+u,y+v,&count); if (count > maxima) { maxima=count; break; } } } if (u < (ssize_t) (width/2)) break; } (void) GetMatrixElement(accumulator,x,y,&count); if (maxima > count) continue; if ((x >= 45) && (x <= 135)) { /* y = (r-x cos(t))/sin(t) */ line.x1=0.0; line.y1=((double) (y-(accumulator_height/2.0))-((line.x1- (image->columns/2.0))*cos(DegreesToRadians((double) x))))/ sin(DegreesToRadians((double) x))+(image->rows/2.0); line.x2=(double) image->columns; line.y2=((double) (y-(accumulator_height/2.0))-((line.x2- (image->columns/2.0))*cos(DegreesToRadians((double) x))))/ sin(DegreesToRadians((double) x))+(image->rows/2.0); } else { /* x = (r-y cos(t))/sin(t) */ line.y1=0.0; line.x1=((double) (y-(accumulator_height/2.0))-((line.y1- (image->rows/2.0))*sin(DegreesToRadians((double) x))))/ cos(DegreesToRadians((double) x))+(image->columns/2.0); line.y2=(double) image->rows; line.x2=((double) (y-(accumulator_height/2.0))-((line.y2- (image->rows/2.0))*sin(DegreesToRadians((double) x))))/ cos(DegreesToRadians((double) x))+(image->columns/2.0); } (void) FormatLocaleString(message,MagickPathExtent, "line %g,%g %g,%g # %g %g %g\n",line.x1,line.y1,line.x2,line.y2, maxima,(double) x,(double) y); if (write(file,message,strlen(message)) != (ssize_t) strlen(message)) status=MagickFalse; } } } (void) close(file); /* Render lines to image canvas. */ image_info=AcquireImageInfo(); image_info->background_color=image->background_color; (void) FormatLocaleString(image_info->filename,MagickPathExtent,"%s",path); artifact=GetImageArtifact(image,"background"); if (artifact != (const char *) NULL) (void) SetImageOption(image_info,"background",artifact); artifact=GetImageArtifact(image,"fill"); if (artifact != (const char *) NULL) (void) SetImageOption(image_info,"fill",artifact); artifact=GetImageArtifact(image,"stroke"); if (artifact != (const char *) NULL) (void) SetImageOption(image_info,"stroke",artifact); artifact=GetImageArtifact(image,"strokewidth"); if (artifact != (const char *) NULL) (void) SetImageOption(image_info,"strokewidth",artifact); lines_image=RenderHoughLines(image_info,image->columns,image->rows,exception); artifact=GetImageArtifact(image,"hough-lines:accumulator"); if ((lines_image != (Image *) NULL) && (IsStringTrue(artifact) != MagickFalse)) { Image *accumulator_image; accumulator_image=MatrixToImage(accumulator,exception); if (accumulator_image != (Image *) NULL) AppendImageToList(&lines_image,accumulator_image); } /* Free resources. */ accumulator=DestroyMatrixInfo(accumulator); image_info=DestroyImageInfo(image_info); (void) RelinquishUniqueFileResource(path); return(GetFirstImageInList(lines_image)); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % M e a n S h i f t I m a g e % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % MeanShiftImage() delineate arbitrarily shaped clusters in the image. For % each pixel, it visits all the pixels in the neighborhood specified by % the window centered at the pixel and excludes those that are outside the % radius=(window-1)/2 surrounding the pixel. From those pixels, it finds those % that are within the specified color distance from the current mean, and % computes a new x,y centroid from those coordinates and a new mean. This new % x,y centroid is used as the center for a new window. This process iterates % until it converges and the final mean is replaces the (original window % center) pixel value. It repeats this process for the next pixel, etc., % until it processes all pixels in the image. Results are typically better with % colorspaces other than sRGB. We recommend YIQ, YUV or YCbCr. % % The format of the MeanShiftImage method is: % % Image *MeanShiftImage(const Image *image,const size_t width, % const size_t height,const double color_distance, % ExceptionInfo *exception) % % A description of each parameter follows: % % o image: the image. % % o width, height: find pixels in this neighborhood. % % o color_distance: the color distance. % % o exception: return any errors or warnings in this structure. % */ MagickExport Image *MeanShiftImage(const Image *image,const size_t width, const size_t height,const double color_distance,ExceptionInfo *exception) { #define MaxMeanShiftIterations 100 #define MeanShiftImageTag "MeanShift/Image" CacheView *image_view, *mean_view, *pixel_view; Image *mean_image; MagickBooleanType status; MagickOffsetType progress; ssize_t y; assert(image != (const Image *) NULL); assert(image->signature == MagickCoreSignature); if (image->debug != MagickFalse) (void) LogMagickEvent(TraceEvent,GetMagickModule(),"%s",image->filename); assert(exception != (ExceptionInfo *) NULL); assert(exception->signature == MagickCoreSignature); mean_image=CloneImage(image,0,0,MagickTrue,exception); if (mean_image == (Image *) NULL) return((Image *) NULL); if (SetImageStorageClass(mean_image,DirectClass,exception) == MagickFalse) { mean_image=DestroyImage(mean_image); return((Image *) NULL); } status=MagickTrue; progress=0; image_view=AcquireVirtualCacheView(image,exception); pixel_view=AcquireVirtualCacheView(image,exception); mean_view=AcquireAuthenticCacheView(mean_image,exception); #if defined(MAGICKCORE_OPENMP_SUPPORT) #pragma omp parallel for schedule(static) shared(status,progress) \ magick_number_threads(mean_image,mean_image,mean_image->rows,1) #endif for (y=0; y < (ssize_t) mean_image->rows; y++) { register const Quantum *magick_restrict p; register Quantum *magick_restrict q; register ssize_t x; if (status == MagickFalse) continue; p=GetCacheViewVirtualPixels(image_view,0,y,image->columns,1,exception); q=GetCacheViewAuthenticPixels(mean_view,0,y,mean_image->columns,1, exception); if ((p == (const Quantum *) NULL) || (q == (Quantum *) NULL)) { status=MagickFalse; continue; } for (x=0; x < (ssize_t) mean_image->columns; x++) { PixelInfo mean_pixel, previous_pixel; PointInfo mean_location, previous_location; register ssize_t i; GetPixelInfo(image,&mean_pixel); GetPixelInfoPixel(image,p,&mean_pixel); mean_location.x=(double) x; mean_location.y=(double) y; for (i=0; i < MaxMeanShiftIterations; i++) { double distance, gamma; PixelInfo sum_pixel; PointInfo sum_location; ssize_t count, v; sum_location.x=0.0; sum_location.y=0.0; GetPixelInfo(image,&sum_pixel); previous_location=mean_location; previous_pixel=mean_pixel; count=0; for (v=(-((ssize_t) height/2)); v <= (((ssize_t) height/2)); v++) { ssize_t u; for (u=(-((ssize_t) width/2)); u <= (((ssize_t) width/2)); u++) { if ((v*v+u*u) <= (ssize_t) ((width/2)*(height/2))) { PixelInfo pixel; status=GetOneCacheViewVirtualPixelInfo(pixel_view,(ssize_t) MagickRound(mean_location.x+u),(ssize_t) MagickRound( mean_location.y+v),&pixel,exception); distance=(mean_pixel.red-pixel.red)*(mean_pixel.red-pixel.red)+ (mean_pixel.green-pixel.green)*(mean_pixel.green-pixel.green)+ (mean_pixel.blue-pixel.blue)*(mean_pixel.blue-pixel.blue); if (distance <= (color_distance*color_distance)) { sum_location.x+=mean_location.x+u; sum_location.y+=mean_location.y+v; sum_pixel.red+=pixel.red; sum_pixel.green+=pixel.green; sum_pixel.blue+=pixel.blue; sum_pixel.alpha+=pixel.alpha; count++; } } } } gamma=PerceptibleReciprocal(count); mean_location.x=gamma*sum_location.x; mean_location.y=gamma*sum_location.y; mean_pixel.red=gamma*sum_pixel.red; mean_pixel.green=gamma*sum_pixel.green; mean_pixel.blue=gamma*sum_pixel.blue; mean_pixel.alpha=gamma*sum_pixel.alpha; distance=(mean_location.x-previous_location.x)* (mean_location.x-previous_location.x)+ (mean_location.y-previous_location.y)* (mean_location.y-previous_location.y)+ 255.0*QuantumScale*(mean_pixel.red-previous_pixel.red)* 255.0*QuantumScale*(mean_pixel.red-previous_pixel.red)+ 255.0*QuantumScale*(mean_pixel.green-previous_pixel.green)* 255.0*QuantumScale*(mean_pixel.green-previous_pixel.green)+ 255.0*QuantumScale*(mean_pixel.blue-previous_pixel.blue)* 255.0*QuantumScale*(mean_pixel.blue-previous_pixel.blue); if (distance <= 3.0) break; } SetPixelRed(mean_image,ClampToQuantum(mean_pixel.red),q); SetPixelGreen(mean_image,ClampToQuantum(mean_pixel.green),q); SetPixelBlue(mean_image,ClampToQuantum(mean_pixel.blue),q); SetPixelAlpha(mean_image,ClampToQuantum(mean_pixel.alpha),q); p+=GetPixelChannels(image); q+=GetPixelChannels(mean_image); } if (SyncCacheViewAuthenticPixels(mean_view,exception) == MagickFalse) status=MagickFalse; if (image->progress_monitor != (MagickProgressMonitor) NULL) { MagickBooleanType proceed; #if defined(MAGICKCORE_OPENMP_SUPPORT) #pragma omp atomic #endif progress++; proceed=SetImageProgress(image,MeanShiftImageTag,progress,image->rows); if (proceed == MagickFalse) status=MagickFalse; } } mean_view=DestroyCacheView(mean_view); pixel_view=DestroyCacheView(pixel_view); image_view=DestroyCacheView(image_view); return(mean_image); }

moleintor.c

/* Copyright 2014-2018 The PySCF Developers. All Rights Reserved. Licensed under the Apache License, Version 2.0 (the "License"); you may not use this file except in compliance with the License. You may obtain a copy of the License at http://www.apache.org/licenses/LICENSE-2.0 Unless required by applicable law or agreed to in writing, software distributed under the License is distributed on an "AS IS" BASIS, WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. See the License for the specific language governing permissions and limitations under the License. * * Author: Qiming Sun <osirpt.sun@gmail.com> */ #include <stdlib.h> #include <complex.h> //#include <omp.h> #include "config.h" #include "cint.h" #define PLAIN 0 #define HERMITIAN 1 #define ANTIHERMI 2 #define NCTRMAX 64 static void cart_or_sph(int (*intor)(), int (*num_cgto)(), double *mat, int ncomp, int hermi, int *bralst, int nbra, int *ketlst, int nket, int *atm, int natm, int *bas, int nbas, double *env) { int ish; int ilocs[nbra+1]; int naoi = 0; int naoj = 0; for (ish = 0; ish < nbra; ish++) { ilocs[ish] = naoi; naoi += (*num_cgto)(bralst[ish], bas); } ilocs[nbra] = naoi; for (ish = 0; ish < nket; ish++) { naoj += (*num_cgto)(ketlst[ish], bas); } #pragma omp parallel default(none) \ shared(intor, num_cgto, mat, ncomp, hermi, bralst, nbra, ketlst, nket,\ atm, natm, bas, nbas, env, naoi, naoj, ilocs) \ private(ish) { int jsh, jsh1, i, j, i0, j0, icomp; int di, dj, iloc, jloc; int shls[2]; double *buf = malloc(sizeof(double)*NCTRMAX*NCTRMAX*ncomp); double *pmat, *pbuf; #pragma omp for nowait schedule(dynamic) for (ish = 0; ish < nbra; ish++) { iloc = ilocs[ish]; di = ilocs[ish+1] - iloc; if (hermi == PLAIN) { jsh1 = nket; } else { jsh1 = ish + 1; } for (jloc = 0, jsh = 0; jsh < jsh1; jsh++, jloc+=dj) { dj = (*num_cgto)(ketlst[jsh], bas); shls[0] = bralst[ish]; shls[1] = ketlst[jsh]; (*intor)(buf, shls, atm, natm, bas, nbas, env); for (icomp = 0; icomp < ncomp; icomp++) { pmat = mat + icomp*naoi*naoj; pbuf = buf + icomp*di*dj; for (i0=iloc, i=0; i < di; i++, i0++) { for (j0=jloc, j=0; j < dj; j++, j0++) { pmat[i0*naoj+j0] = pbuf[j*di+i]; } } } } } free(buf); } } void GTO1eintor_sph(int (*intor)(), double *mat, int ncomp, int hermi, int *bralst, int nbra, int *ketlst, int nket, int *atm, int natm, int *bas, int nbas, double *env) { cart_or_sph(intor, CINTcgto_spheric, mat, ncomp, hermi, bralst, nbra, ketlst, nket, atm, natm, bas, nbas, env); } void GTO1eintor_cart(int (*intor)(), double *mat, int ncomp, int hermi, int *bralst, int nbra, int *ketlst, int nket, int *atm, int natm, int *bas, int nbas, double *env) { cart_or_sph(intor, CINTcgto_cart, mat, ncomp, hermi, bralst, nbra, ketlst, nket, atm, natm, bas, nbas, env); } void GTO1eintor_spinor(int (*intor)(), double complex *mat, int ncomp, int hermi, int *bralst, int nbra, int *ketlst, int nket, int *atm, int natm, int *bas, int nbas, double *env) { int ish; int ilocs[nbra+1]; int naoi = 0; int naoj = 0; for (ish = 0; ish < nbra; ish++) { ilocs[ish] = naoi; naoi += CINTcgto_spinor(bralst[ish], bas); } ilocs[nbra] = naoi; for (ish = 0; ish < nket; ish++) { naoj += CINTcgto_spinor(ketlst[ish], bas); } #pragma omp parallel default(none) \ shared(intor, mat, ncomp, hermi, bralst, nbra, ketlst, nket,\ atm, natm, bas, nbas, env, naoi, naoj, ilocs) \ private(ish) { int jsh, jsh1, i, j, i0, j0, icomp; int di, dj, iloc, jloc; int shls[2]; double complex *buf = malloc(sizeof(double complex)*NCTRMAX*NCTRMAX*4*ncomp); double complex *pmat, *pbuf; #pragma omp for nowait schedule(dynamic) for (ish = 0; ish < nbra; ish++) { iloc = ilocs[ish]; di = CINTcgto_spinor(bralst[ish], bas); if (hermi == PLAIN) { jsh1 = nket; } else { jsh1 = ish + 1; } for (jloc = 0, jsh = 0; jsh < jsh1; jsh++, jloc+=dj) { dj = CINTcgto_spinor(ketlst[jsh], bas); shls[0] = bralst[ish]; shls[1] = ketlst[jsh]; (*intor)(buf, shls, atm, natm, bas, nbas, env); for (icomp = 0; icomp < ncomp; icomp++) { pmat = mat + icomp*naoi*naoj; pbuf = buf + icomp*di*dj; for (i0=iloc, i=0; i < di; i++, i0++) { for (j0=jloc, j=0; j < dj; j++, j0++) { pmat[i0*naoj+j0] = pbuf[j*di+i]; } } } } } free(buf); } } void GTO1e_intor_drv(int (*intor)(), double *mat, size_t ijoff, int *basrange, int naoi, int naoj, int *iloc, int *jloc, int ncomp, int hermi, CINTOpt *cintopt, int *atm, int natm, int *bas, int nbas, double *env) { #pragma omp parallel default(none) \ shared(intor, mat, ijoff, basrange, naoi, naoj, iloc, jloc, \ ncomp, hermi, cintopt, atm, natm, bas, nbas, env) { int ish, jsh, i, j, i0, j0, icomp; int brastart = basrange[0]; int bracount = basrange[1]; int ketstart = basrange[2]; int ketcount = basrange[3]; int di, dj; int shls[2]; double *buf = malloc(sizeof(double)*NCTRMAX*NCTRMAX*ncomp); double *pmat, *pbuf; #pragma omp for nowait schedule(dynamic) for (ish = 0; ish < bracount; ish++) { di = iloc[ish+1] - iloc[ish]; for (jsh = 0; jsh < ketcount; jsh++) { if (hermi != PLAIN && iloc[ish] < jloc[jsh]) { continue; } dj = jloc[jsh+1] - jloc[jsh]; shls[0] = brastart + ish; shls[1] = ketstart + jsh; (*intor)(buf, shls, atm, natm, bas, nbas, env); for (icomp = 0; icomp < ncomp; icomp++) { pmat = mat + icomp*naoi*naoj + ijoff; pbuf = buf + icomp*di*dj; for (i0=iloc[ish], i=0; i < di; i++, i0++) { for (j0=jloc[jsh], j=0; j < dj; j++, j0++) { pmat[i0*naoj+j0] = pbuf[j*di+i]; } } } } } free(buf); } } void GTO1e_spinor_drv(int (*intor)(), double complex *mat, size_t ijoff, int *basrange, int naoi, int naoj, int *iloc, int *jloc, int ncomp, int hermi, CINTOpt *cintopt, int *atm, int natm, int *bas, int nbas, double *env) { #pragma omp parallel default(none) \ shared(intor, mat, ijoff, basrange, naoi, naoj, iloc, jloc, \ ncomp, hermi, cintopt, atm, natm, bas, nbas, env) { int ish, jsh, i, j, i0, j0, icomp; int brastart = basrange[0]; int bracount = basrange[1]; int ketstart = basrange[2]; int ketcount = basrange[3]; int di, dj; int shls[2]; double complex *buf = malloc(sizeof(double)*NCTRMAX*NCTRMAX*ncomp); double complex *pmat, *pbuf; #pragma omp for nowait schedule(dynamic) for (ish = 0; ish < bracount; ish++) { di = iloc[ish+1] - iloc[ish]; for (jsh = 0; jsh < ketcount; jsh++) { if (hermi != PLAIN && iloc[ish] < jloc[jsh]) { continue; } dj = jloc[jsh+1] - jloc[jsh]; shls[0] = brastart + ish; shls[1] = ketstart + jsh; (*intor)(buf, shls, atm, natm, bas, nbas, env); for (icomp = 0; icomp < ncomp; icomp++) { pmat = mat + icomp*naoi*naoj + ijoff; pbuf = buf + icomp*di*dj; for (i0=iloc[ish], i=0; i < di; i++, i0++) { for (j0=jloc[jsh], j=0; j < dj; j++, j0++) { pmat[i0*naoj+j0] = pbuf[j*di+i]; } } } } } free(buf); } }

3045.c

/* POLYBENCH/GPU-OPENMP * * This file is a part of the Polybench/GPU-OpenMP suite * * Contact: * William Killian <killian@udel.edu> * * Copyright 2013, The University of Delaware */ #include <stdio.h> #include <unistd.h> #include <string.h> #include <math.h> /* Include polybench common header. */ #include <polybench.h> /* Include benchmark-specific header. */ /* Default data type is double, default size is 4000. */ #include "3mm.h" /* Array initialization. */ static void init_array(int ni, int nj, int nk, int nl, int nm, DATA_TYPE POLYBENCH_2D(A,NI,NK,ni,nk), DATA_TYPE POLYBENCH_2D(B,NK,NJ,nk,nj), DATA_TYPE POLYBENCH_2D(C,NJ,NM,nj,nm), DATA_TYPE POLYBENCH_2D(D,NM,NL,nm,nl)) { int i, j; for (i = 0; i < ni; i++) for (j = 0; j < nk; j++) A[i][j] = ((DATA_TYPE) i*j) / ni; for (i = 0; i < nk; i++) for (j = 0; j < nj; j++) B[i][j] = ((DATA_TYPE) i*(j+1)) / nj; for (i = 0; i < nj; i++) for (j = 0; j < nm; j++) C[i][j] = ((DATA_TYPE) i*(j+3)) / nl; for (i = 0; i < nm; i++) for (j = 0; j < nl; j++) D[i][j] = ((DATA_TYPE) i*(j+2)) / nk; } /* DCE code. Must scan the entire live-out data. Can be used also to check the correctness of the output. */ static void print_array(int ni, int nl, DATA_TYPE POLYBENCH_2D(G,NI,NL,ni,nl)) { int i, j; for (i = 0; i < ni; i++) for (j = 0; j < nl; j++) { fprintf (stderr, DATA_PRINTF_MODIFIER, G[i][j]); if ((i * ni + j) % 20 == 0) fprintf (stderr, "\n"); } fprintf (stderr, "\n"); } /* Main computational kernel. The whole function will be timed, including the call and return. */ static void kernel_3mm(int ni, int nj, int nk, int nl, int nm, DATA_TYPE POLYBENCH_2D(E,NI,NJ,ni,nj), DATA_TYPE POLYBENCH_2D(A,NI,NK,ni,nk), DATA_TYPE POLYBENCH_2D(B,NK,NJ,nk,nj), DATA_TYPE POLYBENCH_2D(F,NJ,NL,nj,nl), DATA_TYPE POLYBENCH_2D(C,NJ,NM,nj,nm), DATA_TYPE POLYBENCH_2D(D,NM,NL,nm,nl), DATA_TYPE POLYBENCH_2D(G,NI,NL,ni,nl)) { int i, j, k; #pragma scop #pragma omp parallel private (j, k) num_threads(1) { /* E := A*B */ #pragma omp for schedule(static, 1) for (i = 0; i < _PB_NI; i++) for (j = 0; j < _PB_NJ; j++) { E[i][j] = 0; for (k = 0; k < _PB_NK; ++k) E[i][j] += A[i][k] * B[k][j]; } /* F := C*D */ #pragma omp for schedule(static, 1) for (i = 0; i < _PB_NJ; i++) for (j = 0; j < _PB_NL; j++) { F[i][j] = 0; for (k = 0; k < _PB_NM; ++k) F[i][j] += C[i][k] * D[k][j]; } /* G := E*F */ #pragma omp for schedule(static, 1) for (i = 0; i < _PB_NI; i++) for (j = 0; j < _PB_NL; j++) { G[i][j] = 0; for (k = 0; k < _PB_NJ; ++k) G[i][j] += E[i][k] * F[k][j]; } } #pragma endscop } int main(int argc, char** argv) { /* Retrieve problem size. */ int ni = NI; int nj = NJ; int nk = NK; int nl = NL; int nm = NM; /* Variable declaration/allocation. */ POLYBENCH_2D_ARRAY_DECL(E, DATA_TYPE, NI, NJ, ni, nj); POLYBENCH_2D_ARRAY_DECL(A, DATA_TYPE, NI, NK, ni, nk); POLYBENCH_2D_ARRAY_DECL(B, DATA_TYPE, NK, NJ, nk, nj); POLYBENCH_2D_ARRAY_DECL(F, DATA_TYPE, NJ, NL, nj, nl); POLYBENCH_2D_ARRAY_DECL(C, DATA_TYPE, NJ, NM, nj, nm); POLYBENCH_2D_ARRAY_DECL(D, DATA_TYPE, NM, NL, nm, nl); POLYBENCH_2D_ARRAY_DECL(G, DATA_TYPE, NI, NL, ni, nl); /* Initialize array(s). */ init_array (ni, nj, nk, nl, nm, POLYBENCH_ARRAY(A), POLYBENCH_ARRAY(B), POLYBENCH_ARRAY(C), POLYBENCH_ARRAY(D)); /* Start timer. */ polybench_start_instruments; /* Run kernel. */ kernel_3mm (ni, nj, nk, nl, nm, POLYBENCH_ARRAY(E), POLYBENCH_ARRAY(A), POLYBENCH_ARRAY(B), POLYBENCH_ARRAY(F), POLYBENCH_ARRAY(C), POLYBENCH_ARRAY(D), POLYBENCH_ARRAY(G)); /* Stop and print timer. */ polybench_stop_instruments; polybench_print_instruments; /* Prevent dead-code elimination. All live-out data must be printed by the function call in argument. */ polybench_prevent_dce(print_array(ni, nl, POLYBENCH_ARRAY(G))); /* Be clean. */ POLYBENCH_FREE_ARRAY(E); POLYBENCH_FREE_ARRAY(A); POLYBENCH_FREE_ARRAY(B); POLYBENCH_FREE_ARRAY(F); POLYBENCH_FREE_ARRAY(C); POLYBENCH_FREE_ARRAY(D); POLYBENCH_FREE_ARRAY(G); return 0; }

threaded_eigen_matrix.h

/* * Copyright (c) 2017 Ivan Iakoupov * * Permission is hereby granted, free of charge, to any person obtaining a * copy of this software and associated documentation files (the "Software"), * to deal in the Software without restriction, including without limitation * the rights to use, copy, modify, merge, publish, distribute, sublicense, * and/or sell copies of the Software, and to permit persons to whom the * Software is furnished to do so, subject to the following conditions: * * The above copyright notice and this permission notice shall be included * in all copies or substantial portions of the Software. * * THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR * IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, * FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL * THE AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER * LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING * FROM, OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER * DEALINGS IN THE SOFTWARE. */ #ifndef THREADED_EIGEN_MATRIX_H #define THREADED_EIGEN_MATRIX_H #include <omp.h> #include <vector> #include "Eigen/Dense" class ThreadedEigenMatrix { int m_rows; int m_cols; int m_threads; std::vector<Eigen::MatrixXcd> m_matrix_chunks; std::vector<int> m_block_start_indices; public: ThreadedEigenMatrix() : m_threads(omp_get_max_threads()), m_rows(0), m_cols(0) {} explicit ThreadedEigenMatrix(std::function<std::complex<double>(int,int)> f, int rows, int cols) : m_threads(omp_get_max_threads()), m_rows(rows), m_cols(cols) { m_matrix_chunks.resize(m_threads); const int normal_chunk_size = m_rows/m_threads; std::vector<int> chunk_sizes(m_threads); for (int n = 0; n < m_threads; ++n) { chunk_sizes[n] = normal_chunk_size; } // The last chunk size can be different const int last_chunk_size = m_rows - (m_threads-1)*normal_chunk_size; chunk_sizes[m_threads-1] = last_chunk_size; #pragma omp parallel for for (int n = 0; n < m_threads; ++n) { const int chunk_size = chunk_sizes[n]; m_matrix_chunks[n] = Eigen::MatrixXcd::Zero(chunk_size, m_cols); for (int i = 0; i < chunk_size; ++i) { for (int j = 0; j < m_cols; ++j) { m_matrix_chunks[n](i,j) = f(i + n*normal_chunk_size, j); } } } m_block_start_indices.resize(m_threads); int rowsSum = 0; for (int j = 0; j < m_threads; ++j) { m_block_start_indices[j] = rowsSum; rowsSum += m_matrix_chunks[j].rows(); } } explicit ThreadedEigenMatrix(Eigen::MatrixXcd M) : m_threads(omp_get_max_threads()), m_rows(M.rows()), m_cols(M.cols()) { m_matrix_chunks.resize(m_threads); const int normal_chunk_size = m_rows/m_threads; std::vector<int> chunk_sizes(m_threads); for (int n = 0; n < m_threads; ++n) { chunk_sizes[n] = normal_chunk_size; } // The last chunk size can be different const int last_chunk_size = m_rows - (m_threads-1)*normal_chunk_size; chunk_sizes[m_threads-1] = last_chunk_size; #pragma omp parallel for for (int n = 0; n < m_threads; ++n) { const int chunk_size = chunk_sizes[n]; m_matrix_chunks[n] = Eigen::MatrixXcd::Zero(chunk_size, m_cols); for (int i = 0; i < chunk_size; ++i) { for (int j = 0; j < m_cols; ++j) { m_matrix_chunks[n](i,j) = M(i + n*normal_chunk_size, j); } } } m_block_start_indices.resize(m_threads); int rowsSum = 0; for (int j = 0; j < m_threads; ++j) { m_block_start_indices[j] = rowsSum; rowsSum += m_matrix_chunks[j].rows(); } } Eigen::VectorXcd operator*(const Eigen::VectorXcd &v) const { Eigen::VectorXcd ret(m_rows); #pragma omp parallel for for (int j = 0; j < m_threads; ++j) { const int block_start = m_block_start_indices[j]; const int block_end = block_start + m_matrix_chunks[j].rows(); Eigen::VectorXcd ret_i = m_matrix_chunks[j]*v; for (int k = block_start; k < block_end; ++k) { ret(k) = ret_i(k-block_start); } } return ret; } }; #endif // THREADED_EIGEN_MATRIX_H

omp_lock.c

<ompts:test> <ompts:testdescription>Test which checks the omp_set_lock and the omp_unset_lock function by counting the threads entering and exiting a single region with locks.</ompts:testdescription> <ompts:ompversion>2.0</ompts:ompversion> <ompts:directive>omp_lock</ompts:directive> <ompts:dependences>omp flush</ompts:dependences> <ompts:testcode> #include <stdio.h> #include "omp_testsuite.h" omp_lock_t lck; int <ompts:testcode:functionname>omp_lock</ompts:testcode:functionname>(FILE * logFile) { int nr_threads_in_single = 0; int result = 0; int nr_iterations = 0; int i; omp_init_lock (&lck); #pragma omp parallel shared(lck) { #pragma omp for for(i = 0; i < LOOPCOUNT; i++) { <ompts:orphan> <ompts:check>omp_set_lock (&lck);</ompts:check> </ompts:orphan> #pragma omp flush nr_threads_in_single++; #pragma omp flush nr_iterations++; nr_threads_in_single--; result = result + nr_threads_in_single; <ompts:orphan> <ompts:check>omp_unset_lock(&lck);</ompts:check> </ompts:orphan> } } omp_destroy_lock (&lck); return ((result == 0) && (nr_iterations == LOOPCOUNT)); } </ompts:testcode> </ompts:test>

dataset.h

/*! * Copyright (c) 2016 Microsoft Corporation. All rights reserved. * Licensed under the MIT License. See LICENSE file in the project root for license information. */ #ifndef LIGHTGBM_DATASET_H_ #define LIGHTGBM_DATASET_H_ #include <LightGBM/config.h> #include <LightGBM/feature_group.h> #include <LightGBM/meta.h> #include <LightGBM/utils/common.h> #include <LightGBM/utils/openmp_wrapper.h> #include <LightGBM/utils/random.h> #include <LightGBM/utils/text_reader.h> #include <string> #include <functional> #include <memory> #include <mutex> #include <unordered_set> #include <utility> #include <vector> namespace LightGBM { /*! \brief forward declaration */ class DatasetLoader; /*! * \brief This class is used to store some meta(non-feature) data for training data, * e.g. labels, weights, initial scores, query level informations. * * Some details: * 1. Label, used for training. * 2. Weights, weighs of records, optional * 3. Query Boundaries, necessary for lambdarank. * The documents of i-th query is in [ query_boundaries[i], query_boundaries[i+1] ) * 4. Query Weights, auto calculate by weights and query_boundaries(if both of them are existed) * the weight for i-th query is sum(query_boundaries[i] , .., query_boundaries[i+1]) / (query_boundaries[i + 1] - query_boundaries[i+1]) * 5. Initial score. optional. if existing, the model will boost from this score, otherwise will start from 0. */ class Metadata { public: /*! * \brief Null constructor */ Metadata(); /*! * \brief Initialization will load query level informations, since it is need for sampling data * \param data_filename Filename of data * \param init_score_filename Filename of initial score */ void Init(const char* data_filename, const char* initscore_file); /*! * \brief init as subset * \param metadata Filename of data * \param used_indices * \param num_used_indices */ void Init(const Metadata& metadata, const data_size_t* used_indices, data_size_t num_used_indices); /*! * \brief Initial with binary memory * \param memory Pointer to memory */ void LoadFromMemory(const void* memory); /*! \brief Destructor */ ~Metadata(); /*! * \brief Initial work, will allocate space for label, weight(if exists) and query(if exists) * \param num_data Number of training data * \param weight_idx Index of weight column, < 0 means doesn't exists * \param query_idx Index of query id column, < 0 means doesn't exists */ void Init(data_size_t num_data, int weight_idx, int query_idx); /*! * \brief Partition label by used indices * \param used_indices Indices of local used */ void PartitionLabel(const std::vector<data_size_t>& used_indices); /*! * \brief Partition meta data according to local used indices if need * \param num_all_data Number of total training data, including other machines' data on parallel learning * \param used_data_indices Indices of local used training data */ void CheckOrPartition(data_size_t num_all_data, const std::vector<data_size_t>& used_data_indices); void SetLabel(const label_t* label, data_size_t len); void SetWeights(const label_t* weights, data_size_t len); void SetQuery(const data_size_t* query, data_size_t len); /*! * \brief Set initial scores * \param init_score Initial scores, this class will manage memory for init_score. */ void SetInitScore(const double* init_score, data_size_t len); /*! * \brief Save binary data to file * \param file File want to write */ void SaveBinaryToFile(const VirtualFileWriter* writer) const; /*! * \brief Get sizes in byte of this object */ size_t SizesInByte() const; /*! * \brief Get pointer of label * \return Pointer of label */ inline const label_t* label() const { return label_.data(); } /*! * \brief Set label for one record * \param idx Index of this record * \param value Label value of this record */ inline void SetLabelAt(data_size_t idx, label_t value) { label_[idx] = value; } /*! * \brief Set Weight for one record * \param idx Index of this record * \param value Weight value of this record */ inline void SetWeightAt(data_size_t idx, label_t value) { weights_[idx] = value; } /*! * \brief Set Query Id for one record * \param idx Index of this record * \param value Query Id value of this record */ inline void SetQueryAt(data_size_t idx, data_size_t value) { queries_[idx] = static_cast<data_size_t>(value); } /*! * \brief Get weights, if not exists, will return nullptr * \return Pointer of weights */ inline const label_t* weights() const { if (!weights_.empty()) { return weights_.data(); } else { return nullptr; } } /*! * \brief Get data boundaries on queries, if not exists, will return nullptr * we assume data will order by query, * the interval of [query_boundaris[i], query_boundaris[i+1]) * is the data indices for query i. * \return Pointer of data boundaries on queries */ inline const data_size_t* query_boundaries() const { if (!query_boundaries_.empty()) { return query_boundaries_.data(); } else { return nullptr; } } /*! * \brief Get Number of queries * \return Number of queries */ inline data_size_t num_queries() const { return num_queries_; } /*! * \brief Get weights for queries, if not exists, will return nullptr * \return Pointer of weights for queries */ inline const label_t* query_weights() const { if (!query_weights_.empty()) { return query_weights_.data(); } else { return nullptr; } } /*! * \brief Get initial scores, if not exists, will return nullptr * \return Pointer of initial scores */ inline const double* init_score() const { if (!init_score_.empty()) { return init_score_.data(); } else { return nullptr; } } /*! * \brief Get size of initial scores */ inline int64_t num_init_score() const { return num_init_score_; } /*! \brief Disable copy */ Metadata& operator=(const Metadata&) = delete; /*! \brief Disable copy */ Metadata(const Metadata&) = delete; private: /*! \brief Load initial scores from file */ void LoadInitialScore(const char* initscore_file); /*! \brief Load wights from file */ void LoadWeights(); /*! \brief Load query boundaries from file */ void LoadQueryBoundaries(); /*! \brief Load query wights */ void LoadQueryWeights(); /*! \brief Filename of current data */ std::string data_filename_; /*! \brief Number of data */ data_size_t num_data_; /*! \brief Number of weights, used to check correct weight file */ data_size_t num_weights_; /*! \brief Label data */ std::vector<label_t> label_; /*! \brief Weights data */ std::vector<label_t> weights_; /*! \brief Query boundaries */ std::vector<data_size_t> query_boundaries_; /*! \brief Query weights */ std::vector<label_t> query_weights_; /*! \brief Number of querys */ data_size_t num_queries_; /*! \brief Number of Initial score, used to check correct weight file */ int64_t num_init_score_; /*! \brief Initial score */ std::vector<double> init_score_; /*! \brief Queries data */ std::vector<data_size_t> queries_; /*! \brief mutex for threading safe call */ std::mutex mutex_; bool weight_load_from_file_; bool query_load_from_file_; bool init_score_load_from_file_; }; /*! \brief Interface for Parser */ class Parser { public: /*! \brief virtual destructor */ virtual ~Parser() {} /*! * \brief Parse one line with label * \param str One line record, string format, should end with '\0' * \param out_features Output columns, store in (column_idx, values) * \param out_label Label will store to this if exists */ virtual void ParseOneLine(const char* str, std::vector<std::pair<int, double>>* out_features, double* out_label) const = 0; virtual int NumFeatures() const = 0; /*! * \brief Create an object of parser, will auto choose the format depend on file * \param filename One Filename of data * \param num_features Pass num_features of this data file if you know, <=0 means don't know * \param label_idx index of label column * \return Object of parser */ static Parser* CreateParser(const char* filename, bool header, int num_features, int label_idx); }; /*! \brief The main class of data set, * which are used to training or validation */ class Dataset { public: friend DatasetLoader; LIGHTGBM_EXPORT Dataset(); LIGHTGBM_EXPORT Dataset(data_size_t num_data); void Construct( std::vector<std::unique_ptr<BinMapper>>* bin_mappers, int num_total_features, const std::vector<std::vector<double>>& forced_bins, int** sample_non_zero_indices, const int* num_per_col, size_t total_sample_cnt, const Config& io_config); /*! \brief Destructor */ LIGHTGBM_EXPORT ~Dataset(); LIGHTGBM_EXPORT bool CheckAlign(const Dataset& other) const { if (num_features_ != other.num_features_) { return false; } if (num_total_features_ != other.num_total_features_) { return false; } if (label_idx_ != other.label_idx_) { return false; } for (int i = 0; i < num_features_; ++i) { if (!FeatureBinMapper(i)->CheckAlign(*(other.FeatureBinMapper(i)))) { return false; } } return true; } inline void PushOneRow(int tid, data_size_t row_idx, const std::vector<double>& feature_values) { if (is_finish_load_) { return; } for (size_t i = 0; i < feature_values.size() && i < static_cast<size_t>(num_total_features_); ++i) { int feature_idx = used_feature_map_[i]; if (feature_idx >= 0) { const int group = feature2group_[feature_idx]; const int sub_feature = feature2subfeature_[feature_idx]; feature_groups_[group]->PushData(tid, sub_feature, row_idx, feature_values[i]); } } } inline void PushOneRow(int tid, data_size_t row_idx, const std::vector<std::pair<int, double>>& feature_values) { if (is_finish_load_) { return; } for (auto& inner_data : feature_values) { if (inner_data.first >= num_total_features_) { continue; } int feature_idx = used_feature_map_[inner_data.first]; if (feature_idx >= 0) { const int group = feature2group_[feature_idx]; const int sub_feature = feature2subfeature_[feature_idx]; feature_groups_[group]->PushData(tid, sub_feature, row_idx, inner_data.second); } } } inline void PushOneData(int tid, data_size_t row_idx, int group, int sub_feature, double value) { feature_groups_[group]->PushData(tid, sub_feature, row_idx, value); } inline int RealFeatureIndex(int fidx) const { return real_feature_idx_[fidx]; } inline int InnerFeatureIndex(int col_idx) const { return used_feature_map_[col_idx]; } inline int Feature2Group(int feature_idx) const { return feature2group_[feature_idx]; } inline int Feture2SubFeature(int feature_idx) const { return feature2subfeature_[feature_idx]; } inline uint64_t GroupBinBoundary(int group_idx) const { return group_bin_boundaries_[group_idx]; } inline uint64_t NumTotalBin() const { return group_bin_boundaries_.back(); } inline std::vector<int> ValidFeatureIndices() const { std::vector<int> ret; for (int i = 0; i < num_total_features_; ++i) { if (used_feature_map_[i] >= 0) { ret.push_back(i); } } return ret; } void ReSize(data_size_t num_data); void CopySubset(const Dataset* fullset, const data_size_t* used_indices, data_size_t num_used_indices, bool need_meta_data); LIGHTGBM_EXPORT void FinishLoad(); LIGHTGBM_EXPORT bool SetFloatField(const char* field_name, const float* field_data, data_size_t num_element); LIGHTGBM_EXPORT bool SetDoubleField(const char* field_name, const double* field_data, data_size_t num_element); LIGHTGBM_EXPORT bool SetIntField(const char* field_name, const int* field_data, data_size_t num_element); LIGHTGBM_EXPORT bool GetFloatField(const char* field_name, data_size_t* out_len, const float** out_ptr); LIGHTGBM_EXPORT bool GetDoubleField(const char* field_name, data_size_t* out_len, const double** out_ptr); LIGHTGBM_EXPORT bool GetIntField(const char* field_name, data_size_t* out_len, const int** out_ptr); LIGHTGBM_EXPORT bool GetInt8Field(const char* field_name, data_size_t* out_len, const int8_t** out_ptr); /*! * \brief Save current dataset into binary file, will save to "filename.bin" */ LIGHTGBM_EXPORT void SaveBinaryFile(const char* bin_filename); LIGHTGBM_EXPORT void DumpTextFile(const char* text_filename); LIGHTGBM_EXPORT void CopyFeatureMapperFrom(const Dataset* dataset); LIGHTGBM_EXPORT void CreateValid(const Dataset* dataset); void ConstructHistograms(const std::vector<int8_t>& is_feature_used, const data_size_t* data_indices, data_size_t num_data, int leaf_idx, std::vector<std::unique_ptr<OrderedBin>>* ordered_bins, const score_t* gradients, const score_t* hessians, score_t* ordered_gradients, score_t* ordered_hessians, bool is_constant_hessian, HistogramBinEntry* histogram_data) const; void FixHistogram(int feature_idx, double sum_gradient, double sum_hessian, data_size_t num_data, HistogramBinEntry* data) const; inline data_size_t Split(int feature, const uint32_t* threshold, int num_threshold, bool default_left, data_size_t* data_indices, data_size_t num_data, data_size_t* lte_indices, data_size_t* gt_indices) const { const int group = feature2group_[feature]; const int sub_feature = feature2subfeature_[feature]; return feature_groups_[group]->Split(sub_feature, threshold, num_threshold, default_left, data_indices, num_data, lte_indices, gt_indices); } inline int SubFeatureBinOffset(int i) const { const int sub_feature = feature2subfeature_[i]; if (sub_feature == 0) { return 1; } else { return 0; } } inline int FeatureNumBin(int i) const { const int group = feature2group_[i]; const int sub_feature = feature2subfeature_[i]; return feature_groups_[group]->bin_mappers_[sub_feature]->num_bin(); } inline int8_t FeatureMonotone(int i) const { if (monotone_types_.empty()) { return 0; } else { return monotone_types_[i]; } } inline double FeaturePenalte(int i) const { if (feature_penalty_.empty()) { return 1; } else { return feature_penalty_[i]; } } bool HasMonotone() const { if (monotone_types_.empty()) { return false; } else { for (size_t i = 0; i < monotone_types_.size(); ++i) { if (monotone_types_[i] != 0) { return true; } } return false; } } inline int FeatureGroupNumBin(int group) const { return feature_groups_[group]->num_total_bin_; } inline const BinMapper* FeatureBinMapper(int i) const { const int group = feature2group_[i]; const int sub_feature = feature2subfeature_[i]; return feature_groups_[group]->bin_mappers_[sub_feature].get(); } inline const Bin* FeatureBin(int i) const { const int group = feature2group_[i]; return feature_groups_[group]->bin_data_.get(); } inline const Bin* FeatureGroupBin(int group) const { return feature_groups_[group]->bin_data_.get(); } inline bool FeatureGroupIsSparse(int group) const { return feature_groups_[group]->is_sparse_; } inline BinIterator* FeatureIterator(int i) const { const int group = feature2group_[i]; const int sub_feature = feature2subfeature_[i]; return feature_groups_[group]->SubFeatureIterator(sub_feature); } inline BinIterator* FeatureGroupIterator(int group) const { return feature_groups_[group]->FeatureGroupIterator(); } inline double RealThreshold(int i, uint32_t threshold) const { const int group = feature2group_[i]; const int sub_feature = feature2subfeature_[i]; return feature_groups_[group]->bin_mappers_[sub_feature]->BinToValue(threshold); } // given a real threshold, find the closest threshold bin inline uint32_t BinThreshold(int i, double threshold_double) const { const int group = feature2group_[i]; const int sub_feature = feature2subfeature_[i]; return feature_groups_[group]->bin_mappers_[sub_feature]->ValueToBin(threshold_double); } inline void CreateOrderedBins(std::vector<std::unique_ptr<OrderedBin>>* ordered_bins) const { ordered_bins->resize(num_groups_); OMP_INIT_EX(); #pragma omp parallel for schedule(guided) for (int i = 0; i < num_groups_; ++i) { OMP_LOOP_EX_BEGIN(); ordered_bins->at(i).reset(feature_groups_[i]->bin_data_->CreateOrderedBin()); OMP_LOOP_EX_END(); } OMP_THROW_EX(); } /*! * \brief Get meta data pointer * \return Pointer of meta data */ inline const Metadata& metadata() const { return metadata_; } /*! \brief Get Number of used features */ inline int num_features() const { return num_features_; } /*! \brief Get Number of feature groups */ inline int num_feature_groups() const { return num_groups_;} /*! \brief Get Number of total features */ inline int num_total_features() const { return num_total_features_; } /*! \brief Get the index of label column */ inline int label_idx() const { return label_idx_; } /*! \brief Get names of current data set */ inline const std::vector<std::string>& feature_names() const { return feature_names_; } inline void set_feature_names(const std::vector<std::string>& feature_names) { if (feature_names.size() != static_cast<size_t>(num_total_features_)) { Log::Fatal("Size of feature_names error, should equal with total number of features"); } feature_names_ = std::vector<std::string>(feature_names); // replace ' ' in feature_names with '_' bool spaceInFeatureName = false; for (auto& feature_name : feature_names_) { // check ascii if (!Common::CheckASCII(feature_name)) { Log::Fatal("Do not support non-ascii characters in feature name."); } if (feature_name.find(' ') != std::string::npos) { spaceInFeatureName = true; std::replace(feature_name.begin(), feature_name.end(), ' ', '_'); } } if (spaceInFeatureName) { Log::Warning("Find whitespaces in feature_names, replace with underlines"); } } inline std::vector<std::string> feature_infos() const { std::vector<std::string> bufs; for (int i = 0; i < num_total_features_; i++) { int fidx = used_feature_map_[i]; if (fidx == -1) { bufs.push_back("none"); } else { const auto bin_mapper = FeatureBinMapper(fidx); bufs.push_back(bin_mapper->bin_info()); } } return bufs; } void ResetConfig(const char* parameters); /*! \brief Get Number of data */ inline data_size_t num_data() const { return num_data_; } /*! \brief Disable copy */ Dataset& operator=(const Dataset&) = delete; /*! \brief Disable copy */ Dataset(const Dataset&) = delete; void addFeaturesFrom(Dataset* other); private: std::string data_filename_; /*! \brief Store used features */ std::vector<std::unique_ptr<FeatureGroup>> feature_groups_; /*! \brief Mapper from real feature index to used index*/ std::vector<int> used_feature_map_; /*! \brief Number of used features*/ int num_features_; /*! \brief Number of total features*/ int num_total_features_; /*! \brief Number of total data*/ data_size_t num_data_; /*! \brief Store some label level data*/ Metadata metadata_; /*! \brief index of label column */ int label_idx_ = 0; /*! \brief Threshold for treating a feature as a sparse feature */ double sparse_threshold_; /*! \brief store feature names */ std::vector<std::string> feature_names_; /*! \brief store feature names */ static const char* binary_file_token; int num_groups_; std::vector<int> real_feature_idx_; std::vector<int> feature2group_; std::vector<int> feature2subfeature_; std::vector<uint64_t> group_bin_boundaries_; std::vector<int> group_feature_start_; std::vector<int> group_feature_cnt_; std::vector<int8_t> monotone_types_; std::vector<double> feature_penalty_; bool is_finish_load_; int max_bin_; std::vector<int32_t> max_bin_by_feature_; std::vector<std::vector<double>> forced_bin_bounds_; int bin_construct_sample_cnt_; int min_data_in_bin_; bool use_missing_; bool zero_as_missing_; }; } // namespace LightGBM #endif // LightGBM_DATA_H_

dSchCompUdt-2Ddynamic.c

/*! \file Copyright (c) 2003, The Regents of the University of California, through Lawrence Berkeley National Laboratory (subject to receipt of any required approvals from U.S. Dept. of Energy) All rights reserved. The source code is distributed under BSD license, see the file License.txt at the top-level directory. */ /*! @file * \brief This file contains the main loop of pdgstrf which involves rank k * update of the Schur complement. * Uses 2D partitioning for the scatter phase. * * <pre> * -- Distributed SuperLU routine (version 5.4) -- * Lawrence Berkeley National Lab, Univ. of California Berkeley. * October 1, 2014 * * Modified: * September 14, 2017 * - First gather U-panel, then depending on "ldu" (excluding leading zeros), * gather only trailing columns of the L-panel corresponding to the nonzero * of U-rows. * - Padding zeros for nice dimensions of GEMM. * * June 1, 2018 add parallel AWPM pivoting; add back arrive_at_ublock() */ #define SCHEDULE_STRATEGY guided /* * Buffers: * [ lookAhead_L_buff | Remain_L_buff ] : stores the gathered L-panel * (A matrix in C := A*B ) * bigU : stores the U-panel (B matrix in C := A*B) * bigV : stores the block GEMM result (C matrix in C := A*B) */ if ( msg0 && msg2 ) { /* L(:,k) and U(k,:) are not empty. */ int cum_nrow = 0; /* cumulative number of nonzero rows in L(:,k) */ int temp_nbrow; /* nonzero rows in current block L(i,k) */ lptr = lptr0; luptr = luptr0; int Lnbrow, Rnbrow; /* number of nonzero rows in look-ahead window, and remaining part. */ /******************************************************************* * Separating L blocks into the top part within look-ahead window * and the remaining ones. *******************************************************************/ int lookAheadBlk=0, RemainBlk=0; tt_start = SuperLU_timer_(); /* Sherry -- can this loop be threaded?? */ /* Loop through all blocks in L(:,k) to set up pointers to the start * of each block in the data arrays. * - lookAheadFullRow[i] := number of nonzero rows from block 0 to i * - lookAheadStRow[i] := number of nonzero rows before block i * - lookAhead_lptr[i] := point to the start of block i in L's index[] * - (ditto Remain_Info[i]) */ for (int i = 0; i < nlb; ++i) { ib = lsub[lptr]; /* Block number of L(i,k). */ temp_nbrow = lsub[lptr+1]; /* Number of full rows. */ int look_up_flag = 1; /* assume ib is outside look-up window */ for (int j = k0+1; j < SUPERLU_MIN (k0 + num_look_aheads+2, nsupers ); ++j) { if ( ib == perm_c_supno[j] ) { look_up_flag = 0; /* flag ib within look-up window */ break; /* Sherry -- can exit the loop?? */ } } if ( look_up_flag == 0 ) { /* ib is within look-up window */ if (lookAheadBlk==0) { lookAheadFullRow[lookAheadBlk] = temp_nbrow; } else { lookAheadFullRow[lookAheadBlk] = temp_nbrow + lookAheadFullRow[lookAheadBlk-1]; } lookAheadStRow[lookAheadBlk] = cum_nrow; lookAhead_lptr[lookAheadBlk] = lptr; lookAhead_ib[lookAheadBlk] = ib; lookAheadBlk++; } else { /* ib is not in look-up window */ if ( RemainBlk==0 ) { Remain_info[RemainBlk].FullRow = temp_nbrow; } else { Remain_info[RemainBlk].FullRow = temp_nbrow + Remain_info[RemainBlk-1].FullRow; } RemainStRow[RemainBlk] = cum_nrow; // Remain_lptr[RemainBlk] = lptr; Remain_info[RemainBlk].lptr = lptr; // Remain_ib[RemainBlk] = ib; Remain_info[RemainBlk].ib = ib; RemainBlk++; } cum_nrow += temp_nbrow; lptr += LB_DESCRIPTOR; /* Skip descriptor. */ lptr += temp_nbrow; /* Move to next block */ luptr += temp_nbrow; } /* for i ... set up pointers for all blocks in L(:,k) */ lptr = lptr0; luptr = luptr0; /* leading dimension of L look-ahead buffer, same as Lnbrow */ //int LDlookAhead_LBuff = lookAheadBlk==0 ? 0 :lookAheadFullRow[lookAheadBlk-1]; Lnbrow = lookAheadBlk==0 ? 0 : lookAheadFullRow[lookAheadBlk-1]; /* leading dimension of L remaining buffer, same as Rnbrow */ //int LDRemain_LBuff = RemainBlk==0 ? 0 : Remain_info[RemainBlk-1].FullRow; Rnbrow = RemainBlk==0 ? 0 : Remain_info[RemainBlk-1].FullRow; /* assert( cum_nrow == (LDlookAhead_LBuff + LDRemain_LBuff) );*/ /* Piyush fix */ //int LDlookAhead_LBuff = lookAheadBlk==0? 0 : lookAheadFullRow[lookAheadBlk-1]; nbrow = Lnbrow + Rnbrow; /* total number of rows in L */ LookAheadRowSepMOP += 2*knsupc*(nbrow); /*********************************************** * Gather U blocks (AFTER LOOK-AHEAD WINDOW) * ***********************************************/ tt_start = SuperLU_timer_(); if ( nbrow > 0 ) { /* L(:,k) is not empty */ /* * Counting U blocks */ ldu = 0; /* Calculate ldu for U(k,:) after look-ahead window. */ ncols = 0; /* Total number of nonzero columns in U(k,:) */ int temp_ncols = 0; /* jj0 contains the look-ahead window that was updated in dlook_ahead_update.c. Now the search can continue from that point, not to start from block 0. */ #if 0 // Sherry comment out 5/21/208 /* Save pointers at location right after look-ahead window for later restart. */ iukp0 = iukp; rukp0 = rukp; #endif /* if ( iam==0 ) printf("--- k0 %d, k %d, jj0 %d, nub %d\n", k0, k, jj0, nub);*/ /* * Loop through all blocks in U(k,:) to set up pointers to the start * of each block in the data arrays, store them in Ublock_info[j] * for block U(k,j). */ for (j = jj0; j < nub; ++j) { /* jj0 starts after look-ahead window. */ temp_ncols = 0; #if 1 /* Cannot remove following call, since perm_u != Identity */ arrive_at_ublock( j, &iukp, &rukp, &jb, &ljb, &nsupc, iukp0, rukp0, usub, perm_u, xsup, grid ); #else jb = usub[iukp]; /* ljb = LBj (jb, grid); Local block number of U(k,j). */ nsupc = SuperSize(jb); iukp += UB_DESCRIPTOR; /* Start fstnz of block U(k,j). */ #endif Ublock_info[j].iukp = iukp; Ublock_info[j].rukp = rukp; Ublock_info[j].jb = jb; /* if ( iam==0 ) printf("j %d: Ublock_info[j].iukp %d, Ublock_info[j].rukp %d," "Ublock_info[j].jb %d, nsupc %d\n", j, Ublock_info[j].iukp, Ublock_info[j].rukp, Ublock_info[j].jb, nsupc); */ /* Prepare to call GEMM. */ jj = iukp; for (; jj < iukp+nsupc; ++jj) { segsize = klst - usub[jj]; if ( segsize ) { ++temp_ncols; if ( segsize > ldu ) ldu = segsize; } } Ublock_info[j].full_u_cols = temp_ncols; ncols += temp_ncols; #if 0 // Sherry comment out 5/31/2018 */ /* Jump number of nonzeros in block U(k,jj); Move to block U(k,j+1) in nzval[] array. */ rukp += usub[iukp - 1]; iukp += nsupc; #endif } /* end for j ... compute ldu & ncols */ /* Now doing prefix sum on full_u_cols. * After this, full_u_cols is the number of nonzero columns * from block 0 to block j. */ for ( j = jj0+1; j < nub; ++j) { Ublock_info[j].full_u_cols += Ublock_info[j-1].full_u_cols; } /* Padding zeros to make {m,n,k} multiple of vector length. */ jj = 8; //n; if (gemm_padding > 0 && Rnbrow > jj && ncols > jj && ldu > jj) { gemm_m_pad = Rnbrow + (Rnbrow % GEMM_PADLEN); gemm_n_pad = ncols + (ncols % GEMM_PADLEN); //gemm_n_pad = ncols; //gemm_k_pad = ldu + (ldu % GEMM_PADLEN); gemm_k_pad = ldu; for (i = Rnbrow; i < gemm_m_pad; ++i) // padding A matrix for (j = 0; j < gemm_k_pad; ++j) Remain_L_buff[i + j*gemm_m_pad] = zero; for (i = 0; i < Rnbrow; ++i) for (j = ldu; j < gemm_k_pad; ++j) Remain_L_buff[i + j*gemm_m_pad] = zero; for (i = ldu; i < gemm_k_pad; ++i) // padding B matrix for (j = 0; j < gemm_n_pad; ++j) bigU[i + j*gemm_k_pad] = zero; for (i = 0; i < ldu; ++i) for (j = ncols; j < gemm_n_pad; ++j) bigU[i + j*gemm_k_pad] = zero; } else { gemm_m_pad = Rnbrow; gemm_n_pad = ncols; gemm_k_pad = ldu; } tempu = bigU; /* buffer the entire row block U(k,:) */ /* Gather U(k,:) into buffer bigU[] to prepare for GEMM */ #ifdef _OPENMP #pragma omp parallel for firstprivate(iukp, rukp) \ private(j,tempu, jb, nsupc,ljb,segsize, lead_zero, jj, i) \ default (shared) schedule(SCHEDULE_STRATEGY) #endif for (j = jj0; j < nub; ++j) { /* jj0 starts after look-ahead window. */ if (j==jj0) tempu = bigU; //else tempu = bigU + ldu * Ublock_info[j-1].full_u_cols; else tempu = bigU + gemm_k_pad * Ublock_info[j-1].full_u_cols; /* == processing each of the remaining columns in parallel == */ #if 0 /* Can remove following call, since search was already done. */ arrive_at_ublock(j, &iukp, &rukp, &jb, &ljb, &nsupc, iukp0, rukp0, usub,perm_u, xsup, grid); #else iukp = Ublock_info[j].iukp; rukp = Ublock_info[j].rukp; jb = Ublock_info[j].jb; nsupc = SuperSize (jb ); #endif /* Copy from U(k,j) to tempu[], padding zeros. */ for (jj = iukp; jj < iukp+nsupc; ++jj) { segsize = klst - usub[jj]; if ( segsize ) { lead_zero = ldu - segsize; for (i = 0; i < lead_zero; ++i) tempu[i] = zero; //tempu += lead_zero; #if (_OPENMP>=201307) #pragma omp simd #endif for (i = 0; i < segsize; ++i) tempu[i+lead_zero] = uval[rukp+i]; rukp += segsize; tempu += gemm_k_pad; } } } /* parallel for j = jj0 .. nub */ #if 0 if (ldu==0) printf("[%d] .. k0 %d, before updating: ldu %d, Lnbrow %d, Rnbrow %d, ncols %d\n",iam,k0,ldu,Lnbrow,Rnbrow, ncols); fflush(stdout); #endif GatherMOP += 2*ldu*ncols; } /* end if (nbrow>0), end gather U blocks */ GatherUTimer += SuperLU_timer_() - tt_start; int jj_cpu = nub; /* limit between CPU and GPU */ int thread_id; /*tempv = bigV;*/ /********************** * Gather L blocks * **********************/ tt_start = SuperLU_timer_(); /* Loop through the look-ahead blocks to copy Lval into the buffer */ #ifdef _OPENMP #pragma omp parallel for private(j,jj,tempu,tempv) default (shared) #endif for (i = 0; i < lookAheadBlk; ++i) { int StRowDest, temp_nbrow; if ( i==0 ) { StRowDest = 0; temp_nbrow = lookAheadFullRow[0]; } else { StRowDest = lookAheadFullRow[i-1]; temp_nbrow = lookAheadFullRow[i]-lookAheadFullRow[i-1]; } int StRowSource = lookAheadStRow[i]; /* Now copying one block into L lookahead buffer */ /* #pragma omp parallel for (gives slow down) */ // for (int j = 0; j < knsupc; ++j) { for (j = knsupc-ldu; j < knsupc; ++j) { /* skip leading columns corresponding to zero U rows */ #if 1 /* Better let compiler generate memcpy or vectorized code. */ //tempu = &lookAhead_L_buff[StRowDest + j*LDlookAhead_LBuff]; //tempu = &lookAhead_L_buff[StRowDest + j * Lnbrow]; tempu = &lookAhead_L_buff[StRowDest + (j - (knsupc-ldu)) * Lnbrow]; tempv = &lusup[luptr+j*nsupr + StRowSource]; #if (_OPENMP>=201307) #pragma omp simd #endif for (jj = 0; jj < temp_nbrow; ++jj) tempu[jj] = tempv[jj]; #else //memcpy(&lookAhead_L_buff[StRowDest + j*LDlookAhead_LBuff], memcpy(&lookAhead_L_buff[StRowDest + (j - (knsupc-ldu)) * Lnbrow], &lusup[luptr+j*nsupr + StRowSource], temp_nbrow * sizeof(double) ); #endif } /* end for j ... */ } /* parallel for i ... gather Lval blocks from lookahead window */ /* Loop through the remaining blocks to copy Lval into the buffer */ #ifdef _OPENMP #pragma omp parallel for private(i,j,jj,tempu,tempv) default (shared) \ schedule(SCHEDULE_STRATEGY) #endif for (int i = 0; i < RemainBlk; ++i) { int StRowDest, temp_nbrow; if ( i==0 ) { StRowDest = 0; temp_nbrow = Remain_info[0].FullRow; } else { StRowDest = Remain_info[i-1].FullRow; temp_nbrow = Remain_info[i].FullRow - Remain_info[i-1].FullRow; } int StRowSource = RemainStRow[i]; /* Now copying a block into L remaining buffer */ // #pragma omp parallel for (gives slow down) // for (int j = 0; j < knsupc; ++j) { for (int j = knsupc-ldu; j < knsupc; ++j) { // printf("StRowDest %d Rnbrow %d StRowSource %d \n", StRowDest,Rnbrow ,StRowSource); #if 1 /* Better let compiler generate memcpy or vectorized code. */ //tempu = &Remain_L_buff[StRowDest + j*LDRemain_LBuff]; //tempu = &Remain_L_buff[StRowDest + (j - (knsupc-ldu)) * Rnbrow]; tempu = &Remain_L_buff[StRowDest + (j - (knsupc-ldu)) * gemm_m_pad]; tempv = &lusup[luptr + j*nsupr + StRowSource]; #if (_OPENMP>=201307) #pragma omp simd #endif for (jj = 0; jj < temp_nbrow; ++jj) tempu[jj] = tempv[jj]; #else //memcpy(&Remain_L_buff[StRowDest + j*LDRemain_LBuff], memcpy(&Remain_L_buff[StRowDest + (j - (knsupc-ldu)) * gemm_m_pad], &lusup[luptr+j*nsupr + StRowSource], temp_nbrow * sizeof(double) ); #endif } /* end for j ... */ } /* parallel for i ... copy Lval into the remaining buffer */ tt_end = SuperLU_timer_(); GatherLTimer += tt_end - tt_start; /************************************************************************* * Perform GEMM (look-ahead L part, and remain L part) followed by Scatter *************************************************************************/ tempu = bigU; /* setting to the start of padded U(k,:) */ if ( Lnbrow>0 && ldu>0 && ncols>0 ) { /* Both L(:,k) and U(k,:) nonempty */ /*************************************************************** * Updating blocks in look-ahead window of the LU(look-ahead-rows,:) ***************************************************************/ /* Count flops for total GEMM calls */ ncols = Ublock_info[nub-1].full_u_cols; flops_t flps = 2.0 * (flops_t)Lnbrow * ldu * ncols; LookAheadScatterMOP += 3 * Lnbrow * ncols; /* scatter-add */ schur_flop_counter += flps; stat->ops[FACT] += flps; LookAheadGEMMFlOp += flps; #ifdef _OPENMP #pragma omp parallel default (shared) private(thread_id) { thread_id = omp_get_thread_num(); /* Ideally, should organize the loop as: for (j = 0; j < nub; ++j) { for (lb = 0; lb < lookAheadBlk; ++lb) { L(lb,k) X U(k,j) -> tempv[] } } But now, we use collapsed loop to achieve more parallelism. Total number of block updates is: (# of lookAheadBlk in L(:,k)) X (# of blocks in U(k,:)) */ int i = sizeof(int); int* indirect_thread = indirect + (ldt + CACHELINE/i) * thread_id; int* indirect2_thread = indirect2 + (ldt + CACHELINE/i) * thread_id; #pragma omp for \ private (nsupc,ljb,lptr,ib,temp_nbrow,cum_nrow) \ schedule(dynamic) #else /* not use _OPENMP */ thread_id = 0; int* indirect_thread = indirect; int* indirect2_thread = indirect2; #endif /* Each thread is assigned one loop index ij, responsible for block update L(lb,k) * U(k,j) -> tempv[]. */ for (int ij = 0; ij < lookAheadBlk*(nub-jj0); ++ij) { /* jj0 starts after look-ahead window. */ int j = ij/lookAheadBlk + jj0; int lb = ij%lookAheadBlk; /* Getting U block U(k,j) information */ /* unsigned long long ut_start, ut_end; */ int_t rukp = Ublock_info[j].rukp; int_t iukp = Ublock_info[j].iukp; int jb = Ublock_info[j].jb; int nsupc = SuperSize(jb); int ljb = LBj (jb, grid); /* destination column block */ int st_col; int ncols; /* Local variable counts only columns in the block */ if ( j > jj0 ) { /* jj0 starts after look-ahead window. */ ncols = Ublock_info[j].full_u_cols-Ublock_info[j-1].full_u_cols; st_col = Ublock_info[j-1].full_u_cols; } else { ncols = Ublock_info[j].full_u_cols; st_col = 0; } /* Getting L block L(i,k) information */ int_t lptr = lookAhead_lptr[lb]; int ib = lookAhead_ib[lb]; int temp_nbrow = lsub[lptr+1]; lptr += LB_DESCRIPTOR; int cum_nrow = (lb==0 ? 0 : lookAheadFullRow[lb-1]); /* Block-by-block GEMM in look-ahead window */ #if 0 i = sizeof(double); double* tempv1 = bigV + thread_id * (ldt*ldt + CACHELINE/i); #else double* tempv1 = bigV + thread_id * (ldt*ldt); #endif #if ( PRNTlevel>= 1) if (thread_id == 0) tt_start = SuperLU_timer_(); gemm_max_m = SUPERLU_MAX(gemm_max_m, temp_nbrow); gemm_max_n = SUPERLU_MAX(gemm_max_n, ncols); gemm_max_k = SUPERLU_MAX(gemm_max_k, ldu); #endif #if defined (USE_VENDOR_BLAS) dgemm_("N", "N", &temp_nbrow, &ncols, &ldu, &alpha, //&lookAhead_L_buff[(knsupc-ldu)*Lnbrow+cum_nrow], &Lnbrow, &lookAhead_L_buff[cum_nrow], &Lnbrow, &tempu[st_col*ldu], &ldu, &beta, tempv1, &temp_nbrow, 1, 1); #else dgemm_("N", "N", &temp_nbrow, &ncols, &ldu, &alpha, //&lookAhead_L_buff[(knsupc-ldu)*Lnbrow+cum_nrow], &Lnbrow, &lookAhead_L_buff[cum_nrow], &Lnbrow, &tempu[st_col*ldu], &ldu, &beta, tempv1, &temp_nbrow); #endif #if (PRNTlevel>=1 ) if (thread_id == 0) { tt_end = SuperLU_timer_(); LookAheadGEMMTimer += tt_end - tt_start; tt_start = tt_end; } #endif if ( ib < jb ) { dscatter_u ( ib, jb, nsupc, iukp, xsup, klst, temp_nbrow, lptr, temp_nbrow, lsub, usub, tempv1, Ufstnz_br_ptr, Unzval_br_ptr, grid ); } else { #if 0 //#ifdef USE_VTUNE __SSC_MARK(0x111);// start SDE tracing, note uses 2 underscores __itt_resume(); // start VTune, again use 2 underscores #endif dscatter_l ( ib, ljb, nsupc, iukp, xsup, klst, temp_nbrow, lptr, temp_nbrow, usub, lsub, tempv1, indirect_thread, indirect2_thread, Lrowind_bc_ptr, Lnzval_bc_ptr, grid ); #if 0 //#ifdef USE_VTUNE __itt_pause(); // stop VTune __SSC_MARK(0x222); // stop SDE tracing #endif } #if ( PRNTlevel>=1 ) if (thread_id == 0) LookAheadScatterTimer += SuperLU_timer_() - tt_start; #endif } /* end omp for ij = ... */ #ifdef _OPENMP } /* end omp parallel */ #endif } /* end if Lnbrow>0 ... look-ahead GEMM and scatter */ /*************************************************************** * Updating remaining rows and columns on CPU. ***************************************************************/ ncols = jj_cpu==0 ? 0 : Ublock_info[jj_cpu-1].full_u_cols; if ( Rnbrow>0 && ldu>0 ) { /* There are still blocks remaining ... */ double flps = 2.0 * (double)Rnbrow * ldu * ncols; schur_flop_counter += flps; stat->ops[FACT] += flps; #if ( PRNTlevel>=1 ) RemainGEMM_flops += flps; gemm_max_m = SUPERLU_MAX(gemm_max_m, Rnbrow); gemm_max_n = SUPERLU_MAX(gemm_max_n, ncols); gemm_max_k = SUPERLU_MAX(gemm_max_k, ldu); tt_start = SuperLU_timer_(); /* printf("[%d] .. k0 %d, before large GEMM: %d-%d-%d, RemainBlk %d\n", iam, k0,Rnbrow,ldu,ncols,RemainBlk); fflush(stdout); assert( Rnbrow*ncols < bigv_size ); */ #endif /* calling aggregated large GEMM, result stored in bigV[]. */ #if defined (USE_VENDOR_BLAS) //dgemm_("N", "N", &Rnbrow, &ncols, &ldu, &alpha, dgemm_("N", "N", &gemm_m_pad, &gemm_n_pad, &gemm_k_pad, &alpha, //&Remain_L_buff[(knsupc-ldu)*Rnbrow], &Rnbrow, &Remain_L_buff[0], &gemm_m_pad, &bigU[0], &gemm_k_pad, &beta, bigV, &gemm_m_pad, 1, 1); #else //dgemm_("N", "N", &Rnbrow, &ncols, &ldu, &alpha, dgemm_("N", "N", &gemm_m_pad, &gemm_n_pad, &gemm_k_pad, &alpha, //&Remain_L_buff[(knsupc-ldu)*Rnbrow], &Rnbrow, &Remain_L_buff[0], &gemm_m_pad, &bigU[0], &gemm_k_pad, &beta, bigV, &gemm_m_pad); #endif #if ( PRNTlevel>=1 ) tt_end = SuperLU_timer_(); RemainGEMMTimer += tt_end - tt_start; #if ( PROFlevel>=1 ) //fprintf(fgemm, "%8d%8d%8d %16.8e\n", Rnbrow, ncols, ldu, // (tt_end - tt_start)*1e6); // time in microsecond //fflush(fgemm); gemm_stats[gemm_count].m = Rnbrow; gemm_stats[gemm_count].n = ncols; gemm_stats[gemm_count].k = ldu; gemm_stats[gemm_count++].microseconds = (tt_end - tt_start) * 1e6; #endif tt_start = SuperLU_timer_(); #endif #ifdef USE_VTUNE __SSC_MARK(0x111);// start SDE tracing, note uses 2 underscores __itt_resume(); // start VTune, again use 2 underscores #endif /* Scatter into destination block-by-block. */ #ifdef _OPENMP #pragma omp parallel default(shared) private(thread_id) { thread_id = omp_get_thread_num(); /* Ideally, should organize the loop as: for (j = 0; j < jj_cpu; ++j) { for (lb = 0; lb < RemainBlk; ++lb) { L(lb,k) X U(k,j) -> tempv[] } } But now, we use collapsed loop to achieve more parallelism. Total number of block updates is: (# of RemainBlk in L(:,k)) X (# of blocks in U(k,:)) */ int i = sizeof(int); int* indirect_thread = indirect + (ldt + CACHELINE/i) * thread_id; int* indirect2_thread = indirect2 + (ldt + CACHELINE/i) * thread_id; #pragma omp for \ private (j,lb,rukp,iukp,jb,nsupc,ljb,lptr,ib,temp_nbrow,cum_nrow) \ schedule(dynamic) #else /* not use _OPENMP */ thread_id = 0; int* indirect_thread = indirect; int* indirect2_thread = indirect2; #endif /* Each thread is assigned one loop index ij, responsible for block update L(lb,k) * U(k,j) -> tempv[]. */ for (int ij = 0; ij < RemainBlk*(jj_cpu-jj0); ++ij) { /* jj_cpu := nub, jj0 starts after look-ahead window. */ int j = ij / RemainBlk + jj0; /* j-th block in U panel */ int lb = ij % RemainBlk; /* lb-th block in L panel */ /* Getting U block U(k,j) information */ /* unsigned long long ut_start, ut_end; */ int_t rukp = Ublock_info[j].rukp; int_t iukp = Ublock_info[j].iukp; int jb = Ublock_info[j].jb; int nsupc = SuperSize(jb); int ljb = LBj (jb, grid); int st_col; int ncols; if ( j>jj0 ) { ncols = Ublock_info[j].full_u_cols - Ublock_info[j-1].full_u_cols; st_col = Ublock_info[j-1].full_u_cols; } else { ncols = Ublock_info[j].full_u_cols; st_col = 0; } /* Getting L block L(i,k) information */ int_t lptr = Remain_info[lb].lptr; int ib = Remain_info[lb].ib; int temp_nbrow = lsub[lptr+1]; lptr += LB_DESCRIPTOR; int cum_nrow = (lb==0 ? 0 : Remain_info[lb-1].FullRow); /* tempv1 points to block(i,j) in bigV : LDA == Rnbrow */ //double* tempv1 = bigV + (st_col * Rnbrow + cum_nrow); Sherry double* tempv1 = bigV + (st_col * gemm_m_pad + cum_nrow); /* Sherry */ // printf("[%d] .. before scatter: ib %d, jb %d, temp_nbrow %d, Rnbrow %d\n", iam, ib, jb, temp_nbrow, Rnbrow); fflush(stdout); /* Now scattering the block */ if ( ib < jb ) { dscatter_u ( ib, jb, nsupc, iukp, xsup, //klst, Rnbrow, /*** klst, temp_nbrow, Sherry */ klst, gemm_m_pad, /*** klst, temp_nbrow, Sherry */ lptr, temp_nbrow, /* row dimension of the block */ lsub, usub, tempv1, Ufstnz_br_ptr, Unzval_br_ptr, grid ); } else { dscatter_l( ib, ljb, nsupc, iukp, xsup, //klst, temp_nbrow, Sherry klst, gemm_m_pad, /*** temp_nbrow, Sherry */ lptr, temp_nbrow, /* row dimension of the block */ usub, lsub, tempv1, indirect_thread, indirect2_thread, Lrowind_bc_ptr,Lnzval_bc_ptr, grid ); } } /* end omp for (int ij =...) */ #ifdef _OPENMP } /* end omp parallel region */ #endif #if ( PRNTlevel>=1 ) RemainScatterTimer += SuperLU_timer_() - tt_start; #endif #ifdef USE_VTUNE __itt_pause(); // stop VTune __SSC_MARK(0x222); // stop SDE tracing #endif } /* end if Rnbrow>0 ... update remaining block */ } /* end if L(:,k) and U(k,:) are not empty */

LLT_ROF_core.c

/* This work is part of the Core Imaging Library developed by Visual Analytics and Imaging System Group of the Science Technology Facilities Council, STFC Copyright 2017 Daniil Kazantsev Copyright 2017 Srikanth Nagella, Edoardo Pasca Licensed under the Apache License, Version 2.0 (the "License"); you may not use this file except in compliance with the License. You may obtain a copy of the License at http://www.apache.org/licenses/LICENSE-2.0 Unless required by applicable law or agreed to in writing, software distributed under the License is distributed on an "AS IS" BASIS, WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. See the License for the specific language governing permissions and limitations under the License. */ #include "LLT_ROF_core.h" #define EPS_LLT 1.0e-12 #define EPS_ROF 1.0e-12 #define MAX(x, y) (((x) > (y)) ? (x) : (y)) #define MIN(x, y) (((x) < (y)) ? (x) : (y)) /*sign function*/ int signLLT(float x) { return (x > 0) - (x < 0); } /* C-OMP implementation of Lysaker, Lundervold and Tai (LLT) model [1] combined with Rudin-Osher-Fatemi [2] TV regularisation penalty. * * This penalty can deliver visually pleasant piecewise-smooth recovery if regularisation parameters are selected well. * The rule of thumb for selection is to start with lambdaLLT = 0 (just the ROF-TV model) and then proceed to increase * lambdaLLT starting with smaller values. * * Input Parameters: * 1. U0 - original noise image/volume * 2. lambdaROF - ROF-related regularisation parameter * 3. lambdaLLT - LLT-related regularisation parameter * 4. tau - time-marching step * 5. iter - iterations number (for both models) * 6. eplsilon: tolerance constant * * Output: * [1] Filtered/regularized image/volume * [2] Information vector which contains [iteration no., reached tolerance] * * References: * [1] Lysaker, M., Lundervold, A. and Tai, X.C., 2003. Noise removal using fourth-order partial differential equation with applications to medical magnetic resonance images in space and time. IEEE Transactions on image processing, 12(12), pp.1579-1590. * [2] Rudin, Osher, Fatemi, "Nonlinear Total Variation based noise removal algorithms" */ float LLT_ROF_CPU_main(float *Input, float *Output, float *infovector, float lambdaROF, float lambdaLLT, int iterationsNumb, float tau, float epsil, int dimX, int dimY, int dimZ) { long DimTotal; int ll, j; float re, re1; re = 0.0f; re1 = 0.0f; int count = 0; float *D1_LLT=NULL, *D2_LLT=NULL, *D3_LLT=NULL, *D1_ROF=NULL, *D2_ROF=NULL, *D3_ROF=NULL, *Output_prev=NULL; DimTotal = (long)(dimX*dimY*dimZ); D1_ROF = calloc(DimTotal, sizeof(float)); D2_ROF = calloc(DimTotal, sizeof(float)); D3_ROF = calloc(DimTotal, sizeof(float)); D1_LLT = calloc(DimTotal, sizeof(float)); D2_LLT = calloc(DimTotal, sizeof(float)); D3_LLT = calloc(DimTotal, sizeof(float)); copyIm(Input, Output, (long)(dimX), (long)(dimY), (long)(dimZ)); /* initialize */ if (epsil != 0.0f) Output_prev = calloc(DimTotal, sizeof(float)); for(ll = 0; ll < iterationsNumb; ll++) { if ((epsil != 0.0f) && (ll % 5 == 0)) copyIm(Output, Output_prev, (long)(dimX), (long)(dimY), (long)(dimZ)); if (dimZ == 1) { /* 2D case */ /****************ROF******************/ /* calculate first-order differences */ D1_func_ROF(Output, D1_ROF, (long)(dimX), (long)(dimY), 1l); D2_func_ROF(Output, D2_ROF, (long)(dimX), (long)(dimY), 1l); /****************LLT******************/ /* estimate second-order derrivatives */ der2D_LLT(Output, D1_LLT, D2_LLT, (long)(dimX), (long)(dimY), 1l); /* Joint update for ROF and LLT models */ Update2D_LLT_ROF(Input, Output, D1_LLT, D2_LLT, D1_ROF, D2_ROF, lambdaROF, lambdaLLT, tau, (long)(dimX), (long)(dimY), 1l); } else { /* 3D case */ /* calculate first-order differences */ D1_func_ROF(Output, D1_ROF, (long)(dimX), (long)(dimY), (long)(dimZ)); D2_func_ROF(Output, D2_ROF, (long)(dimX), (long)(dimY), (long)(dimZ)); D3_func_ROF(Output, D3_ROF, (long)(dimX), (long)(dimY), (long)(dimZ)); /****************LLT******************/ /* estimate second-order derrivatives */ der3D_LLT(Output, D1_LLT, D2_LLT, D3_LLT,(long)(dimX), (long)(dimY), (long)(dimZ)); /* Joint update for ROF and LLT models */ Update3D_LLT_ROF(Input, Output, D1_LLT, D2_LLT, D3_LLT, D1_ROF, D2_ROF, D3_ROF, lambdaROF, lambdaLLT, tau, (long)(dimX), (long)(dimY), (long)(dimZ)); } /* check early stopping criteria */ if ((epsil != 0.0f) && (ll % 5 == 0)) { re = 0.0f; re1 = 0.0f; for(j=0; j<DimTotal; j++) { re += powf(Output[j] - Output_prev[j],2); re1 += powf(Output[j],2); } re = sqrtf(re)/sqrtf(re1); if (re < epsil) count++; if (count > 3) break; } } /*end of iterations*/ free(D1_LLT);free(D2_LLT);free(D3_LLT); free(D1_ROF);free(D2_ROF);free(D3_ROF); if (epsil != 0.0f) free(Output_prev); /*adding info into info_vector */ infovector[0] = (float)(ll); /*iterations number (if stopped earlier based on tolerance)*/ infovector[1] = re; /* reached tolerance */ return 0; } /*************************************************************************/ /**********************LLT-related functions *****************************/ /*************************************************************************/ float der2D_LLT(float *U, float *D1, float *D2, long dimX, long dimY, long dimZ) { long i, j, index, i_p, i_m, j_m, j_p; float dxx, dyy, denom_xx, denom_yy; #pragma omp parallel for shared(U,D1,D2) private(i, j, index, i_p, i_m, j_m, j_p, denom_xx, denom_yy, dxx, dyy) for (i = 0; i<dimX; i++) { for (j = 0; j<dimY; j++) { index = j*dimX+i; /* symmetric boundary conditions (Neuman) */ i_p = i + 1; if (i_p == dimX) i_p = i - 1; i_m = i - 1; if (i_m < 0) i_m = i + 1; j_p = j + 1; if (j_p == dimY) j_p = j - 1; j_m = j - 1; if (j_m < 0) j_m = j + 1; dxx = U[j*dimX+i_p] - 2.0f*U[index] + U[j*dimX+i_m]; dyy = U[j_p*dimX+i] - 2.0f*U[index] + U[j_m*dimX+i]; denom_xx = fabs(dxx) + EPS_LLT; denom_yy = fabs(dyy) + EPS_LLT; D1[index] = dxx / denom_xx; D2[index] = dyy / denom_yy; } } return 1; } float der3D_LLT(float *U, float *D1, float *D2, float *D3, long dimX, long dimY, long dimZ) { long i, j, k, i_p, i_m, j_m, j_p, k_p, k_m, index; float dxx, dyy, dzz, denom_xx, denom_yy, denom_zz; #pragma omp parallel for shared(U,D1,D2,D3) private(i, j, index, k, i_p, i_m, j_m, j_p, k_p, k_m, denom_xx, denom_yy, denom_zz, dxx, dyy, dzz) for (i = 0; i<dimX; i++) { for (j = 0; j<dimY; j++) { for (k = 0; k<dimZ; k++) { /* symmetric boundary conditions (Neuman) */ i_p = i + 1; if (i_p == dimX) i_p = i - 1; i_m = i - 1; if (i_m < 0) i_m = i + 1; j_p = j + 1; if (j_p == dimY) j_p = j - 1; j_m = j - 1; if (j_m < 0) j_m = j + 1; k_p = k + 1; if (k_p == dimZ) k_p = k - 1; k_m = k - 1; if (k_m < 0) k_m = k + 1; index = (dimX*dimY)*k + j*dimX+i; dxx = U[(dimX*dimY)*k + j*dimX+i_p] - 2.0f*U[index] + U[(dimX*dimY)*k + j*dimX+i_m]; dyy = U[(dimX*dimY)*k + j_p*dimX+i] - 2.0f*U[index] + U[(dimX*dimY)*k + j_m*dimX+i]; dzz = U[(dimX*dimY)*k_p + j*dimX+i] - 2.0f*U[index] + U[(dimX*dimY)*k_m + j*dimX+i]; denom_xx = fabs(dxx) + EPS_LLT; denom_yy = fabs(dyy) + EPS_LLT; denom_zz = fabs(dzz) + EPS_LLT; D1[index] = dxx / denom_xx; D2[index] = dyy / denom_yy; D3[index] = dzz / denom_zz; } } } return 1; } /*************************************************************************/ /**********************ROF-related functions *****************************/ /*************************************************************************/ /* calculate differences 1 */ float D1_func_ROF(float *A, float *D1, long dimX, long dimY, long dimZ) { float NOMx_1, NOMy_1, NOMy_0, NOMz_1, NOMz_0, denom1, denom2,denom3, T1; long i,j,k,i1,i2,k1,j1,j2,k2,index; if (dimZ > 1) { #pragma omp parallel for shared (A, D1, dimX, dimY, dimZ) private(index, i, j, k, i1, j1, k1, i2, j2, k2, NOMx_1,NOMy_1,NOMy_0,NOMz_1,NOMz_0,denom1,denom2,denom3,T1) for(j=0; j<dimY; j++) { for(i=0; i<dimX; i++) { for(k=0; k<dimZ; k++) { index = (dimX*dimY)*k + j*dimX+i; /* symmetric boundary conditions (Neuman) */ i1 = i + 1; if (i1 >= dimX) i1 = i-1; i2 = i - 1; if (i2 < 0) i2 = i+1; j1 = j + 1; if (j1 >= dimY) j1 = j-1; j2 = j - 1; if (j2 < 0) j2 = j+1; k1 = k + 1; if (k1 >= dimZ) k1 = k-1; k2 = k - 1; if (k2 < 0) k2 = k+1; /* Forward-backward differences */ NOMx_1 = A[(dimX*dimY)*k + j1*dimX + i] - A[index]; /* x+ */ NOMy_1 = A[(dimX*dimY)*k + j*dimX + i1] - A[index]; /* y+ */ /*NOMx_0 = (A[(i)*dimY + j] - A[(i2)*dimY + j]); */ /* x- */ NOMy_0 = A[index] - A[(dimX*dimY)*k + j*dimX + i2]; /* y- */ NOMz_1 = A[(dimX*dimY)*k1 + j*dimX + i] - A[index]; /* z+ */ NOMz_0 = A[index] - A[(dimX*dimY)*k2 + j*dimX + i]; /* z- */ denom1 = NOMx_1*NOMx_1; denom2 = 0.5f*(signLLT(NOMy_1) + signLLT(NOMy_0))*(MIN(fabs(NOMy_1),fabs(NOMy_0))); denom2 = denom2*denom2; denom3 = 0.5f*(signLLT(NOMz_1) + signLLT(NOMz_0))*(MIN(fabs(NOMz_1),fabs(NOMz_0))); denom3 = denom3*denom3; T1 = sqrt(denom1 + denom2 + denom3 + EPS_ROF); D1[index] = NOMx_1/T1; }}} } else { #pragma omp parallel for shared (A, D1, dimX, dimY) private(i, j, i1, j1, i2, j2,NOMx_1,NOMy_1,NOMy_0,denom1,denom2,T1,index) for(j=0; j<dimY; j++) { for(i=0; i<dimX; i++) { index = j*dimX+i; /* symmetric boundary conditions (Neuman) */ i1 = i + 1; if (i1 >= dimX) i1 = i-1; i2 = i - 1; if (i2 < 0) i2 = i+1; j1 = j + 1; if (j1 >= dimY) j1 = j-1; j2 = j - 1; if (j2 < 0) j2 = j+1; /* Forward-backward differences */ NOMx_1 = A[j1*dimX + i] - A[index]; /* x+ */ NOMy_1 = A[j*dimX + i1] - A[index]; /* y+ */ /*NOMx_0 = (A[(i)*dimY + j] - A[(i2)*dimY + j]); */ /* x- */ NOMy_0 = A[index] - A[(j)*dimX + i2]; /* y- */ denom1 = NOMx_1*NOMx_1; denom2 = 0.5f*(signLLT(NOMy_1) + signLLT(NOMy_0))*(MIN(fabs(NOMy_1),fabs(NOMy_0))); denom2 = denom2*denom2; T1 = sqrtf(denom1 + denom2 + EPS_ROF); D1[index] = NOMx_1/T1; }} } return *D1; } /* calculate differences 2 */ float D2_func_ROF(float *A, float *D2, long dimX, long dimY, long dimZ) { float NOMx_1, NOMy_1, NOMx_0, NOMz_1, NOMz_0, denom1, denom2, denom3, T2; long i,j,k,i1,i2,k1,j1,j2,k2,index; if (dimZ > 1) { #pragma omp parallel for shared (A, D2, dimX, dimY, dimZ) private(index, i, j, k, i1, j1, k1, i2, j2, k2, NOMx_1, NOMy_1, NOMx_0, NOMz_1, NOMz_0, denom1, denom2, denom3, T2) for(j=0; j<dimY; j++) { for(i=0; i<dimX; i++) { for(k=0; k<dimZ; k++) { index = (dimX*dimY)*k + j*dimX+i; /* symmetric boundary conditions (Neuman) */ i1 = i + 1; if (i1 >= dimX) i1 = i-1; i2 = i - 1; if (i2 < 0) i2 = i+1; j1 = j + 1; if (j1 >= dimY) j1 = j-1; j2 = j - 1; if (j2 < 0) j2 = j+1; k1 = k + 1; if (k1 >= dimZ) k1 = k-1; k2 = k - 1; if (k2 < 0) k2 = k+1; /* Forward-backward differences */ NOMx_1 = A[(dimX*dimY)*k + (j1)*dimX + i] - A[index]; /* x+ */ NOMy_1 = A[(dimX*dimY)*k + (j)*dimX + i1] - A[index]; /* y+ */ NOMx_0 = A[index] - A[(dimX*dimY)*k + (j2)*dimX + i]; /* x- */ NOMz_1 = A[(dimX*dimY)*k1 + j*dimX + i] - A[index]; /* z+ */ NOMz_0 = A[index] - A[(dimX*dimY)*k2 + (j)*dimX + i]; /* z- */ denom1 = NOMy_1*NOMy_1; denom2 = 0.5f*(signLLT(NOMx_1) + signLLT(NOMx_0))*(MIN(fabs(NOMx_1),fabs(NOMx_0))); denom2 = denom2*denom2; denom3 = 0.5f*(signLLT(NOMz_1) + signLLT(NOMz_0))*(MIN(fabs(NOMz_1),fabs(NOMz_0))); denom3 = denom3*denom3; T2 = sqrtf(denom1 + denom2 + denom3 + EPS_ROF); D2[index] = NOMy_1/T2; }}} } else { #pragma omp parallel for shared (A, D2, dimX, dimY) private(i, j, i1, j1, i2, j2, NOMx_1,NOMy_1,NOMx_0,denom1,denom2,T2,index) for(j=0; j<dimY; j++) { for(i=0; i<dimX; i++) { index = j*dimX+i; /* symmetric boundary conditions (Neuman) */ i1 = i + 1; if (i1 >= dimX) i1 = i-1; i2 = i - 1; if (i2 < 0) i2 = i+1; j1 = j + 1; if (j1 >= dimY) j1 = j-1; j2 = j - 1; if (j2 < 0) j2 = j+1; /* Forward-backward differences */ NOMx_1 = A[j1*dimX + i] - A[index]; /* x+ */ NOMy_1 = A[j*dimX + i1] - A[index]; /* y+ */ NOMx_0 = A[index] - A[j2*dimX + i]; /* x- */ /*NOMy_0 = A[(i)*dimY + j] - A[(i)*dimY + j2]; */ /* y- */ denom1 = NOMy_1*NOMy_1; denom2 = 0.5f*(signLLT(NOMx_1) + signLLT(NOMx_0))*(MIN(fabs(NOMx_1),fabs(NOMx_0))); denom2 = denom2*denom2; T2 = sqrtf(denom1 + denom2 + EPS_ROF); D2[index] = NOMy_1/T2; }} } return *D2; } /* calculate differences 3 */ float D3_func_ROF(float *A, float *D3, long dimX, long dimY, long dimZ) { float NOMx_1, NOMy_1, NOMx_0, NOMy_0, NOMz_1, denom1, denom2, denom3, T3; long index,i,j,k,i1,i2,k1,j1,j2,k2; #pragma omp parallel for shared (A, D3, dimX, dimY, dimZ) private(index, i, j, k, i1, j1, k1, i2, j2, k2, NOMx_1, NOMy_1, NOMy_0, NOMx_0, NOMz_1, denom1, denom2, denom3, T3) for(j=0; j<dimY; j++) { for(i=0; i<dimX; i++) { for(k=0; k<dimZ; k++) { index = (dimX*dimY)*k + j*dimX+i; /* symmetric boundary conditions (Neuman) */ i1 = i + 1; if (i1 >= dimX) i1 = i-1; i2 = i - 1; if (i2 < 0) i2 = i+1; j1 = j + 1; if (j1 >= dimY) j1 = j-1; j2 = j - 1; if (j2 < 0) j2 = j+1; k1 = k + 1; if (k1 >= dimZ) k1 = k-1; k2 = k - 1; if (k2 < 0) k2 = k+1; /* Forward-backward differences */ NOMx_1 = A[(dimX*dimY)*k + (j1)*dimX + i] - A[index]; /* x+ */ NOMy_1 = A[(dimX*dimY)*k + (j)*dimX + i1] - A[index]; /* y+ */ NOMy_0 = A[index] - A[(dimX*dimY)*k + (j)*dimX + i2]; /* y- */ NOMx_0 = A[index] - A[(dimX*dimY)*k + (j2)*dimX + i]; /* x- */ NOMz_1 = A[(dimX*dimY)*k1 + j*dimX + i] - A[index]; /* z+ */ /*NOMz_0 = A[(dimX*dimY)*k + (i)*dimY + j] - A[(dimX*dimY)*k2 + (i)*dimY + j]; */ /* z- */ denom1 = NOMz_1*NOMz_1; denom2 = 0.5f*(signLLT(NOMx_1) + signLLT(NOMx_0))*(MIN(fabs(NOMx_1),fabs(NOMx_0))); denom2 = denom2*denom2; denom3 = 0.5f*(signLLT(NOMy_1) + signLLT(NOMy_0))*(MIN(fabs(NOMy_1),fabs(NOMy_0))); denom3 = denom3*denom3; T3 = sqrtf(denom1 + denom2 + denom3 + EPS_ROF); D3[index] = NOMz_1/T3; }}} return *D3; } /*************************************************************************/ /**********************ROF-LLT-related functions *************************/ /*************************************************************************/ float Update2D_LLT_ROF(float *U0, float *U, float *D1_LLT, float *D2_LLT, float *D1_ROF, float *D2_ROF, float lambdaROF, float lambdaLLT, float tau, long dimX, long dimY, long dimZ) { long i, j, index, i_p, i_m, j_m, j_p; float div, laplc, dxx, dyy, dv1, dv2; #pragma omp parallel for shared(U,U0) private(i, j, index, i_p, i_m, j_m, j_p, laplc, div, dxx, dyy, dv1, dv2) for (i = 0; i<dimX; i++) { for (j = 0; j<dimY; j++) { index = j*dimX+i; /* symmetric boundary conditions (Neuman) */ i_p = i + 1; if (i_p == dimX) i_p = i - 1; i_m = i - 1; if (i_m < 0) i_m = i + 1; j_p = j + 1; if (j_p == dimY) j_p = j - 1; j_m = j - 1; if (j_m < 0) j_m = j + 1; /*LLT-related part*/ dxx = D1_LLT[j*dimX+i_p] - 2.0f*D1_LLT[index] + D1_LLT[j*dimX+i_m]; dyy = D2_LLT[j_p*dimX+i] - 2.0f*D2_LLT[index] + D2_LLT[j_m*dimX+i]; laplc = dxx + dyy; /*build Laplacian*/ /*ROF-related part*/ dv1 = D1_ROF[index] - D1_ROF[j_m*dimX + i]; dv2 = D2_ROF[index] - D2_ROF[j*dimX + i_m]; div = dv1 + dv2; /*build Divirgent*/ /*combine all into one cost function to minimise */ U[index] += tau*(lambdaROF*(div) - lambdaLLT*(laplc) - (U[index] - U0[index])); } } return *U; } float Update3D_LLT_ROF(float *U0, float *U, float *D1_LLT, float *D2_LLT, float *D3_LLT, float *D1_ROF, float *D2_ROF, float *D3_ROF, float lambdaROF, float lambdaLLT, float tau, long dimX, long dimY, long dimZ) { long i, j, k, i_p, i_m, j_m, j_p, k_p, k_m, index; float div, laplc, dxx, dyy, dzz, dv1, dv2, dv3; #pragma omp parallel for shared(U,U0) private(i, j, k, index, i_p, i_m, j_m, j_p, k_p, k_m, laplc, div, dxx, dyy, dzz, dv1, dv2, dv3) for (i = 0; i<dimX; i++) { for (j = 0; j<dimY; j++) { for (k = 0; k<dimZ; k++) { /* symmetric boundary conditions (Neuman) */ i_p = i + 1; if (i_p == dimX) i_p = i - 1; i_m = i - 1; if (i_m < 0) i_m = i + 1; j_p = j + 1; if (j_p == dimY) j_p = j - 1; j_m = j - 1; if (j_m < 0) j_m = j + 1; k_p = k + 1; if (k_p == dimZ) k_p = k - 1; k_m = k - 1; if (k_m < 0) k_m = k + 1; index = (dimX*dimY)*k + j*dimX+i; /*LLT-related part*/ dxx = D1_LLT[(dimX*dimY)*k + j*dimX+i_p] - 2.0f*D1_LLT[index] + D1_LLT[(dimX*dimY)*k + j*dimX+i_m]; dyy = D2_LLT[(dimX*dimY)*k + j_p*dimX+i] - 2.0f*D2_LLT[index] + D2_LLT[(dimX*dimY)*k + j_m*dimX+i]; dzz = D3_LLT[(dimX*dimY)*k_p + j*dimX+i] - 2.0f*D3_LLT[index] + D3_LLT[(dimX*dimY)*k_m + j*dimX+i]; laplc = dxx + dyy + dzz; /*build Laplacian*/ /*ROF-related part*/ dv1 = D1_ROF[index] - D1_ROF[(dimX*dimY)*k + j_m*dimX+i]; dv2 = D2_ROF[index] - D2_ROF[(dimX*dimY)*k + j*dimX+i_m]; dv3 = D3_ROF[index] - D3_ROF[(dimX*dimY)*k_m + j*dimX+i]; div = dv1 + dv2 + dv3; /*build Divirgent*/ /*combine all into one cost function to minimise */ U[index] += tau*(lambdaROF*(div) - lambdaLLT*(laplc) - (U[index] - U0[index])); } } } return *U; }

io.c

/* -*- mode: C; tab-width: 2; indent-tabs-mode: nil; fill-column: 79; coding: iso-latin-1-unix -*- */ /* hpcc.c */ #include <hpcc.h> #include <ctype.h> #include <string.h> #include <time.h> #ifdef _OPENMP #include <omp.h> #endif static double HPCC_MemProc = -1.0, HPCC_MemVal = -1.0; static int HPCC_MemSpec = -1; static int ReadInts(char *buf, int n, int *val) { int i, j; for (j = i = 0; i < n; i++) { if (sscanf( buf + j, "%d", val + i ) != 1) { i--; break; } for (; buf[j] && isdigit(buf[j]); j++) ; /* EMPTY */ for (; buf[j] && ! isdigit(buf[j]); j++) ; /* EMPTY */ if (! buf[j]) { i--; break; } } return i + 1; } static int HPCC_InitHPL(HPCC_Params *p) { HPL_pdinfo( &p->test, &p->ns, p->nval, &p->nbs, p->nbval, &p->porder, &p->npqs, p->pval, p->qval, &p->npfs, p->pfaval, &p->nbms, p->nbmval, &p->ndvs, p->ndvval, &p->nrfs, p->rfaval, &p->ntps, p->topval, &p->ndhs, p->ndhval, &p->fswap, &p->tswap, &p->L1notran, &p->Unotran, &p->equil, &p->align ); if (p->test.thrsh <= 0.0) p->Failure = 1; return 0; } static int iiamax(int n, int *x, int incx) { int i, v, mx, idx = 0; idx = 0; mx = (x[0] < 0 ? -x[0] : x[0]); for (i = 0; i < n; i += incx) { v = (x[i] < 0 ? -x[i] : x[i]); if (mx < v) {mx = v; idx = i;} } return idx; } static void icopy(int n, int *src, int sinc, int *dst, int dinc) { int i; for (i = n; i; i--) { *dst = *src; dst += dinc; src += sinc; } } int HPCC_InputFileInit(HPCC_Params *params) { int myRank, commSize; int i, j, n, ioErr, lastConfigLine = 32, line, rv, maxHPLn; char buf[82]; int nbuf = 82; FILE *f, *outputFile; MPI_Comm comm = MPI_COMM_WORLD; MPI_Comm_size( comm, &commSize ); MPI_Comm_rank( comm, &myRank ); if (0 == myRank) { f = fopen( params->inFname, "r" ); if (! f) { ioErr = 1; goto ioEnd; } /* skip irrelevant lines in config file */ for (line = 0; line < lastConfigLine; line++) if (! fgets( buf, nbuf, f )) break; if (line < lastConfigLine) { /* if didn't read all the required lines */ ioErr = 1; goto ioEnd; } /* Get values of N for PTRANS */ line++; fgets( buf, nbuf, f ); rv = sscanf( buf, "%d", &n ); if (rv != 1 || n < 0) { /* parse error or negative value*/ n = 0; BEGIN_IO(myRank, params->outFname, outputFile); fprintf( outputFile, "Error in line %d of the input file.\n", line ); END_IO( myRank, outputFile ); } n = Mmin( n, HPL_MAX_PARAM ); line++; fgets( buf, nbuf, f ); ReadInts( buf, n, params->PTRANSnval ); /* find the largest matrix for HPL */ maxHPLn = params->nval[iiamax( params->ns, params->nval, 1 )]; for (j = i = 0; i < n; i++) { /* if memory for PTRANS is at least 90% of what's used for HPL */ if (params->PTRANSnval[i] >= 0.9486 * maxHPLn * 0.5) { params->PTRANSnval[j] = params->PTRANSnval[i]; j++; } } n = j; /* only this many entries use enough memory */ /* copy matrix sizes from HPL, divide by 2 so both PTRANS matrices (plus "work" arrays) occupy as much as HPL's one */ for (i = 0; i < params->ns; i++) params->PTRANSnval[i + n] = params->nval[i] / 2; params->PTRANSns = n + params->ns; /* Get values of block sizes */ line++; fgets( buf, nbuf, f ); rv = sscanf( buf, "%d", &n ); if (rv != 1 || n < 0) { /* parse error or negative value*/ n = 0; BEGIN_IO( myRank, params->outFname, outputFile ); fprintf( outputFile, "Error in line %d of the input file.\n", line ); END_IO( myRank, outputFile ); } n = Mmin( n, HPL_MAX_PARAM ); line++; fgets( buf, nbuf, f ); ReadInts( buf, n, params->PTRANSnbval ); icopy( params->nbs, params->nbval, 1, params->PTRANSnbval + n, 1 ); params->PTRANSnbs = n + params->nbs; ioErr = 0; ioEnd: if (f) fclose( f ); } MPI_Bcast( &ioErr, 1, MPI_INT, 0, comm ); if (ioErr) { /* copy matrix sizes from HPL, divide by 2 so both PTRANS matrices (plus "work" arrays) occupy as much as HPL's one */ for (i = 0; i < params->ns; i++) params->PTRANSnval[i] = params->nval[i] / 2; params->PTRANSns = params->ns; icopy( params->nbs, params->nbval, 1, params->PTRANSnbval, 1 ); params->PTRANSnbs = params->nbs; } /* broadcast what's been read on node 0 */ MPI_Bcast( &params->PTRANSns, 1, MPI_INT, 0, comm ); if (params->PTRANSns > 0) MPI_Bcast( &params->PTRANSnval, params->PTRANSns, MPI_INT, 0, comm ); MPI_Bcast( &params->PTRANSnbs, 1, MPI_INT, 0, comm ); if (params->PTRANSnbs > 0) MPI_Bcast( &params->PTRANSnbval, params->PTRANSnbs, MPI_INT, 0, comm ); /* copy what HPL has */ params->PTRANSnpqs = params->npqs; icopy( params->npqs, params->qval, 1, params->PTRANSqval, 1 ); icopy( params->npqs, params->pval, 1, params->PTRANSpval, 1 ); return ioErr; } static int ErrorReduce(FILE *f, char *str, int eCode, MPI_Comm comm) { int rCode; if (eCode) eCode = 1; /* make sure error is indicated with 1 */ MPI_Allreduce( &eCode, &rCode, 1, MPI_INT, MPI_SUM, comm ); if (rCode) { if (f) fprintf( f, "%s", str ); return -1; } return 0; } int HPCC_Init(HPCC_Params *params) { int myRank, commSize; int i, nMax, nbMax, procCur, procMax, procMin, errCode; double totalMem; char inFname[12] = "hpccinf.txt", outFname[13] = "hpccoutf.txt"; FILE *outputFile; MPI_Comm comm = MPI_COMM_WORLD; time_t currentTime; char hostname[MPI_MAX_PROCESSOR_NAME + 1]; int hostnameLen; #ifdef HPCC_MEMALLCTR size_t hpl_mem, ptrans_mem; long dMemSize; #endif outputFile = NULL; MPI_Comm_size( comm, &commSize ); MPI_Comm_rank( comm, &myRank ); strcpy( params->inFname, inFname ); strcpy( params->outFname, outFname ); if (0 == myRank) outputFile = fopen( params->outFname, "a" ); errCode = 0; if (sizeof(u64Int) < 8 || sizeof(s64Int) < 8) errCode = 1; if (ErrorReduce( outputFile, "No 64-bit integer type available.", errCode, comm )) return -1; i = MPI_Get_processor_name( hostname, &hostnameLen ); if (i) hostname[0] = 0; else hostname[Mmax(hostnameLen, MPI_MAX_PROCESSOR_NAME)] = 0; time( &currentTime ); BEGIN_IO( myRank, params->outFname, outputFile ); fprintf( outputFile, "########################################################################\n" ); fprintf( outputFile, "This is the DARPA/DOE HPC Challenge Benchmark version %d.%d.%d October 2012\n", HPCC_VERSION_MAJOR, HPCC_VERSION_MINOR, HPCC_VERSION_MICRO ); fprintf( outputFile, "Produced by Jack Dongarra and Piotr Luszczek\n" ); fprintf( outputFile, "Innovative Computing Laboratory\n" ); fprintf( outputFile, "University of Tennessee Knoxville and Oak Ridge National Laboratory\n\n" ); fprintf( outputFile, "See the source files for authors of specific codes.\n" ); fprintf( outputFile, "Compiled on %s at %s\n", __DATE__ , __TIME__ ); fprintf( outputFile, "Current time (%ld) is %s\n",(long)currentTime,ctime(&currentTime)); fprintf( outputFile, "Hostname: '%s'\n", hostname ); fprintf( outputFile, "########################################################################\n" ); END_IO( myRank, outputFile ); params->Failure = 0; HPCC_InitHPL( params ); /* HPL calls exit() if there is a problem */ HPCC_InputFileInit( params ); params->RunHPL = 0; params->RunStarDGEMM = 0; params->RunSingleDGEMM = 0; params->RunPTRANS = 0; params->RunStarStream = 0; params->RunSingleStream = 0; params->RunMPIRandomAccess_LCG = 0; params->RunStarRandomAccess_LCG = 0; params->RunSingleRandomAccess_LCG = 0; params->RunMPIRandomAccess = 0; params->RunStarRandomAccess = 0; params->RunSingleRandomAccess = 0; params->RunLatencyBandwidth = 0; params->RunMPIFFT = 0; params->RunStarFFT = 0; params->RunSingleFFT = 0; params->RunHPL = params->RunStarDGEMM = params->RunSingleDGEMM = params->RunPTRANS = params->RunStarStream = params->RunSingleStream = params->RunMPIRandomAccess_LCG = params->RunStarRandomAccess_LCG = params->RunSingleRandomAccess_LCG = params->RunMPIRandomAccess = params->RunStarRandomAccess = params->RunSingleRandomAccess = params->RunMPIFFT = params->RunStarFFT = params->RunSingleFFT = params->RunLatencyBandwidth = 1; params->MPIRandomAccess_LCG_GUPs = params->MPIRandomAccess_GUPs = params->StarGUPs = params->SingleGUPs = params->StarDGEMMGflops = params->SingleDGEMMGflops = -1.0; params->StarStreamCopyGBs = params->StarStreamScaleGBs = params->StarStreamAddGBs = params->StarStreamTriadGBs = params->SingleStreamCopyGBs = params->SingleStreamScaleGBs = params->SingleStreamAddGBs = params->SingleStreamTriadGBs = params->SingleFFTGflops = params->StarFFTGflops = params->MPIFFTGflops = params->MPIFFT_maxErr = params->MaxPingPongLatency = params-> RandomlyOrderedRingLatency = params-> MinPingPongBandwidth = params->NaturallyOrderedRingBandwidth = params->RandomlyOrderedRingBandwidth = params->MinPingPongLatency = params->AvgPingPongLatency = params->MaxPingPongBandwidth = params->AvgPingPongBandwidth = params->NaturallyOrderedRingLatency = -1.0; params->HPLrdata.Gflops = -1000.0; params->HPLrdata.time = params->HPLrdata.eps = params->HPLrdata.RnormI = params->HPLrdata.Anorm1 = params->HPLrdata.AnormI = params->HPLrdata.Xnorm1 = params->HPLrdata.XnormI = -1.0; params->HPLrdata.N = params->HPLrdata.NB = params->HPLrdata.nprow = params->HPLrdata.npcol = params->HPLrdata.depth = params->HPLrdata.nbdiv = params->HPLrdata.nbmin = -1; params->HPLrdata.cpfact = params->HPLrdata.crfact = params->HPLrdata.ctop = params->HPLrdata.order = '-'; params->PTRANSrdata.GBs = params->PTRANSrdata.time = params->PTRANSrdata.residual = -1.0; params->PTRANSrdata.n = params->PTRANSrdata.nb = params->PTRANSrdata.nprow = params->PTRANSrdata.npcol = -1; params->MPIRandomAccess_LCG_ErrorsFraction = params->MPIRandomAccess_ErrorsFraction = params->MPIRandomAccess_LCG_time = params->MPIRandomAccess_LCG_CheckTime = params->MPIRandomAccess_time = params->MPIRandomAccess_CheckTime = params->MPIRandomAccess_LCG_TimeBound = params->MPIRandomAccess_TimeBound = -1.0; params->DGEMM_N = params->FFT_N = params->StreamVectorSize = params->MPIRandomAccess_LCG_Algorithm = params->MPIRandomAccess_Algorithm = params->MPIFFT_Procs = -1; params->StreamThreads = 1; params->FFTEnblk = params->FFTEnp = params->FFTEl2size = -1; params->MPIFFT_N = params->RandomAccess_LCG_N = params->MPIRandomAccess_LCG_N = params->MPIRandomAccess_LCG_Errors = params->RandomAccess_N = params->MPIRandomAccess_N = params->MPIRandomAccess_Errors = params->MPIRandomAccess_LCG_ExeUpdates = params->MPIRandomAccess_ExeUpdates = (s64Int)(-1); procMax = procMin = params->pval[0] * params->qval[0]; for (i = 1; i < params->npqs; ++i) { procCur = params->pval[i] * params->qval[i]; if (procMax < procCur) procMax = procCur; if (procMin > procCur) procMin = procCur; } params->HPLMaxProc = procMax; params->HPLMinProc = procMin; nMax = params->nval[iiamax( params->ns, params->nval, 1 )]; /* totalMem = (nMax*nMax) * sizeof(double) */ totalMem = nMax; totalMem *= nMax; totalMem *= sizeof(double); params->HPLMaxProcMem = totalMem / procMin; for (i = 0; i < MPIFFT_TIMING_COUNT; i++) params->MPIFFTtimingsForward[i] = 0.0; i = iiamax( params->PTRANSnbs, params->PTRANSnbval, 1 ); nbMax = params->PTRANSnbval[i]; #ifdef HPCC_MEMALLCTR MaxMem( commSize, 0, 0, params->PTRANSns, params->PTRANSnval, params->PTRANSnval, params->PTRANSnbs, params->PTRANSnbval, params->PTRANSnbval, params->PTRANSnpqs, params->PTRANSpval, params->PTRANSqval, &dMemSize ); ptrans_mem = dMemSize * sizeof(double) + 3 * commSize * sizeof(int); hpl_mem = params->HPLMaxProcMem + (nMax + nbMax) * sizeof(double) * nbMax; HPCC_alloc_init( Mmax( ptrans_mem, hpl_mem ) ); #endif return 0; } int HPCC_Finalize(HPCC_Params *params) { int myRank, commSize; int i; FILE *outputFile; MPI_Comm comm = MPI_COMM_WORLD; time_t currentTime; #ifdef HPCC_MEMALLCTR HPCC_alloc_finalize(); #endif time( &currentTime ); MPI_Comm_rank( comm, &myRank ); MPI_Comm_size( comm, &commSize ); BEGIN_IO(myRank, params->outFname, outputFile); fprintf( outputFile, "Begin of Summary section.\n" ); fprintf( outputFile, "VersionMajor=%d\n", HPCC_VERSION_MAJOR ); fprintf( outputFile, "VersionMinor=%d\n", HPCC_VERSION_MINOR ); fprintf( outputFile, "VersionMicro=%d\n", HPCC_VERSION_MICRO ); fprintf( outputFile, "VersionRelease=%c\n", HPCC_VERSION_RELEASE ); fprintf( outputFile, "LANG=%s\n", "C" ); fprintf( outputFile, "Success=%d\n", params->Failure ? 0 : 1 ); fprintf( outputFile, "sizeof_char=%d\n", (int)sizeof(char) ); fprintf( outputFile, "sizeof_short=%d\n", (int)sizeof(short) ); fprintf( outputFile, "sizeof_int=%d\n", (int)sizeof(int) ); fprintf( outputFile, "sizeof_long=%d\n", (int)sizeof(long) ); fprintf( outputFile, "sizeof_void_ptr=%d\n", (int)sizeof(void*) ); fprintf( outputFile, "sizeof_size_t=%d\n", (int)sizeof(size_t) ); fprintf( outputFile, "sizeof_float=%d\n", (int)sizeof(float) ); fprintf( outputFile, "sizeof_double=%d\n", (int)sizeof(double) ); fprintf( outputFile, "sizeof_s64Int=%d\n", (int)sizeof(s64Int) ); fprintf( outputFile, "sizeof_u64Int=%d\n", (int)sizeof(u64Int) ); fprintf( outputFile, "sizeof_struct_double_double=%d\n", (int)sizeof(struct{double HPCC_r,HPCC_i;}) ); fprintf( outputFile, "CommWorldProcs=%d\n", commSize ); fprintf( outputFile, "MPI_Wtick=%e\n", MPI_Wtick() ); fprintf( outputFile, "HPL_Tflops=%g\n", params->HPLrdata.Gflops * 1e-3 ); fprintf( outputFile, "HPL_time=%g\n", params->HPLrdata.time ); fprintf( outputFile, "HPL_eps=%g\n", params->HPLrdata.eps ); fprintf( outputFile, "HPL_RnormI=%g\n", params->HPLrdata.RnormI ); fprintf( outputFile, "HPL_Anorm1=%g\n", params->HPLrdata.Anorm1 ); fprintf( outputFile, "HPL_AnormI=%g\n", params->HPLrdata.AnormI ); fprintf( outputFile, "HPL_Xnorm1=%g\n", params->HPLrdata.Xnorm1 ); fprintf( outputFile, "HPL_XnormI=%g\n", params->HPLrdata.XnormI ); fprintf( outputFile, "HPL_BnormI=%g\n", params->HPLrdata.BnormI ); fprintf( outputFile, "HPL_N=%d\n", params->HPLrdata.N ); fprintf( outputFile, "HPL_NB=%d\n", params->HPLrdata.NB ); fprintf( outputFile, "HPL_nprow=%d\n", params->HPLrdata.nprow ); fprintf( outputFile, "HPL_npcol=%d\n", params->HPLrdata.npcol ); fprintf( outputFile, "HPL_depth=%d\n", params->HPLrdata.depth ); fprintf( outputFile, "HPL_nbdiv=%d\n", params->HPLrdata.nbdiv ); fprintf( outputFile, "HPL_nbmin=%d\n", params->HPLrdata.nbmin ); fprintf( outputFile, "HPL_cpfact=%c\n", params->HPLrdata.cpfact ); fprintf( outputFile, "HPL_crfact=%c\n", params->HPLrdata.crfact ); fprintf( outputFile, "HPL_ctop=%c\n", params->HPLrdata.ctop ); fprintf( outputFile, "HPL_order=%c\n", params->HPLrdata.order ); fprintf( outputFile, "HPL_dMACH_EPS=%e\n", HPL_dlamch( HPL_MACH_EPS ) ); fprintf( outputFile, "HPL_dMACH_SFMIN=%e\n",HPL_dlamch( HPL_MACH_SFMIN ) ); fprintf( outputFile, "HPL_dMACH_BASE=%e\n", HPL_dlamch( HPL_MACH_BASE ) ); fprintf( outputFile, "HPL_dMACH_PREC=%e\n", HPL_dlamch( HPL_MACH_PREC ) ); fprintf( outputFile, "HPL_dMACH_MLEN=%e\n", HPL_dlamch( HPL_MACH_MLEN ) ); fprintf( outputFile, "HPL_dMACH_RND=%e\n", HPL_dlamch( HPL_MACH_RND ) ); fprintf( outputFile, "HPL_dMACH_EMIN=%e\n", HPL_dlamch( HPL_MACH_EMIN ) ); fprintf( outputFile, "HPL_dMACH_RMIN=%e\n", HPL_dlamch( HPL_MACH_RMIN ) ); fprintf( outputFile, "HPL_dMACH_EMAX=%e\n", HPL_dlamch( HPL_MACH_EMAX ) ); fprintf( outputFile, "HPL_dMACH_RMAX=%e\n", HPL_dlamch( HPL_MACH_RMAX ) ); fprintf( outputFile, "HPL_sMACH_EPS=%e\n", (double)HPL_slamch( HPL_MACH_EPS ) ); fprintf( outputFile, "HPL_sMACH_SFMIN=%e\n",(double)HPL_slamch( HPL_MACH_SFMIN ) ); fprintf( outputFile, "HPL_sMACH_BASE=%e\n", (double)HPL_slamch( HPL_MACH_BASE ) ); fprintf( outputFile, "HPL_sMACH_PREC=%e\n", (double)HPL_slamch( HPL_MACH_PREC ) ); fprintf( outputFile, "HPL_sMACH_MLEN=%e\n", (double)HPL_slamch( HPL_MACH_MLEN ) ); fprintf( outputFile, "HPL_sMACH_RND=%e\n", (double)HPL_slamch( HPL_MACH_RND ) ); fprintf( outputFile, "HPL_sMACH_EMIN=%e\n", (double)HPL_slamch( HPL_MACH_EMIN ) ); fprintf( outputFile, "HPL_sMACH_RMIN=%e\n", (double)HPL_slamch( HPL_MACH_RMIN ) ); fprintf( outputFile, "HPL_sMACH_EMAX=%e\n", (double)HPL_slamch( HPL_MACH_EMAX ) ); fprintf( outputFile, "HPL_sMACH_RMAX=%e\n", (double)HPL_slamch( HPL_MACH_RMAX ) ); fprintf( outputFile, "dweps=%e\n", HPCC_dweps() ); fprintf( outputFile, "sweps=%e\n", (double)HPCC_sweps() ); fprintf( outputFile, "HPLMaxProcs=%d\n", params->HPLMaxProc ); fprintf( outputFile, "HPLMinProcs=%d\n", params->HPLMinProc ); fprintf( outputFile, "DGEMM_N=%d\n", params->DGEMM_N ); fprintf( outputFile, "StarDGEMM_Gflops=%g\n", params->StarDGEMMGflops ); fprintf( outputFile, "SingleDGEMM_Gflops=%g\n", params->SingleDGEMMGflops ); fprintf( outputFile, "PTRANS_GBs=%g\n", params->PTRANSrdata.GBs ); fprintf( outputFile, "PTRANS_time=%g\n", params->PTRANSrdata.time ); fprintf( outputFile, "PTRANS_residual=%g\n", params->PTRANSrdata.residual ); fprintf( outputFile, "PTRANS_n=%d\n", params->PTRANSrdata.n ); fprintf( outputFile, "PTRANS_nb=%d\n", params->PTRANSrdata.nb ); fprintf( outputFile, "PTRANS_nprow=%d\n", params->PTRANSrdata.nprow ); fprintf( outputFile, "PTRANS_npcol=%d\n", params->PTRANSrdata.npcol ); fprintf( outputFile, "MPIRandomAccess_LCG_N=" FSTR64 "\n", params->MPIRandomAccess_LCG_N ); fprintf( outputFile, "MPIRandomAccess_LCG_time=%g\n", params->MPIRandomAccess_LCG_time ); fprintf( outputFile, "MPIRandomAccess_LCG_CheckTime=%g\n", params->MPIRandomAccess_LCG_CheckTime ); fprintf( outputFile, "MPIRandomAccess_LCG_Errors=" FSTR64 "\n", params->MPIRandomAccess_LCG_Errors ); fprintf( outputFile, "MPIRandomAccess_LCG_ErrorsFraction=%g\n", params->MPIRandomAccess_LCG_ErrorsFraction ); fprintf( outputFile, "MPIRandomAccess_LCG_ExeUpdates=" FSTR64 "\n", params->MPIRandomAccess_LCG_ExeUpdates ); fprintf( outputFile, "MPIRandomAccess_LCG_GUPs=%g\n", params->MPIRandomAccess_LCG_GUPs ); fprintf( outputFile, "MPIRandomAccess_LCG_TimeBound=%g\n", params->MPIRandomAccess_LCG_TimeBound ); fprintf( outputFile, "MPIRandomAccess_LCG_Algorithm=%d\n", params->MPIRandomAccess_LCG_Algorithm ); fprintf( outputFile, "MPIRandomAccess_N=" FSTR64 "\n", params->MPIRandomAccess_N ); fprintf( outputFile, "MPIRandomAccess_time=%g\n", params->MPIRandomAccess_time ); fprintf( outputFile, "MPIRandomAccess_CheckTime=%g\n", params->MPIRandomAccess_CheckTime ); fprintf( outputFile, "MPIRandomAccess_Errors=" FSTR64 "\n", params->MPIRandomAccess_Errors ); fprintf( outputFile, "MPIRandomAccess_ErrorsFraction=%g\n", params->MPIRandomAccess_ErrorsFraction ); fprintf( outputFile, "MPIRandomAccess_ExeUpdates=" FSTR64 "\n", params->MPIRandomAccess_ExeUpdates ); fprintf( outputFile, "MPIRandomAccess_GUPs=%g\n", params->MPIRandomAccess_GUPs ); fprintf( outputFile, "MPIRandomAccess_TimeBound=%g\n", params->MPIRandomAccess_TimeBound ); fprintf( outputFile, "MPIRandomAccess_Algorithm=%d\n", params->MPIRandomAccess_Algorithm ); fprintf( outputFile, "RandomAccess_LCG_N=" FSTR64 "\n", params->RandomAccess_LCG_N ); fprintf( outputFile, "StarRandomAccess_LCG_GUPs=%g\n", params->Star_LCG_GUPs ); fprintf( outputFile, "SingleRandomAccess_LCG_GUPs=%g\n", params->Single_LCG_GUPs ); fprintf( outputFile, "RandomAccess_N=" FSTR64 "\n", params->RandomAccess_N ); fprintf( outputFile, "StarRandomAccess_GUPs=%g\n", params->StarGUPs ); fprintf( outputFile, "SingleRandomAccess_GUPs=%g\n", params->SingleGUPs ); fprintf( outputFile, "STREAM_VectorSize=%d\n", params->StreamVectorSize ); fprintf( outputFile, "STREAM_Threads=%d\n", params->StreamThreads ); fprintf( outputFile, "StarSTREAM_Copy=%g\n", params->StarStreamCopyGBs ); fprintf( outputFile, "StarSTREAM_Scale=%g\n", params->StarStreamScaleGBs ); fprintf( outputFile, "StarSTREAM_Add=%g\n", params->StarStreamAddGBs ); fprintf( outputFile, "StarSTREAM_Triad=%g\n", params->StarStreamTriadGBs ); fprintf( outputFile, "SingleSTREAM_Copy=%g\n", params->SingleStreamCopyGBs ); fprintf( outputFile, "SingleSTREAM_Scale=%g\n", params->SingleStreamScaleGBs ); fprintf( outputFile, "SingleSTREAM_Add=%g\n", params->SingleStreamAddGBs ); fprintf( outputFile, "SingleSTREAM_Triad=%g\n", params->SingleStreamTriadGBs ); fprintf( outputFile, "FFT_N=%d\n", params->FFT_N ); fprintf( outputFile, "StarFFT_Gflops=%g\n", params->StarFFTGflops ); fprintf( outputFile, "SingleFFT_Gflops=%g\n", params->SingleFFTGflops ); fprintf( outputFile, "MPIFFT_N=" FSTR64 "\n", params->MPIFFT_N ); fprintf( outputFile, "MPIFFT_Gflops=%g\n", params->MPIFFTGflops ); fprintf( outputFile, "MPIFFT_maxErr=%g\n", params->MPIFFT_maxErr ); fprintf( outputFile, "MPIFFT_Procs=%d\n", params->MPIFFT_Procs ); fprintf( outputFile, "MaxPingPongLatency_usec=%g\n", params->MaxPingPongLatency ); fprintf( outputFile, "RandomlyOrderedRingLatency_usec=%g\n", params->RandomlyOrderedRingLatency ); fprintf( outputFile, "MinPingPongBandwidth_GBytes=%g\n", params->MinPingPongBandwidth ); fprintf( outputFile, "NaturallyOrderedRingBandwidth_GBytes=%g\n", params->NaturallyOrderedRingBandwidth ); fprintf( outputFile, "RandomlyOrderedRingBandwidth_GBytes=%g\n", params->RandomlyOrderedRingBandwidth ); fprintf( outputFile, "MinPingPongLatency_usec=%g\n", params->MinPingPongLatency ); fprintf( outputFile, "AvgPingPongLatency_usec=%g\n", params->AvgPingPongLatency ); fprintf( outputFile, "MaxPingPongBandwidth_GBytes=%g\n", params->MaxPingPongBandwidth ); fprintf( outputFile, "AvgPingPongBandwidth_GBytes=%g\n", params->AvgPingPongBandwidth ); fprintf( outputFile, "NaturallyOrderedRingLatency_usec=%g\n", params->NaturallyOrderedRingLatency ); fprintf( outputFile, "FFTEnblk=%d\n", params->FFTEnblk ); fprintf( outputFile, "FFTEnp=%d\n", params->FFTEnp ); fprintf( outputFile, "FFTEl2size=%d\n", params->FFTEl2size ); #ifdef _OPENMP fprintf( outputFile, "M_OPENMP=%ld\n", (long)(_OPENMP) ); #pragma omp parallel { #pragma omp single nowait { fprintf( outputFile, "omp_get_num_threads=%d\n", omp_get_num_threads() ); fprintf( outputFile, "omp_get_max_threads=%d\n", omp_get_max_threads() ); fprintf( outputFile, "omp_get_num_procs=%d\n", omp_get_num_procs() ); } } #else fprintf( outputFile, "M_OPENMP=%ld\n", -1L ); fprintf( outputFile, "omp_get_num_threads=%d\n", 0 ); fprintf( outputFile, "omp_get_max_threads=%d\n", 0 ); fprintf( outputFile, "omp_get_num_procs=%d\n", 0 ); #endif fprintf( outputFile, "MemProc=%g\n", HPCC_MemProc ); fprintf( outputFile, "MemSpec=%d\n", HPCC_MemSpec ); fprintf( outputFile, "MemVal=%g\n", HPCC_MemVal ); for (i = 0; i < MPIFFT_TIMING_COUNT - 1; i++) fprintf( outputFile, "MPIFFT_time%d=%g\n", i, params->MPIFFTtimingsForward[i+1] - params->MPIFFTtimingsForward[i] ); /* CPS: C Preprocessor Symbols */ i = 0; #ifdef HPCC_FFT_235 i = 1; #endif fprintf( outputFile, "CPS_HPCC_FFT_235=%d\n", i ); i = 0; #ifdef HPCC_FFTW_ESTIMATE i = 1; #endif fprintf( outputFile, "CPS_HPCC_FFTW_ESTIMATE=%d\n", i ); i = 0; #ifdef HPCC_MEMALLCTR i = 1; #endif fprintf( outputFile, "CPS_HPCC_MEMALLCTR=%d\n", i ); i = 0; #ifdef HPL_USE_GETPROCESSTIMES i = 1; #endif fprintf( outputFile, "CPS_HPL_USE_GETPROCESSTIMES=%d\n", i ); i = 0; #ifdef RA_SANDIA_NOPT i = 1; #endif fprintf( outputFile, "CPS_RA_SANDIA_NOPT=%d\n", i ); i = 0; #ifdef RA_SANDIA_OPT2 i = 1; #endif fprintf( outputFile, "CPS_RA_SANDIA_OPT2=%d\n", i ); i = 0; #ifdef USING_FFTW i = 1; #endif fprintf( outputFile, "CPS_USING_FFTW=%d\n", i ); fprintf( outputFile, "End of Summary section.%s\n", "" ); fprintf( outputFile, "########################################################################\n" ); fprintf( outputFile, "End of HPC Challenge tests.\n" ); fprintf( outputFile, "Current time (%ld) is %s\n",(long)currentTime,ctime(&currentTime)); fprintf( outputFile, "########################################################################\n" ); END_IO( myRank, outputFile ); return 0; } int HPCC_LocalVectorSize(HPCC_Params *params, int vecCnt, size_t size, int pow2) { int flg2, maxIntBits2; /* this is the maximum power of 2 that that can be held in a signed integer (for a 4-byte integer, 2**31-1 is the maximum integer, so the maximum power of 2 is 30) */ maxIntBits2 = sizeof(int) * 8 - 2; /* flg2 = floor(log2(params->HPLMaxProcMem / size / vecCnt)) */ for (flg2 = 1; params->HPLMaxProcMem / size / vecCnt >> flg2; ++flg2) ; /* EMPTY */ --flg2; if (flg2 <= maxIntBits2) { if (pow2) return 1 << flg2; return params->HPLMaxProcMem / size / vecCnt; } return 1 << maxIntBits2; } int HPCC_ProcessGrid(int *P, int *Q, MPI_Comm comm) { int myRank, commSize; int i, p, q, nproc; MPI_Comm_size( comm, &commSize ); MPI_Comm_rank( comm, &myRank ); for (nproc = commSize; ; --nproc) { /* this loop makes at most two iterations */ for (i = (int)sqrt( nproc ); i > 1; --i) { q = nproc / i; p = nproc / q; if (p * q == nproc) { *P = p; *Q = q; return 0; } } /* if the code gets here `nproc' is small or is a prime */ if (nproc < 20) { /* do 1D grid for small process counts */ *P = 1; *Q = nproc; return 0; } } return 0; } size_t HPCC_Memory(MPI_Comm comm) { int myRank, commSize; int num_threads; char memFile[13] = "hpccmemf.txt"; char buf[HPL_LINE_MAX]; int nbuf = HPL_LINE_MAX; char *sVal; FILE *f; double mult, mval, procMem; size_t rv; mult = 1.0; num_threads = 1; MPI_Comm_size( comm, &commSize ); MPI_Comm_rank( comm, &myRank ); #ifdef _OPENMP #pragma omp parallel { #pragma omp single nowait { num_threads = omp_get_num_threads(); } } #endif if (myRank == 0) { procMem = 64; f = fopen( memFile, "r" ); if (f) { if (fgets( buf, nbuf, f )) { if (strncmp( "Total=", buf, 6 ) == 0) { mult = 1.0 / commSize; sVal = buf + 6; HPCC_MemSpec = 1; } else if (strncmp( "Thread=", buf, 7 ) == 0) { mult = num_threads; sVal = buf + 7; HPCC_MemSpec = 2; } else if (strncmp( "Process=", buf, 8 ) == 0) { mult = 1.0; sVal = buf + 8; HPCC_MemSpec = 3; } else sVal = NULL; if (sVal && 1 == sscanf( sVal, "%lf", &mval )) { procMem = mval * mult; HPCC_MemVal = mval; } } fclose( f ); } } MPI_Bcast( &procMem, 1, MPI_DOUBLE, 0, comm ); rv = procMem; rv *= 1024; rv *= 1024; HPCC_MemProc = procMem; return rv; } int HPCC_Defaults(HPL_T_test *TEST, int *NS, int *N, int *NBS, int *NB, HPL_T_ORDER *PMAPPIN, int *NPQS, int *P, int *Q, int *NPFS, HPL_T_FACT *PF, int *NBMS, int *NBM, int *NDVS, int *NDV, int *NRFS, HPL_T_FACT *RF, int *NTPS, HPL_T_TOP *TP, int *NDHS, int *DH, HPL_T_SWAP *FSWAP, int *TSWAP, int *L1NOTRAN, int *UNOTRAN, int *EQUIL, int *ALIGN, MPI_Comm comm) { int nb = 80; double memFactor = 0.8; *NS = *NBS = *NPQS = *NPFS = *NBMS = *NDVS = *NRFS = *NTPS = *NDHS = 1; TEST->thrsh = 16.0; *NB = nb; *PMAPPIN = HPL_COLUMN_MAJOR; HPCC_ProcessGrid( P, Q, comm ); *N = (int)sqrt( memFactor * (double)(*P * *Q) * (double)(HPCC_Memory( comm ) / sizeof(double)) ) / (2 * nb); *N *= 2*nb; /* make N multiple of 2*nb so both HPL and PTRANS see matrix dimension divisible by nb */ *PF = HPL_RIGHT_LOOKING; *NBM = 4; *NDV = 2; *RF = HPL_CROUT; *TP = HPL_1RING_M; *DH = 1; *FSWAP = HPL_SW_MIX; *TSWAP = 64; *L1NOTRAN = 0; *UNOTRAN = 0; *EQUIL = 1; *ALIGN = 8; return 0; } #ifdef XERBLA_MISSING #ifdef Add_ #define F77xerbla xerbla_ #endif #ifdef Add__ #define F77xerbla xerbla__ #endif #ifdef NoChange #define F77xerbla xerbla #endif #ifdef UpCase #define F77xerbla XERBLA #endif #ifdef f77IsF2C #define F77xerbla xerbla_ #endif void F77xerbla(char *srname, F77_INTEGER *info, long srname_len) { /* int i; char Cname[7]; for (i = 0; i < 6; i++) Cname[i] = srname[i]; Cname[6] = 0; printf("xerbla(%d)\n", *info); */ printf("xerbla()\n"); fflush(stdout); } #endif #ifdef HPCC_MEMALLCTR #define MEM_MAXCNT 7 typedef double Mem_t; static Mem_t *Mem_base; static size_t Mem_dsize; /* Each entry can be in one of three states: 1. Full (holds a block of allocated memory) if: ptr != NULL; size > 0; free == 0 2. Free (holds block of unallocated memory) if: ptr != NULL; free = 1 3 Empty (doesn't hold a block of memory) if: ptr == NULL; free = 1 */ typedef struct { Mem_t *Mem_ptr; size_t Mem_size; int Mem_free; } Mem_entry_t; static Mem_entry_t Mem_blocks[MEM_MAXCNT]; static void HPCC_alloc_set_empty(int idx) { int i, n0, n; if (MEM_MAXCNT == idx) { n0 = 0; n = idx; } else { n0 = idx; n = idx + 1; } /* initialize all blocks to empty */ for (i = n0; i < n; ++i) { Mem_blocks[i].Mem_ptr = (Mem_t *)(NULL); Mem_blocks[i].Mem_size = 0; Mem_blocks[i].Mem_free = 1; } } static void HPCC_alloc_set_free(int idx, Mem_t *dptr, size_t size) { Mem_blocks[idx].Mem_ptr = dptr; Mem_blocks[idx].Mem_size = size; Mem_blocks[idx].Mem_free = 1; } int HPCC_alloc_init(size_t total_size) { size_t dsize; Mem_dsize = dsize = Mceil( total_size, sizeof(Mem_t) ); Mem_base = (Mem_t *)malloc( dsize * sizeof(Mem_t) ); HPCC_alloc_set_empty( MEM_MAXCNT ); if (Mem_base) { HPCC_alloc_set_free( 0, Mem_base, dsize ); return 0; } return -1; } int HPCC_alloc_finalize() { free( Mem_base ); HPCC_alloc_set_empty( MEM_MAXCNT ); return 0; } void * HPCC_malloc(size_t size) { size_t dsize, diff_size, cur_diff_size; int i, cur_best, cur_free; dsize = Mceil( size, sizeof(Mem_t) ); cur_diff_size = Mem_dsize + 1; cur_free = cur_best = MEM_MAXCNT; for (i = 0; i < MEM_MAXCNT; ++i) { /* skip full spots */ if (! Mem_blocks[i].Mem_free) continue; /* find empty spot */ if (! Mem_blocks[i].Mem_ptr) { cur_free = i; continue; } diff_size = Mem_blocks[i].Mem_size - dsize; if (Mem_blocks[i].Mem_size >= dsize && diff_size < cur_diff_size) { /* a match that's the best (so far) was found */ cur_diff_size = diff_size; cur_best = i; } } /* found a match */ if (cur_best < MEM_MAXCNT) { if (cur_free < MEM_MAXCNT && cur_diff_size > 0) { /* create a new free block */ HPCC_alloc_set_free( cur_free, Mem_blocks[cur_best].Mem_ptr + dsize, cur_diff_size ); Mem_blocks[cur_best].Mem_size = dsize; /* shrink the best match */ } Mem_blocks[cur_best].Mem_free = 0; return (void *)(Mem_blocks[cur_best].Mem_ptr); } return NULL; } void HPCC_free(void *ptr) { Mem_t *dptr = (Mem_t *)ptr; int cur_blk = MEM_MAXCNT, made_changes, i, j; /* look for the block being freed */ for (i = 0; i < MEM_MAXCNT; ++i) { if (Mem_blocks[i].Mem_free) continue; if (Mem_blocks[i].Mem_ptr == dptr) { cur_blk = i; break; } } /* not finding the pointer (including NULL) causes abort */ if (MEM_MAXCNT == cur_blk) { HPL_pabort( __LINE__, "HPCC_free", "Unknown pointer in HPCC_free()." ); } /* double-free causes abort */ if (1 == Mem_blocks[cur_blk].Mem_free) { HPL_pabort( __LINE__, "HPCC_free", "Second call to HPCC_free() with the same pointer." ); } Mem_blocks[cur_blk].Mem_free = 1; /* merge as many blocks as possible */ for (made_changes = 1; made_changes;) { made_changes = 0; for (i = 0; i < MEM_MAXCNT; ++i) { /* empty or full blocks can't be merged */ if (! Mem_blocks[i].Mem_free || ! Mem_blocks[i].Mem_ptr) continue; for (j = 0; j < MEM_MAXCNT; ++j) { /* empty or occupied blocks can't be merged */ if (! Mem_blocks[j].Mem_free || ! Mem_blocks[j].Mem_ptr) continue; if (Mem_blocks[i].Mem_ptr + Mem_blocks[i].Mem_size == Mem_blocks[j].Mem_ptr) { Mem_blocks[i].Mem_size += Mem_blocks[j].Mem_size; HPCC_alloc_set_empty( j ); made_changes = 1; } } } } } #endif

graph.h

// copyright (c) 2015, The Regents of the University of California (Regents) // See LICENSE.txt for license details #ifndef GRAPH_H_ #define GRAPH_H_ #include <stdio.h> #include <cinttypes> #include <iostream> #include <type_traits> #include <map> #include "pvector.h" #include "util.h" #include "segmentgraph.h" /* GAP Benchmark Suite Class: CSRGraph Author: Scott Beamer Simple container for graph in CSR format - Intended to be constructed by a Builder - To make weighted, set DestID_ template type to NodeWeight - MakeInverse parameter controls whether graph stores its inverse */ // Used to hold node & weight, with another node it makes a weighted edge template <typename NodeID_=int32_t, typename WeightT_=int32_t> struct NodeWeight { NodeID_ v; WeightT_ w; NodeWeight() {} NodeWeight(NodeID_ v) : v(v), w(1) {} NodeWeight(NodeID_ v, WeightT_ w) : v(v), w(w) {} bool operator< (const NodeWeight& rhs) const { return v == rhs.v ? w < rhs.w : v < rhs.v; } // doesn't check WeightT_s, needed to remove duplicate edges bool operator== (const NodeWeight& rhs) const { return v == rhs.v; } // doesn't check WeightT_s, needed to remove self edges bool operator== (const NodeID_& rhs) const { return v == rhs; } operator NodeID_() { return v; } }; template <typename NodeID_, typename WeightT_> std::ostream& operator<<(std::ostream& os, const NodeWeight<NodeID_, WeightT_>& nw) { os << nw.v << " " << nw.w; return os; } template <typename NodeID_, typename WeightT_> std::istream& operator>>(std::istream& is, NodeWeight<NodeID_, WeightT_>& nw) { is >> nw.v >> nw.w; return is; } // Syntatic sugar for an edge template <typename SrcT, typename DstT = SrcT> struct EdgePair { SrcT u; DstT v; EdgePair() {} EdgePair(SrcT u, DstT v) : u(u), v(v) {} }; // SG = serialized graph, these types are for writing graph to file typedef int32_t SGID; typedef EdgePair<SGID> SGEdge; typedef int64_t SGOffset; template <class NodeID_, class DestID_ = NodeID_, bool MakeInverse = true> class CSRGraph { // Used to access neighbors of vertex, basically sugar for iterators class Neighborhood { NodeID_ n_; DestID_** g_index_; public: Neighborhood(NodeID_ n, DestID_** g_index) : n_(n), g_index_(g_index) {} typedef DestID_* iterator; iterator begin() { return g_index_[n_]; } iterator end() { return g_index_[n_+1]; } }; void ReleaseResources() { //added a second condition to prevent double free (transpose graphs) if (out_index_ != nullptr) delete[] out_index_; if (out_neighbors_ != nullptr) delete[] out_neighbors_; if (directed_) { if (in_index_ != nullptr) delete[] in_index_; if (in_neighbors_ != nullptr) delete[] in_neighbors_; } if (flags_ != nullptr) delete[] flags_; for (auto iter = label_to_segment.begin(); iter != label_to_segment.end(); iter++) { delete ((*iter).second); } } public: CSRGraph() : directed_(false), num_nodes_(-1), num_edges_(-1), out_index_(nullptr), out_neighbors_(nullptr), in_index_(nullptr), in_neighbors_(nullptr), flags_(nullptr), is_transpose_(false) {} CSRGraph(int64_t num_nodes, DestID_** index, DestID_* neighs) : directed_(false), num_nodes_(num_nodes), out_index_(index), out_neighbors_(neighs), in_index_(index), in_neighbors_(neighs) { num_edges_ = (out_index_[num_nodes_] - out_index_[0]) / 2; //adding flags used for deduplication flags_ = new int[num_nodes_]; //adding offsets for load balacne scheme SetUpOffsets(true); } CSRGraph(int64_t num_nodes, DestID_** out_index, DestID_* out_neighs, DestID_** in_index, DestID_* in_neighs) : directed_(true), num_nodes_(num_nodes), out_index_(out_index), out_neighbors_(out_neighs), in_index_(in_index), in_neighbors_(in_neighs), is_transpose_(false) { num_edges_ = out_index_[num_nodes_] - out_index_[0]; flags_ = new int[num_nodes_]; SetUpOffsets(true); } CSRGraph(int64_t num_nodes, DestID_** out_index, DestID_* out_neighs, DestID_** in_index, DestID_* in_neighs, bool is_transpose) : directed_(true), num_nodes_(num_nodes), out_index_(out_index), out_neighbors_(out_neighs), in_index_(in_index), in_neighbors_(in_neighs) , is_transpose_(is_transpose){ num_edges_ = out_index_[num_nodes_] - out_index_[0]; flags_ = new int[num_nodes_]; SetUpOffsets(true); } CSRGraph(CSRGraph&& other) : directed_(other.directed_), num_nodes_(other.num_nodes_), num_edges_(other.num_edges_), out_index_(other.out_index_), out_neighbors_(other.out_neighbors_), in_index_(other.in_index_), in_neighbors_(other.in_neighbors_), is_transpose_(false) { other.num_edges_ = -1; other.num_nodes_ = -1; other.out_index_ = nullptr; other.out_neighbors_ = nullptr; other.in_index_ = nullptr; other.in_neighbors_ = nullptr; other.flags_ = nullptr; other.offsets_ = nullptr; } ~CSRGraph() { if (!is_transpose_) ReleaseResources(); } CSRGraph& operator=(CSRGraph&& other) { if (this != &other) { if (!is_transpose_) ReleaseResources(); directed_ = other.directed_; num_edges_ = other.num_edges_; num_nodes_ = other.num_nodes_; out_index_ = other.out_index_; out_neighbors_ = other.out_neighbors_; in_index_ = other.in_index_; in_neighbors_ = other.in_neighbors_; other.num_edges_ = -1; other.num_nodes_ = -1; other.out_index_ = nullptr; other.out_neighbors_ = nullptr; other.in_index_ = nullptr; other.in_neighbors_ = nullptr; other.flags_ = nullptr; other.offsets_ = nullptr; } return *this; } bool directed() const { return directed_; } int64_t num_nodes() const { return num_nodes_; } int64_t num_edges() const { return num_edges_; } int64_t num_edges_directed() const { return directed_ ? num_edges_ : 2*num_edges_; } int64_t out_degree(NodeID_ v) const { return out_index_[v+1] - out_index_[v]; } int64_t in_degree(NodeID_ v) const { static_assert(MakeInverse, "Graph inversion disabled but reading inverse"); return in_index_[v+1] - in_index_[v]; } Neighborhood out_neigh(NodeID_ n) const { return Neighborhood(n, out_index_); } Neighborhood in_neigh(NodeID_ n) const { static_assert(MakeInverse, "Graph inversion disabled but reading inverse"); return Neighborhood(n, in_index_); } void PrintStats() const { std::cout << "Graph has " << num_nodes_ << " nodes and " << num_edges_ << " "; if (!directed_) std::cout << "un"; std::cout << "directed edges for degree: "; std::cout << num_edges_/num_nodes_ << std::endl; } void PrintTopology() const { for (NodeID_ i=0; i < num_nodes_; i++) { std::cout << i << ": "; for (DestID_ j : out_neigh(i)) { std::cout << j << " "; } std::cout << std::endl; } } static DestID_** GenIndex(const pvector<SGOffset> &offsets, DestID_* neighs) { NodeID_ length = offsets.size(); DestID_** index = new DestID_*[length]; #pragma omp parallel for for (NodeID_ n=0; n < length; n++) index[n] = neighs + offsets[n]; return index; } pvector<SGOffset> VertexOffsets(bool in_graph = false) const { pvector<SGOffset> offsets(num_nodes_+1); for (NodeID_ n=0; n < num_nodes_+1; n++) if (in_graph) offsets[n] = in_index_[n] - in_index_[0]; else offsets[n] = out_index_[n] - out_index_[0]; return offsets; } void SetUpOffsets(bool in_graph = false) { offsets_ = new SGOffset[num_nodes_+1]; for (NodeID_ n=0; n < num_nodes_+1; n++) if (in_graph) offsets_[n] = in_index_[n] - in_index_[0]; else offsets_[n] = out_index_[n] - out_index_[0]; } Range<NodeID_> vertices() const { return Range<NodeID_>(num_nodes()); } SegmentedGraph<DestID_, NodeID_>* getSegmentedGraph(std::string label, int id) { return label_to_segment[label]->getSegmentedGraph(id); } int getNumSegments(std::string label) { return label_to_segment[label]->numSegments; } void buildPullSegmentedGraphs(std::string label, int numSegments, bool numa_aware=false, std::string path="") { auto graphSegments = new GraphSegments<DestID_,NodeID_>(numSegments, numa_aware); label_to_segment[label] = graphSegments; #ifdef LOADSEG cout << "loading segmented graph from " << path << endl; #pragma omp parallel for num_threads(numSegments) for (int i = 0; i < numSegments; i++) { FILE *in; in = fopen((path + "/" + std::to_string(i)).c_str(), "r"); auto sg = graphSegments->getSegmentedGraph(i); fread((void *) &sg->numVertices, sizeof(sg->numVertices), 1, in); fread((void *) &sg->numEdges, sizeof(sg->numEdges), 1, in); sg->allocate(i); fread((void *) sg->graphId, sizeof(*sg->graphId), sg->numVertices, in); fread((void *) sg->edgeArray, sizeof(*sg->edgeArray), sg->numEdges, in); fread((void *) sg->vertexArray, sizeof(*sg->vertexArray), sg->numVertices + 1, in); fclose(in); } return; #endif int segmentRange = (num_nodes() + numSegments - 1) / numSegments; //Go through the original graph and count the number of target vertices and edges for each segment for (auto d : vertices()){ for (auto s : in_neigh(d)){ int segment_id; if (std::is_same<DestID_, NodeWeight<>>::value) segment_id = static_cast<NodeWeight<>>(s).v/segmentRange; else segment_id = s/segmentRange; graphSegments->getSegmentedGraph(segment_id)->countEdge(d); } } //Allocate each segment graphSegments->allocate(); //Add the edges for each segment for (auto d : vertices()){ for (auto s : in_neigh(d)){ int segment_id; if (std::is_same<DestID_, NodeWeight<>>::value) segment_id = static_cast<NodeWeight<>>(s).v/segmentRange; else segment_id = s/segmentRange; graphSegments->getSegmentedGraph(segment_id)->addEdge(d, s); } } #ifdef STORESEG cout << "output serialized graph segments to " << path << endl; #pragma omp parallel for num_threads(numSegments) for(int i = 0; i < numSegments; i++) { FILE *out = fopen((path + "/" + std::to_string(i)).c_str(), "w"); auto sg = graphSegments->getSegmentedGraph(i); fwrite((void *) &sg->numVertices, sizeof(sg->numVertices), 1, out); fwrite((void *) &sg->numEdges, sizeof(sg->numEdges), 1, out); fwrite((void *) sg->graphId, sizeof(*sg->graphId), sg->numVertices, out); fwrite((void *) sg->edgeArray, sizeof(*sg->edgeArray), sg->numEdges, out); fwrite((void *) sg->vertexArray, sizeof(*sg->vertexArray), sg->numVertices + 1, out); fclose(out); } #endif } //useful for deduplication int* flags_; SGOffset * offsets_; // private: bool is_transpose_; bool directed_; int64_t num_nodes_; int64_t num_edges_; DestID_** out_index_; DestID_* out_neighbors_; DestID_** in_index_; DestID_* in_neighbors_; std::map<std::string, GraphSegments<DestID_,NodeID_>*> label_to_segment; }; #endif // GRAPH_H_

openmp.c

/* * Copyright (c) 2003, 2007-14 Matteo Frigo * Copyright (c) 2003, 2007-14 Massachusetts Institute of Technology * * This program is free software; you can redistribute it and/or modify * it under the terms of the GNU General Public License as published by * the Free Software Foundation; either version 2 of the License, or * (at your option) any later version. * * This program is distributed in the hope that it will be useful, * but WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the * GNU General Public License for more details. * * You should have received a copy of the GNU General Public License * along with this program; if not, write to the Free Software * Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA * */ /* openmp.c: thread spawning via OpenMP */ #include "threads/threads.h" #if !defined(_OPENMP) #error OpenMP enabled but not using an OpenMP compiler #endif int X(ithreads_init)(void) { return 0; /* no error */ } /* Distribute a loop from 0 to loopmax-1 over nthreads threads. proc(d) is called to execute a block of iterations from d->min to d->max-1. d->thr_num indicate the number of the thread that is executing proc (from 0 to nthreads-1), and d->data is the same as the data parameter passed to X(spawn_loop). This function returns only after all the threads have completed. */ void X(spawn_loop)(int loopmax, int nthr, spawn_function proc, void *data) { int block_size; spawn_data d; int i; A(loopmax >= 0); A(nthr > 0); A(proc); if (!loopmax) return; /* Choose the block size and number of threads in order to (1) minimize the critical path and (2) use the fewest threads that achieve the same critical path (to minimize overhead). e.g. if loopmax is 5 and nthr is 4, we should use only 3 threads with block sizes of 2, 2, and 1. */ block_size = (loopmax + nthr - 1) / nthr; nthr = (loopmax + block_size - 1) / block_size; if (X(spawnloop_callback)) { /* user-defined spawnloop backend */ spawn_data *sdata; STACK_MALLOC(spawn_data *, sdata, sizeof(spawn_data) * nthr); for (i = 0; i < nthr; ++i) { spawn_data *d = &sdata[i]; d->max = (d->min = i * block_size) + block_size; if (d->max > loopmax) d->max = loopmax; d->thr_num = i; d->data = data; } X(spawnloop_callback)(proc, sdata, sizeof(spawn_data), nthr, X(spawnloop_callback_data)); STACK_FREE(sdata); return; } #pragma omp parallel for private(d) for (i = 0; i < nthr; ++i) { d.max = (d.min = i * block_size) + block_size; if (d.max > loopmax) d.max = loopmax; d.thr_num = i; d.data = data; proc(&d); } } void X(threads_cleanup)(void) { } /* FIXME [Matteo Frigo 2015-05-25] What does "thread-safe" mean for openmp? */ void X(threads_register_planner_hooks)(void) { }

gp.h

#include <iostream> #include <armadillo> #include <omp.h> using namespace std; using namespace arma; //const double pi = M_PI; dmat calc_covariance_matrix(dmat X,float bandwidth=0.01) { bandwidth = 1.0 / (2.0 * pow(bandwidth,2)); int n = X.n_cols; dmat K(n,n,fill::eye); #pragma omp parallel { #pragma omp for for(int i=0;i<n;i++) for(int j=i+1;j<n;j++) { vec diff = X.col(i) - X.col(j); double mean_diff = mean(diff % diff); K(i,j) = exp(-mean_diff*bandwidth); K(j,i) = K(i,j); } } return K; } double probit_log_likelihood(vec latent_variables, vec class_labels) { return accu(log(normcdf(latent_variables % class_labels))); } dmat elliptical_slice_sampling(dmat K,vec y,int N_mcmc=100000,int burn_in=1000,int seed=-1,bool verbose=true) { dmat samples; int n = K.n_rows; int N = y.n_elem; if (seed == -1) arma_rng::set_seed_random(); else arma_rng::set_seed(seed); dmat mcmc_samples(burn_in+N_mcmc,N,fill::zeros); dvec mean(n,fill::zeros); dmat norm_samples = mvnrnd(mean,K,burn_in+N_mcmc).t(); dvec unif_samples = randu<dvec>(burn_in+N_mcmc); dvec theta = randu<dvec>(burn_in+N_mcmc)*(2.0*pi); dvec theta_min = theta - (2.0 * pi); dvec theta_max = theta + (2.0 * pi); for(int i=1;i<burn_in+N_mcmc;i++) { if (i < burn_in) { cout << "Burning in...\r"; cout << flush; } else { cout << "Elliptical slice sampling Step " << (i-burn_in+1) << "...\r"; cout << flush; } dvec f = conv_to<dvec>::from(mcmc_samples.row(i-1)); double llh_thresh = probit_log_likelihood(f,y) + log(unif_samples(i)); dvec f_star = f * cos(theta(i)) + norm_samples.row(i).t(); while(probit_log_likelihood(f_star,y) < llh_thresh) { if (theta(i) < 0) theta_min(i) = theta(i); else theta_max(i) = theta(i); theta(i) = randu<double>() * (theta_max(i)-theta_min(i)) + theta_min(i); f_star = f * cos(theta(i)) + norm_samples.row(i).t() * sin(theta(i)); } mcmc_samples.row(i) = f_star.t(); } cout << '\n'; return mcmc_samples.rows(burn_in,burn_in+N_mcmc-1); } dmat sherman_r(dmat A, dvec u, dvec v) { dmat x = v.t() * A * u; dmat B = A * u * v.t() * A; double c = 1.0 / (x(0) + 1.0); return A - B * c; } dvec calc_rate(dmat X, dmat f_draws, bool verbose=true) { dmat beta_draws = (pinv(X) * f_draws.t()).t(); dmat V = cov(beta_draws); dmat D = pinv(V); dmat D_U, D_V; dvec D_s; svd(D_U,D_s,D_V,D); uvec ind = find(D_s > 1e-10); D_U = D_U.cols(ind); dmat U = D_U.each_row() % sqrt(D_s.elem(ind)).t(); dvec mu = conv_to<dvec>::from(mean(beta_draws,0)); mu = abs(mu); dmat Lambda = U * U.t(); dvec kld(mu.n_elem,fill::zeros); for(int q=0;q<mu.n_elem;q++) { if (verbose) cout << "Calculating KLD(" << q << ")...\r"; dvec Vq = conv_to<dvec>::from(V.col(q)); dmat U_Lambda_sub = sherman_r(Lambda,Vq,Vq); dmat U_no_q = U_Lambda_sub; U_no_q.shed_row(q); dmat U_no_qq = U_no_q; U_no_qq.shed_col(q); dvec U_no_q_q = conv_to<dvec>::from(U_no_q.col(q)); dvec alpha = U_no_q_q.t() * U_no_qq * U_no_q_q; kld(q) = pow(mu(q),2.0) * alpha(0) * 0.5; } kld.save("kld.txt",raw_ascii); if (verbose) cout << "KLD calculation Completed.\n"; // Compute the corresponding “RelATive cEntrality” (RATE) measure dvec rates = kld / sum(kld); /// Find the entropic deviation from a uniform distribution //delta = np.sum(rates*np.log(len(mu)*rates)) // Calibrate Delta via the effective sample size (ESS) measures from importance sampling ### // (Gruber and West, 2016, 2017) //eff_samp_size = 1./(1.+delta)*100. return rates; } dmat find_rate_variables_with_other_sampling_methods(dmat X,vec y,float bandwidth = 0.01, string sampling_method = "ESS", int size = 100000, int N_mcmc = 100000, int burn_in = 1000, bool probit = true, int seed = -1) { int n_fils = X.n_cols; uvec nonzero_col = find(any(X,0)); nonzero_col.print(); X = conv_to<dmat>::from(X.cols(nonzero_col)); cout << "X " << X.n_rows << ' ' << X.n_cols << endl; dmat X_colmean = mean(X,0); dmat X_colstd = stddev(X,0,0); X.each_row() -= X_colmean; X.each_row() /= X_colstd; cout << X.n_rows << ' ' << X.n_cols << endl; dmat K = calc_covariance_matrix(X.t(),bandwidth); //K.save("K.bin",arma_binary); dmat samples; //if (not sampling_method.compare("ESS")) samples = elliptical_slice_sampling(K,y,N_mcmc,burn_in,seed,true); //samples.save("ESS.bin",arma_binary); //samples.load("ESS.bin",arma_binary); dvec rates_nv = calc_rate(X,samples); dvec rates(n_fils,fill::zeros); for(int i=0;i<nonzero_col.n_elem;i++) rates(nonzero_col(i)) = rates_nv(i); return rates; }

draw.c

/* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % DDDD RRRR AAA W W % % D D R R A A W W % % D D RRRR AAAAA W W W % % D D R RN A A WW WW % % DDDD R R A A W W % % % % % % MagickCore Image Drawing Methods % % % % % % Software Design % % Cristy % % July 1998 % % % % % % Copyright 1999-2019 ImageMagick Studio LLC, a non-profit organization % % dedicated to making software imaging solutions freely available. % % % % You may not use this file except in compliance with the License. You may % % obtain a copy of the License at % % % % https://imagemagick.org/script/license.php % % % % Unless required by applicable law or agreed to in writing, software % % distributed under the License is distributed on an "AS IS" BASIS, % % WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. % % See the License for the specific language governing permissions and % % limitations under the License. % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % Bill Radcliffe of Corbis (www.corbis.com) contributed the polygon % rendering code based on Paul Heckbert's "Concave Polygon Scan Conversion", % Graphics Gems, 1990. Leonard Rosenthal and David Harr of Appligent % (www.appligent.com) contributed the dash pattern, linecap stroking % algorithm, and minor rendering improvements. % */ /* Include declarations. */ #include "MagickCore/studio.h" #include "MagickCore/annotate.h" #include "MagickCore/artifact.h" #include "MagickCore/blob.h" #include "MagickCore/cache.h" #include "MagickCore/cache-private.h" #include "MagickCore/cache-view.h" #include "MagickCore/channel.h" #include "MagickCore/color.h" #include "MagickCore/colorspace-private.h" #include "MagickCore/composite.h" #include "MagickCore/composite-private.h" #include "MagickCore/constitute.h" #include "MagickCore/draw.h" #include "MagickCore/draw-private.h" #include "MagickCore/enhance.h" #include "MagickCore/exception.h" #include "MagickCore/exception-private.h" #include "MagickCore/gem.h" #include "MagickCore/geometry.h" #include "MagickCore/image-private.h" #include "MagickCore/list.h" #include "MagickCore/log.h" #include "MagickCore/memory-private.h" #include "MagickCore/monitor.h" #include "MagickCore/monitor-private.h" #include "MagickCore/option.h" #include "MagickCore/paint.h" #include "MagickCore/pixel-accessor.h" #include "MagickCore/pixel-private.h" #include "MagickCore/property.h" #include "MagickCore/resample.h" #include "MagickCore/resample-private.h" #include "MagickCore/resource_.h" #include "MagickCore/splay-tree.h" #include "MagickCore/string_.h" #include "MagickCore/string-private.h" #include "MagickCore/thread-private.h" #include "MagickCore/token.h" #include "MagickCore/transform-private.h" #include "MagickCore/utility.h" /* Define declarations. */ #define BezierQuantum 200 #define PrimitiveExtentPad 2048 #define MaxBezierCoordinates 4194304 #define ThrowPointExpectedException(token,exception) \ { \ (void) ThrowMagickException(exception,GetMagickModule(),DrawError, \ "NonconformingDrawingPrimitiveDefinition","`%s'",token); \ status=MagickFalse; \ break; \ } /* Typedef declarations. */ typedef struct _EdgeInfo { SegmentInfo bounds; double scanline; PointInfo *points; size_t number_points; ssize_t direction; MagickBooleanType ghostline; size_t highwater; } EdgeInfo; typedef struct _ElementInfo { double cx, cy, major, minor, angle; } ElementInfo; typedef struct _MVGInfo { PrimitiveInfo **primitive_info; size_t *extent; ssize_t offset; PointInfo point; ExceptionInfo *exception; } MVGInfo; typedef struct _PolygonInfo { EdgeInfo *edges; size_t number_edges; } PolygonInfo; typedef enum { MoveToCode, OpenCode, GhostlineCode, LineToCode, EndCode } PathInfoCode; typedef struct _PathInfo { PointInfo point; PathInfoCode code; } PathInfo; /* Forward declarations. */ static Image *DrawClippingMask(Image *,const DrawInfo *,const char *,const char *, ExceptionInfo *); static MagickBooleanType DrawStrokePolygon(Image *,const DrawInfo *,const PrimitiveInfo *, ExceptionInfo *), RenderMVGContent(Image *,const DrawInfo *,const size_t,ExceptionInfo *), TraceArc(MVGInfo *,const PointInfo,const PointInfo,const PointInfo), TraceArcPath(MVGInfo *,const PointInfo,const PointInfo,const PointInfo, const double,const MagickBooleanType,const MagickBooleanType), TraceBezier(MVGInfo *,const size_t), TraceCircle(MVGInfo *,const PointInfo,const PointInfo), TraceEllipse(MVGInfo *,const PointInfo,const PointInfo,const PointInfo), TraceLine(PrimitiveInfo *,const PointInfo,const PointInfo), TraceRectangle(PrimitiveInfo *,const PointInfo,const PointInfo), TraceRoundRectangle(MVGInfo *,const PointInfo,const PointInfo,PointInfo), TraceSquareLinecap(PrimitiveInfo *,const size_t,const double); static PrimitiveInfo *TraceStrokePolygon(const Image *,const DrawInfo *,const PrimitiveInfo *); static size_t TracePath(MVGInfo *,const char *,ExceptionInfo *); /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % A c q u i r e D r a w I n f o % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % AcquireDrawInfo() returns a DrawInfo structure properly initialized. % % The format of the AcquireDrawInfo method is: % % DrawInfo *AcquireDrawInfo(void) % */ MagickExport DrawInfo *AcquireDrawInfo(void) { DrawInfo *draw_info; draw_info=(DrawInfo *) AcquireCriticalMemory(sizeof(*draw_info)); GetDrawInfo((ImageInfo *) NULL,draw_info); return(draw_info); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % C l o n e D r a w I n f o % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % CloneDrawInfo() makes a copy of the given draw_info structure. If NULL % is specified, a new DrawInfo structure is created initialized to default % values. % % The format of the CloneDrawInfo method is: % % DrawInfo *CloneDrawInfo(const ImageInfo *image_info, % const DrawInfo *draw_info) % % A description of each parameter follows: % % o image_info: the image info. % % o draw_info: the draw info. % */ MagickExport DrawInfo *CloneDrawInfo(const ImageInfo *image_info, const DrawInfo *draw_info) { DrawInfo *clone_info; ExceptionInfo *exception; clone_info=(DrawInfo *) AcquireCriticalMemory(sizeof(*clone_info)); GetDrawInfo(image_info,clone_info); if (draw_info == (DrawInfo *) NULL) return(clone_info); exception=AcquireExceptionInfo(); if (draw_info->id != (char *) NULL) (void) CloneString(&clone_info->id,draw_info->id); if (draw_info->primitive != (char *) NULL) (void) CloneString(&clone_info->primitive,draw_info->primitive); if (draw_info->geometry != (char *) NULL) (void) CloneString(&clone_info->geometry,draw_info->geometry); clone_info->compliance=draw_info->compliance; clone_info->viewbox=draw_info->viewbox; clone_info->affine=draw_info->affine; clone_info->gravity=draw_info->gravity; clone_info->fill=draw_info->fill; clone_info->stroke=draw_info->stroke; clone_info->stroke_width=draw_info->stroke_width; if (draw_info->fill_pattern != (Image *) NULL) clone_info->fill_pattern=CloneImage(draw_info->fill_pattern,0,0,MagickTrue, exception); if (draw_info->stroke_pattern != (Image *) NULL) clone_info->stroke_pattern=CloneImage(draw_info->stroke_pattern,0,0, MagickTrue,exception); clone_info->stroke_antialias=draw_info->stroke_antialias; clone_info->text_antialias=draw_info->text_antialias; clone_info->fill_rule=draw_info->fill_rule; clone_info->linecap=draw_info->linecap; clone_info->linejoin=draw_info->linejoin; clone_info->miterlimit=draw_info->miterlimit; clone_info->dash_offset=draw_info->dash_offset; clone_info->decorate=draw_info->decorate; clone_info->compose=draw_info->compose; if (draw_info->text != (char *) NULL) (void) CloneString(&clone_info->text,draw_info->text); if (draw_info->font != (char *) NULL) (void) CloneString(&clone_info->font,draw_info->font); if (draw_info->metrics != (char *) NULL) (void) CloneString(&clone_info->metrics,draw_info->metrics); if (draw_info->family != (char *) NULL) (void) CloneString(&clone_info->family,draw_info->family); clone_info->style=draw_info->style; clone_info->stretch=draw_info->stretch; clone_info->weight=draw_info->weight; if (draw_info->encoding != (char *) NULL) (void) CloneString(&clone_info->encoding,draw_info->encoding); clone_info->pointsize=draw_info->pointsize; clone_info->kerning=draw_info->kerning; clone_info->interline_spacing=draw_info->interline_spacing; clone_info->interword_spacing=draw_info->interword_spacing; clone_info->direction=draw_info->direction; if (draw_info->density != (char *) NULL) (void) CloneString(&clone_info->density,draw_info->density); clone_info->align=draw_info->align; clone_info->undercolor=draw_info->undercolor; clone_info->border_color=draw_info->border_color; if (draw_info->server_name != (char *) NULL) (void) CloneString(&clone_info->server_name,draw_info->server_name); if (draw_info->dash_pattern != (double *) NULL) { register ssize_t x; for (x=0; fabs(draw_info->dash_pattern[x]) >= MagickEpsilon; x++) ; clone_info->dash_pattern=(double *) AcquireQuantumMemory((size_t) (2*x+2), sizeof(*clone_info->dash_pattern)); if (clone_info->dash_pattern == (double *) NULL) ThrowFatalException(ResourceLimitFatalError, "UnableToAllocateDashPattern"); (void) memset(clone_info->dash_pattern,0,(size_t) (2*x+2)* sizeof(*clone_info->dash_pattern)); (void) memcpy(clone_info->dash_pattern,draw_info->dash_pattern,(size_t) (x+1)*sizeof(*clone_info->dash_pattern)); } clone_info->gradient=draw_info->gradient; if (draw_info->gradient.stops != (StopInfo *) NULL) { size_t number_stops; number_stops=clone_info->gradient.number_stops; clone_info->gradient.stops=(StopInfo *) AcquireQuantumMemory((size_t) number_stops,sizeof(*clone_info->gradient.stops)); if (clone_info->gradient.stops == (StopInfo *) NULL) ThrowFatalException(ResourceLimitFatalError, "UnableToAllocateDashPattern"); (void) memcpy(clone_info->gradient.stops,draw_info->gradient.stops, (size_t) number_stops*sizeof(*clone_info->gradient.stops)); } clone_info->bounds=draw_info->bounds; clone_info->fill_alpha=draw_info->fill_alpha; clone_info->stroke_alpha=draw_info->stroke_alpha; clone_info->element_reference=draw_info->element_reference; clone_info->clip_path=draw_info->clip_path; clone_info->clip_units=draw_info->clip_units; if (draw_info->clip_mask != (char *) NULL) (void) CloneString(&clone_info->clip_mask,draw_info->clip_mask); if (draw_info->clipping_mask != (Image *) NULL) clone_info->clipping_mask=CloneImage(draw_info->clipping_mask,0,0, MagickTrue,exception); if (draw_info->composite_mask != (Image *) NULL) clone_info->composite_mask=CloneImage(draw_info->composite_mask,0,0, MagickTrue,exception); clone_info->render=draw_info->render; clone_info->debug=IsEventLogging(); exception=DestroyExceptionInfo(exception); return(clone_info); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % + C o n v e r t P a t h T o P o l y g o n % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % ConvertPathToPolygon() converts a path to the more efficient sorted % rendering form. % % The format of the ConvertPathToPolygon method is: % % PolygonInfo *ConvertPathToPolygon(const PathInfo *path_info) % % A description of each parameter follows: % % o Method ConvertPathToPolygon returns the path in a more efficient sorted % rendering form of type PolygonInfo. % % o draw_info: Specifies a pointer to an DrawInfo structure. % % o path_info: Specifies a pointer to an PathInfo structure. % % */ #if defined(__cplusplus) || defined(c_plusplus) extern "C" { #endif static int DrawCompareEdges(const void *p_edge,const void *q_edge) { #define DrawCompareEdge(p,q) \ { \ if (((p)-(q)) < 0.0) \ return(-1); \ if (((p)-(q)) > 0.0) \ return(1); \ } register const PointInfo *p, *q; /* Edge sorting for right-handed coordinate system. */ p=((const EdgeInfo *) p_edge)->points; q=((const EdgeInfo *) q_edge)->points; DrawCompareEdge(p[0].y,q[0].y); DrawCompareEdge(p[0].x,q[0].x); DrawCompareEdge((p[1].x-p[0].x)*(q[1].y-q[0].y),(p[1].y-p[0].y)* (q[1].x-q[0].x)); DrawCompareEdge(p[1].y,q[1].y); DrawCompareEdge(p[1].x,q[1].x); return(0); } #if defined(__cplusplus) || defined(c_plusplus) } #endif static void LogPolygonInfo(const PolygonInfo *polygon_info) { register EdgeInfo *p; register ssize_t i, j; (void) LogMagickEvent(DrawEvent,GetMagickModule()," begin active-edge"); p=polygon_info->edges; for (i=0; i < (ssize_t) polygon_info->number_edges; i++) { (void) LogMagickEvent(DrawEvent,GetMagickModule()," edge %.20g:", (double) i); (void) LogMagickEvent(DrawEvent,GetMagickModule()," direction: %s", p->direction != MagickFalse ? "down" : "up"); (void) LogMagickEvent(DrawEvent,GetMagickModule()," ghostline: %s", p->ghostline != MagickFalse ? "transparent" : "opaque"); (void) LogMagickEvent(DrawEvent,GetMagickModule(), " bounds: %g,%g - %g,%g",p->bounds.x1,p->bounds.y1, p->bounds.x2,p->bounds.y2); for (j=0; j < (ssize_t) p->number_points; j++) (void) LogMagickEvent(DrawEvent,GetMagickModule()," %g,%g", p->points[j].x,p->points[j].y); p++; } (void) LogMagickEvent(DrawEvent,GetMagickModule()," end active-edge"); } static void ReversePoints(PointInfo *points,const size_t number_points) { PointInfo point; register ssize_t i; for (i=0; i < (ssize_t) (number_points >> 1); i++) { point=points[i]; points[i]=points[number_points-(i+1)]; points[number_points-(i+1)]=point; } } static PolygonInfo *ConvertPathToPolygon(const PathInfo *path_info) { long direction, next_direction; PointInfo point, *points; PolygonInfo *polygon_info; SegmentInfo bounds; register ssize_t i, n; MagickBooleanType ghostline; size_t edge, number_edges, number_points; /* Convert a path to the more efficient sorted rendering form. */ polygon_info=(PolygonInfo *) AcquireMagickMemory(sizeof(*polygon_info)); if (polygon_info == (PolygonInfo *) NULL) return((PolygonInfo *) NULL); number_edges=16; polygon_info->edges=(EdgeInfo *) AcquireQuantumMemory(number_edges, sizeof(*polygon_info->edges)); if (polygon_info->edges == (EdgeInfo *) NULL) return((PolygonInfo *) NULL); (void) memset(polygon_info->edges,0,number_edges* sizeof(*polygon_info->edges)); direction=0; edge=0; ghostline=MagickFalse; n=0; number_points=0; points=(PointInfo *) NULL; (void) memset(&point,0,sizeof(point)); (void) memset(&bounds,0,sizeof(bounds)); polygon_info->edges[edge].number_points=(size_t) n; polygon_info->edges[edge].scanline=0.0; polygon_info->edges[edge].highwater=0; polygon_info->edges[edge].ghostline=ghostline; polygon_info->edges[edge].direction=(ssize_t) direction; polygon_info->edges[edge].points=points; polygon_info->edges[edge].bounds=bounds; polygon_info->number_edges=0; for (i=0; path_info[i].code != EndCode; i++) { if ((path_info[i].code == MoveToCode) || (path_info[i].code == OpenCode) || (path_info[i].code == GhostlineCode)) { /* Move to. */ if ((points != (PointInfo *) NULL) && (n >= 2)) { if (edge == number_edges) { number_edges<<=1; polygon_info->edges=(EdgeInfo *) ResizeQuantumMemory( polygon_info->edges,(size_t) number_edges, sizeof(*polygon_info->edges)); if (polygon_info->edges == (EdgeInfo *) NULL) return((PolygonInfo *) NULL); } polygon_info->edges[edge].number_points=(size_t) n; polygon_info->edges[edge].scanline=(-1.0); polygon_info->edges[edge].highwater=0; polygon_info->edges[edge].ghostline=ghostline; polygon_info->edges[edge].direction=(ssize_t) (direction > 0); if (direction < 0) ReversePoints(points,(size_t) n); polygon_info->edges[edge].points=points; polygon_info->edges[edge].bounds=bounds; polygon_info->edges[edge].bounds.y1=points[0].y; polygon_info->edges[edge].bounds.y2=points[n-1].y; points=(PointInfo *) NULL; ghostline=MagickFalse; edge++; } if (points == (PointInfo *) NULL) { number_points=16; points=(PointInfo *) AcquireQuantumMemory((size_t) number_points, sizeof(*points)); if (points == (PointInfo *) NULL) return((PolygonInfo *) NULL); } ghostline=path_info[i].code == GhostlineCode ? MagickTrue : MagickFalse; point=path_info[i].point; points[0]=point; bounds.x1=point.x; bounds.x2=point.x; direction=0; n=1; continue; } /* Line to. */ next_direction=((path_info[i].point.y > point.y) || ((fabs(path_info[i].point.y-point.y) < MagickEpsilon) && (path_info[i].point.x > point.x))) ? 1 : -1; if ((points != (PointInfo *) NULL) && (direction != 0) && (direction != next_direction)) { /* New edge. */ point=points[n-1]; if (edge == number_edges) { number_edges<<=1; polygon_info->edges=(EdgeInfo *) ResizeQuantumMemory( polygon_info->edges,(size_t) number_edges, sizeof(*polygon_info->edges)); if (polygon_info->edges == (EdgeInfo *) NULL) return((PolygonInfo *) NULL); } polygon_info->edges[edge].number_points=(size_t) n; polygon_info->edges[edge].scanline=(-1.0); polygon_info->edges[edge].highwater=0; polygon_info->edges[edge].ghostline=ghostline; polygon_info->edges[edge].direction=(ssize_t) (direction > 0); if (direction < 0) ReversePoints(points,(size_t) n); polygon_info->edges[edge].points=points; polygon_info->edges[edge].bounds=bounds; polygon_info->edges[edge].bounds.y1=points[0].y; polygon_info->edges[edge].bounds.y2=points[n-1].y; number_points=16; points=(PointInfo *) AcquireQuantumMemory((size_t) number_points, sizeof(*points)); if (points == (PointInfo *) NULL) return((PolygonInfo *) NULL); n=1; ghostline=MagickFalse; points[0]=point; bounds.x1=point.x; bounds.x2=point.x; edge++; } direction=next_direction; if (points == (PointInfo *) NULL) continue; if (n == (ssize_t) number_points) { number_points<<=1; points=(PointInfo *) ResizeQuantumMemory(points,(size_t) number_points, sizeof(*points)); if (points == (PointInfo *) NULL) return((PolygonInfo *) NULL); } point=path_info[i].point; points[n]=point; if (point.x < bounds.x1) bounds.x1=point.x; if (point.x > bounds.x2) bounds.x2=point.x; n++; } if (points != (PointInfo *) NULL) { if (n < 2) points=(PointInfo *) RelinquishMagickMemory(points); else { if (edge == number_edges) { number_edges<<=1; polygon_info->edges=(EdgeInfo *) ResizeQuantumMemory( polygon_info->edges,(size_t) number_edges, sizeof(*polygon_info->edges)); if (polygon_info->edges == (EdgeInfo *) NULL) return((PolygonInfo *) NULL); } polygon_info->edges[edge].number_points=(size_t) n; polygon_info->edges[edge].scanline=(-1.0); polygon_info->edges[edge].highwater=0; polygon_info->edges[edge].ghostline=ghostline; polygon_info->edges[edge].direction=(ssize_t) (direction > 0); if (direction < 0) ReversePoints(points,(size_t) n); polygon_info->edges[edge].points=points; polygon_info->edges[edge].bounds=bounds; polygon_info->edges[edge].bounds.y1=points[0].y; polygon_info->edges[edge].bounds.y2=points[n-1].y; ghostline=MagickFalse; edge++; } } polygon_info->number_edges=edge; qsort(polygon_info->edges,(size_t) polygon_info->number_edges, sizeof(*polygon_info->edges),DrawCompareEdges); if (IsEventLogging() != MagickFalse) LogPolygonInfo(polygon_info); return(polygon_info); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % + C o n v e r t P r i m i t i v e T o P a t h % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % ConvertPrimitiveToPath() converts a PrimitiveInfo structure into a vector % path structure. % % The format of the ConvertPrimitiveToPath method is: % % PathInfo *ConvertPrimitiveToPath(const DrawInfo *draw_info, % const PrimitiveInfo *primitive_info) % % A description of each parameter follows: % % o Method ConvertPrimitiveToPath returns a vector path structure of type % PathInfo. % % o draw_info: a structure of type DrawInfo. % % o primitive_info: Specifies a pointer to an PrimitiveInfo structure. % % */ static void LogPathInfo(const PathInfo *path_info) { register const PathInfo *p; (void) LogMagickEvent(DrawEvent,GetMagickModule()," begin vector-path"); for (p=path_info; p->code != EndCode; p++) (void) LogMagickEvent(DrawEvent,GetMagickModule(), " %g,%g %s",p->point.x,p->point.y,p->code == GhostlineCode ? "moveto ghostline" : p->code == OpenCode ? "moveto open" : p->code == MoveToCode ? "moveto" : p->code == LineToCode ? "lineto" : "?"); (void) LogMagickEvent(DrawEvent,GetMagickModule()," end vector-path"); } static PathInfo *ConvertPrimitiveToPath(const PrimitiveInfo *primitive_info) { MagickBooleanType closed_subpath; PathInfo *path_info; PathInfoCode code; PointInfo p, q; register ssize_t i, n; ssize_t coordinates, start; /* Converts a PrimitiveInfo structure into a vector path structure. */ switch (primitive_info->primitive) { case AlphaPrimitive: case ColorPrimitive: case ImagePrimitive: case PointPrimitive: case TextPrimitive: return((PathInfo *) NULL); default: break; } for (i=0; primitive_info[i].primitive != UndefinedPrimitive; i++) ; path_info=(PathInfo *) AcquireQuantumMemory((size_t) (3UL*i+1UL), sizeof(*path_info)); if (path_info == (PathInfo *) NULL) return((PathInfo *) NULL); coordinates=0; closed_subpath=MagickFalse; n=0; p.x=(-1.0); p.y=(-1.0); q.x=(-1.0); q.y=(-1.0); start=0; for (i=0; primitive_info[i].primitive != UndefinedPrimitive; i++) { code=LineToCode; if (coordinates <= 0) { /* New subpath. */ coordinates=(ssize_t) primitive_info[i].coordinates; p=primitive_info[i].point; start=n; code=MoveToCode; closed_subpath=primitive_info[i].closed_subpath; } coordinates--; if ((code == MoveToCode) || (coordinates <= 0) || (fabs(q.x-primitive_info[i].point.x) >= MagickEpsilon) || (fabs(q.y-primitive_info[i].point.y) >= MagickEpsilon)) { /* Eliminate duplicate points. */ path_info[n].code=code; path_info[n].point=primitive_info[i].point; q=primitive_info[i].point; n++; } if (coordinates > 0) continue; /* next point in current subpath */ if (closed_subpath != MagickFalse) { closed_subpath=MagickFalse; continue; } /* Mark the p point as open if the subpath is not closed. */ path_info[start].code=OpenCode; path_info[n].code=GhostlineCode; path_info[n].point=primitive_info[i].point; n++; path_info[n].code=LineToCode; path_info[n].point=p; n++; } path_info[n].code=EndCode; path_info[n].point.x=0.0; path_info[n].point.y=0.0; if (IsEventLogging() != MagickFalse) LogPathInfo(path_info); path_info=(PathInfo *) ResizeQuantumMemory(path_info,(size_t) (n+1), sizeof(*path_info)); return(path_info); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % D e s t r o y D r a w I n f o % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % DestroyDrawInfo() deallocates memory associated with an DrawInfo structure. % % The format of the DestroyDrawInfo method is: % % DrawInfo *DestroyDrawInfo(DrawInfo *draw_info) % % A description of each parameter follows: % % o draw_info: the draw info. % */ MagickExport DrawInfo *DestroyDrawInfo(DrawInfo *draw_info) { assert(draw_info != (DrawInfo *) NULL); if (draw_info->debug != MagickFalse) (void) LogMagickEvent(TraceEvent,GetMagickModule(),"..."); assert(draw_info->signature == MagickCoreSignature); if (draw_info->id != (char *) NULL) draw_info->id=DestroyString(draw_info->id); if (draw_info->primitive != (char *) NULL) draw_info->primitive=DestroyString(draw_info->primitive); if (draw_info->text != (char *) NULL) draw_info->text=DestroyString(draw_info->text); if (draw_info->geometry != (char *) NULL) draw_info->geometry=DestroyString(draw_info->geometry); if (draw_info->fill_pattern != (Image *) NULL) draw_info->fill_pattern=DestroyImage(draw_info->fill_pattern); if (draw_info->stroke_pattern != (Image *) NULL) draw_info->stroke_pattern=DestroyImage(draw_info->stroke_pattern); if (draw_info->font != (char *) NULL) draw_info->font=DestroyString(draw_info->font); if (draw_info->metrics != (char *) NULL) draw_info->metrics=DestroyString(draw_info->metrics); if (draw_info->family != (char *) NULL) draw_info->family=DestroyString(draw_info->family); if (draw_info->encoding != (char *) NULL) draw_info->encoding=DestroyString(draw_info->encoding); if (draw_info->density != (char *) NULL) draw_info->density=DestroyString(draw_info->density); if (draw_info->server_name != (char *) NULL) draw_info->server_name=(char *) RelinquishMagickMemory(draw_info->server_name); if (draw_info->dash_pattern != (double *) NULL) draw_info->dash_pattern=(double *) RelinquishMagickMemory( draw_info->dash_pattern); if (draw_info->gradient.stops != (StopInfo *) NULL) draw_info->gradient.stops=(StopInfo *) RelinquishMagickMemory( draw_info->gradient.stops); if (draw_info->clip_mask != (char *) NULL) draw_info->clip_mask=DestroyString(draw_info->clip_mask); if (draw_info->clipping_mask != (Image *) NULL) draw_info->clipping_mask=DestroyImage(draw_info->clipping_mask); if (draw_info->composite_mask != (Image *) NULL) draw_info->composite_mask=DestroyImage(draw_info->composite_mask); draw_info->signature=(~MagickCoreSignature); draw_info=(DrawInfo *) RelinquishMagickMemory(draw_info); return(draw_info); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % + D e s t r o y E d g e % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % DestroyEdge() destroys the specified polygon edge. % % The format of the DestroyEdge method is: % % ssize_t DestroyEdge(PolygonInfo *polygon_info,const int edge) % % A description of each parameter follows: % % o polygon_info: Specifies a pointer to an PolygonInfo structure. % % o edge: the polygon edge number to destroy. % */ static size_t DestroyEdge(PolygonInfo *polygon_info, const size_t edge) { assert(edge < polygon_info->number_edges); polygon_info->edges[edge].points=(PointInfo *) RelinquishMagickMemory( polygon_info->edges[edge].points); polygon_info->number_edges--; if (edge < polygon_info->number_edges) (void) memmove(polygon_info->edges+edge,polygon_info->edges+edge+1, (size_t) (polygon_info->number_edges-edge)*sizeof(*polygon_info->edges)); return(polygon_info->number_edges); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % + D e s t r o y P o l y g o n I n f o % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % DestroyPolygonInfo() destroys the PolygonInfo data structure. % % The format of the DestroyPolygonInfo method is: % % PolygonInfo *DestroyPolygonInfo(PolygonInfo *polygon_info) % % A description of each parameter follows: % % o polygon_info: Specifies a pointer to an PolygonInfo structure. % */ static PolygonInfo *DestroyPolygonInfo(PolygonInfo *polygon_info) { register ssize_t i; for (i=0; i < (ssize_t) polygon_info->number_edges; i++) polygon_info->edges[i].points=(PointInfo *) RelinquishMagickMemory(polygon_info->edges[i].points); polygon_info->edges=(EdgeInfo *) RelinquishMagickMemory(polygon_info->edges); return((PolygonInfo *) RelinquishMagickMemory(polygon_info)); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % D r a w A f f i n e I m a g e % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % DrawAffineImage() composites the source over the destination image as % dictated by the affine transform. % % The format of the DrawAffineImage method is: % % MagickBooleanType DrawAffineImage(Image *image,const Image *source, % const AffineMatrix *affine,ExceptionInfo *exception) % % A description of each parameter follows: % % o image: the image. % % o source: the source image. % % o affine: the affine transform. % % o exception: return any errors or warnings in this structure. % */ static SegmentInfo AffineEdge(const Image *image,const AffineMatrix *affine, const double y,const SegmentInfo *edge) { double intercept, z; register double x; SegmentInfo inverse_edge; /* Determine left and right edges. */ inverse_edge.x1=edge->x1; inverse_edge.y1=edge->y1; inverse_edge.x2=edge->x2; inverse_edge.y2=edge->y2; z=affine->ry*y+affine->tx; if (affine->sx >= MagickEpsilon) { intercept=(-z/affine->sx); x=intercept; if (x > inverse_edge.x1) inverse_edge.x1=x; intercept=(-z+(double) image->columns)/affine->sx; x=intercept; if (x < inverse_edge.x2) inverse_edge.x2=x; } else if (affine->sx < -MagickEpsilon) { intercept=(-z+(double) image->columns)/affine->sx; x=intercept; if (x > inverse_edge.x1) inverse_edge.x1=x; intercept=(-z/affine->sx); x=intercept; if (x < inverse_edge.x2) inverse_edge.x2=x; } else if ((z < 0.0) || ((size_t) floor(z+0.5) >= image->columns)) { inverse_edge.x2=edge->x1; return(inverse_edge); } /* Determine top and bottom edges. */ z=affine->sy*y+affine->ty; if (affine->rx >= MagickEpsilon) { intercept=(-z/affine->rx); x=intercept; if (x > inverse_edge.x1) inverse_edge.x1=x; intercept=(-z+(double) image->rows)/affine->rx; x=intercept; if (x < inverse_edge.x2) inverse_edge.x2=x; } else if (affine->rx < -MagickEpsilon) { intercept=(-z+(double) image->rows)/affine->rx; x=intercept; if (x > inverse_edge.x1) inverse_edge.x1=x; intercept=(-z/affine->rx); x=intercept; if (x < inverse_edge.x2) inverse_edge.x2=x; } else if ((z < 0.0) || ((size_t) floor(z+0.5) >= image->rows)) { inverse_edge.x2=edge->x2; return(inverse_edge); } return(inverse_edge); } static AffineMatrix InverseAffineMatrix(const AffineMatrix *affine) { AffineMatrix inverse_affine; double determinant; determinant=PerceptibleReciprocal(affine->sx*affine->sy-affine->rx* affine->ry); inverse_affine.sx=determinant*affine->sy; inverse_affine.rx=determinant*(-affine->rx); inverse_affine.ry=determinant*(-affine->ry); inverse_affine.sy=determinant*affine->sx; inverse_affine.tx=(-affine->tx)*inverse_affine.sx-affine->ty* inverse_affine.ry; inverse_affine.ty=(-affine->tx)*inverse_affine.rx-affine->ty* inverse_affine.sy; return(inverse_affine); } MagickExport MagickBooleanType DrawAffineImage(Image *image, const Image *source,const AffineMatrix *affine,ExceptionInfo *exception) { AffineMatrix inverse_affine; CacheView *image_view, *source_view; MagickBooleanType status; PixelInfo zero; PointInfo extent[4], min, max; register ssize_t i; SegmentInfo edge; ssize_t start, stop, y; /* Determine bounding box. */ assert(image != (Image *) NULL); assert(image->signature == MagickCoreSignature); if (image->debug != MagickFalse) (void) LogMagickEvent(TraceEvent,GetMagickModule(),"%s",image->filename); assert(source != (const Image *) NULL); assert(source->signature == MagickCoreSignature); assert(affine != (AffineMatrix *) NULL); extent[0].x=0.0; extent[0].y=0.0; extent[1].x=(double) source->columns-1.0; extent[1].y=0.0; extent[2].x=(double) source->columns-1.0; extent[2].y=(double) source->rows-1.0; extent[3].x=0.0; extent[3].y=(double) source->rows-1.0; for (i=0; i < 4; i++) { PointInfo point; point=extent[i]; extent[i].x=point.x*affine->sx+point.y*affine->ry+affine->tx; extent[i].y=point.x*affine->rx+point.y*affine->sy+affine->ty; } min=extent[0]; max=extent[0]; for (i=1; i < 4; i++) { if (min.x > extent[i].x) min.x=extent[i].x; if (min.y > extent[i].y) min.y=extent[i].y; if (max.x < extent[i].x) max.x=extent[i].x; if (max.y < extent[i].y) max.y=extent[i].y; } /* Affine transform image. */ if (SetImageStorageClass(image,DirectClass,exception) == MagickFalse) return(MagickFalse); status=MagickTrue; edge.x1=MagickMax(min.x,0.0); edge.y1=MagickMax(min.y,0.0); edge.x2=MagickMin(max.x,(double) image->columns-1.0); edge.y2=MagickMin(max.y,(double) image->rows-1.0); inverse_affine=InverseAffineMatrix(affine); GetPixelInfo(image,&zero); start=(ssize_t) ceil(edge.y1-0.5); stop=(ssize_t) floor(edge.y2+0.5); source_view=AcquireVirtualCacheView(source,exception); image_view=AcquireAuthenticCacheView(image,exception); #if defined(MAGICKCORE_OPENMP_SUPPORT) #pragma omp parallel for schedule(static) shared(status) \ magick_number_threads(source,image,stop-start,1) #endif for (y=start; y <= stop; y++) { PixelInfo composite, pixel; PointInfo point; register ssize_t x; register Quantum *magick_restrict q; SegmentInfo inverse_edge; ssize_t x_offset; inverse_edge=AffineEdge(source,&inverse_affine,(double) y,&edge); if (inverse_edge.x2 < inverse_edge.x1) continue; q=GetCacheViewAuthenticPixels(image_view,(ssize_t) ceil(inverse_edge.x1- 0.5),y,(size_t) (floor(inverse_edge.x2+0.5)-ceil(inverse_edge.x1-0.5)+1), 1,exception); if (q == (Quantum *) NULL) continue; pixel=zero; composite=zero; x_offset=0; for (x=(ssize_t) ceil(inverse_edge.x1-0.5); x <= (ssize_t) floor(inverse_edge.x2+0.5); x++) { point.x=(double) x*inverse_affine.sx+y*inverse_affine.ry+ inverse_affine.tx; point.y=(double) x*inverse_affine.rx+y*inverse_affine.sy+ inverse_affine.ty; status=InterpolatePixelInfo(source,source_view,UndefinedInterpolatePixel, point.x,point.y,&pixel,exception); if (status == MagickFalse) break; GetPixelInfoPixel(image,q,&composite); CompositePixelInfoOver(&pixel,pixel.alpha,&composite,composite.alpha, &composite); SetPixelViaPixelInfo(image,&composite,q); x_offset++; q+=GetPixelChannels(image); } if (SyncCacheViewAuthenticPixels(image_view,exception) == MagickFalse) status=MagickFalse; } source_view=DestroyCacheView(source_view); image_view=DestroyCacheView(image_view); return(status); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % + D r a w B o u n d i n g R e c t a n g l e s % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % DrawBoundingRectangles() draws the bounding rectangles on the image. This % is only useful for developers debugging the rendering algorithm. % % The format of the DrawBoundingRectangles method is: % % MagickBooleanType DrawBoundingRectangles(Image *image, % const DrawInfo *draw_info,PolygonInfo *polygon_info, % ExceptionInfo *exception) % % A description of each parameter follows: % % o image: the image. % % o draw_info: the draw info. % % o polygon_info: Specifies a pointer to a PolygonInfo structure. % % o exception: return any errors or warnings in this structure. % */ static inline double SaneStrokeWidth(const Image *image, const DrawInfo *draw_info) { return(MagickMin((double) draw_info->stroke_width, (2.0*sqrt(2.0)+MagickEpsilon)*MagickMax(image->columns,image->rows))); } static MagickBooleanType DrawBoundingRectangles(Image *image, const DrawInfo *draw_info,const PolygonInfo *polygon_info, ExceptionInfo *exception) { double mid; DrawInfo *clone_info; MagickStatusType status; PointInfo end, resolution, start; PrimitiveInfo primitive_info[6]; register ssize_t i; SegmentInfo bounds; ssize_t coordinates; (void) memset(primitive_info,0,sizeof(primitive_info)); clone_info=CloneDrawInfo((ImageInfo *) NULL,draw_info); status=QueryColorCompliance("#000F",AllCompliance,&clone_info->fill, exception); if (status == MagickFalse) { clone_info=DestroyDrawInfo(clone_info); return(MagickFalse); } resolution.x=96.0; resolution.y=96.0; if (clone_info->density != (char *) NULL) { GeometryInfo geometry_info; MagickStatusType flags; flags=ParseGeometry(clone_info->density,&geometry_info); resolution.x=geometry_info.rho; resolution.y=geometry_info.sigma; if ((flags & SigmaValue) == MagickFalse) resolution.y=resolution.x; } mid=(resolution.x/96.0)*ExpandAffine(&clone_info->affine)* SaneStrokeWidth(image,clone_info)/2.0; bounds.x1=0.0; bounds.y1=0.0; bounds.x2=0.0; bounds.y2=0.0; if (polygon_info != (PolygonInfo *) NULL) { bounds=polygon_info->edges[0].bounds; for (i=1; i < (ssize_t) polygon_info->number_edges; i++) { if (polygon_info->edges[i].bounds.x1 < (double) bounds.x1) bounds.x1=polygon_info->edges[i].bounds.x1; if (polygon_info->edges[i].bounds.y1 < (double) bounds.y1) bounds.y1=polygon_info->edges[i].bounds.y1; if (polygon_info->edges[i].bounds.x2 > (double) bounds.x2) bounds.x2=polygon_info->edges[i].bounds.x2; if (polygon_info->edges[i].bounds.y2 > (double) bounds.y2) bounds.y2=polygon_info->edges[i].bounds.y2; } bounds.x1-=mid; bounds.x1=bounds.x1 < 0.0 ? 0.0 : bounds.x1 >= (double) image->columns ? (double) image->columns-1 : bounds.x1; bounds.y1-=mid; bounds.y1=bounds.y1 < 0.0 ? 0.0 : bounds.y1 >= (double) image->rows ? (double) image->rows-1 : bounds.y1; bounds.x2+=mid; bounds.x2=bounds.x2 < 0.0 ? 0.0 : bounds.x2 >= (double) image->columns ? (double) image->columns-1 : bounds.x2; bounds.y2+=mid; bounds.y2=bounds.y2 < 0.0 ? 0.0 : bounds.y2 >= (double) image->rows ? (double) image->rows-1 : bounds.y2; for (i=0; i < (ssize_t) polygon_info->number_edges; i++) { if (polygon_info->edges[i].direction != 0) status=QueryColorCompliance("#f00",AllCompliance,&clone_info->stroke, exception); else status=QueryColorCompliance("#0f0",AllCompliance,&clone_info->stroke, exception); if (status == MagickFalse) break; start.x=(double) (polygon_info->edges[i].bounds.x1-mid); start.y=(double) (polygon_info->edges[i].bounds.y1-mid); end.x=(double) (polygon_info->edges[i].bounds.x2+mid); end.y=(double) (polygon_info->edges[i].bounds.y2+mid); primitive_info[0].primitive=RectanglePrimitive; status&=TraceRectangle(primitive_info,start,end); primitive_info[0].method=ReplaceMethod; coordinates=(ssize_t) primitive_info[0].coordinates; primitive_info[coordinates].primitive=UndefinedPrimitive; status=DrawPrimitive(image,clone_info,primitive_info,exception); if (status == MagickFalse) break; } if (i < (ssize_t) polygon_info->number_edges) { clone_info=DestroyDrawInfo(clone_info); return(status == 0 ? MagickFalse : MagickTrue); } } status=QueryColorCompliance("#00f",AllCompliance,&clone_info->stroke, exception); if (status == MagickFalse) { clone_info=DestroyDrawInfo(clone_info); return(MagickFalse); } start.x=(double) (bounds.x1-mid); start.y=(double) (bounds.y1-mid); end.x=(double) (bounds.x2+mid); end.y=(double) (bounds.y2+mid); primitive_info[0].primitive=RectanglePrimitive; status&=TraceRectangle(primitive_info,start,end); primitive_info[0].method=ReplaceMethod; coordinates=(ssize_t) primitive_info[0].coordinates; primitive_info[coordinates].primitive=UndefinedPrimitive; status=DrawPrimitive(image,clone_info,primitive_info,exception); clone_info=DestroyDrawInfo(clone_info); return(status == 0 ? MagickFalse : MagickTrue); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % D r a w C l i p P a t h % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % DrawClipPath() draws the clip path on the image mask. % % The format of the DrawClipPath method is: % % MagickBooleanType DrawClipPath(Image *image,const DrawInfo *draw_info, % const char *id,ExceptionInfo *exception) % % A description of each parameter follows: % % o image: the image. % % o draw_info: the draw info. % % o id: the clip path id. % % o exception: return any errors or warnings in this structure. % */ MagickExport MagickBooleanType DrawClipPath(Image *image, const DrawInfo *draw_info,const char *id,ExceptionInfo *exception) { const char *clip_path; Image *clipping_mask; MagickBooleanType status; clip_path=GetImageArtifact(image,id); if (clip_path == (const char *) NULL) return(MagickFalse); clipping_mask=DrawClippingMask(image,draw_info,draw_info->clip_mask,clip_path, exception); if (clipping_mask == (Image *) NULL) return(MagickFalse); status=SetImageMask(image,WritePixelMask,clipping_mask,exception); clipping_mask=DestroyImage(clipping_mask); return(status); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % D r a w C l i p p i n g M a s k % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % DrawClippingMask() draws the clip path and returns it as an image clipping % mask. % % The format of the DrawClippingMask method is: % % Image *DrawClippingMask(Image *image,const DrawInfo *draw_info, % const char *id,const char *clip_path,ExceptionInfo *exception) % % A description of each parameter follows: % % o image: the image. % % o draw_info: the draw info. % % o id: the clip path id. % % o clip_path: the clip path. % % o exception: return any errors or warnings in this structure. % */ static Image *DrawClippingMask(Image *image,const DrawInfo *draw_info, const char *id,const char *clip_path,ExceptionInfo *exception) { DrawInfo *clone_info; Image *clip_mask, *separate_mask; MagickStatusType status; /* Draw a clip path. */ assert(image != (Image *) NULL); assert(image->signature == MagickCoreSignature); if (image->debug != MagickFalse) (void) LogMagickEvent(TraceEvent,GetMagickModule(),"%s",image->filename); assert(draw_info != (const DrawInfo *) NULL); clip_mask=AcquireImage((const ImageInfo *) NULL,exception); status=SetImageExtent(clip_mask,image->columns,image->rows,exception); if (status == MagickFalse) return(DestroyImage(clip_mask)); status=SetImageMask(clip_mask,WritePixelMask,(Image *) NULL,exception); status=QueryColorCompliance("#0000",AllCompliance, &clip_mask->background_color,exception); clip_mask->background_color.alpha=(MagickRealType) TransparentAlpha; clip_mask->background_color.alpha_trait=BlendPixelTrait; status=SetImageBackgroundColor(clip_mask,exception); if (image->debug != MagickFalse) (void) LogMagickEvent(DrawEvent,GetMagickModule(),"\nbegin clip-path %s", id); clone_info=CloneDrawInfo((ImageInfo *) NULL,draw_info); (void) CloneString(&clone_info->primitive,clip_path); status=QueryColorCompliance("#ffffff",AllCompliance,&clone_info->fill, exception); if (clone_info->clip_mask != (char *) NULL) clone_info->clip_mask=DestroyString(clone_info->clip_mask); status=QueryColorCompliance("#00000000",AllCompliance,&clone_info->stroke, exception); clone_info->stroke_width=0.0; clone_info->alpha=OpaqueAlpha; clone_info->clip_path=MagickTrue; status=RenderMVGContent(clip_mask,clone_info,0,exception); clone_info=DestroyDrawInfo(clone_info); separate_mask=SeparateImage(clip_mask,AlphaChannel,exception); if (separate_mask != (Image *) NULL) { clip_mask=DestroyImage(clip_mask); clip_mask=separate_mask; status=NegateImage(clip_mask,MagickFalse,exception); if (status == MagickFalse) clip_mask=DestroyImage(clip_mask); } if (image->debug != MagickFalse) (void) LogMagickEvent(DrawEvent,GetMagickModule(),"end clip-path"); return(clip_mask); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % D r a w C o m p o s i t e M a s k % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % DrawCompositeMask() draws the mask path and returns it as an image mask. % % The format of the DrawCompositeMask method is: % % Image *DrawCompositeMask(Image *image,const DrawInfo *draw_info, % const char *id,const char *mask_path,ExceptionInfo *exception) % % A description of each parameter follows: % % o image: the image. % % o draw_info: the draw info. % % o id: the mask path id. % % o mask_path: the mask path. % % o exception: return any errors or warnings in this structure. % */ static Image *DrawCompositeMask(Image *image,const DrawInfo *draw_info, const char *id,const char *mask_path,ExceptionInfo *exception) { Image *composite_mask, *separate_mask; DrawInfo *clone_info; MagickStatusType status; /* Draw a mask path. */ assert(image != (Image *) NULL); assert(image->signature == MagickCoreSignature); if (image->debug != MagickFalse) (void) LogMagickEvent(TraceEvent,GetMagickModule(),"%s",image->filename); assert(draw_info != (const DrawInfo *) NULL); composite_mask=AcquireImage((const ImageInfo *) NULL,exception); status=SetImageExtent(composite_mask,image->columns,image->rows,exception); if (status == MagickFalse) return(DestroyImage(composite_mask)); status=SetImageMask(composite_mask,CompositePixelMask,(Image *) NULL, exception); status=QueryColorCompliance("#0000",AllCompliance, &composite_mask->background_color,exception); composite_mask->background_color.alpha=(MagickRealType) TransparentAlpha; composite_mask->background_color.alpha_trait=BlendPixelTrait; (void) SetImageBackgroundColor(composite_mask,exception); if (image->debug != MagickFalse) (void) LogMagickEvent(DrawEvent,GetMagickModule(),"\nbegin mask-path %s", id); clone_info=CloneDrawInfo((ImageInfo *) NULL,draw_info); (void) CloneString(&clone_info->primitive,mask_path); status=QueryColorCompliance("#ffffff",AllCompliance,&clone_info->fill, exception); status=QueryColorCompliance("#00000000",AllCompliance,&clone_info->stroke, exception); clone_info->stroke_width=0.0; clone_info->alpha=OpaqueAlpha; status=RenderMVGContent(composite_mask,clone_info,0,exception); clone_info=DestroyDrawInfo(clone_info); separate_mask=SeparateImage(composite_mask,AlphaChannel,exception); if (separate_mask != (Image *) NULL) { composite_mask=DestroyImage(composite_mask); composite_mask=separate_mask; status=NegateImage(composite_mask,MagickFalse,exception); if (status == MagickFalse) composite_mask=DestroyImage(composite_mask); } if (image->debug != MagickFalse) (void) LogMagickEvent(DrawEvent,GetMagickModule(),"end mask-path"); return(composite_mask); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % + D r a w D a s h P o l y g o n % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % DrawDashPolygon() draws a dashed polygon (line, rectangle, ellipse) on the % image while respecting the dash offset and dash pattern attributes. % % The format of the DrawDashPolygon method is: % % MagickBooleanType DrawDashPolygon(const DrawInfo *draw_info, % const PrimitiveInfo *primitive_info,Image *image, % ExceptionInfo *exception) % % A description of each parameter follows: % % o draw_info: the draw info. % % o primitive_info: Specifies a pointer to a PrimitiveInfo structure. % % o image: the image. % % o exception: return any errors or warnings in this structure. % */ static MagickBooleanType DrawDashPolygon(const DrawInfo *draw_info, const PrimitiveInfo *primitive_info,Image *image,ExceptionInfo *exception) { double length, maximum_length, offset, scale, total_length; DrawInfo *clone_info; MagickStatusType status; PrimitiveInfo *dash_polygon; register double dx, dy; register ssize_t i; size_t number_vertices; ssize_t j, n; assert(draw_info != (const DrawInfo *) NULL); if (image->debug != MagickFalse) (void) LogMagickEvent(DrawEvent,GetMagickModule()," begin draw-dash"); for (i=0; primitive_info[i].primitive != UndefinedPrimitive; i++) ; number_vertices=(size_t) i; dash_polygon=(PrimitiveInfo *) AcquireQuantumMemory((size_t) (2UL*number_vertices+32UL),sizeof(*dash_polygon)); if (dash_polygon == (PrimitiveInfo *) NULL) return(MagickFalse); (void) memset(dash_polygon,0,(2UL*number_vertices+32UL)* sizeof(*dash_polygon)); clone_info=CloneDrawInfo((ImageInfo *) NULL,draw_info); clone_info->miterlimit=0; dash_polygon[0]=primitive_info[0]; scale=ExpandAffine(&draw_info->affine); length=scale*draw_info->dash_pattern[0]; offset=fabs(draw_info->dash_offset) >= MagickEpsilon ? scale*draw_info->dash_offset : 0.0; j=1; for (n=0; offset > 0.0; j=0) { if (draw_info->dash_pattern[n] <= 0.0) break; length=scale*(draw_info->dash_pattern[n]+(n == 0 ? -0.5 : 0.5)); if (offset > length) { offset-=length; n++; length=scale*draw_info->dash_pattern[n]; continue; } if (offset < length) { length-=offset; offset=0.0; break; } offset=0.0; n++; } status=MagickTrue; maximum_length=0.0; total_length=0.0; for (i=1; (i < (ssize_t) number_vertices) && (length >= 0.0); i++) { dx=primitive_info[i].point.x-primitive_info[i-1].point.x; dy=primitive_info[i].point.y-primitive_info[i-1].point.y; maximum_length=hypot(dx,dy); if (maximum_length > MaxBezierCoordinates) break; if (fabs(length) < MagickEpsilon) { if (fabs(draw_info->dash_pattern[n]) >= MagickEpsilon) n++; if (fabs(draw_info->dash_pattern[n]) < MagickEpsilon) n=0; length=scale*draw_info->dash_pattern[n]; } for (total_length=0.0; (length >= 0.0) && (maximum_length >= (total_length+length)); ) { total_length+=length; if ((n & 0x01) != 0) { dash_polygon[0]=primitive_info[0]; dash_polygon[0].point.x=(double) (primitive_info[i-1].point.x+dx* total_length*PerceptibleReciprocal(maximum_length)); dash_polygon[0].point.y=(double) (primitive_info[i-1].point.y+dy* total_length*PerceptibleReciprocal(maximum_length)); j=1; } else { if ((j+1) > (ssize_t) number_vertices) break; dash_polygon[j]=primitive_info[i-1]; dash_polygon[j].point.x=(double) (primitive_info[i-1].point.x+dx* total_length*PerceptibleReciprocal(maximum_length)); dash_polygon[j].point.y=(double) (primitive_info[i-1].point.y+dy* total_length*PerceptibleReciprocal(maximum_length)); dash_polygon[j].coordinates=1; j++; dash_polygon[0].coordinates=(size_t) j; dash_polygon[j].primitive=UndefinedPrimitive; status&=DrawStrokePolygon(image,clone_info,dash_polygon,exception); if (status == MagickFalse) break; } if (fabs(draw_info->dash_pattern[n]) >= MagickEpsilon) n++; if (fabs(draw_info->dash_pattern[n]) < MagickEpsilon) n=0; length=scale*draw_info->dash_pattern[n]; } length-=(maximum_length-total_length); if ((n & 0x01) != 0) continue; dash_polygon[j]=primitive_info[i]; dash_polygon[j].coordinates=1; j++; } if ((status != MagickFalse) && (total_length < maximum_length) && ((n & 0x01) == 0) && (j > 1)) { dash_polygon[j]=primitive_info[i-1]; dash_polygon[j].point.x+=MagickEpsilon; dash_polygon[j].point.y+=MagickEpsilon; dash_polygon[j].coordinates=1; j++; dash_polygon[0].coordinates=(size_t) j; dash_polygon[j].primitive=UndefinedPrimitive; status&=DrawStrokePolygon(image,clone_info,dash_polygon,exception); } dash_polygon=(PrimitiveInfo *) RelinquishMagickMemory(dash_polygon); clone_info=DestroyDrawInfo(clone_info); if (image->debug != MagickFalse) (void) LogMagickEvent(DrawEvent,GetMagickModule()," end draw-dash"); return(status != 0 ? MagickTrue : MagickFalse); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % D r a w G r a d i e n t I m a g e % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % DrawGradientImage() draws a linear gradient on the image. % % The format of the DrawGradientImage method is: % % MagickBooleanType DrawGradientImage(Image *image, % const DrawInfo *draw_info,ExceptionInfo *exception) % % A description of each parameter follows: % % o image: the image. % % o draw_info: the draw info. % % o exception: return any errors or warnings in this structure. % */ static inline double GetStopColorOffset(const GradientInfo *gradient, const ssize_t x,const ssize_t y) { switch (gradient->type) { case UndefinedGradient: case LinearGradient: { double gamma, length, offset, scale; PointInfo p, q; const SegmentInfo *gradient_vector; gradient_vector=(&gradient->gradient_vector); p.x=gradient_vector->x2-gradient_vector->x1; p.y=gradient_vector->y2-gradient_vector->y1; q.x=(double) x-gradient_vector->x1; q.y=(double) y-gradient_vector->y1; length=sqrt(q.x*q.x+q.y*q.y); gamma=sqrt(p.x*p.x+p.y*p.y)*length; gamma=PerceptibleReciprocal(gamma); scale=p.x*q.x+p.y*q.y; offset=gamma*scale*length; return(offset); } case RadialGradient: { PointInfo v; if (gradient->spread == RepeatSpread) { v.x=(double) x-gradient->center.x; v.y=(double) y-gradient->center.y; return(sqrt(v.x*v.x+v.y*v.y)); } v.x=(double) (((x-gradient->center.x)*cos(DegreesToRadians( gradient->angle)))+((y-gradient->center.y)*sin(DegreesToRadians( gradient->angle))))*PerceptibleReciprocal(gradient->radii.x); v.y=(double) (((x-gradient->center.x)*sin(DegreesToRadians( gradient->angle)))-((y-gradient->center.y)*cos(DegreesToRadians( gradient->angle))))*PerceptibleReciprocal(gradient->radii.y); return(sqrt(v.x*v.x+v.y*v.y)); } } return(0.0); } static int StopInfoCompare(const void *x,const void *y) { StopInfo *stop_1, *stop_2; stop_1=(StopInfo *) x; stop_2=(StopInfo *) y; if (stop_1->offset > stop_2->offset) return(1); if (fabs(stop_1->offset-stop_2->offset) <= MagickEpsilon) return(0); return(-1); } MagickExport MagickBooleanType DrawGradientImage(Image *image, const DrawInfo *draw_info,ExceptionInfo *exception) { CacheView *image_view; const GradientInfo *gradient; const SegmentInfo *gradient_vector; double length; MagickBooleanType status; PixelInfo zero; PointInfo point; RectangleInfo bounding_box; ssize_t y; /* Draw linear or radial gradient on image. */ assert(image != (Image *) NULL); assert(image->signature == MagickCoreSignature); if (image->debug != MagickFalse) (void) LogMagickEvent(TraceEvent,GetMagickModule(),"%s",image->filename); assert(draw_info != (const DrawInfo *) NULL); gradient=(&draw_info->gradient); qsort(gradient->stops,gradient->number_stops,sizeof(StopInfo), StopInfoCompare); gradient_vector=(&gradient->gradient_vector); point.x=gradient_vector->x2-gradient_vector->x1; point.y=gradient_vector->y2-gradient_vector->y1; length=sqrt(point.x*point.x+point.y*point.y); bounding_box=gradient->bounding_box; status=MagickTrue; GetPixelInfo(image,&zero); image_view=AcquireAuthenticCacheView(image,exception); #if defined(MAGICKCORE_OPENMP_SUPPORT) #pragma omp parallel for schedule(static) shared(status) \ magick_number_threads(image,image,bounding_box.height-bounding_box.y,1) #endif for (y=bounding_box.y; y < (ssize_t) bounding_box.height; y++) { PixelInfo composite, pixel; double alpha, offset; register Quantum *magick_restrict q; register ssize_t i, x; ssize_t j; if (status == MagickFalse) continue; q=GetCacheViewAuthenticPixels(image_view,0,y,image->columns,1,exception); if (q == (Quantum *) NULL) { status=MagickFalse; continue; } pixel=zero; composite=zero; offset=GetStopColorOffset(gradient,0,y); if (gradient->type != RadialGradient) offset*=PerceptibleReciprocal(length); for (x=bounding_box.x; x < (ssize_t) bounding_box.width; x++) { GetPixelInfoPixel(image,q,&pixel); switch (gradient->spread) { case UndefinedSpread: case PadSpread: { if ((x != (ssize_t) ceil(gradient_vector->x1-0.5)) || (y != (ssize_t) ceil(gradient_vector->y1-0.5))) { offset=GetStopColorOffset(gradient,x,y); if (gradient->type != RadialGradient) offset*=PerceptibleReciprocal(length); } for (i=0; i < (ssize_t) gradient->number_stops; i++) if (offset < gradient->stops[i].offset) break; if ((offset < 0.0) || (i == 0)) composite=gradient->stops[0].color; else if ((offset > 1.0) || (i == (ssize_t) gradient->number_stops)) composite=gradient->stops[gradient->number_stops-1].color; else { j=i; i--; alpha=(offset-gradient->stops[i].offset)/ (gradient->stops[j].offset-gradient->stops[i].offset); CompositePixelInfoBlend(&gradient->stops[i].color,1.0-alpha, &gradient->stops[j].color,alpha,&composite); } break; } case ReflectSpread: { if ((x != (ssize_t) ceil(gradient_vector->x1-0.5)) || (y != (ssize_t) ceil(gradient_vector->y1-0.5))) { offset=GetStopColorOffset(gradient,x,y); if (gradient->type != RadialGradient) offset*=PerceptibleReciprocal(length); } if (offset < 0.0) offset=(-offset); if ((ssize_t) fmod(offset,2.0) == 0) offset=fmod(offset,1.0); else offset=1.0-fmod(offset,1.0); for (i=0; i < (ssize_t) gradient->number_stops; i++) if (offset < gradient->stops[i].offset) break; if (i == 0) composite=gradient->stops[0].color; else if (i == (ssize_t) gradient->number_stops) composite=gradient->stops[gradient->number_stops-1].color; else { j=i; i--; alpha=(offset-gradient->stops[i].offset)/ (gradient->stops[j].offset-gradient->stops[i].offset); CompositePixelInfoBlend(&gradient->stops[i].color,1.0-alpha, &gradient->stops[j].color,alpha,&composite); } break; } case RepeatSpread: { MagickBooleanType antialias; double repeat; antialias=MagickFalse; repeat=0.0; if ((x != (ssize_t) ceil(gradient_vector->x1-0.5)) || (y != (ssize_t) ceil(gradient_vector->y1-0.5))) { offset=GetStopColorOffset(gradient,x,y); if (gradient->type == LinearGradient) { repeat=fmod(offset,length); if (repeat < 0.0) repeat=length-fmod(-repeat,length); else repeat=fmod(offset,length); antialias=(repeat < length) && ((repeat+1.0) > length) ? MagickTrue : MagickFalse; offset=PerceptibleReciprocal(length)*repeat; } else { repeat=fmod(offset,gradient->radius); if (repeat < 0.0) repeat=gradient->radius-fmod(-repeat,gradient->radius); else repeat=fmod(offset,gradient->radius); antialias=repeat+1.0 > gradient->radius ? MagickTrue : MagickFalse; offset=repeat/gradient->radius; } } for (i=0; i < (ssize_t) gradient->number_stops; i++) if (offset < gradient->stops[i].offset) break; if (i == 0) composite=gradient->stops[0].color; else if (i == (ssize_t) gradient->number_stops) composite=gradient->stops[gradient->number_stops-1].color; else { j=i; i--; alpha=(offset-gradient->stops[i].offset)/ (gradient->stops[j].offset-gradient->stops[i].offset); if (antialias != MagickFalse) { if (gradient->type == LinearGradient) alpha=length-repeat; else alpha=gradient->radius-repeat; i=0; j=(ssize_t) gradient->number_stops-1L; } CompositePixelInfoBlend(&gradient->stops[i].color,1.0-alpha, &gradient->stops[j].color,alpha,&composite); } break; } } CompositePixelInfoOver(&composite,composite.alpha,&pixel,pixel.alpha, &pixel); SetPixelViaPixelInfo(image,&pixel,q); q+=GetPixelChannels(image); } if (SyncCacheViewAuthenticPixels(image_view,exception) == MagickFalse) status=MagickFalse; } image_view=DestroyCacheView(image_view); return(status); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % D r a w I m a g e % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % DrawImage() draws a graphic primitive on your image. The primitive % may be represented as a string or filename. Precede the filename with an % "at" sign (@) and the contents of the file are drawn on the image. You % can affect how text is drawn by setting one or more members of the draw % info structure. % % The format of the DrawImage method is: % % MagickBooleanType DrawImage(Image *image,const DrawInfo *draw_info, % ExceptionInfo *exception) % % A description of each parameter follows: % % o image: the image. % % o draw_info: the draw info. % % o exception: return any errors or warnings in this structure. % */ static MagickBooleanType CheckPrimitiveExtent(MVGInfo *mvg_info, const size_t pad) { double extent; size_t quantum; /* Check if there is enough storage for drawing pimitives. */ extent=(double) mvg_info->offset+pad+PrimitiveExtentPad; quantum=sizeof(**mvg_info->primitive_info); if (((extent*quantum) < (double) SSIZE_MAX) && ((extent*quantum) < (double) GetMaxMemoryRequest())) { if (extent <= (double) *mvg_info->extent) return(MagickTrue); *mvg_info->primitive_info=(PrimitiveInfo *) ResizeQuantumMemory( *mvg_info->primitive_info,(size_t) extent,quantum); if (*mvg_info->primitive_info != (PrimitiveInfo *) NULL) { register ssize_t i; *mvg_info->extent=(size_t) extent; for (i=mvg_info->offset+1; i < (ssize_t) extent; i++) (*mvg_info->primitive_info)[i].primitive=UndefinedPrimitive; return(MagickTrue); } } /* Reallocation failed, allocate a primitive to facilitate unwinding. */ (void) ThrowMagickException(mvg_info->exception,GetMagickModule(), ResourceLimitError,"MemoryAllocationFailed","`%s'",""); if (*mvg_info->primitive_info != (PrimitiveInfo *) NULL) *mvg_info->primitive_info=(PrimitiveInfo *) RelinquishMagickMemory( *mvg_info->primitive_info); *mvg_info->primitive_info=(PrimitiveInfo *) AcquireCriticalMemory( PrimitiveExtentPad*quantum); (void) memset(*mvg_info->primitive_info,0,PrimitiveExtentPad*quantum); *mvg_info->extent=1; return(MagickFalse); } MagickExport int MVGMacroCompare(const void *target,const void *source) { const char *p, *q; p=(const char *) target; q=(const char *) source; return(strcmp(p,q)); } static SplayTreeInfo *GetMVGMacros(const char *primitive) { char *macro, *token; const char *q; size_t extent; SplayTreeInfo *macros; /* Scan graphic primitives for definitions and classes. */ if (primitive == (const char *) NULL) return((SplayTreeInfo *) NULL); macros=NewSplayTree(MVGMacroCompare,RelinquishMagickMemory, RelinquishMagickMemory); macro=AcquireString(primitive); token=AcquireString(primitive); extent=strlen(token)+MagickPathExtent; for (q=primitive; *q != '\0'; ) { if (GetNextToken(q,&q,extent,token) < 1) break; if (*token == '\0') break; if (LocaleCompare("push",token) == 0) { register const char *end, *start; (void) GetNextToken(q,&q,extent,token); if (*q == '"') { char name[MagickPathExtent]; const char *p; ssize_t n; /* Named macro (e.g. push graphic-context "wheel"). */ (void) GetNextToken(q,&q,extent,token); start=q; end=q; (void) CopyMagickString(name,token,MagickPathExtent); n=1; for (p=q; *p != '\0'; ) { if (GetNextToken(p,&p,extent,token) < 1) break; if (*token == '\0') break; if (LocaleCompare(token,"pop") == 0) { end=p-strlen(token)-1; n--; } if (LocaleCompare(token,"push") == 0) n++; if ((n == 0) && (end > start)) { /* Extract macro. */ (void) GetNextToken(p,&p,extent,token); (void) CopyMagickString(macro,start,(size_t) (end-start)); (void) AddValueToSplayTree(macros,ConstantString(name), ConstantString(macro)); break; } } } } } token=DestroyString(token); macro=DestroyString(macro); return(macros); } static inline MagickBooleanType IsPoint(const char *point) { char *p; double value; value=StringToDouble(point,&p); return((fabs(value) < MagickEpsilon) && (p == point) ? MagickFalse : MagickTrue); } static inline MagickBooleanType TracePoint(PrimitiveInfo *primitive_info, const PointInfo point) { primitive_info->coordinates=1; primitive_info->closed_subpath=MagickFalse; primitive_info->point=point; return(MagickTrue); } static MagickBooleanType RenderMVGContent(Image *image, const DrawInfo *draw_info,const size_t depth,ExceptionInfo *exception) { #define RenderImageTag "Render/Image" AffineMatrix affine, current; char keyword[MagickPathExtent], geometry[MagickPathExtent], *next_token, pattern[MagickPathExtent], *primitive, *token; const char *q; double angle, coordinates, cursor, factor, primitive_extent; DrawInfo *clone_info, **graphic_context; MagickBooleanType proceed; MagickStatusType status; MVGInfo mvg_info; PointInfo point; PrimitiveInfo *primitive_info; PrimitiveType primitive_type; register const char *p; register ssize_t i, x; SegmentInfo bounds; size_t extent, number_points, number_stops; SplayTreeInfo *macros; ssize_t defsDepth, j, k, n, symbolDepth; StopInfo *stops; TypeMetric metrics; assert(image != (Image *) NULL); assert(image->signature == MagickCoreSignature); if (image->debug != MagickFalse) (void) LogMagickEvent(TraceEvent,GetMagickModule(),"%s",image->filename); assert(draw_info != (DrawInfo *) NULL); assert(draw_info->signature == MagickCoreSignature); if (image->debug != MagickFalse) (void) LogMagickEvent(TraceEvent,GetMagickModule(),"..."); if (depth > MagickMaxRecursionDepth) ThrowBinaryException(DrawError,"VectorGraphicsNestedTooDeeply", image->filename); if ((draw_info->primitive == (char *) NULL) || (*draw_info->primitive == '\0')) return(MagickFalse); if (image->debug != MagickFalse) (void) LogMagickEvent(DrawEvent,GetMagickModule(),"begin draw-image"); if (SetImageStorageClass(image,DirectClass,exception) == MagickFalse) return(MagickFalse); if (image->alpha_trait == UndefinedPixelTrait) { status=SetImageAlphaChannel(image,OpaqueAlphaChannel,exception); if (status == MagickFalse) return(MagickFalse); } if ((*draw_info->primitive == '@') && (strlen(draw_info->primitive) > 1) && (*(draw_info->primitive+1) != '-') && (depth == 0)) primitive=FileToString(draw_info->primitive+1,~0UL,exception); else primitive=AcquireString(draw_info->primitive); if (primitive == (char *) NULL) return(MagickFalse); primitive_extent=(double) strlen(primitive); (void) SetImageArtifact(image,"mvg:vector-graphics",primitive); n=0; number_stops=0; stops=(StopInfo *) NULL; /* Allocate primitive info memory. */ graphic_context=(DrawInfo **) AcquireMagickMemory(sizeof(*graphic_context)); if (graphic_context == (DrawInfo **) NULL) { primitive=DestroyString(primitive); ThrowBinaryException(ResourceLimitError,"MemoryAllocationFailed", image->filename); } number_points=PrimitiveExtentPad; primitive_info=(PrimitiveInfo *) AcquireQuantumMemory((size_t) number_points, sizeof(*primitive_info)); if (primitive_info == (PrimitiveInfo *) NULL) { primitive=DestroyString(primitive); for ( ; n >= 0; n--) graphic_context[n]=DestroyDrawInfo(graphic_context[n]); graphic_context=(DrawInfo **) RelinquishMagickMemory(graphic_context); ThrowBinaryException(ResourceLimitError,"MemoryAllocationFailed", image->filename); } (void) memset(primitive_info,0,(size_t) number_points* sizeof(*primitive_info)); (void) memset(&mvg_info,0,sizeof(mvg_info)); mvg_info.primitive_info=(&primitive_info); mvg_info.extent=(&number_points); mvg_info.exception=exception; graphic_context[n]=CloneDrawInfo((ImageInfo *) NULL,draw_info); graphic_context[n]->viewbox=image->page; if ((image->page.width == 0) || (image->page.height == 0)) { graphic_context[n]->viewbox.width=image->columns; graphic_context[n]->viewbox.height=image->rows; } token=AcquireString(primitive); extent=strlen(token)+MagickPathExtent; defsDepth=0; symbolDepth=0; cursor=0.0; macros=GetMVGMacros(primitive); status=MagickTrue; for (q=primitive; *q != '\0'; ) { /* Interpret graphic primitive. */ if (GetNextToken(q,&q,MagickPathExtent,keyword) < 1) break; if (*keyword == '\0') break; if (*keyword == '#') { /* Comment. */ while ((*q != '\n') && (*q != '\0')) q++; continue; } p=q-strlen(keyword)-1; primitive_type=UndefinedPrimitive; current=graphic_context[n]->affine; GetAffineMatrix(&affine); *token='\0'; switch (*keyword) { case ';': break; case 'a': case 'A': { if (LocaleCompare("affine",keyword) == 0) { (void) GetNextToken(q,&q,extent,token); affine.sx=StringToDouble(token,&next_token); if (token == next_token) ThrowPointExpectedException(token,exception); (void) GetNextToken(q,&q,extent,token); if (*token == ',') (void) GetNextToken(q,&q,extent,token); affine.rx=StringToDouble(token,&next_token); if (token == next_token) ThrowPointExpectedException(token,exception); (void) GetNextToken(q,&q,extent,token); if (*token == ',') (void) GetNextToken(q,&q,extent,token); affine.ry=StringToDouble(token,&next_token); if (token == next_token) ThrowPointExpectedException(token,exception); (void) GetNextToken(q,&q,extent,token); if (*token == ',') (void) GetNextToken(q,&q,extent,token); affine.sy=StringToDouble(token,&next_token); if (token == next_token) ThrowPointExpectedException(token,exception); (void) GetNextToken(q,&q,extent,token); if (*token == ',') (void) GetNextToken(q,&q,extent,token); affine.tx=StringToDouble(token,&next_token); if (token == next_token) ThrowPointExpectedException(token,exception); (void) GetNextToken(q,&q,extent,token); if (*token == ',') (void) GetNextToken(q,&q,extent,token); affine.ty=StringToDouble(token,&next_token); if (token == next_token) ThrowPointExpectedException(token,exception); break; } if (LocaleCompare("alpha",keyword) == 0) { primitive_type=AlphaPrimitive; break; } if (LocaleCompare("arc",keyword) == 0) { primitive_type=ArcPrimitive; break; } status=MagickFalse; break; } case 'b': case 'B': { if (LocaleCompare("bezier",keyword) == 0) { primitive_type=BezierPrimitive; break; } if (LocaleCompare("border-color",keyword) == 0) { (void) GetNextToken(q,&q,extent,token); status&=QueryColorCompliance(token,AllCompliance, &graphic_context[n]->border_color,exception); break; } status=MagickFalse; break; } case 'c': case 'C': { if (LocaleCompare("class",keyword) == 0) { const char *mvg_class; (void) GetNextToken(q,&q,extent,token); if (*token == '\0') { status=MagickFalse; break; } if (LocaleCompare(token,graphic_context[n]->id) == 0) break; mvg_class=(const char *) GetValueFromSplayTree(macros,token); if (mvg_class != (const char *) NULL) { char *elements; ssize_t offset; /* Inject class elements in stream. */ offset=(ssize_t) (p-primitive); elements=AcquireString(primitive); elements[offset]='\0'; (void) ConcatenateString(&elements,mvg_class); (void) ConcatenateString(&elements,"\n"); (void) ConcatenateString(&elements,q); primitive=DestroyString(primitive); primitive=elements; q=primitive+offset; } break; } if (LocaleCompare("clip-path",keyword) == 0) { const char *clip_path; /* Take a node from within the MVG document, and duplicate it here. */ (void) GetNextToken(q,&q,extent,token); if (*token == '\0') { status=MagickFalse; break; } (void) CloneString(&graphic_context[n]->clip_mask,token); clip_path=(const char *) GetValueFromSplayTree(macros,token); if (clip_path != (const char *) NULL) { if (graphic_context[n]->clipping_mask != (Image *) NULL) graphic_context[n]->clipping_mask= DestroyImage(graphic_context[n]->clipping_mask); graphic_context[n]->clipping_mask=DrawClippingMask(image, graphic_context[n],token,clip_path,exception); if (graphic_context[n]->compliance != SVGCompliance) { clip_path=(const char *) GetValueFromSplayTree(macros, graphic_context[n]->clip_mask); if (clip_path != (const char *) NULL) (void) SetImageArtifact(image, graphic_context[n]->clip_mask,clip_path); status&=DrawClipPath(image,graphic_context[n], graphic_context[n]->clip_mask,exception); } } break; } if (LocaleCompare("clip-rule",keyword) == 0) { ssize_t fill_rule; (void) GetNextToken(q,&q,extent,token); fill_rule=ParseCommandOption(MagickFillRuleOptions,MagickFalse, token); if (fill_rule == -1) { status=MagickFalse; break; } graphic_context[n]->fill_rule=(FillRule) fill_rule; break; } if (LocaleCompare("clip-units",keyword) == 0) { ssize_t clip_units; (void) GetNextToken(q,&q,extent,token); clip_units=ParseCommandOption(MagickClipPathOptions,MagickFalse, token); if (clip_units == -1) { status=MagickFalse; break; } graphic_context[n]->clip_units=(ClipPathUnits) clip_units; if (clip_units == ObjectBoundingBox) { GetAffineMatrix(&current); affine.sx=draw_info->bounds.x2; affine.sy=draw_info->bounds.y2; affine.tx=draw_info->bounds.x1; affine.ty=draw_info->bounds.y1; break; } break; } if (LocaleCompare("circle",keyword) == 0) { primitive_type=CirclePrimitive; break; } if (LocaleCompare("color",keyword) == 0) { primitive_type=ColorPrimitive; break; } if (LocaleCompare("compliance",keyword) == 0) { /* MVG compliance associates a clipping mask with an image; SVG compliance associates a clipping mask with a graphics context. */ (void) GetNextToken(q,&q,extent,token); graphic_context[n]->compliance=(ComplianceType) ParseCommandOption( MagickComplianceOptions,MagickFalse,token); break; } status=MagickFalse; break; } case 'd': case 'D': { if (LocaleCompare("decorate",keyword) == 0) { ssize_t decorate; (void) GetNextToken(q,&q,extent,token); decorate=ParseCommandOption(MagickDecorateOptions,MagickFalse, token); if (decorate == -1) { status=MagickFalse; break; } graphic_context[n]->decorate=(DecorationType) decorate; break; } if (LocaleCompare("density",keyword) == 0) { (void) GetNextToken(q,&q,extent,token); (void) CloneString(&graphic_context[n]->density,token); break; } if (LocaleCompare("direction",keyword) == 0) { ssize_t direction; (void) GetNextToken(q,&q,extent,token); direction=ParseCommandOption(MagickDirectionOptions,MagickFalse, token); if (direction == -1) status=MagickFalse; else graphic_context[n]->direction=(DirectionType) direction; break; } status=MagickFalse; break; } case 'e': case 'E': { if (LocaleCompare("ellipse",keyword) == 0) { primitive_type=EllipsePrimitive; break; } if (LocaleCompare("encoding",keyword) == 0) { (void) GetNextToken(q,&q,extent,token); (void) CloneString(&graphic_context[n]->encoding,token); break; } status=MagickFalse; break; } case 'f': case 'F': { if (LocaleCompare("fill",keyword) == 0) { (void) GetNextToken(q,&q,extent,token); if (graphic_context[n]->clip_path != MagickFalse) break; (void) FormatLocaleString(pattern,MagickPathExtent,"%s",token); if (GetImageArtifact(image,pattern) != (const char *) NULL) (void) DrawPatternPath(image,draw_info,token, &graphic_context[n]->fill_pattern,exception); else { status&=QueryColorCompliance(token,AllCompliance, &graphic_context[n]->fill,exception); if (graphic_context[n]->fill_alpha != OpaqueAlpha) graphic_context[n]->fill.alpha=graphic_context[n]->fill_alpha; } break; } if (LocaleCompare("fill-opacity",keyword) == 0) { double opacity; (void) GetNextToken(q,&q,extent,token); if (graphic_context[n]->clip_path != MagickFalse) break; factor=strchr(token,'%') != (char *) NULL ? 0.01 : 1.0; opacity=MagickMin(MagickMax(factor* StringToDouble(token,&next_token),0.0),1.0); if (token == next_token) ThrowPointExpectedException(token,exception); graphic_context[n]->fill_alpha*=opacity; if (graphic_context[n]->fill.alpha != TransparentAlpha) graphic_context[n]->fill.alpha=graphic_context[n]->fill_alpha; else graphic_context[n]->fill.alpha=(MagickRealType) ClampToQuantum(QuantumRange*(1.0-opacity)); break; } if (LocaleCompare("fill-rule",keyword) == 0) { ssize_t fill_rule; (void) GetNextToken(q,&q,extent,token); fill_rule=ParseCommandOption(MagickFillRuleOptions,MagickFalse, token); if (fill_rule == -1) { status=MagickFalse; break; } graphic_context[n]->fill_rule=(FillRule) fill_rule; break; } if (LocaleCompare("font",keyword) == 0) { (void) GetNextToken(q,&q,extent,token); (void) CloneString(&graphic_context[n]->font,token); if (LocaleCompare("none",token) == 0) graphic_context[n]->font=(char *) RelinquishMagickMemory( graphic_context[n]->font); break; } if (LocaleCompare("font-family",keyword) == 0) { (void) GetNextToken(q,&q,extent,token); (void) CloneString(&graphic_context[n]->family,token); break; } if (LocaleCompare("font-size",keyword) == 0) { (void) GetNextToken(q,&q,extent,token); graphic_context[n]->pointsize=StringToDouble(token,&next_token); if (token == next_token) ThrowPointExpectedException(token,exception); break; } if (LocaleCompare("font-stretch",keyword) == 0) { ssize_t stretch; (void) GetNextToken(q,&q,extent,token); stretch=ParseCommandOption(MagickStretchOptions,MagickFalse,token); if (stretch == -1) { status=MagickFalse; break; } graphic_context[n]->stretch=(StretchType) stretch; break; } if (LocaleCompare("font-style",keyword) == 0) { ssize_t style; (void) GetNextToken(q,&q,extent,token); style=ParseCommandOption(MagickStyleOptions,MagickFalse,token); if (style == -1) { status=MagickFalse; break; } graphic_context[n]->style=(StyleType) style; break; } if (LocaleCompare("font-weight",keyword) == 0) { ssize_t weight; (void) GetNextToken(q,&q,extent,token); weight=ParseCommandOption(MagickWeightOptions,MagickFalse,token); if (weight == -1) weight=(ssize_t) StringToUnsignedLong(token); graphic_context[n]->weight=(size_t) weight; break; } status=MagickFalse; break; } case 'g': case 'G': { if (LocaleCompare("gradient-units",keyword) == 0) { (void) GetNextToken(q,&q,extent,token); break; } if (LocaleCompare("gravity",keyword) == 0) { ssize_t gravity; (void) GetNextToken(q,&q,extent,token); gravity=ParseCommandOption(MagickGravityOptions,MagickFalse,token); if (gravity == -1) { status=MagickFalse; break; } graphic_context[n]->gravity=(GravityType) gravity; break; } status=MagickFalse; break; } case 'i': case 'I': { if (LocaleCompare("image",keyword) == 0) { ssize_t compose; primitive_type=ImagePrimitive; (void) GetNextToken(q,&q,extent,token); compose=ParseCommandOption(MagickComposeOptions,MagickFalse,token); if (compose == -1) { status=MagickFalse; break; } graphic_context[n]->compose=(CompositeOperator) compose; break; } if (LocaleCompare("interline-spacing",keyword) == 0) { (void) GetNextToken(q,&q,extent,token); graphic_context[n]->interline_spacing=StringToDouble(token, &next_token); if (token == next_token) ThrowPointExpectedException(token,exception); break; } if (LocaleCompare("interword-spacing",keyword) == 0) { (void) GetNextToken(q,&q,extent,token); graphic_context[n]->interword_spacing=StringToDouble(token, &next_token); if (token == next_token) ThrowPointExpectedException(token,exception); break; } status=MagickFalse; break; } case 'k': case 'K': { if (LocaleCompare("kerning",keyword) == 0) { (void) GetNextToken(q,&q,extent,token); graphic_context[n]->kerning=StringToDouble(token,&next_token); if (token == next_token) ThrowPointExpectedException(token,exception); break; } status=MagickFalse; break; } case 'l': case 'L': { if (LocaleCompare("letter-spacing",keyword) == 0) { (void) GetNextToken(q,&q,extent,token); clone_info=CloneDrawInfo((ImageInfo *) NULL,graphic_context[n]); clone_info->text=AcquireString(" "); status&=GetTypeMetrics(image,clone_info,&metrics,exception); graphic_context[n]->kerning=metrics.width* StringToDouble(token,&next_token); clone_info=DestroyDrawInfo(clone_info); if (token == next_token) ThrowPointExpectedException(token,exception); break; } if (LocaleCompare("line",keyword) == 0) { primitive_type=LinePrimitive; break; } status=MagickFalse; break; } case 'm': case 'M': { if (LocaleCompare("mask",keyword) == 0) { const char *mask_path; /* Take a node from within the MVG document, and duplicate it here. */ (void) GetNextToken(q,&q,extent,token); mask_path=(const char *) GetValueFromSplayTree(macros,token); if (mask_path != (const char *) NULL) { if (graphic_context[n]->composite_mask != (Image *) NULL) graphic_context[n]->composite_mask= DestroyImage(graphic_context[n]->composite_mask); graphic_context[n]->composite_mask=DrawCompositeMask(image, graphic_context[n],token,mask_path,exception); if (graphic_context[n]->compliance != SVGCompliance) status=SetImageMask(image,CompositePixelMask, graphic_context[n]->composite_mask,exception); } break; } break; } case 'o': case 'O': { if (LocaleCompare("offset",keyword) == 0) { (void) GetNextToken(q,&q,extent,token); break; } if (LocaleCompare("opacity",keyword) == 0) { double opacity; (void) GetNextToken(q,&q,extent,token); if (graphic_context[n]->clip_path != MagickFalse) break; factor=strchr(token,'%') != (char *) NULL ? 0.01 : 1.0; opacity=MagickMin(MagickMax(factor* StringToDouble(token,&next_token),0.0),1.0); if (token == next_token) ThrowPointExpectedException(token,exception); graphic_context[n]->fill_alpha*=opacity; graphic_context[n]->stroke_alpha*=opacity; break; } status=MagickFalse; break; } case 'p': case 'P': { if (LocaleCompare("path",keyword) == 0) { primitive_type=PathPrimitive; break; } if (LocaleCompare("point",keyword) == 0) { primitive_type=PointPrimitive; break; } if (LocaleCompare("polyline",keyword) == 0) { primitive_type=PolylinePrimitive; break; } if (LocaleCompare("polygon",keyword) == 0) { primitive_type=PolygonPrimitive; break; } if (LocaleCompare("pop",keyword) == 0) { if (GetNextToken(q,&q,extent,token) < 1) break; if (LocaleCompare("class",token) == 0) break; if (LocaleCompare("clip-path",token) == 0) break; if (LocaleCompare("defs",token) == 0) { defsDepth--; graphic_context[n]->render=defsDepth > 0 ? MagickFalse : MagickTrue; break; } if (LocaleCompare("gradient",token) == 0) break; if (LocaleCompare("graphic-context",token) == 0) { if (n <= 0) { (void) ThrowMagickException(exception,GetMagickModule(), DrawError,"UnbalancedGraphicContextPushPop","`%s'",token); status=MagickFalse; n=0; break; } if ((graphic_context[n]->clip_mask != (char *) NULL) && (graphic_context[n]->compliance != SVGCompliance)) if (LocaleCompare(graphic_context[n]->clip_mask, graphic_context[n-1]->clip_mask) != 0) status=SetImageMask(image,WritePixelMask,(Image *) NULL, exception); graphic_context[n]=DestroyDrawInfo(graphic_context[n]); n--; break; } if (LocaleCompare("mask",token) == 0) break; if (LocaleCompare("pattern",token) == 0) break; if (LocaleCompare("symbol",token) == 0) { symbolDepth--; graphic_context[n]->render=symbolDepth > 0 ? MagickFalse : MagickTrue; break; } status=MagickFalse; break; } if (LocaleCompare("push",keyword) == 0) { if (GetNextToken(q,&q,extent,token) < 1) break; if (LocaleCompare("class",token) == 0) { /* Class context. */ for (p=q; *q != '\0'; ) { if (GetNextToken(q,&q,extent,token) < 1) break; if (LocaleCompare(token,"pop") != 0) continue; (void) GetNextToken(q,(const char **) NULL,extent,token); if (LocaleCompare(token,"class") != 0) continue; break; } (void) GetNextToken(q,&q,extent,token); break; } if (LocaleCompare("clip-path",token) == 0) { (void) GetNextToken(q,&q,extent,token); for (p=q; *q != '\0'; ) { if (GetNextToken(q,&q,extent,token) < 1) break; if (LocaleCompare(token,"pop") != 0) continue; (void) GetNextToken(q,(const char **) NULL,extent,token); if (LocaleCompare(token,"clip-path") != 0) continue; break; } if ((q == (char *) NULL) || (p == (char *) NULL) || ((q-4) < p)) { status=MagickFalse; break; } (void) GetNextToken(q,&q,extent,token); break; } if (LocaleCompare("defs",token) == 0) { defsDepth++; graphic_context[n]->render=defsDepth > 0 ? MagickFalse : MagickTrue; break; } if (LocaleCompare("gradient",token) == 0) { char key[2*MagickPathExtent], name[MagickPathExtent], type[MagickPathExtent]; SegmentInfo segment; (void) GetNextToken(q,&q,extent,token); (void) CopyMagickString(name,token,MagickPathExtent); (void) GetNextToken(q,&q,extent,token); (void) CopyMagickString(type,token,MagickPathExtent); (void) GetNextToken(q,&q,extent,token); segment.x1=StringToDouble(token,&next_token); if (token == next_token) ThrowPointExpectedException(token,exception); (void) GetNextToken(q,&q,extent,token); if (*token == ',') (void) GetNextToken(q,&q,extent,token); segment.y1=StringToDouble(token,&next_token); if (token == next_token) ThrowPointExpectedException(token,exception); (void) GetNextToken(q,&q,extent,token); if (*token == ',') (void) GetNextToken(q,&q,extent,token); segment.x2=StringToDouble(token,&next_token); if (token == next_token) ThrowPointExpectedException(token,exception); (void) GetNextToken(q,&q,extent,token); if (*token == ',') (void) GetNextToken(q,&q,extent,token); segment.y2=StringToDouble(token,&next_token); if (token == next_token) ThrowPointExpectedException(token,exception); if (LocaleCompare(type,"radial") == 0) { (void) GetNextToken(q,&q,extent,token); if (*token == ',') (void) GetNextToken(q,&q,extent,token); } for (p=q; *q != '\0'; ) { if (GetNextToken(q,&q,extent,token) < 1) break; if (LocaleCompare(token,"pop") != 0) continue; (void) GetNextToken(q,(const char **) NULL,extent,token); if (LocaleCompare(token,"gradient") != 0) continue; break; } if ((q == (char *) NULL) || (p == (char *) NULL) || ((q-4) < p)) { status=MagickFalse; break; } (void) CopyMagickString(token,p,(size_t) (q-p-4+1)); bounds.x1=graphic_context[n]->affine.sx*segment.x1+ graphic_context[n]->affine.ry*segment.y1+ graphic_context[n]->affine.tx; bounds.y1=graphic_context[n]->affine.rx*segment.x1+ graphic_context[n]->affine.sy*segment.y1+ graphic_context[n]->affine.ty; bounds.x2=graphic_context[n]->affine.sx*segment.x2+ graphic_context[n]->affine.ry*segment.y2+ graphic_context[n]->affine.tx; bounds.y2=graphic_context[n]->affine.rx*segment.x2+ graphic_context[n]->affine.sy*segment.y2+ graphic_context[n]->affine.ty; (void) FormatLocaleString(key,MagickPathExtent,"%s",name); (void) SetImageArtifact(image,key,token); (void) FormatLocaleString(key,MagickPathExtent,"%s-type",name); (void) SetImageArtifact(image,key,type); (void) FormatLocaleString(key,MagickPathExtent,"%s-geometry", name); (void) FormatLocaleString(geometry,MagickPathExtent, "%gx%g%+.15g%+.15g", MagickMax(fabs(bounds.x2-bounds.x1+1.0),1.0), MagickMax(fabs(bounds.y2-bounds.y1+1.0),1.0), bounds.x1,bounds.y1); (void) SetImageArtifact(image,key,geometry); (void) GetNextToken(q,&q,extent,token); break; } if (LocaleCompare("graphic-context",token) == 0) { n++; graphic_context=(DrawInfo **) ResizeQuantumMemory( graphic_context,(size_t) (n+1),sizeof(*graphic_context)); if (graphic_context == (DrawInfo **) NULL) { (void) ThrowMagickException(exception,GetMagickModule(), ResourceLimitError,"MemoryAllocationFailed","`%s'", image->filename); break; } graphic_context[n]=CloneDrawInfo((ImageInfo *) NULL, graphic_context[n-1]); if (*q == '"') { (void) GetNextToken(q,&q,extent,token); (void) CloneString(&graphic_context[n]->id,token); } break; } if (LocaleCompare("mask",token) == 0) { (void) GetNextToken(q,&q,extent,token); break; } if (LocaleCompare("pattern",token) == 0) { char key[2*MagickPathExtent], name[MagickPathExtent]; RectangleInfo bounds; (void) GetNextToken(q,&q,extent,token); (void) CopyMagickString(name,token,MagickPathExtent); (void) GetNextToken(q,&q,extent,token); bounds.x=(ssize_t) ceil(StringToDouble(token,&next_token)-0.5); if (token == next_token) ThrowPointExpectedException(token,exception); (void) GetNextToken(q,&q,extent,token); if (*token == ',') (void) GetNextToken(q,&q,extent,token); bounds.y=(ssize_t) ceil(StringToDouble(token,&next_token)-0.5); if (token == next_token) ThrowPointExpectedException(token,exception); (void) GetNextToken(q,&q,extent,token); if (*token == ',') (void) GetNextToken(q,&q,extent,token); bounds.width=(size_t) floor(StringToDouble(token,&next_token)+ 0.5); if (token == next_token) ThrowPointExpectedException(token,exception); (void) GetNextToken(q,&q,extent,token); if (*token == ',') (void) GetNextToken(q,&q,extent,token); bounds.height=(size_t) floor(StringToDouble(token,&next_token)+ 0.5); if (token == next_token) ThrowPointExpectedException(token,exception); for (p=q; *q != '\0'; ) { if (GetNextToken(q,&q,extent,token) < 1) break; if (LocaleCompare(token,"pop") != 0) continue; (void) GetNextToken(q,(const char **) NULL,extent,token); if (LocaleCompare(token,"pattern") != 0) continue; break; } if ((q == (char *) NULL) || (p == (char *) NULL) || ((q-4) < p)) { status=MagickFalse; break; } (void) CopyMagickString(token,p,(size_t) (q-p-4+1)); (void) FormatLocaleString(key,MagickPathExtent,"%s",name); (void) SetImageArtifact(image,key,token); (void) FormatLocaleString(key,MagickPathExtent,"%s-geometry", name); (void) FormatLocaleString(geometry,MagickPathExtent, "%.20gx%.20g%+.20g%+.20g",(double) bounds.width,(double) bounds.height,(double) bounds.x,(double) bounds.y); (void) SetImageArtifact(image,key,geometry); (void) GetNextToken(q,&q,extent,token); break; } if (LocaleCompare("symbol",token) == 0) { symbolDepth++; graphic_context[n]->render=symbolDepth > 0 ? MagickFalse : MagickTrue; break; } status=MagickFalse; break; } status=MagickFalse; break; } case 'r': case 'R': { if (LocaleCompare("rectangle",keyword) == 0) { primitive_type=RectanglePrimitive; break; } if (LocaleCompare("rotate",keyword) == 0) { (void) GetNextToken(q,&q,extent,token); angle=StringToDouble(token,&next_token); if (token == next_token) ThrowPointExpectedException(token,exception); affine.sx=cos(DegreesToRadians(fmod((double) angle,360.0))); affine.rx=sin(DegreesToRadians(fmod((double) angle,360.0))); affine.ry=(-sin(DegreesToRadians(fmod((double) angle,360.0)))); affine.sy=cos(DegreesToRadians(fmod((double) angle,360.0))); break; } if (LocaleCompare("roundRectangle",keyword) == 0) { primitive_type=RoundRectanglePrimitive; break; } status=MagickFalse; break; } case 's': case 'S': { if (LocaleCompare("scale",keyword) == 0) { (void) GetNextToken(q,&q,extent,token); affine.sx=StringToDouble(token,&next_token); if (token == next_token) ThrowPointExpectedException(token,exception); (void) GetNextToken(q,&q,extent,token); if (*token == ',') (void) GetNextToken(q,&q,extent,token); affine.sy=StringToDouble(token,&next_token); if (token == next_token) ThrowPointExpectedException(token,exception); break; } if (LocaleCompare("skewX",keyword) == 0) { (void) GetNextToken(q,&q,extent,token); angle=StringToDouble(token,&next_token); if (token == next_token) ThrowPointExpectedException(token,exception); affine.ry=sin(DegreesToRadians(angle)); break; } if (LocaleCompare("skewY",keyword) == 0) { (void) GetNextToken(q,&q,extent,token); angle=StringToDouble(token,&next_token); if (token == next_token) ThrowPointExpectedException(token,exception); affine.rx=(-tan(DegreesToRadians(angle)/2.0)); break; } if (LocaleCompare("stop-color",keyword) == 0) { PixelInfo stop_color; number_stops++; if (number_stops == 1) stops=(StopInfo *) AcquireQuantumMemory(2,sizeof(*stops)); else if (number_stops > 2) stops=(StopInfo *) ResizeQuantumMemory(stops,number_stops, sizeof(*stops)); if (stops == (StopInfo *) NULL) { (void) ThrowMagickException(exception,GetMagickModule(), ResourceLimitError,"MemoryAllocationFailed","`%s'", image->filename); break; } (void) GetNextToken(q,&q,extent,token); status&=QueryColorCompliance(token,AllCompliance,&stop_color, exception); stops[number_stops-1].color=stop_color; (void) GetNextToken(q,&q,extent,token); factor=strchr(token,'%') != (char *) NULL ? 0.01 : 1.0; stops[number_stops-1].offset=factor*StringToDouble(token, &next_token); if (token == next_token) ThrowPointExpectedException(token,exception); break; } if (LocaleCompare("stroke",keyword) == 0) { (void) GetNextToken(q,&q,extent,token); if (graphic_context[n]->clip_path != MagickFalse) break; (void) FormatLocaleString(pattern,MagickPathExtent,"%s",token); if (GetImageArtifact(image,pattern) != (const char *) NULL) (void) DrawPatternPath(image,draw_info,token, &graphic_context[n]->stroke_pattern,exception); else { status&=QueryColorCompliance(token,AllCompliance, &graphic_context[n]->stroke,exception); if (graphic_context[n]->stroke_alpha != OpaqueAlpha) graphic_context[n]->stroke.alpha= graphic_context[n]->stroke_alpha; } break; } if (LocaleCompare("stroke-antialias",keyword) == 0) { (void) GetNextToken(q,&q,extent,token); graphic_context[n]->stroke_antialias=StringToLong(token) != 0 ? MagickTrue : MagickFalse; break; } if (LocaleCompare("stroke-dasharray",keyword) == 0) { if (graphic_context[n]->dash_pattern != (double *) NULL) graphic_context[n]->dash_pattern=(double *) RelinquishMagickMemory(graphic_context[n]->dash_pattern); if (IsPoint(q) != MagickFalse) { const char *r; r=q; (void) GetNextToken(r,&r,extent,token); if (*token == ',') (void) GetNextToken(r,&r,extent,token); for (x=0; IsPoint(token) != MagickFalse; x++) { (void) GetNextToken(r,&r,extent,token); if (*token == ',') (void) GetNextToken(r,&r,extent,token); } graphic_context[n]->dash_pattern=(double *) AcquireQuantumMemory((size_t) (2*x+2), sizeof(*graphic_context[n]->dash_pattern)); if (graphic_context[n]->dash_pattern == (double *) NULL) { (void) ThrowMagickException(exception,GetMagickModule(), ResourceLimitError,"MemoryAllocationFailed","`%s'", image->filename); status=MagickFalse; break; } (void) memset(graphic_context[n]->dash_pattern,0,(size_t) (2*x+2)*sizeof(*graphic_context[n]->dash_pattern)); for (j=0; j < x; j++) { (void) GetNextToken(q,&q,extent,token); if (*token == ',') (void) GetNextToken(q,&q,extent,token); graphic_context[n]->dash_pattern[j]=StringToDouble(token, &next_token); if (token == next_token) ThrowPointExpectedException(token,exception); if (graphic_context[n]->dash_pattern[j] < 0.0) status=MagickFalse; } if ((x & 0x01) != 0) for ( ; j < (2*x); j++) graphic_context[n]->dash_pattern[j]= graphic_context[n]->dash_pattern[j-x]; graphic_context[n]->dash_pattern[j]=0.0; break; } (void) GetNextToken(q,&q,extent,token); break; } if (LocaleCompare("stroke-dashoffset",keyword) == 0) { (void) GetNextToken(q,&q,extent,token); graphic_context[n]->dash_offset=StringToDouble(token,&next_token); if (token == next_token) ThrowPointExpectedException(token,exception); break; } if (LocaleCompare("stroke-linecap",keyword) == 0) { ssize_t linecap; (void) GetNextToken(q,&q,extent,token); linecap=ParseCommandOption(MagickLineCapOptions,MagickFalse,token); if (linecap == -1) { status=MagickFalse; break; } graphic_context[n]->linecap=(LineCap) linecap; break; } if (LocaleCompare("stroke-linejoin",keyword) == 0) { ssize_t linejoin; (void) GetNextToken(q,&q,extent,token); linejoin=ParseCommandOption(MagickLineJoinOptions,MagickFalse, token); if (linejoin == -1) { status=MagickFalse; break; } graphic_context[n]->linejoin=(LineJoin) linejoin; break; } if (LocaleCompare("stroke-miterlimit",keyword) == 0) { (void) GetNextToken(q,&q,extent,token); graphic_context[n]->miterlimit=StringToUnsignedLong(token); break; } if (LocaleCompare("stroke-opacity",keyword) == 0) { double opacity; (void) GetNextToken(q,&q,extent,token); if (graphic_context[n]->clip_path != MagickFalse) break; factor=strchr(token,'%') != (char *) NULL ? 0.01 : 1.0; opacity=MagickMin(MagickMax(factor* StringToDouble(token,&next_token),0.0),1.0); if (token == next_token) ThrowPointExpectedException(token,exception); graphic_context[n]->stroke_alpha*=opacity; if (graphic_context[n]->stroke.alpha != TransparentAlpha) graphic_context[n]->stroke.alpha=graphic_context[n]->stroke_alpha; else graphic_context[n]->stroke.alpha=(MagickRealType) ClampToQuantum(QuantumRange*(1.0-opacity)); break; } if (LocaleCompare("stroke-width",keyword) == 0) { (void) GetNextToken(q,&q,extent,token); if (graphic_context[n]->clip_path != MagickFalse) break; graphic_context[n]->stroke_width=StringToDouble(token,&next_token); if (token == next_token) ThrowPointExpectedException(token,exception); break; } status=MagickFalse; break; } case 't': case 'T': { if (LocaleCompare("text",keyword) == 0) { primitive_type=TextPrimitive; break; } if (LocaleCompare("text-align",keyword) == 0) { ssize_t align; (void) GetNextToken(q,&q,extent,token); align=ParseCommandOption(MagickAlignOptions,MagickFalse,token); if (align == -1) { status=MagickFalse; break; } graphic_context[n]->align=(AlignType) align; break; } if (LocaleCompare("text-anchor",keyword) == 0) { ssize_t align; (void) GetNextToken(q,&q,extent,token); align=ParseCommandOption(MagickAlignOptions,MagickFalse,token); if (align == -1) { status=MagickFalse; break; } graphic_context[n]->align=(AlignType) align; break; } if (LocaleCompare("text-antialias",keyword) == 0) { (void) GetNextToken(q,&q,extent,token); graphic_context[n]->text_antialias=StringToLong(token) != 0 ? MagickTrue : MagickFalse; break; } if (LocaleCompare("text-undercolor",keyword) == 0) { (void) GetNextToken(q,&q,extent,token); status&=QueryColorCompliance(token,AllCompliance, &graphic_context[n]->undercolor,exception); break; } if (LocaleCompare("translate",keyword) == 0) { (void) GetNextToken(q,&q,extent,token); affine.tx=StringToDouble(token,&next_token); if (token == next_token) ThrowPointExpectedException(token,exception); (void) GetNextToken(q,&q,extent,token); if (*token == ',') (void) GetNextToken(q,&q,extent,token); affine.ty=StringToDouble(token,&next_token); if (token == next_token) ThrowPointExpectedException(token,exception); cursor=0.0; break; } status=MagickFalse; break; } case 'u': case 'U': { if (LocaleCompare("use",keyword) == 0) { const char *use; /* Get a macro from the MVG document, and "use" it here. */ (void) GetNextToken(q,&q,extent,token); use=(const char *) GetValueFromSplayTree(macros,token); if (use != (const char *) NULL) { clone_info=CloneDrawInfo((ImageInfo *) NULL,graphic_context[n]); (void) CloneString(&clone_info->primitive,use); status=RenderMVGContent(image,clone_info,depth+1,exception); clone_info=DestroyDrawInfo(clone_info); } break; } break; } case 'v': case 'V': { if (LocaleCompare("viewbox",keyword) == 0) { (void) GetNextToken(q,&q,extent,token); graphic_context[n]->viewbox.x=(ssize_t) ceil(StringToDouble(token, &next_token)-0.5); if (token == next_token) ThrowPointExpectedException(token,exception); (void) GetNextToken(q,&q,extent,token); if (*token == ',') (void) GetNextToken(q,&q,extent,token); graphic_context[n]->viewbox.y=(ssize_t) ceil(StringToDouble(token, &next_token)-0.5); if (token == next_token) ThrowPointExpectedException(token,exception); (void) GetNextToken(q,&q,extent,token); if (*token == ',') (void) GetNextToken(q,&q,extent,token); graphic_context[n]->viewbox.width=(size_t) floor(StringToDouble( token,&next_token)+0.5); if (token == next_token) ThrowPointExpectedException(token,exception); (void) GetNextToken(q,&q,extent,token); if (*token == ',') (void) GetNextToken(q,&q,extent,token); graphic_context[n]->viewbox.height=(size_t) floor(StringToDouble( token,&next_token)+0.5); if (token == next_token) ThrowPointExpectedException(token,exception); break; } status=MagickFalse; break; } case 'w': case 'W': { if (LocaleCompare("word-spacing",keyword) == 0) { (void) GetNextToken(q,&q,extent,token); graphic_context[n]->interword_spacing=StringToDouble(token, &next_token); if (token == next_token) ThrowPointExpectedException(token,exception); break; } status=MagickFalse; break; } default: { status=MagickFalse; break; } } if (status == MagickFalse) break; if ((fabs(affine.sx-1.0) >= MagickEpsilon) || (fabs(affine.rx) >= MagickEpsilon) || (fabs(affine.ry) >= MagickEpsilon) || (fabs(affine.sy-1.0) >= MagickEpsilon) || (fabs(affine.tx) >= MagickEpsilon) || (fabs(affine.ty) >= MagickEpsilon)) { graphic_context[n]->affine.sx=current.sx*affine.sx+current.ry*affine.rx; graphic_context[n]->affine.rx=current.rx*affine.sx+current.sy*affine.rx; graphic_context[n]->affine.ry=current.sx*affine.ry+current.ry*affine.sy; graphic_context[n]->affine.sy=current.rx*affine.ry+current.sy*affine.sy; graphic_context[n]->affine.tx=current.sx*affine.tx+current.ry*affine.ty+ current.tx; graphic_context[n]->affine.ty=current.rx*affine.tx+current.sy*affine.ty+ current.ty; } if (primitive_type == UndefinedPrimitive) { if (*q == '\0') { if (number_stops > 1) { GradientType type; type=LinearGradient; if (draw_info->gradient.type == RadialGradient) type=RadialGradient; (void) GradientImage(image,type,PadSpread,stops,number_stops, exception); } if (number_stops > 0) stops=(StopInfo *) RelinquishMagickMemory(stops); } if ((image->debug != MagickFalse) && (q > p)) (void) LogMagickEvent(DrawEvent,GetMagickModule()," %.*s",(int) (q-p-1),p); continue; } /* Parse the primitive attributes. */ for (i=0; primitive_info[i].primitive != UndefinedPrimitive; i++) if ((primitive_info[i].primitive == TextPrimitive) || (primitive_info[i].primitive == ImagePrimitive)) if (primitive_info[i].text != (char *) NULL) primitive_info[i].text=DestroyString(primitive_info[i].text); i=0; mvg_info.offset=i; j=0; primitive_info[0].point.x=0.0; primitive_info[0].point.y=0.0; primitive_info[0].coordinates=0; primitive_info[0].method=FloodfillMethod; primitive_info[0].closed_subpath=MagickFalse; for (x=0; *q != '\0'; x++) { /* Define points. */ if (IsPoint(q) == MagickFalse) break; (void) GetNextToken(q,&q,extent,token); point.x=StringToDouble(token,&next_token); if (token == next_token) ThrowPointExpectedException(token,exception); (void) GetNextToken(q,&q,extent,token); if (*token == ',') (void) GetNextToken(q,&q,extent,token); point.y=StringToDouble(token,&next_token); if (token == next_token) ThrowPointExpectedException(token,exception); (void) GetNextToken(q,(const char **) NULL,extent,token); if (*token == ',') (void) GetNextToken(q,&q,extent,token); primitive_info[i].primitive=primitive_type; primitive_info[i].point=point; primitive_info[i].coordinates=0; primitive_info[i].method=FloodfillMethod; primitive_info[i].closed_subpath=MagickFalse; i++; mvg_info.offset=i; if (i < (ssize_t) number_points) continue; status&=CheckPrimitiveExtent(&mvg_info,number_points); } if (status == MagickFalse) break; if ((primitive_info[j].primitive == TextPrimitive) || (primitive_info[j].primitive == ImagePrimitive)) if (primitive_info[j].text != (char *) NULL) primitive_info[j].text=DestroyString(primitive_info[j].text); primitive_info[j].primitive=primitive_type; primitive_info[j].coordinates=(size_t) x; primitive_info[j].method=FloodfillMethod; primitive_info[j].closed_subpath=MagickFalse; /* Circumscribe primitive within a circle. */ bounds.x1=primitive_info[j].point.x; bounds.y1=primitive_info[j].point.y; bounds.x2=primitive_info[j].point.x; bounds.y2=primitive_info[j].point.y; for (k=1; k < (ssize_t) primitive_info[j].coordinates; k++) { point=primitive_info[j+k].point; if (point.x < bounds.x1) bounds.x1=point.x; if (point.y < bounds.y1) bounds.y1=point.y; if (point.x > bounds.x2) bounds.x2=point.x; if (point.y > bounds.y2) bounds.y2=point.y; } /* Speculate how many points our primitive might consume. */ coordinates=(double) primitive_info[j].coordinates; switch (primitive_type) { case RectanglePrimitive: { coordinates*=5.0; break; } case RoundRectanglePrimitive: { double alpha, beta, radius; alpha=bounds.x2-bounds.x1; beta=bounds.y2-bounds.y1; radius=hypot((double) alpha,(double) beta); coordinates*=5.0; coordinates+=2.0*((size_t) ceil((double) MagickPI*radius))+6.0* BezierQuantum+360.0; break; } case BezierPrimitive: { coordinates=(double) (BezierQuantum*primitive_info[j].coordinates); if (primitive_info[j].coordinates > (107*BezierQuantum)) { (void) ThrowMagickException(exception,GetMagickModule(),DrawError, "TooManyBezierCoordinates","`%s'",token); status=MagickFalse; break; } break; } case PathPrimitive: { char *s, *t; (void) GetNextToken(q,&q,extent,token); coordinates=1.0; t=token; for (s=token; *s != '\0'; s=t) { double value; value=StringToDouble(s,&t); (void) value; if (s == t) { t++; continue; } coordinates++; } for (s=token; *s != '\0'; s++) if (strspn(s,"AaCcQqSsTt") != 0) coordinates+=(20.0*BezierQuantum)+360.0; break; } case CirclePrimitive: case ArcPrimitive: case EllipsePrimitive: { double alpha, beta, radius; alpha=bounds.x2-bounds.x1; beta=bounds.y2-bounds.y1; radius=hypot(alpha,beta); coordinates=2.0*(ceil(MagickPI*radius))+6.0*BezierQuantum+360.0; break; } default: break; } if (coordinates > MaxBezierCoordinates) { (void) ThrowMagickException(exception,GetMagickModule(), ResourceLimitError,"TooManyBezierCoordinates","`%s'",token); status=MagickFalse; } if (status == MagickFalse) break; if (((size_t) (i+coordinates)) >= number_points) { /* Resize based on speculative points required by primitive. */ number_points+=coordinates+1; if (number_points < (size_t) coordinates) { (void) ThrowMagickException(exception,GetMagickModule(), ResourceLimitError,"MemoryAllocationFailed","`%s'", image->filename); break; } mvg_info.offset=i; status&=CheckPrimitiveExtent(&mvg_info,number_points); } status&=CheckPrimitiveExtent(&mvg_info,PrimitiveExtentPad); if (status == MagickFalse) break; mvg_info.offset=j; switch (primitive_type) { case PointPrimitive: default: { if (primitive_info[j].coordinates != 1) { status=MagickFalse; break; } status&=TracePoint(primitive_info+j,primitive_info[j].point); i=(ssize_t) (j+primitive_info[j].coordinates); break; } case LinePrimitive: { if (primitive_info[j].coordinates != 2) { status=MagickFalse; break; } status&=TraceLine(primitive_info+j,primitive_info[j].point, primitive_info[j+1].point); i=(ssize_t) (j+primitive_info[j].coordinates); break; } case RectanglePrimitive: { if (primitive_info[j].coordinates != 2) { status=MagickFalse; break; } status&=TraceRectangle(primitive_info+j,primitive_info[j].point, primitive_info[j+1].point); i=(ssize_t) (j+primitive_info[j].coordinates); break; } case RoundRectanglePrimitive: { if (primitive_info[j].coordinates != 3) { status=MagickFalse; break; } if ((primitive_info[j+2].point.x < 0.0) || (primitive_info[j+2].point.y < 0.0)) { status=MagickFalse; break; } if ((primitive_info[j+1].point.x-primitive_info[j].point.x) < 0.0) { status=MagickFalse; break; } if ((primitive_info[j+1].point.y-primitive_info[j].point.y) < 0.0) { status=MagickFalse; break; } status&=TraceRoundRectangle(&mvg_info,primitive_info[j].point, primitive_info[j+1].point,primitive_info[j+2].point); i=(ssize_t) (j+primitive_info[j].coordinates); break; } case ArcPrimitive: { if (primitive_info[j].coordinates != 3) { primitive_type=UndefinedPrimitive; break; } status&=TraceArc(&mvg_info,primitive_info[j].point, primitive_info[j+1].point,primitive_info[j+2].point); i=(ssize_t) (j+primitive_info[j].coordinates); break; } case EllipsePrimitive: { if (primitive_info[j].coordinates != 3) { status=MagickFalse; break; } if ((primitive_info[j+1].point.x < 0.0) || (primitive_info[j+1].point.y < 0.0)) { status=MagickFalse; break; } status&=TraceEllipse(&mvg_info,primitive_info[j].point, primitive_info[j+1].point,primitive_info[j+2].point); i=(ssize_t) (j+primitive_info[j].coordinates); break; } case CirclePrimitive: { if (primitive_info[j].coordinates != 2) { status=MagickFalse; break; } status&=TraceCircle(&mvg_info,primitive_info[j].point, primitive_info[j+1].point); i=(ssize_t) (j+primitive_info[j].coordinates); break; } case PolylinePrimitive: { if (primitive_info[j].coordinates < 1) { status=MagickFalse; break; } break; } case PolygonPrimitive: { if (primitive_info[j].coordinates < 3) { status=MagickFalse; break; } primitive_info[i]=primitive_info[j]; primitive_info[i].coordinates=0; primitive_info[j].coordinates++; primitive_info[j].closed_subpath=MagickTrue; i++; break; } case BezierPrimitive: { if (primitive_info[j].coordinates < 3) { status=MagickFalse; break; } status&=TraceBezier(&mvg_info,primitive_info[j].coordinates); i=(ssize_t) (j+primitive_info[j].coordinates); break; } case PathPrimitive: { coordinates=(double) TracePath(&mvg_info,token,exception); if (coordinates == 0.0) { status=MagickFalse; break; } i=(ssize_t) (j+coordinates); break; } case AlphaPrimitive: case ColorPrimitive: { ssize_t method; if (primitive_info[j].coordinates != 1) { status=MagickFalse; break; } (void) GetNextToken(q,&q,extent,token); method=ParseCommandOption(MagickMethodOptions,MagickFalse,token); if (method == -1) { status=MagickFalse; break; } primitive_info[j].method=(PaintMethod) method; break; } case TextPrimitive: { char geometry[MagickPathExtent]; if (primitive_info[j].coordinates != 1) { status=MagickFalse; break; } if (*token != ',') (void) GetNextToken(q,&q,extent,token); (void) CloneString(&primitive_info[j].text,token); /* Compute text cursor offset. */ clone_info=CloneDrawInfo((ImageInfo *) NULL,graphic_context[n]); if ((fabs(mvg_info.point.x-primitive_info->point.x) < MagickEpsilon) && (fabs(mvg_info.point.y-primitive_info->point.y) < MagickEpsilon)) { mvg_info.point=primitive_info->point; primitive_info->point.x+=cursor; } else { mvg_info.point=primitive_info->point; cursor=0.0; } (void) FormatLocaleString(geometry,MagickPathExtent,"%+f%+f", primitive_info->point.x,primitive_info->point.y); clone_info->render=MagickFalse; clone_info->text=AcquireString(token); status&=GetTypeMetrics(image,clone_info,&metrics,exception); clone_info=DestroyDrawInfo(clone_info); cursor+=metrics.width; if (graphic_context[n]->compliance != SVGCompliance) cursor=0.0; break; } case ImagePrimitive: { if (primitive_info[j].coordinates != 2) { status=MagickFalse; break; } (void) GetNextToken(q,&q,extent,token); (void) CloneString(&primitive_info[j].text,token); break; } } mvg_info.offset=i; if ((image->debug != MagickFalse) && (q > p)) (void) LogMagickEvent(DrawEvent,GetMagickModule()," %.*s",(int) (q-p-1), p); if (status == MagickFalse) break; primitive_info[i].primitive=UndefinedPrimitive; if (i == 0) continue; /* Transform points. */ for (i=0; primitive_info[i].primitive != UndefinedPrimitive; i++) { point=primitive_info[i].point; primitive_info[i].point.x=graphic_context[n]->affine.sx*point.x+ graphic_context[n]->affine.ry*point.y+graphic_context[n]->affine.tx; primitive_info[i].point.y=graphic_context[n]->affine.rx*point.x+ graphic_context[n]->affine.sy*point.y+graphic_context[n]->affine.ty; point=primitive_info[i].point; if (point.x < graphic_context[n]->bounds.x1) graphic_context[n]->bounds.x1=point.x; if (point.y < graphic_context[n]->bounds.y1) graphic_context[n]->bounds.y1=point.y; if (point.x > graphic_context[n]->bounds.x2) graphic_context[n]->bounds.x2=point.x; if (point.y > graphic_context[n]->bounds.y2) graphic_context[n]->bounds.y2=point.y; if (primitive_info[i].primitive == ImagePrimitive) break; if (i >= (ssize_t) number_points) ThrowFatalException(ResourceLimitFatalError,"MemoryAllocationFailed"); } if (graphic_context[n]->render != MagickFalse) { if ((n != 0) && (graphic_context[n]->compliance != SVGCompliance) && (graphic_context[n]->clip_mask != (char *) NULL) && (LocaleCompare(graphic_context[n]->clip_mask, graphic_context[n-1]->clip_mask) != 0)) { const char *clip_path; clip_path=(const char *) GetValueFromSplayTree(macros, graphic_context[n]->clip_mask); if (clip_path != (const char *) NULL) (void) SetImageArtifact(image,graphic_context[n]->clip_mask, clip_path); status&=DrawClipPath(image,graphic_context[n], graphic_context[n]->clip_mask,exception); } status&=DrawPrimitive(image,graphic_context[n],primitive_info, exception); } proceed=SetImageProgress(image,RenderImageTag,q-primitive,(MagickSizeType) primitive_extent); if (proceed == MagickFalse) break; if (status == 0) break; } if (image->debug != MagickFalse) (void) LogMagickEvent(DrawEvent,GetMagickModule(),"end draw-image"); /* Relinquish resources. */ macros=DestroySplayTree(macros); token=DestroyString(token); if (primitive_info != (PrimitiveInfo *) NULL) { for (i=0; primitive_info[i].primitive != UndefinedPrimitive; i++) if ((primitive_info[i].primitive == TextPrimitive) || (primitive_info[i].primitive == ImagePrimitive)) if (primitive_info[i].text != (char *) NULL) primitive_info[i].text=DestroyString(primitive_info[i].text); primitive_info=(PrimitiveInfo *) RelinquishMagickMemory(primitive_info); } primitive=DestroyString(primitive); if (stops != (StopInfo *) NULL) stops=(StopInfo *) RelinquishMagickMemory(stops); for ( ; n >= 0; n--) graphic_context[n]=DestroyDrawInfo(graphic_context[n]); graphic_context=(DrawInfo **) RelinquishMagickMemory(graphic_context); if (status == MagickFalse) ThrowBinaryException(DrawError,"NonconformingDrawingPrimitiveDefinition", keyword); return(status != 0 ? MagickTrue : MagickFalse); } MagickExport MagickBooleanType DrawImage(Image *image,const DrawInfo *draw_info, ExceptionInfo *exception) { return(RenderMVGContent(image,draw_info,0,exception)); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % D r a w P a t t e r n P a t h % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % DrawPatternPath() draws a pattern. % % The format of the DrawPatternPath method is: % % MagickBooleanType DrawPatternPath(Image *image,const DrawInfo *draw_info, % const char *name,Image **pattern,ExceptionInfo *exception) % % A description of each parameter follows: % % o image: the image. % % o draw_info: the draw info. % % o name: the pattern name. % % o image: the image. % % o exception: return any errors or warnings in this structure. % */ MagickExport MagickBooleanType DrawPatternPath(Image *image, const DrawInfo *draw_info,const char *name,Image **pattern, ExceptionInfo *exception) { char property[MagickPathExtent]; const char *geometry, *path, *type; DrawInfo *clone_info; ImageInfo *image_info; MagickBooleanType status; assert(image != (Image *) NULL); assert(image->signature == MagickCoreSignature); if (image->debug != MagickFalse) (void) LogMagickEvent(TraceEvent,GetMagickModule(),"%s",image->filename); assert(draw_info != (const DrawInfo *) NULL); assert(name != (const char *) NULL); (void) FormatLocaleString(property,MagickPathExtent,"%s",name); path=GetImageArtifact(image,property); if (path == (const char *) NULL) return(MagickFalse); (void) FormatLocaleString(property,MagickPathExtent,"%s-geometry",name); geometry=GetImageArtifact(image,property); if (geometry == (const char *) NULL) return(MagickFalse); if ((*pattern) != (Image *) NULL) *pattern=DestroyImage(*pattern); image_info=AcquireImageInfo(); image_info->size=AcquireString(geometry); *pattern=AcquireImage(image_info,exception); image_info=DestroyImageInfo(image_info); (void) QueryColorCompliance("#000000ff",AllCompliance, &(*pattern)->background_color,exception); (void) SetImageBackgroundColor(*pattern,exception); if (image->debug != MagickFalse) (void) LogMagickEvent(DrawEvent,GetMagickModule(), "begin pattern-path %s %s",name,geometry); clone_info=CloneDrawInfo((ImageInfo *) NULL,draw_info); clone_info->fill_pattern=NewImageList(); clone_info->stroke_pattern=NewImageList(); (void) FormatLocaleString(property,MagickPathExtent,"%s-type",name); type=GetImageArtifact(image,property); if (type != (const char *) NULL) clone_info->gradient.type=(GradientType) ParseCommandOption( MagickGradientOptions,MagickFalse,type); (void) CloneString(&clone_info->primitive,path); status=RenderMVGContent(*pattern,clone_info,0,exception); clone_info=DestroyDrawInfo(clone_info); if (image->debug != MagickFalse) (void) LogMagickEvent(DrawEvent,GetMagickModule(),"end pattern-path"); return(status); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % + D r a w P o l y g o n P r i m i t i v e % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % DrawPolygonPrimitive() draws a polygon on the image. % % The format of the DrawPolygonPrimitive method is: % % MagickBooleanType DrawPolygonPrimitive(Image *image, % const DrawInfo *draw_info,const PrimitiveInfo *primitive_info, % ExceptionInfo *exception) % % A description of each parameter follows: % % o image: the image. % % o draw_info: the draw info. % % o primitive_info: Specifies a pointer to a PrimitiveInfo structure. % % o exception: return any errors or warnings in this structure. % */ static PolygonInfo **DestroyPolygonThreadSet(PolygonInfo **polygon_info) { register ssize_t i; assert(polygon_info != (PolygonInfo **) NULL); for (i=0; i < (ssize_t) GetMagickResourceLimit(ThreadResource); i++) if (polygon_info[i] != (PolygonInfo *) NULL) polygon_info[i]=DestroyPolygonInfo(polygon_info[i]); polygon_info=(PolygonInfo **) RelinquishMagickMemory(polygon_info); return(polygon_info); } static PolygonInfo **AcquirePolygonThreadSet( const PrimitiveInfo *primitive_info) { PathInfo *magick_restrict path_info; PolygonInfo **polygon_info; register ssize_t i; size_t number_threads; number_threads=(size_t) GetMagickResourceLimit(ThreadResource); polygon_info=(PolygonInfo **) AcquireQuantumMemory(number_threads, sizeof(*polygon_info)); if (polygon_info == (PolygonInfo **) NULL) return((PolygonInfo **) NULL); (void) memset(polygon_info,0,number_threads*sizeof(*polygon_info)); path_info=ConvertPrimitiveToPath(primitive_info); if (path_info == (PathInfo *) NULL) return(DestroyPolygonThreadSet(polygon_info)); for (i=0; i < (ssize_t) number_threads; i++) { polygon_info[i]=ConvertPathToPolygon(path_info); if (polygon_info[i] == (PolygonInfo *) NULL) return(DestroyPolygonThreadSet(polygon_info)); } path_info=(PathInfo *) RelinquishMagickMemory(path_info); return(polygon_info); } static double GetFillAlpha(PolygonInfo *polygon_info,const double mid, const MagickBooleanType fill,const FillRule fill_rule,const ssize_t x, const ssize_t y,double *stroke_alpha) { double alpha, beta, distance, subpath_alpha; PointInfo delta; register const PointInfo *q; register EdgeInfo *p; register ssize_t i; ssize_t j, winding_number; /* Compute fill & stroke opacity for this (x,y) point. */ *stroke_alpha=0.0; subpath_alpha=0.0; p=polygon_info->edges; for (j=0; j < (ssize_t) polygon_info->number_edges; j++, p++) { if ((double) y <= (p->bounds.y1-mid-0.5)) break; if ((double) y > (p->bounds.y2+mid+0.5)) { (void) DestroyEdge(polygon_info,(size_t) j); continue; } if (((double) x <= (p->bounds.x1-mid-0.5)) || ((double) x > (p->bounds.x2+mid+0.5))) continue; i=(ssize_t) MagickMax((double) p->highwater,1.0); for ( ; i < (ssize_t) p->number_points; i++) { if ((double) y <= (p->points[i-1].y-mid-0.5)) break; if ((double) y > (p->points[i].y+mid+0.5)) continue; if (p->scanline != (double) y) { p->scanline=(double) y; p->highwater=(size_t) i; } /* Compute distance between a point and an edge. */ q=p->points+i-1; delta.x=(q+1)->x-q->x; delta.y=(q+1)->y-q->y; beta=delta.x*(x-q->x)+delta.y*(y-q->y); if (beta <= 0.0) { delta.x=(double) x-q->x; delta.y=(double) y-q->y; distance=delta.x*delta.x+delta.y*delta.y; } else { alpha=delta.x*delta.x+delta.y*delta.y; if (beta >= alpha) { delta.x=(double) x-(q+1)->x; delta.y=(double) y-(q+1)->y; distance=delta.x*delta.x+delta.y*delta.y; } else { alpha=PerceptibleReciprocal(alpha); beta=delta.x*(y-q->y)-delta.y*(x-q->x); distance=alpha*beta*beta; } } /* Compute stroke & subpath opacity. */ beta=0.0; if (p->ghostline == MagickFalse) { alpha=mid+0.5; if ((*stroke_alpha < 1.0) && (distance <= ((alpha+0.25)*(alpha+0.25)))) { alpha=mid-0.5; if (distance <= ((alpha+0.25)*(alpha+0.25))) *stroke_alpha=1.0; else { beta=1.0; if (fabs(distance-1.0) >= MagickEpsilon) beta=sqrt((double) distance); alpha=beta-mid-0.5; if (*stroke_alpha < ((alpha-0.25)*(alpha-0.25))) *stroke_alpha=(alpha-0.25)*(alpha-0.25); } } } if ((fill == MagickFalse) || (distance > 1.0) || (subpath_alpha >= 1.0)) continue; if (distance <= 0.0) { subpath_alpha=1.0; continue; } if (distance > 1.0) continue; if (fabs(beta) < MagickEpsilon) { beta=1.0; if (fabs(distance-1.0) >= MagickEpsilon) beta=sqrt(distance); } alpha=beta-1.0; if (subpath_alpha < (alpha*alpha)) subpath_alpha=alpha*alpha; } } /* Compute fill opacity. */ if (fill == MagickFalse) return(0.0); if (subpath_alpha >= 1.0) return(1.0); /* Determine winding number. */ winding_number=0; p=polygon_info->edges; for (j=0; j < (ssize_t) polygon_info->number_edges; j++, p++) { if ((double) y <= p->bounds.y1) break; if (((double) y > p->bounds.y2) || ((double) x <= p->bounds.x1)) continue; if ((double) x > p->bounds.x2) { winding_number+=p->direction ? 1 : -1; continue; } i=(ssize_t) MagickMax((double) p->highwater,1.0); for ( ; i < (ssize_t) (p->number_points-1); i++) if ((double) y <= p->points[i].y) break; q=p->points+i-1; if ((((q+1)->x-q->x)*(y-q->y)) <= (((q+1)->y-q->y)*(x-q->x))) winding_number+=p->direction ? 1 : -1; } if (fill_rule != NonZeroRule) { if ((MagickAbsoluteValue(winding_number) & 0x01) != 0) return(1.0); } else if (MagickAbsoluteValue(winding_number) != 0) return(1.0); return(subpath_alpha); } static MagickBooleanType DrawPolygonPrimitive(Image *image, const DrawInfo *draw_info,const PrimitiveInfo *primitive_info, ExceptionInfo *exception) { CacheView *image_view; MagickBooleanType fill, status; double mid; PolygonInfo **magick_restrict polygon_info; register EdgeInfo *p; register ssize_t i; SegmentInfo bounds; ssize_t start_y, stop_y, y; assert(image != (Image *) NULL); assert(image->signature == MagickCoreSignature); if (image->debug != MagickFalse) (void) LogMagickEvent(TraceEvent,GetMagickModule(),"%s",image->filename); assert(draw_info != (DrawInfo *) NULL); assert(draw_info->signature == MagickCoreSignature); assert(primitive_info != (PrimitiveInfo *) NULL); if (primitive_info->coordinates <= 1) return(MagickTrue); /* Compute bounding box. */ polygon_info=AcquirePolygonThreadSet(primitive_info); if (polygon_info == (PolygonInfo **) NULL) return(MagickFalse); DisableMSCWarning(4127) if (0) { status=DrawBoundingRectangles(image,draw_info,polygon_info[0],exception); if (status == MagickFalse) { polygon_info=DestroyPolygonThreadSet(polygon_info); return(status); } } RestoreMSCWarning if (image->debug != MagickFalse) (void) LogMagickEvent(DrawEvent,GetMagickModule()," begin draw-polygon"); fill=(primitive_info->method == FillToBorderMethod) || (primitive_info->method == FloodfillMethod) ? MagickTrue : MagickFalse; mid=ExpandAffine(&draw_info->affine)*SaneStrokeWidth(image,draw_info)/2.0; bounds=polygon_info[0]->edges[0].bounds; for (i=1; i < (ssize_t) polygon_info[0]->number_edges; i++) { p=polygon_info[0]->edges+i; if (p->bounds.x1 < bounds.x1) bounds.x1=p->bounds.x1; if (p->bounds.y1 < bounds.y1) bounds.y1=p->bounds.y1; if (p->bounds.x2 > bounds.x2) bounds.x2=p->bounds.x2; if (p->bounds.y2 > bounds.y2) bounds.y2=p->bounds.y2; } bounds.x1-=(mid+1.0); bounds.y1-=(mid+1.0); bounds.x2+=(mid+1.0); bounds.y2+=(mid+1.0); if ((bounds.x1 >= (double) image->columns) || (bounds.y1 >= (double) image->rows) || (bounds.x2 <= 0.0) || (bounds.y2 <= 0.0)) { polygon_info=DestroyPolygonThreadSet(polygon_info); return(MagickTrue); /* virtual polygon */ } bounds.x1=bounds.x1 < 0.0 ? 0.0 : bounds.x1 >= (double) image->columns-1.0 ? (double) image->columns-1.0 : bounds.x1; bounds.y1=bounds.y1 < 0.0 ? 0.0 : bounds.y1 >= (double) image->rows-1.0 ? (double) image->rows-1.0 : bounds.y1; bounds.x2=bounds.x2 < 0.0 ? 0.0 : bounds.x2 >= (double) image->columns-1.0 ? (double) image->columns-1.0 : bounds.x2; bounds.y2=bounds.y2 < 0.0 ? 0.0 : bounds.y2 >= (double) image->rows-1.0 ? (double) image->rows-1.0 : bounds.y2; status=MagickTrue; image_view=AcquireAuthenticCacheView(image,exception); if ((primitive_info->coordinates == 1) || (polygon_info[0]->number_edges == 0)) { /* Draw point. */ start_y=(ssize_t) ceil(bounds.y1-0.5); stop_y=(ssize_t) floor(bounds.y2+0.5); #if defined(MAGICKCORE_OPENMP_SUPPORT) #pragma omp parallel for schedule(static) shared(status) \ magick_number_threads(image,image,stop_y-start_y+1,1) #endif for (y=start_y; y <= stop_y; y++) { MagickBooleanType sync; PixelInfo pixel; register ssize_t x; register Quantum *magick_restrict q; ssize_t start_x, stop_x; if (status == MagickFalse) continue; start_x=(ssize_t) ceil(bounds.x1-0.5); stop_x=(ssize_t) floor(bounds.x2+0.5); x=start_x; q=GetCacheViewAuthenticPixels(image_view,x,y,(size_t) (stop_x-x+1),1, exception); if (q == (Quantum *) NULL) { status=MagickFalse; continue; } GetPixelInfo(image,&pixel); for ( ; x <= stop_x; x++) { if ((x == (ssize_t) ceil(primitive_info->point.x-0.5)) && (y == (ssize_t) ceil(primitive_info->point.y-0.5))) { GetFillColor(draw_info,x-start_x,y-start_y,&pixel,exception); SetPixelViaPixelInfo(image,&pixel,q); } q+=GetPixelChannels(image); } sync=SyncCacheViewAuthenticPixels(image_view,exception); if (sync == MagickFalse) status=MagickFalse; } image_view=DestroyCacheView(image_view); polygon_info=DestroyPolygonThreadSet(polygon_info); if (image->debug != MagickFalse) (void) LogMagickEvent(DrawEvent,GetMagickModule(), " end draw-polygon"); return(status); } /* Draw polygon or line. */ start_y=(ssize_t) ceil(bounds.y1-0.5); stop_y=(ssize_t) floor(bounds.y2+0.5); #if defined(MAGICKCORE_OPENMP_SUPPORT) #pragma omp parallel for schedule(static) shared(status) \ magick_number_threads(image,image,stop_y-start_y+1,1) #endif for (y=start_y; y <= stop_y; y++) { const int id = GetOpenMPThreadId(); register Quantum *magick_restrict q; register ssize_t x; ssize_t start_x, stop_x; if (status == MagickFalse) continue; start_x=(ssize_t) ceil(bounds.x1-0.5); stop_x=(ssize_t) floor(bounds.x2+0.5); q=GetCacheViewAuthenticPixels(image_view,start_x,y,(size_t) (stop_x-start_x+ 1),1,exception); if (q == (Quantum *) NULL) { status=MagickFalse; continue; } for (x=start_x; x <= stop_x; x++) { double fill_alpha, stroke_alpha; PixelInfo fill_color, stroke_color; /* Fill and/or stroke. */ fill_alpha=GetFillAlpha(polygon_info[id],mid,fill,draw_info->fill_rule, x,y,&stroke_alpha); if (draw_info->stroke_antialias == MagickFalse) { fill_alpha=fill_alpha > 0.25 ? 1.0 : 0.0; stroke_alpha=stroke_alpha > 0.25 ? 1.0 : 0.0; } GetFillColor(draw_info,x-start_x,y-start_y,&fill_color,exception); CompositePixelOver(image,&fill_color,fill_alpha*fill_color.alpha,q, (double) GetPixelAlpha(image,q),q); GetStrokeColor(draw_info,x-start_x,y-start_y,&stroke_color,exception); CompositePixelOver(image,&stroke_color,stroke_alpha*stroke_color.alpha,q, (double) GetPixelAlpha(image,q),q); q+=GetPixelChannels(image); } if (SyncCacheViewAuthenticPixels(image_view,exception) == MagickFalse) status=MagickFalse; } image_view=DestroyCacheView(image_view); polygon_info=DestroyPolygonThreadSet(polygon_info); if (image->debug != MagickFalse) (void) LogMagickEvent(DrawEvent,GetMagickModule()," end draw-polygon"); return(status); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % D r a w P r i m i t i v e % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % DrawPrimitive() draws a primitive (line, rectangle, ellipse) on the image. % % The format of the DrawPrimitive method is: % % MagickBooleanType DrawPrimitive(Image *image,const DrawInfo *draw_info, % PrimitiveInfo *primitive_info,ExceptionInfo *exception) % % A description of each parameter follows: % % o image: the image. % % o draw_info: the draw info. % % o primitive_info: Specifies a pointer to a PrimitiveInfo structure. % % o exception: return any errors or warnings in this structure. % */ static inline double ConstrainCoordinate(double x) { if (x < (double) -(SSIZE_MAX-512)) return((double) -(SSIZE_MAX-512)); if (x > (double) (SSIZE_MAX-512)) return((double) (SSIZE_MAX-512)); return(x); } static void LogPrimitiveInfo(const PrimitiveInfo *primitive_info) { const char *methods[] = { "point", "replace", "floodfill", "filltoborder", "reset", "?" }; PointInfo p, point, q; register ssize_t i, x; ssize_t coordinates, y; x=(ssize_t) ceil(primitive_info->point.x-0.5); y=(ssize_t) ceil(primitive_info->point.y-0.5); switch (primitive_info->primitive) { case AlphaPrimitive: { (void) LogMagickEvent(DrawEvent,GetMagickModule(), "AlphaPrimitive %.20g,%.20g %s",(double) x,(double) y, methods[primitive_info->method]); return; } case ColorPrimitive: { (void) LogMagickEvent(DrawEvent,GetMagickModule(), "ColorPrimitive %.20g,%.20g %s",(double) x,(double) y, methods[primitive_info->method]); return; } case ImagePrimitive: { (void) LogMagickEvent(DrawEvent,GetMagickModule(), "ImagePrimitive %.20g,%.20g",(double) x,(double) y); return; } case PointPrimitive: { (void) LogMagickEvent(DrawEvent,GetMagickModule(), "PointPrimitive %.20g,%.20g %s",(double) x,(double) y, methods[primitive_info->method]); return; } case TextPrimitive: { (void) LogMagickEvent(DrawEvent,GetMagickModule(), "TextPrimitive %.20g,%.20g",(double) x,(double) y); return; } default: break; } coordinates=0; p=primitive_info[0].point; q.x=(-1.0); q.y=(-1.0); for (i=0; primitive_info[i].primitive != UndefinedPrimitive; i++) { point=primitive_info[i].point; if (coordinates <= 0) { coordinates=(ssize_t) primitive_info[i].coordinates; (void) LogMagickEvent(DrawEvent,GetMagickModule(), " begin open (%.20g)",(double) coordinates); p=point; } point=primitive_info[i].point; if ((fabs(q.x-point.x) >= MagickEpsilon) || (fabs(q.y-point.y) >= MagickEpsilon)) (void) LogMagickEvent(DrawEvent,GetMagickModule(), " %.20g: %.18g,%.18g",(double) coordinates,point.x,point.y); else (void) LogMagickEvent(DrawEvent,GetMagickModule(), " %.20g: %g %g (duplicate)",(double) coordinates,point.x,point.y); q=point; coordinates--; if (coordinates > 0) continue; if ((fabs(p.x-point.x) >= MagickEpsilon) || (fabs(p.y-point.y) >= MagickEpsilon)) (void) LogMagickEvent(DrawEvent,GetMagickModule()," end last (%.20g)", (double) coordinates); else (void) LogMagickEvent(DrawEvent,GetMagickModule()," end open (%.20g)", (double) coordinates); } } MagickExport MagickBooleanType DrawPrimitive(Image *image, const DrawInfo *draw_info,const PrimitiveInfo *primitive_info, ExceptionInfo *exception) { CacheView *image_view; MagickStatusType status; register ssize_t i, x; ssize_t y; if (image->debug != MagickFalse) { (void) LogMagickEvent(DrawEvent,GetMagickModule(), " begin draw-primitive"); (void) LogMagickEvent(DrawEvent,GetMagickModule(), " affine: %g,%g,%g,%g,%g,%g",draw_info->affine.sx, draw_info->affine.rx,draw_info->affine.ry,draw_info->affine.sy, draw_info->affine.tx,draw_info->affine.ty); } status=MagickTrue; if ((IsGrayColorspace(image->colorspace) != MagickFalse) && ((IsPixelInfoGray(&draw_info->fill) == MagickFalse) || (IsPixelInfoGray(&draw_info->stroke) == MagickFalse))) status=SetImageColorspace(image,sRGBColorspace,exception); if (draw_info->compliance == SVGCompliance) { status&=SetImageMask(image,WritePixelMask,draw_info->clipping_mask, exception); status&=SetImageMask(image,CompositePixelMask,draw_info->composite_mask, exception); } x=(ssize_t) ceil(ConstrainCoordinate(primitive_info->point.x-0.5)); y=(ssize_t) ceil(ConstrainCoordinate(primitive_info->point.y-0.5)); image_view=AcquireAuthenticCacheView(image,exception); switch (primitive_info->primitive) { case AlphaPrimitive: { if (image->alpha_trait == UndefinedPixelTrait) (void) SetImageAlphaChannel(image,OpaqueAlphaChannel,exception); switch (primitive_info->method) { case PointMethod: default: { PixelInfo pixel; register Quantum *q; q=GetCacheViewAuthenticPixels(image_view,x,y,1,1,exception); if (q == (Quantum *) NULL) break; GetFillColor(draw_info,x,y,&pixel,exception); SetPixelAlpha(image,ClampToQuantum(pixel.alpha),q); (void) SyncCacheViewAuthenticPixels(image_view,exception); break; } case ReplaceMethod: { MagickBooleanType sync; PixelInfo pixel, target; (void) GetOneCacheViewVirtualPixelInfo(image_view,x,y,&target, exception); GetPixelInfo(image,&pixel); for (y=0; y < (ssize_t) image->rows; y++) { register Quantum *magick_restrict q; q=GetCacheViewAuthenticPixels(image_view,0,y,image->columns,1, exception); if (q == (Quantum *) NULL) break; for (x=0; x < (ssize_t) image->columns; x++) { GetPixelInfoPixel(image,q,&pixel); if (IsFuzzyEquivalencePixelInfo(&pixel,&target) == MagickFalse) { q+=GetPixelChannels(image); continue; } GetFillColor(draw_info,x,y,&pixel,exception); SetPixelAlpha(image,ClampToQuantum(pixel.alpha),q); q+=GetPixelChannels(image); } sync=SyncCacheViewAuthenticPixels(image_view,exception); if (sync == MagickFalse) break; } break; } case FloodfillMethod: case FillToBorderMethod: { ChannelType channel_mask; PixelInfo target; (void) GetOneVirtualPixelInfo(image,TileVirtualPixelMethod,x,y, &target,exception); if (primitive_info->method == FillToBorderMethod) { target.red=(double) draw_info->border_color.red; target.green=(double) draw_info->border_color.green; target.blue=(double) draw_info->border_color.blue; } channel_mask=SetImageChannelMask(image,AlphaChannel); status&=FloodfillPaintImage(image,draw_info,&target,x,y, primitive_info->method == FloodfillMethod ? MagickFalse : MagickTrue,exception); (void) SetImageChannelMask(image,channel_mask); break; } case ResetMethod: { MagickBooleanType sync; PixelInfo pixel; for (y=0; y < (ssize_t) image->rows; y++) { register Quantum *magick_restrict q; q=GetCacheViewAuthenticPixels(image_view,0,y,image->columns,1, exception); if (q == (Quantum *) NULL) break; for (x=0; x < (ssize_t) image->columns; x++) { GetFillColor(draw_info,x,y,&pixel,exception); SetPixelAlpha(image,ClampToQuantum(pixel.alpha),q); q+=GetPixelChannels(image); } sync=SyncCacheViewAuthenticPixels(image_view,exception); if (sync == MagickFalse) break; } break; } } break; } case ColorPrimitive: { switch (primitive_info->method) { case PointMethod: default: { PixelInfo pixel; register Quantum *q; q=GetCacheViewAuthenticPixels(image_view,x,y,1,1,exception); if (q == (Quantum *) NULL) break; GetPixelInfo(image,&pixel); GetFillColor(draw_info,x,y,&pixel,exception); SetPixelViaPixelInfo(image,&pixel,q); (void) SyncCacheViewAuthenticPixels(image_view,exception); break; } case ReplaceMethod: { MagickBooleanType sync; PixelInfo pixel, target; (void) GetOneCacheViewVirtualPixelInfo(image_view,x,y,&target, exception); for (y=0; y < (ssize_t) image->rows; y++) { register Quantum *magick_restrict q; q=GetCacheViewAuthenticPixels(image_view,0,y,image->columns,1, exception); if (q == (Quantum *) NULL) break; for (x=0; x < (ssize_t) image->columns; x++) { GetPixelInfoPixel(image,q,&pixel); if (IsFuzzyEquivalencePixelInfo(&pixel,&target) == MagickFalse) { q+=GetPixelChannels(image); continue; } GetFillColor(draw_info,x,y,&pixel,exception); SetPixelViaPixelInfo(image,&pixel,q); q+=GetPixelChannels(image); } sync=SyncCacheViewAuthenticPixels(image_view,exception); if (sync == MagickFalse) break; } break; } case FloodfillMethod: case FillToBorderMethod: { PixelInfo target; (void) GetOneVirtualPixelInfo(image,TileVirtualPixelMethod,x,y, &target,exception); if (primitive_info->method == FillToBorderMethod) { target.red=(double) draw_info->border_color.red; target.green=(double) draw_info->border_color.green; target.blue=(double) draw_info->border_color.blue; } status&=FloodfillPaintImage(image,draw_info,&target,x,y, primitive_info->method == FloodfillMethod ? MagickFalse : MagickTrue,exception); break; } case ResetMethod: { MagickBooleanType sync; PixelInfo pixel; GetPixelInfo(image,&pixel); for (y=0; y < (ssize_t) image->rows; y++) { register Quantum *magick_restrict q; q=GetCacheViewAuthenticPixels(image_view,0,y,image->columns,1, exception); if (q == (Quantum *) NULL) break; for (x=0; x < (ssize_t) image->columns; x++) { GetFillColor(draw_info,x,y,&pixel,exception); SetPixelViaPixelInfo(image,&pixel,q); q+=GetPixelChannels(image); } sync=SyncCacheViewAuthenticPixels(image_view,exception); if (sync == MagickFalse) break; } break; } } break; } case ImagePrimitive: { AffineMatrix affine; char composite_geometry[MagickPathExtent]; Image *composite_image, *composite_images; ImageInfo *clone_info; RectangleInfo geometry; ssize_t x1, y1; if (primitive_info->text == (char *) NULL) break; clone_info=AcquireImageInfo(); composite_images=(Image *) NULL; if (LocaleNCompare(primitive_info->text,"data:",5) == 0) composite_images=ReadInlineImage(clone_info,primitive_info->text, exception); else if (*primitive_info->text != '\0') { (void) CopyMagickString(clone_info->filename,primitive_info->text, MagickPathExtent); composite_images=ReadImage(clone_info,exception); } clone_info=DestroyImageInfo(clone_info); if (composite_images == (Image *) NULL) { status=0; break; } composite_image=RemoveFirstImageFromList(&composite_images); composite_images=DestroyImageList(composite_images); (void) SetImageProgressMonitor(composite_image,(MagickProgressMonitor) NULL,(void *) NULL); x1=(ssize_t) ceil(primitive_info[1].point.x-0.5); y1=(ssize_t) ceil(primitive_info[1].point.y-0.5); if (((x1 != 0L) && (x1 != (ssize_t) composite_image->columns)) || ((y1 != 0L) && (y1 != (ssize_t) composite_image->rows))) { /* Resize image. */ (void) FormatLocaleString(composite_geometry,MagickPathExtent, "%gx%g!",primitive_info[1].point.x,primitive_info[1].point.y); composite_image->filter=image->filter; (void) TransformImage(&composite_image,(char *) NULL, composite_geometry,exception); } if (composite_image->alpha_trait == UndefinedPixelTrait) (void) SetImageAlphaChannel(composite_image,OpaqueAlphaChannel, exception); if (draw_info->alpha != OpaqueAlpha) (void) SetImageAlpha(composite_image,draw_info->alpha,exception); SetGeometry(image,&geometry); image->gravity=draw_info->gravity; geometry.x=x; geometry.y=y; (void) FormatLocaleString(composite_geometry,MagickPathExtent, "%.20gx%.20g%+.20g%+.20g",(double) composite_image->columns,(double) composite_image->rows,(double) geometry.x,(double) geometry.y); (void) ParseGravityGeometry(image,composite_geometry,&geometry,exception); affine=draw_info->affine; affine.tx=(double) geometry.x; affine.ty=(double) geometry.y; composite_image->interpolate=image->interpolate; if ((draw_info->compose == OverCompositeOp) || (draw_info->compose == SrcOverCompositeOp)) (void) DrawAffineImage(image,composite_image,&affine,exception); else (void) CompositeImage(image,composite_image,draw_info->compose, MagickTrue,geometry.x,geometry.y,exception); composite_image=DestroyImage(composite_image); break; } case PointPrimitive: { PixelInfo fill_color; register Quantum *q; if ((y < 0) || (y >= (ssize_t) image->rows)) break; if ((x < 0) || (x >= (ssize_t) image->columns)) break; q=GetCacheViewAuthenticPixels(image_view,x,y,1,1,exception); if (q == (Quantum *) NULL) break; GetFillColor(draw_info,x,y,&fill_color,exception); CompositePixelOver(image,&fill_color,(double) fill_color.alpha,q, (double) GetPixelAlpha(image,q),q); (void) SyncCacheViewAuthenticPixels(image_view,exception); break; } case TextPrimitive: { char geometry[MagickPathExtent]; DrawInfo *clone_info; if (primitive_info->text == (char *) NULL) break; clone_info=CloneDrawInfo((ImageInfo *) NULL,draw_info); (void) CloneString(&clone_info->text,primitive_info->text); (void) FormatLocaleString(geometry,MagickPathExtent,"%+f%+f", primitive_info->point.x,primitive_info->point.y); (void) CloneString(&clone_info->geometry,geometry); status&=AnnotateImage(image,clone_info,exception); clone_info=DestroyDrawInfo(clone_info); break; } default: { double mid, scale; DrawInfo *clone_info; if (IsEventLogging() != MagickFalse) LogPrimitiveInfo(primitive_info); scale=ExpandAffine(&draw_info->affine); if ((draw_info->dash_pattern != (double *) NULL) && (fabs(draw_info->dash_pattern[0]) >= MagickEpsilon) && (fabs(scale*draw_info->stroke_width) >= MagickEpsilon) && (draw_info->stroke.alpha != (Quantum) TransparentAlpha)) { /* Draw dash polygon. */ clone_info=CloneDrawInfo((ImageInfo *) NULL,draw_info); clone_info->stroke_width=0.0; clone_info->stroke.alpha=(MagickRealType) TransparentAlpha; status&=DrawPolygonPrimitive(image,clone_info,primitive_info, exception); clone_info=DestroyDrawInfo(clone_info); status=DrawDashPolygon(draw_info,primitive_info,image,exception); break; } mid=ExpandAffine(&draw_info->affine)*SaneStrokeWidth(image,draw_info)/2.0; if ((mid > 1.0) && ((draw_info->stroke.alpha != (Quantum) TransparentAlpha) || (draw_info->stroke_pattern != (Image *) NULL))) { double x, y; MagickBooleanType closed_path; /* Draw strokes while respecting line cap/join attributes. */ closed_path=primitive_info[0].closed_subpath; i=(ssize_t) primitive_info[0].coordinates; x=fabs(primitive_info[i-1].point.x-primitive_info[0].point.x); y=fabs(primitive_info[i-1].point.y-primitive_info[0].point.y); if ((x < MagickEpsilon) && (y < MagickEpsilon)) closed_path=MagickTrue; if ((((draw_info->linecap == RoundCap) || (closed_path != MagickFalse)) && (draw_info->linejoin == RoundJoin)) || (primitive_info[i].primitive != UndefinedPrimitive)) { status=DrawPolygonPrimitive(image,draw_info,primitive_info, exception); break; } clone_info=CloneDrawInfo((ImageInfo *) NULL,draw_info); clone_info->stroke_width=0.0; clone_info->stroke.alpha=(MagickRealType) TransparentAlpha; status&=DrawPolygonPrimitive(image,clone_info,primitive_info, exception); clone_info=DestroyDrawInfo(clone_info); status&=DrawStrokePolygon(image,draw_info,primitive_info,exception); break; } status&=DrawPolygonPrimitive(image,draw_info,primitive_info,exception); break; } } image_view=DestroyCacheView(image_view); if (draw_info->compliance == SVGCompliance) { status&=SetImageMask(image,WritePixelMask,(Image *) NULL,exception); status&=SetImageMask(image,CompositePixelMask,(Image *) NULL,exception); } if (image->debug != MagickFalse) (void) LogMagickEvent(DrawEvent,GetMagickModule()," end draw-primitive"); return(status != 0 ? MagickTrue : MagickFalse); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % + D r a w S t r o k e P o l y g o n % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % DrawStrokePolygon() draws a stroked polygon (line, rectangle, ellipse) on % the image while respecting the line cap and join attributes. % % The format of the DrawStrokePolygon method is: % % MagickBooleanType DrawStrokePolygon(Image *image, % const DrawInfo *draw_info,const PrimitiveInfo *primitive_info) % % A description of each parameter follows: % % o image: the image. % % o draw_info: the draw info. % % o primitive_info: Specifies a pointer to a PrimitiveInfo structure. % % */ static MagickBooleanType DrawRoundLinecap(Image *image, const DrawInfo *draw_info,const PrimitiveInfo *primitive_info, ExceptionInfo *exception) { PrimitiveInfo linecap[5]; register ssize_t i; for (i=0; i < 4; i++) linecap[i]=(*primitive_info); linecap[0].coordinates=4; linecap[1].point.x+=2.0*MagickEpsilon; linecap[2].point.x+=2.0*MagickEpsilon; linecap[2].point.y+=2.0*MagickEpsilon; linecap[3].point.y+=2.0*MagickEpsilon; linecap[4].primitive=UndefinedPrimitive; return(DrawPolygonPrimitive(image,draw_info,linecap,exception)); } static MagickBooleanType DrawStrokePolygon(Image *image, const DrawInfo *draw_info,const PrimitiveInfo *primitive_info, ExceptionInfo *exception) { DrawInfo *clone_info; MagickBooleanType closed_path; MagickStatusType status; PrimitiveInfo *stroke_polygon; register const PrimitiveInfo *p, *q; /* Draw stroked polygon. */ if (image->debug != MagickFalse) (void) LogMagickEvent(DrawEvent,GetMagickModule(), " begin draw-stroke-polygon"); clone_info=CloneDrawInfo((ImageInfo *) NULL,draw_info); clone_info->fill=draw_info->stroke; if (clone_info->fill_pattern != (Image *) NULL) clone_info->fill_pattern=DestroyImage(clone_info->fill_pattern); if (clone_info->stroke_pattern != (Image *) NULL) clone_info->fill_pattern=CloneImage(clone_info->stroke_pattern,0,0, MagickTrue,exception); clone_info->stroke.alpha=(MagickRealType) TransparentAlpha; clone_info->stroke_width=0.0; clone_info->fill_rule=NonZeroRule; status=MagickTrue; for (p=primitive_info; p->primitive != UndefinedPrimitive; p+=p->coordinates) { if (p->coordinates == 1) continue; stroke_polygon=TraceStrokePolygon(image,draw_info,p); if (stroke_polygon == (PrimitiveInfo *) NULL) { status=0; break; } status&=DrawPolygonPrimitive(image,clone_info,stroke_polygon,exception); stroke_polygon=(PrimitiveInfo *) RelinquishMagickMemory(stroke_polygon); if (status == 0) break; q=p+p->coordinates-1; closed_path=p->closed_subpath; if ((draw_info->linecap == RoundCap) && (closed_path == MagickFalse)) { status&=DrawRoundLinecap(image,draw_info,p,exception); status&=DrawRoundLinecap(image,draw_info,q,exception); } } clone_info=DestroyDrawInfo(clone_info); if (image->debug != MagickFalse) (void) LogMagickEvent(DrawEvent,GetMagickModule(), " end draw-stroke-polygon"); return(status != 0 ? MagickTrue : MagickFalse); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % % G e t A f f i n e M a t r i x % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % GetAffineMatrix() returns an AffineMatrix initialized to the identity % matrix. % % The format of the GetAffineMatrix method is: % % void GetAffineMatrix(AffineMatrix *affine_matrix) % % A description of each parameter follows: % % o affine_matrix: the affine matrix. % */ MagickExport void GetAffineMatrix(AffineMatrix *affine_matrix) { (void) LogMagickEvent(TraceEvent,GetMagickModule(),"..."); assert(affine_matrix != (AffineMatrix *) NULL); (void) memset(affine_matrix,0,sizeof(*affine_matrix)); affine_matrix->sx=1.0; affine_matrix->sy=1.0; } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % + G e t D r a w I n f o % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % GetDrawInfo() initializes draw_info to default values from image_info. % % The format of the GetDrawInfo method is: % % void GetDrawInfo(const ImageInfo *image_info,DrawInfo *draw_info) % % A description of each parameter follows: % % o image_info: the image info.. % % o draw_info: the draw info. % */ MagickExport void GetDrawInfo(const ImageInfo *image_info,DrawInfo *draw_info) { char *next_token; const char *option; ExceptionInfo *exception; ImageInfo *clone_info; /* Initialize draw attributes. */ (void) LogMagickEvent(TraceEvent,GetMagickModule(),"..."); assert(draw_info != (DrawInfo *) NULL); (void) memset(draw_info,0,sizeof(*draw_info)); clone_info=CloneImageInfo(image_info); GetAffineMatrix(&draw_info->affine); exception=AcquireExceptionInfo(); (void) QueryColorCompliance("#000F",AllCompliance,&draw_info->fill, exception); (void) QueryColorCompliance("#FFF0",AllCompliance,&draw_info->stroke, exception); draw_info->stroke_antialias=clone_info->antialias; draw_info->stroke_width=1.0; draw_info->fill_rule=EvenOddRule; draw_info->alpha=OpaqueAlpha; draw_info->fill_alpha=OpaqueAlpha; draw_info->stroke_alpha=OpaqueAlpha; draw_info->linecap=ButtCap; draw_info->linejoin=MiterJoin; draw_info->miterlimit=10; draw_info->decorate=NoDecoration; draw_info->pointsize=12.0; draw_info->undercolor.alpha=(MagickRealType) TransparentAlpha; draw_info->compose=OverCompositeOp; draw_info->render=MagickTrue; draw_info->clip_path=MagickFalse; draw_info->debug=IsEventLogging(); if (clone_info->font != (char *) NULL) draw_info->font=AcquireString(clone_info->font); if (clone_info->density != (char *) NULL) draw_info->density=AcquireString(clone_info->density); draw_info->text_antialias=clone_info->antialias; if (fabs(clone_info->pointsize) >= MagickEpsilon) draw_info->pointsize=clone_info->pointsize; draw_info->border_color=clone_info->border_color; if (clone_info->server_name != (char *) NULL) draw_info->server_name=AcquireString(clone_info->server_name); option=GetImageOption(clone_info,"direction"); if (option != (const char *) NULL) draw_info->direction=(DirectionType) ParseCommandOption( MagickDirectionOptions,MagickFalse,option); else draw_info->direction=UndefinedDirection; option=GetImageOption(clone_info,"encoding"); if (option != (const char *) NULL) (void) CloneString(&draw_info->encoding,option); option=GetImageOption(clone_info,"family"); if (option != (const char *) NULL) (void) CloneString(&draw_info->family,option); option=GetImageOption(clone_info,"fill"); if (option != (const char *) NULL) (void) QueryColorCompliance(option,AllCompliance,&draw_info->fill, exception); option=GetImageOption(clone_info,"gravity"); if (option != (const char *) NULL) draw_info->gravity=(GravityType) ParseCommandOption(MagickGravityOptions, MagickFalse,option); option=GetImageOption(clone_info,"interline-spacing"); if (option != (const char *) NULL) draw_info->interline_spacing=StringToDouble(option,&next_token); option=GetImageOption(clone_info,"interword-spacing"); if (option != (const char *) NULL) draw_info->interword_spacing=StringToDouble(option,&next_token); option=GetImageOption(clone_info,"kerning"); if (option != (const char *) NULL) draw_info->kerning=StringToDouble(option,&next_token); option=GetImageOption(clone_info,"stroke"); if (option != (const char *) NULL) (void) QueryColorCompliance(option,AllCompliance,&draw_info->stroke, exception); option=GetImageOption(clone_info,"strokewidth"); if (option != (const char *) NULL) draw_info->stroke_width=StringToDouble(option,&next_token); option=GetImageOption(clone_info,"style"); if (option != (const char *) NULL) draw_info->style=(StyleType) ParseCommandOption(MagickStyleOptions, MagickFalse,option); option=GetImageOption(clone_info,"undercolor"); if (option != (const char *) NULL) (void) QueryColorCompliance(option,AllCompliance,&draw_info->undercolor, exception); option=GetImageOption(clone_info,"weight"); if (option != (const char *) NULL) { ssize_t weight; weight=ParseCommandOption(MagickWeightOptions,MagickFalse,option); if (weight == -1) weight=(ssize_t) StringToUnsignedLong(option); draw_info->weight=(size_t) weight; } exception=DestroyExceptionInfo(exception); draw_info->signature=MagickCoreSignature; clone_info=DestroyImageInfo(clone_info); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % + P e r m u t a t e % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % Permutate() returns the permuation of the (n,k). % % The format of the Permutate method is: % % void Permutate(ssize_t n,ssize_t k) % % A description of each parameter follows: % % o n: % % o k: % % */ static inline double Permutate(const ssize_t n,const ssize_t k) { double r; register ssize_t i; r=1.0; for (i=k+1; i <= n; i++) r*=i; for (i=1; i <= (n-k); i++) r/=i; return(r); } /* %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % % % % % + T r a c e P r i m i t i v e % % % % % % % %%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%% % % TracePrimitive is a collection of methods for generating graphic % primitives such as arcs, ellipses, paths, etc. % */ static MagickBooleanType TraceArc(MVGInfo *mvg_info,const PointInfo start, const PointInfo end,const PointInfo degrees) { PointInfo center, radius; center.x=0.5*(end.x+start.x); center.y=0.5*(end.y+start.y); radius.x=fabs(center.x-start.x); radius.y=fabs(center.y-start.y); return(TraceEllipse(mvg_info,center,radius,degrees)); } static MagickBooleanType TraceArcPath(MVGInfo *mvg_info,const PointInfo start, const PointInfo end,const PointInfo arc,const double angle, const MagickBooleanType large_arc,const MagickBooleanType sweep) { double alpha, beta, delta, factor, gamma, theta; MagickStatusType status; PointInfo center, points[3], radii; register double cosine, sine; PrimitiveInfo *primitive_info; register PrimitiveInfo *p; register ssize_t i; size_t arc_segments; ssize_t offset; offset=mvg_info->offset; primitive_info=(*mvg_info->primitive_info)+mvg_info->offset; primitive_info->coordinates=0; if ((fabs(start.x-end.x) < MagickEpsilon) && (fabs(start.y-end.y) < MagickEpsilon)) return(TracePoint(primitive_info,end)); radii.x=fabs(arc.x); radii.y=fabs(arc.y); if ((radii.x < MagickEpsilon) || (radii.y < MagickEpsilon)) return(TraceLine(primitive_info,start,end)); cosine=cos(DegreesToRadians(fmod((double) angle,360.0))); sine=sin(DegreesToRadians(fmod((double) angle,360.0))); center.x=(double) (cosine*(end.x-start.x)/2+sine*(end.y-start.y)/2); center.y=(double) (cosine*(end.y-start.y)/2-sine*(end.x-start.x)/2); delta=(center.x*center.x)/(radii.x*radii.x)+(center.y*center.y)/ (radii.y*radii.y); if (delta < MagickEpsilon) return(TraceLine(primitive_info,start,end)); if (delta > 1.0) { radii.x*=sqrt((double) delta); radii.y*=sqrt((double) delta); } points[0].x=(double) (cosine*start.x/radii.x+sine*start.y/radii.x); points[0].y=(double) (cosine*start.y/radii.y-sine*start.x/radii.y); points[1].x=(double) (cosine*end.x/radii.x+sine*end.y/radii.x); points[1].y=(double) (cosine*end.y/radii.y-sine*end.x/radii.y); alpha=points[1].x-points[0].x; beta=points[1].y-points[0].y; if (fabs(alpha*alpha+beta*beta) < MagickEpsilon) return(TraceLine(primitive_info,start,end)); factor=PerceptibleReciprocal(alpha*alpha+beta*beta)-0.25; if (factor <= 0.0) factor=0.0; else { factor=sqrt((double) factor); if (sweep == large_arc) factor=(-factor); } center.x=(double) ((points[0].x+points[1].x)/2-factor*beta); center.y=(double) ((points[0].y+points[1].y)/2+factor*alpha); alpha=atan2(points[0].y-center.y,points[0].x-center.x); theta=atan2(points[1].y-center.y,points[1].x-center.x)-alpha; if ((theta < 0.0) && (sweep != MagickFalse)) theta+=2.0*MagickPI; else if ((theta > 0.0) && (sweep == MagickFalse)) theta-=2.0*MagickPI; arc_segments=(size_t) ceil(fabs((double) (theta/(0.5*MagickPI+ MagickEpsilon)))); status=MagickTrue; p=primitive_info; for (i=0; i < (ssize_t) arc_segments; i++) { beta=0.5*((alpha+(i+1)*theta/arc_segments)-(alpha+i*theta/arc_segments)); gamma=(8.0/3.0)*sin(fmod((double) (0.5*beta),DegreesToRadians(360.0)))* sin(fmod((double) (0.5*beta),DegreesToRadians(360.0)))/ sin(fmod((double) beta,DegreesToRadians(360.0))); points[0].x=(double) (center.x+cos(fmod((double) (alpha+(double) i*theta/ arc_segments),DegreesToRadians(360.0)))-gamma*sin(fmod((double) (alpha+ (double) i*theta/arc_segments),DegreesToRadians(360.0)))); points[0].y=(double) (center.y+sin(fmod((double) (alpha+(double) i*theta/ arc_segments),DegreesToRadians(360.0)))+gamma*cos(fmod((double) (alpha+ (double) i*theta/arc_segments),DegreesToRadians(360.0)))); points[2].x=(double) (center.x+cos(fmod((double) (alpha+(double) (i+1)* theta/arc_segments),DegreesToRadians(360.0)))); points[2].y=(double) (center.y+sin(fmod((double) (alpha+(double) (i+1)* theta/arc_segments),DegreesToRadians(360.0)))); points[1].x=(double) (points[2].x+gamma*sin(fmod((double) (alpha+(double) (i+1)*theta/arc_segments),DegreesToRadians(360.0)))); points[1].y=(double) (points[2].y-gamma*cos(fmod((double) (alpha+(double) (i+1)*theta/arc_segments),DegreesToRadians(360.0)))); p->point.x=(p == primitive_info) ? start.x : (p-1)->point.x; p->point.y=(p == primitive_info) ? start.y : (p-1)->point.y; (p+1)->point.x=(double) (cosine*radii.x*points[0].x-sine*radii.y* points[0].y); (p+1)->point.y=(double) (sine*radii.x*points[0].x+cosine*radii.y* points[0].y); (p+2)->point.x=(double) (cosine*radii.x*points[1].x-sine*radii.y* points[1].y); (p+2)->point.y=(double) (sine*radii.x*points[1].x+cosine*radii.y* points[1].y); (p+3)->point.x=(double) (cosine*radii.x*points[2].x-sine*radii.y* points[2].y); (p+3)->point.y=(double) (sine*radii.x*points[2].x+cosine*radii.y* points[2].y); if (i == (ssize_t) (arc_segments-1)) (p+3)->point=end; status&=TraceBezier(mvg_info,4); if (status == 0) break; p=(*mvg_info->primitive_info)+mvg_info->offset; mvg_info->offset+=p->coordinates; p+=p->coordinates; } if (status == 0) return(MagickFalse); mvg_info->offset=offset; primitive_info=(*mvg_info->primitive_info)+mvg_info->offset; primitive_info->coordinates=(size_t) (p-primitive_info); primitive_info->closed_subpath=MagickFalse; for (i=0; i < (ssize_t) primitive_info->coordinates; i++) { p->primitive=primitive_info->primitive; p--; } return(MagickTrue); } static MagickBooleanType TraceBezier(MVGInfo *mvg_info, const size_t number_coordinates) { double alpha, *coefficients, weight; PointInfo end, point, *points; PrimitiveInfo *primitive_info; register PrimitiveInfo *p; register ssize_t i, j; size_t control_points, quantum; /* Allocate coefficients. */ primitive_info=(*mvg_info->primitive_info)+mvg_info->offset; quantum=number_coordinates; for (i=0; i < (ssize_t) number_coordinates; i++) { for (j=i+1; j < (ssize_t) number_coordinates; j++) { alpha=fabs(primitive_info[j].point.x-primitive_info[i].point.x); if (alpha > (double) SSIZE_MAX) { (void) ThrowMagickException(mvg_info->exception,GetMagickModule(), ResourceLimitError,"MemoryAllocationFailed","`%s'",""); return(MagickFalse); } if (alpha > (double) quantum) quantum=(size_t) alpha; alpha=fabs(primitive_info[j].point.y-primitive_info[i].point.y); if (alpha > (double) SSIZE_MAX) { (void) ThrowMagickException(mvg_info->exception,GetMagickModule(), ResourceLimitError,"MemoryAllocationFailed","`%s'",""); return(MagickFalse); } if (alpha > (double) quantum) quantum=(size_t) alpha; } } primitive_info=(*mvg_info->primitive_info)+mvg_info->offset; quantum=MagickMin(quantum/number_coordinates,BezierQuantum); coefficients=(double *) AcquireQuantumMemory(number_coordinates, sizeof(*coefficients)); points=(PointInfo *) AcquireQuantumMemory(quantum,number_coordinates* sizeof(*points)); if ((coefficients == (double *) NULL) || (points == (PointInfo *) NULL)) { if (points != (PointInfo *) NULL) points=(PointInfo *) RelinquishMagickMemory(points); if (coefficients != (double *) NULL) coefficients=(double *) RelinquishMagickMemory(coefficients); (void) ThrowMagickException(mvg_info->exception,GetMagickModule(), ResourceLimitError,"MemoryAllocationFailed","`%s'",""); return(MagickFalse); } control_points=quantum*number_coordinates; if (CheckPrimitiveExtent(mvg_info,control_points+1) == MagickFalse) { points=(PointInfo *) RelinquishMagickMemory(points); coefficients=(double *) RelinquishMagickMemory(coefficients); return(MagickFalse); } primitive_info=(*mvg_info->primitive_info)+mvg_info->offset; /* Compute bezier points. */ end=primitive_info[number_coordinates-1].point; for (i=0; i < (ssize_t) number_coordinates; i++) coefficients[i]=Permutate((ssize_t) number_coordinates-1,i); weight=0.0; for (i=0; i < (ssize_t) control_points; i++) { p=primitive_info; point.x=0.0; point.y=0.0; alpha=pow((double) (1.0-weight),(double) number_coordinates-1.0); for (j=0; j < (ssize_t) number_coordinates; j++) { point.x+=alpha*coefficients[j]*p->point.x; point.y+=alpha*coefficients[j]*p->point.y; alpha*=weight/(1.0-weight); p++; } points[i]=point; weight+=1.0/control_points; } /* Bezier curves are just short segmented polys. */ p=primitive_info; for (i=0; i < (ssize_t) control_points; i++) { if (TracePoint(p,points[i]) == MagickFalse) { points=(PointInfo *) RelinquishMagickMemory(points); coefficients=(double *) RelinquishMagickMemory(coefficients); return(MagickFalse); } p+=p->coordinates; } if (TracePoint(p,end) == MagickFalse) { points=(PointInfo *) RelinquishMagickMemory(points); coefficients=(double *) RelinquishMagickMemory(coefficients); return(MagickFalse); } p+=p->coordinates; primitive_info->coordinates=(size_t) (p-primitive_info); primitive_info->closed_subpath=MagickFalse; for (i=0; i < (ssize_t) primitive_info->coordinates; i++) { p->primitive=primitive_info->primitive; p--; } points=(PointInfo *) RelinquishMagickMemory(points); coefficients=(double *) RelinquishMagickMemory(coefficients); return(MagickTrue); } static MagickBooleanType TraceCircle(MVGInfo *mvg_info,const PointInfo start, const PointInfo end) { double alpha, beta, radius; PointInfo offset, degrees; alpha=end.x-start.x; beta=end.y-start.y; radius=hypot((double) alpha,(double) beta); offset.x=(double) radius; offset.y=(double) radius; degrees.x=0.0; degrees.y=360.0; return(TraceEllipse(mvg_info,start,offset,degrees)); } static MagickBooleanType TraceEllipse(MVGInfo *mvg_info,const PointInfo center, const PointInfo radii,const PointInfo arc) { double coordinates, delta, step, x, y; PointInfo angle, point; PrimitiveInfo *primitive_info; register PrimitiveInfo *p; register ssize_t i; /* Ellipses are just short segmented polys. */ primitive_info=(*mvg_info->primitive_info)+mvg_info->offset; primitive_info->coordinates=0; if ((fabs(radii.x) < MagickEpsilon) || (fabs(radii.y) < MagickEpsilon)) return(MagickTrue); delta=2.0*PerceptibleReciprocal(MagickMax(radii.x,radii.y)); step=MagickPI/8.0; if ((delta >= 0.0) && (delta < (MagickPI/8.0))) step=MagickPI/4.0/(MagickPI*PerceptibleReciprocal(delta)/2.0); angle.x=DegreesToRadians(arc.x); y=arc.y; while (y < arc.x) y+=360.0; angle.y=DegreesToRadians(y); coordinates=ceil((angle.y-angle.x)/step+1.0); if (coordinates > (double) SSIZE_MAX) { (void) ThrowMagickException(mvg_info->exception,GetMagickModule(), ResourceLimitError,"MemoryAllocationFailed","`%s'",""); return(MagickFalse); } if (CheckPrimitiveExtent(mvg_info,(size_t) coordinates) == MagickFalse) return(MagickFalse); primitive_info=(*mvg_info->primitive_info)+mvg_info->offset; for (p=primitive_info; angle.x < angle.y; angle.x+=step) { point.x=cos(fmod(angle.x,DegreesToRadians(360.0)))*radii.x+center.x; point.y=sin(fmod(angle.x,DegreesToRadians(360.0)))*radii.y+center.y; if (TracePoint(p,point) == MagickFalse) return(MagickFalse); p+=p->coordinates; } point.x=cos(fmod(angle.y,DegreesToRadians(360.0)))*radii.x+center.x; point.y=sin(fmod(angle.y,DegreesToRadians(360.0)))*radii.y+center.y; if (TracePoint(p,point) == MagickFalse) return(MagickFalse); p+=p->coordinates; primitive_info->coordinates=(size_t) (p-primitive_info); primitive_info->closed_subpath=MagickFalse; x=fabs(primitive_info[0].point.x- primitive_info[primitive_info->coordinates-1].point.x); y=fabs(primitive_info[0].point.y- primitive_info[primitive_info->coordinates-1].point.y); if ((x < MagickEpsilon) && (y < MagickEpsilon)) primitive_info->closed_subpath=MagickTrue; for (i=0; i < (ssize_t) primitive_info->coordinates; i++) { p->primitive=primitive_info->primitive; p--; } return(MagickTrue); } static MagickBooleanType TraceLine(PrimitiveInfo *primitive_info, const PointInfo start,const PointInfo end) { if (TracePoint(primitive_info,start) == MagickFalse) return(MagickFalse); if ((fabs(start.x-end.x) < MagickEpsilon) && (fabs(start.y-end.y) < MagickEpsilon)) { primitive_info->primitive=PointPrimitive; primitive_info->coordinates=1; return(MagickTrue); } if (TracePoint(primitive_info+1,end) == MagickFalse) return(MagickFalse); (primitive_info+1)->primitive=primitive_info->primitive; primitive_info->coordinates=2; primitive_info->closed_subpath=MagickFalse; return(MagickTrue); } static size_t TracePath(MVGInfo *mvg_info,const char *path, ExceptionInfo *exception) { char *next_token, token[MagickPathExtent]; const char *p; double x, y; int attribute, last_attribute; MagickBooleanType status; PointInfo end = {0.0, 0.0}, points[4] = { {0.0, 0.0}, {0.0, 0.0}, {0.0, 0.0}, {0.0, 0.0} }, point = {0.0, 0.0}, start = {0.0, 0.0}; PrimitiveInfo *primitive_info; PrimitiveType primitive_type; register PrimitiveInfo *q; register ssize_t i; size_t number_coordinates, z_count; ssize_t subpath_offset; subpath_offset=mvg_info->offset; primitive_info=(*mvg_info->primitive_info)+mvg_info->offset; status=MagickTrue; attribute=0; number_coordinates=0; z_count=0; primitive_type=primitive_info->primitive; q=primitive_info; for (p=path; *p != '\0'; ) { if (status == MagickFalse) break; while (isspace((int) ((unsigned char) *p)) != 0) p++; if (*p == '\0') break; last_attribute=attribute; attribute=(int) (*p++); switch (attribute) { case 'a': case 'A': { double angle = 0.0; MagickBooleanType large_arc = MagickFalse, sweep = MagickFalse; PointInfo arc = {0.0, 0.0}; /* Elliptical arc. */ do { (void) GetNextToken(p,&p,MagickPathExtent,token); if (*token == ',') (void) GetNextToken(p,&p,MagickPathExtent,token); arc.x=StringToDouble(token,&next_token); if (token == next_token) ThrowPointExpectedException(token,exception); (void) GetNextToken(p,&p,MagickPathExtent,token); if (*token == ',') (void) GetNextToken(p,&p,MagickPathExtent,token); arc.y=StringToDouble(token,&next_token); if (token == next_token) ThrowPointExpectedException(token,exception); (void) GetNextToken(p,&p,MagickPathExtent,token); if (*token == ',') (void) GetNextToken(p,&p,MagickPathExtent,token); angle=StringToDouble(token,&next_token); if (token == next_token) ThrowPointExpectedException(token,exception); (void) GetNextToken(p,&p,MagickPathExtent,token); if (*token == ',') (void) GetNextToken(p,&p,MagickPathExtent,token); large_arc=StringToLong(token) != 0 ? MagickTrue : MagickFalse; (void) GetNextToken(p,&p,MagickPathExtent,token); if (*token == ',') (void) GetNextToken(p,&p,MagickPathExtent,token); sweep=StringToLong(token) != 0 ? MagickTrue : MagickFalse; if (*token == ',') (void) GetNextToken(p,&p,MagickPathExtent,token); (void) GetNextToken(p,&p,MagickPathExtent,token); if (*token == ',') (void) GetNextToken(p,&p,MagickPathExtent,token); x=StringToDouble(token,&next_token); if (token == next_token) ThrowPointExpectedException(token,exception); (void) GetNextToken(p,&p,MagickPathExtent,token); if (*token == ',') (void) GetNextToken(p,&p,MagickPathExtent,token); y=StringToDouble(token,&next_token); if (token == next_token) ThrowPointExpectedException(token,exception); end.x=(double) (attribute == (int) 'A' ? x : point.x+x); end.y=(double) (attribute == (int) 'A' ? y : point.y+y); if (TraceArcPath(mvg_info,point,end,arc,angle,large_arc,sweep) == MagickFalse) return(0); q=(*mvg_info->primitive_info)+mvg_info->offset; mvg_info->offset+=q->coordinates; q+=q->coordinates; point=end; while (isspace((int) ((unsigned char) *p)) != 0) p++; if (*p == ',') p++; } while (IsPoint(p) != MagickFalse); break; } case 'c': case 'C': { /* Cubic Bézier curve. */ do { points[0]=point; for (i=1; i < 4; i++) { (void) GetNextToken(p,&p,MagickPathExtent,token); if (*token == ',') (void) GetNextToken(p,&p,MagickPathExtent,token); x=StringToDouble(token,&next_token); if (token == next_token) ThrowPointExpectedException(token,exception); (void) GetNextToken(p,&p,MagickPathExtent,token); if (*token == ',') (void) GetNextToken(p,&p,MagickPathExtent,token); y=StringToDouble(token,&next_token); if (token == next_token) ThrowPointExpectedException(token,exception); end.x=(double) (attribute == (int) 'C' ? x : point.x+x); end.y=(double) (attribute == (int) 'C' ? y : point.y+y); points[i]=end; } for (i=0; i < 4; i++) (q+i)->point=points[i]; if (TraceBezier(mvg_info,4) == MagickFalse) return(0); q=(*mvg_info->primitive_info)+mvg_info->offset; mvg_info->offset+=q->coordinates; q+=q->coordinates; point=end; while (isspace((int) ((unsigned char) *p)) != 0) p++; if (*p == ',') p++; } while (IsPoint(p) != MagickFalse); break; } case 'H': case 'h': { do { (void) GetNextToken(p,&p,MagickPathExtent,token); if (*token == ',') (void) GetNextToken(p,&p,MagickPathExtent,token); x=StringToDouble(token,&next_token); if (token == next_token) ThrowPointExpectedException(token,exception); point.x=(double) (attribute == (int) 'H' ? x: point.x+x); if (CheckPrimitiveExtent(mvg_info,PrimitiveExtentPad) == MagickFalse) return(0); q=(*mvg_info->primitive_info)+mvg_info->offset; if (TracePoint(q,point) == MagickFalse) return(0); mvg_info->offset+=q->coordinates; q+=q->coordinates; while (isspace((int) ((unsigned char) *p)) != 0) p++; if (*p == ',') p++; } while (IsPoint(p) != MagickFalse); break; } case 'l': case 'L': { /* Line to. */ do { (void) GetNextToken(p,&p,MagickPathExtent,token); if (*token == ',') (void) GetNextToken(p,&p,MagickPathExtent,token); x=StringToDouble(token,&next_token); if (token == next_token) ThrowPointExpectedException(token,exception); (void) GetNextToken(p,&p,MagickPathExtent,token); if (*token == ',') (void) GetNextToken(p,&p,MagickPathExtent,token); y=StringToDouble(token,&next_token); if (token == next_token) ThrowPointExpectedException(token,exception); point.x=(double) (attribute == (int) 'L' ? x : point.x+x); point.y=(double) (attribute == (int) 'L' ? y : point.y+y); if (CheckPrimitiveExtent(mvg_info,PrimitiveExtentPad) == MagickFalse) return(0); q=(*mvg_info->primitive_info)+mvg_info->offset; if (TracePoint(q,point) == MagickFalse) return(0); mvg_info->offset+=q->coordinates; q+=q->coordinates; while (isspace((int) ((unsigned char) *p)) != 0) p++; if (*p == ',') p++; } while (IsPoint(p) != MagickFalse); break; } case 'M': case 'm': { /* Move to. */ if (mvg_info->offset != subpath_offset) { primitive_info=(*mvg_info->primitive_info)+subpath_offset; primitive_info->coordinates=(size_t) (q-primitive_info); number_coordinates+=primitive_info->coordinates; primitive_info=q; subpath_offset=mvg_info->offset; } i=0; do { (void) GetNextToken(p,&p,MagickPathExtent,token); if (*token == ',') (void) GetNextToken(p,&p,MagickPathExtent,token); x=StringToDouble(token,&next_token); if (token == next_token) ThrowPointExpectedException(token,exception); (void) GetNextToken(p,&p,MagickPathExtent,token); if (*token == ',') (void) GetNextToken(p,&p,MagickPathExtent,token); y=StringToDouble(token,&next_token); if (token == next_token) ThrowPointExpectedException(token,exception); point.x=(double) (attribute == (int) 'M' ? x : point.x+x); point.y=(double) (attribute == (int) 'M' ? y : point.y+y); if (i == 0) start=point; i++; if (CheckPrimitiveExtent(mvg_info,PrimitiveExtentPad) == MagickFalse) return(0); q=(*mvg_info->primitive_info)+mvg_info->offset; if (TracePoint(q,point) == MagickFalse) return(0); mvg_info->offset+=q->coordinates; q+=q->coordinates; while (isspace((int) ((unsigned char) *p)) != 0) p++; if (*p == ',') p++; } while (IsPoint(p) != MagickFalse); break; } case 'q': case 'Q': { /* Quadratic Bézier curve. */ do { points[0]=point; for (i=1; i < 3; i++) { (void) GetNextToken(p,&p,MagickPathExtent,token); if (*token == ',') (void) GetNextToken(p,&p,MagickPathExtent,token); x=StringToDouble(token,&next_token); if (token == next_token) ThrowPointExpectedException(token,exception); (void) GetNextToken(p,&p,MagickPathExtent,token); if (*token == ',') (void) GetNextToken(p,&p,MagickPathExtent,token); y=StringToDouble(token,&next_token); if (token == next_token) ThrowPointExpectedException(token,exception); if (*p == ',') p++; end.x=(double) (attribute == (int) 'Q' ? x : point.x+x); end.y=(double) (attribute == (int) 'Q' ? y : point.y+y); points[i]=end; } for (i=0; i < 3; i++) (q+i)->point=points[i]; if (TraceBezier(mvg_info,3) == MagickFalse) return(0); q=(*mvg_info->primitive_info)+mvg_info->offset; mvg_info->offset+=q->coordinates; q+=q->coordinates; point=end; while (isspace((int) ((unsigned char) *p)) != 0) p++; if (*p == ',') p++; } while (IsPoint(p) != MagickFalse); break; } case 's': case 'S': { /* Cubic Bézier curve. */ do { points[0]=points[3]; points[1].x=2.0*points[3].x-points[2].x; points[1].y=2.0*points[3].y-points[2].y; for (i=2; i < 4; i++) { (void) GetNextToken(p,&p,MagickPathExtent,token); if (*token == ',') (void) GetNextToken(p,&p,MagickPathExtent,token); x=StringToDouble(token,&next_token); if (token == next_token) ThrowPointExpectedException(token,exception); (void) GetNextToken(p,&p,MagickPathExtent,token); if (*token == ',') (void) GetNextToken(p,&p,MagickPathExtent,token); y=StringToDouble(token,&next_token); if (token == next_token) ThrowPointExpectedException(token,exception); if (*p == ',') p++; end.x=(double) (attribute == (int) 'S' ? x : point.x+x); end.y=(double) (attribute == (int) 'S' ? y : point.y+y); points[i]=end; } if (strchr("CcSs",last_attribute) == (char *) NULL) { points[0]=point; points[1]=point; } for (i=0; i < 4; i++) (q+i)->point=points[i]; if (TraceBezier(mvg_info,4) == MagickFalse) return(0); q=(*mvg_info->primitive_info)+mvg_info->offset; mvg_info->offset+=q->coordinates; q+=q->coordinates; point=end; last_attribute=attribute; while (isspace((int) ((unsigned char) *p)) != 0) p++; if (*p == ',') p++; } while (IsPoint(p) != MagickFalse); break; } case 't': case 'T': { /* Quadratic Bézier curve. */ do { points[0]=points[2]; points[1].x=2.0*points[2].x-points[1].x; points[1].y=2.0*points[2].y-points[1].y; for (i=2; i < 3; i++) { (void) GetNextToken(p,&p,MagickPathExtent,token); if (*token == ',') (void) GetNextToken(p,&p,MagickPathExtent,token); x=StringToDouble(token,&next_token); if (token == next_token) ThrowPointExpectedException(token,exception); (void) GetNextToken(p,&p,MagickPathExtent,token); if (*token == ',') (void) GetNextToken(p,&p,MagickPathExtent,token); y=StringToDouble(token,&next_token); if (token == next_token) ThrowPointExpectedException(token,exception); end.x=(double) (attribute == (int) 'T' ? x : point.x+x); end.y=(double) (attribute == (int) 'T' ? y : point.y+y); points[i]=end; } if (status == MagickFalse) break; if (strchr("QqTt",last_attribute) == (char *) NULL) { points[0]=point; points[1]=point; } for (i=0; i < 3; i++) (q+i)->point=points[i]; if (TraceBezier(mvg_info,3) == MagickFalse) return(0); q=(*mvg_info->primitive_info)+mvg_info->offset; mvg_info->offset+=q->coordinates; q+=q->coordinates; point=end; last_attribute=attribute; while (isspace((int) ((unsigned char) *p)) != 0) p++; if (*p == ',') p++; } while (IsPoint(p) != MagickFalse); break; } case 'v': case 'V': { /* Line to. */ do { (void) GetNextToken(p,&p,MagickPathExtent,token); if (*token == ',') (void) GetNextToken(p,&p,MagickPathExtent,token); y=StringToDouble(token,&next_token); if (token == next_token) ThrowPointExpectedException(token,exception); point.y=(double) (attribute == (int) 'V' ? y : point.y+y); if (CheckPrimitiveExtent(mvg_info,PrimitiveExtentPad) == MagickFalse) return(0); q=(*mvg_info->primitive_info)+mvg_info->offset; if (TracePoint(q,point) == MagickFalse) return(0); mvg_info->offset+=q->coordinates; q+=q->coordinates; while (isspace((int) ((unsigned char) *p)) != 0) p++; if (*p == ',') p++; } while (IsPoint(p) != MagickFalse); break; } case 'z': case 'Z': { /* Close path. */ point=start; if (CheckPrimitiveExtent(mvg_info,PrimitiveExtentPad) == MagickFalse) return(0); q=(*mvg_info->primitive_info)+mvg_info->offset; if (TracePoint(q,point) == MagickFalse) return(0); mvg_info->offset+=q->coordinates; q+=q->coordinates; primitive_info=(*mvg_info->primitive_info)+subpath_offset; primitive_info->coordinates=(size_t) (q-primitive_info); primitive_info->closed_subpath=MagickTrue; number_coordinates+=primitive_info->coordinates; primitive_info=q; subpath_offset=mvg_info->offset; z_count++; break; } default: { ThrowPointExpectedException(token,exception); break; } } } if (status == MagickFalse) return(0); primitive_info=(*mvg_info->primitive_info)+subpath_offset; primitive_info->coordinates=(size_t) (q-primitive_info); number_coordinates+=primitive_info->coordinates; for (i=0; i < (ssize_t) number_coordinates; i++) { q--; q->primitive=primitive_type; if (z_count > 1) q->method=FillToBorderMethod; } q=primitive_info; return(number_coordinates); } static MagickBooleanType TraceRectangle(PrimitiveInfo *primitive_info, const PointInfo start,const PointInfo end) { PointInfo point; register PrimitiveInfo *p; register ssize_t i; p=primitive_info; if (TracePoint(p,start) == MagickFalse) return(MagickFalse); p+=p->coordinates; point.x=start.x; point.y=end.y; if (TracePoint(p,point) == MagickFalse) return(MagickFalse); p+=p->coordinates; if (TracePoint(p,end) == MagickFalse) return(MagickFalse); p+=p->coordinates; point.x=end.x; point.y=start.y; if (TracePoint(p,point) == MagickFalse) return(MagickFalse); p+=p->coordinates; if (TracePoint(p,start) == MagickFalse) return(MagickFalse); p+=p->coordinates; primitive_info->coordinates=(size_t) (p-primitive_info); primitive_info->closed_subpath=MagickTrue; for (i=0; i < (ssize_t) primitive_info->coordinates; i++) { p->primitive=primitive_info->primitive; p--; } return(MagickTrue); } static MagickBooleanType TraceRoundRectangle(MVGInfo *mvg_info, const PointInfo start,const PointInfo end,PointInfo arc) { PointInfo degrees, point, segment; PrimitiveInfo *primitive_info; register PrimitiveInfo *p; register ssize_t i; ssize_t offset; offset=mvg_info->offset; segment.x=fabs(end.x-start.x); segment.y=fabs(end.y-start.y); if ((segment.x < MagickEpsilon) || (segment.y < MagickEpsilon)) { (*mvg_info->primitive_info+mvg_info->offset)->coordinates=0; return(MagickTrue); } if (arc.x > (0.5*segment.x)) arc.x=0.5*segment.x; if (arc.y > (0.5*segment.y)) arc.y=0.5*segment.y; point.x=start.x+segment.x-arc.x; point.y=start.y+arc.y; degrees.x=270.0; degrees.y=360.0; if (TraceEllipse(mvg_info,point,arc,degrees) == MagickFalse) return(MagickFalse); p=(*mvg_info->primitive_info)+mvg_info->offset; mvg_info->offset+=p->coordinates; point.x=start.x+segment.x-arc.x; point.y=start.y+segment.y-arc.y; degrees.x=0.0; degrees.y=90.0; if (TraceEllipse(mvg_info,point,arc,degrees) == MagickFalse) return(MagickFalse); p=(*mvg_info->primitive_info)+mvg_info->offset; mvg_info->offset+=p->coordinates; point.x=start.x+arc.x; point.y=start.y+segment.y-arc.y; degrees.x=90.0; degrees.y=180.0; if (TraceEllipse(mvg_info,point,arc,degrees) == MagickFalse) return(MagickFalse); p=(*mvg_info->primitive_info)+mvg_info->offset; mvg_info->offset+=p->coordinates; point.x=start.x+arc.x; point.y=start.y+arc.y; degrees.x=180.0; degrees.y=270.0; if (TraceEllipse(mvg_info,point,arc,degrees) == MagickFalse) return(MagickFalse); p=(*mvg_info->primitive_info)+mvg_info->offset; mvg_info->offset+=p->coordinates; if (CheckPrimitiveExtent(mvg_info,PrimitiveExtentPad) == MagickFalse) return(MagickFalse); p=(*mvg_info->primitive_info)+mvg_info->offset; if (TracePoint(p,(*mvg_info->primitive_info+offset)->point) == MagickFalse) return(MagickFalse); p+=p->coordinates; mvg_info->offset=offset; primitive_info=(*mvg_info->primitive_info)+offset; primitive_info->coordinates=(size_t) (p-primitive_info); primitive_info->closed_subpath=MagickTrue; for (i=0; i < (ssize_t) primitive_info->coordinates; i++) { p->primitive=primitive_info->primitive; p--; } return(MagickTrue); } static MagickBooleanType TraceSquareLinecap(PrimitiveInfo *primitive_info, const size_t number_vertices,const double offset) { double distance; register double dx, dy; register ssize_t i; ssize_t j; dx=0.0; dy=0.0; for (i=1; i < (ssize_t) number_vertices; i++) { dx=primitive_info[0].point.x-primitive_info[i].point.x; dy=primitive_info[0].point.y-primitive_info[i].point.y; if ((fabs((double) dx) >= MagickEpsilon) || (fabs((double) dy) >= MagickEpsilon)) break; } if (i == (ssize_t) number_vertices) i=(ssize_t) number_vertices-1L; distance=hypot((double) dx,(double) dy); primitive_info[0].point.x=(double) (primitive_info[i].point.x+ dx*(distance+offset)/distance); primitive_info[0].point.y=(double) (primitive_info[i].point.y+ dy*(distance+offset)/distance); for (j=(ssize_t) number_vertices-2; j >= 0; j--) { dx=primitive_info[number_vertices-1].point.x-primitive_info[j].point.x; dy=primitive_info[number_vertices-1].point.y-primitive_info[j].point.y; if ((fabs((double) dx) >= MagickEpsilon) || (fabs((double) dy) >= MagickEpsilon)) break; } distance=hypot((double) dx,(double) dy); primitive_info[number_vertices-1].point.x=(double) (primitive_info[j].point.x+ dx*(distance+offset)/distance); primitive_info[number_vertices-1].point.y=(double) (primitive_info[j].point.y+ dy*(distance+offset)/distance); return(MagickTrue); } static PrimitiveInfo *TraceStrokePolygon(const Image *image, const DrawInfo *draw_info,const PrimitiveInfo *primitive_info) { #define CheckPathExtent(pad) \ if ((ssize_t) (q+(pad)) >= (ssize_t) max_strokes) \ { \ if (~max_strokes < (pad)) \ { \ path_p=(PointInfo *) RelinquishMagickMemory(path_p); \ path_q=(PointInfo *) RelinquishMagickMemory(path_q); \ } \ else \ { \ max_strokes+=(pad); \ path_p=(PointInfo *) ResizeQuantumMemory(path_p,max_strokes, \ sizeof(*path_p)); \ path_q=(PointInfo *) ResizeQuantumMemory(path_q,max_strokes, \ sizeof(*path_q)); \ } \ if ((path_p == (PointInfo *) NULL) || (path_q == (PointInfo *) NULL)) \ { \ if (path_p != (PointInfo *) NULL) \ path_p=(PointInfo *) RelinquishMagickMemory(path_p); \ if (path_q != (PointInfo *) NULL) \ path_q=(PointInfo *) RelinquishMagickMemory(path_q); \ polygon_primitive=(PrimitiveInfo *) \ RelinquishMagickMemory(polygon_primitive); \ return((PrimitiveInfo *) NULL); \ } \ } typedef struct _LineSegment { double p, q; } LineSegment; double delta_theta, dot_product, mid, miterlimit; LineSegment dx = {0,0}, dy = {0,0}, inverse_slope = {0,0}, slope = {0,0}, theta = {0,0}; MagickBooleanType closed_path; PointInfo box_p[5], box_q[5], center, offset, *path_p, *path_q; PrimitiveInfo *polygon_primitive, *stroke_polygon; register ssize_t i; size_t arc_segments, max_strokes, number_vertices; ssize_t j, n, p, q; /* Allocate paths. */ number_vertices=primitive_info->coordinates; max_strokes=2*number_vertices+6*BezierQuantum+360; polygon_primitive=(PrimitiveInfo *) AcquireQuantumMemory((size_t) number_vertices+2UL,sizeof(*polygon_primitive)); if (polygon_primitive == (PrimitiveInfo *) NULL) return((PrimitiveInfo *) NULL); (void) memcpy(polygon_primitive,primitive_info,(size_t) number_vertices* sizeof(*polygon_primitive)); closed_path=primitive_info[0].closed_subpath; if (((draw_info->linejoin == RoundJoin) || (draw_info->linejoin == MiterJoin)) && (closed_path != MagickFalse)) { polygon_primitive[number_vertices]=primitive_info[1]; number_vertices++; } polygon_primitive[number_vertices].primitive=UndefinedPrimitive; /* Compute the slope for the first line segment, p. */ dx.p=0.0; dy.p=0.0; for (n=1; n < (ssize_t) number_vertices; n++) { dx.p=polygon_primitive[n].point.x-polygon_primitive[0].point.x; dy.p=polygon_primitive[n].point.y-polygon_primitive[0].point.y; if ((fabs(dx.p) >= MagickEpsilon) || (fabs(dy.p) >= MagickEpsilon)) break; } if (n == (ssize_t) number_vertices) { if ((draw_info->linecap != RoundCap) || (closed_path != MagickFalse)) { /* Zero length subpath. */ stroke_polygon=(PrimitiveInfo *) AcquireCriticalMemory( sizeof(*stroke_polygon)); stroke_polygon[0]=polygon_primitive[0]; stroke_polygon[0].coordinates=0; polygon_primitive=(PrimitiveInfo *) RelinquishMagickMemory( polygon_primitive); return(stroke_polygon); } n=(ssize_t) number_vertices-1L; } path_p=(PointInfo *) AcquireQuantumMemory((size_t) max_strokes, sizeof(*path_p)); if (path_p == (PointInfo *) NULL) { polygon_primitive=(PrimitiveInfo *) RelinquishMagickMemory( polygon_primitive); return((PrimitiveInfo *) NULL); } path_q=(PointInfo *) AcquireQuantumMemory((size_t) max_strokes, sizeof(*path_q)); if (path_q == (PointInfo *) NULL) { path_p=(PointInfo *) RelinquishMagickMemory(path_p); polygon_primitive=(PrimitiveInfo *) RelinquishMagickMemory( polygon_primitive); return((PrimitiveInfo *) NULL); } slope.p=0.0; inverse_slope.p=0.0; if (fabs(dx.p) < MagickEpsilon) { if (dx.p >= 0.0) slope.p=dy.p < 0.0 ? -1.0/MagickEpsilon : 1.0/MagickEpsilon; else slope.p=dy.p < 0.0 ? 1.0/MagickEpsilon : -1.0/MagickEpsilon; } else if (fabs(dy.p) < MagickEpsilon) { if (dy.p >= 0.0) inverse_slope.p=dx.p < 0.0 ? -1.0/MagickEpsilon : 1.0/MagickEpsilon; else inverse_slope.p=dx.p < 0.0 ? 1.0/MagickEpsilon : -1.0/MagickEpsilon; } else { slope.p=dy.p/dx.p; inverse_slope.p=(-1.0/slope.p); } mid=ExpandAffine(&draw_info->affine)*SaneStrokeWidth(image,draw_info)/2.0; miterlimit=(double) (draw_info->miterlimit*draw_info->miterlimit*mid*mid); if ((draw_info->linecap == SquareCap) && (closed_path == MagickFalse)) (void) TraceSquareLinecap(polygon_primitive,number_vertices,mid); offset.x=sqrt((double) (mid*mid/(inverse_slope.p*inverse_slope.p+1.0))); offset.y=(double) (offset.x*inverse_slope.p); if ((dy.p*offset.x-dx.p*offset.y) > 0.0) { box_p[0].x=polygon_primitive[0].point.x-offset.x; box_p[0].y=polygon_primitive[0].point.y-offset.x*inverse_slope.p; box_p[1].x=polygon_primitive[n].point.x-offset.x; box_p[1].y=polygon_primitive[n].point.y-offset.x*inverse_slope.p; box_q[0].x=polygon_primitive[0].point.x+offset.x; box_q[0].y=polygon_primitive[0].point.y+offset.x*inverse_slope.p; box_q[1].x=polygon_primitive[n].point.x+offset.x; box_q[1].y=polygon_primitive[n].point.y+offset.x*inverse_slope.p; } else { box_p[0].x=polygon_primitive[0].point.x+offset.x; box_p[0].y=polygon_primitive[0].point.y+offset.y; box_p[1].x=polygon_primitive[n].point.x+offset.x; box_p[1].y=polygon_primitive[n].point.y+offset.y; box_q[0].x=polygon_primitive[0].point.x-offset.x; box_q[0].y=polygon_primitive[0].point.y-offset.y; box_q[1].x=polygon_primitive[n].point.x-offset.x; box_q[1].y=polygon_primitive[n].point.y-offset.y; } /* Create strokes for the line join attribute: bevel, miter, round. */ p=0; q=0; path_q[p++]=box_q[0]; path_p[q++]=box_p[0]; for (i=(ssize_t) n+1; i < (ssize_t) number_vertices; i++) { /* Compute the slope for this line segment, q. */ dx.q=polygon_primitive[i].point.x-polygon_primitive[n].point.x; dy.q=polygon_primitive[i].point.y-polygon_primitive[n].point.y; dot_product=dx.q*dx.q+dy.q*dy.q; if (dot_product < 0.25) continue; slope.q=0.0; inverse_slope.q=0.0; if (fabs(dx.q) < MagickEpsilon) { if (dx.q >= 0.0) slope.q=dy.q < 0.0 ? -1.0/MagickEpsilon : 1.0/MagickEpsilon; else slope.q=dy.q < 0.0 ? 1.0/MagickEpsilon : -1.0/MagickEpsilon; } else if (fabs(dy.q) < MagickEpsilon) { if (dy.q >= 0.0) inverse_slope.q=dx.q < 0.0 ? -1.0/MagickEpsilon : 1.0/MagickEpsilon; else inverse_slope.q=dx.q < 0.0 ? 1.0/MagickEpsilon : -1.0/MagickEpsilon; } else { slope.q=dy.q/dx.q; inverse_slope.q=(-1.0/slope.q); } offset.x=sqrt((double) (mid*mid/(inverse_slope.q*inverse_slope.q+1.0))); offset.y=(double) (offset.x*inverse_slope.q); dot_product=dy.q*offset.x-dx.q*offset.y; if (dot_product > 0.0) { box_p[2].x=polygon_primitive[n].point.x-offset.x; box_p[2].y=polygon_primitive[n].point.y-offset.y; box_p[3].x=polygon_primitive[i].point.x-offset.x; box_p[3].y=polygon_primitive[i].point.y-offset.y; box_q[2].x=polygon_primitive[n].point.x+offset.x; box_q[2].y=polygon_primitive[n].point.y+offset.y; box_q[3].x=polygon_primitive[i].point.x+offset.x; box_q[3].y=polygon_primitive[i].point.y+offset.y; } else { box_p[2].x=polygon_primitive[n].point.x+offset.x; box_p[2].y=polygon_primitive[n].point.y+offset.y; box_p[3].x=polygon_primitive[i].point.x+offset.x; box_p[3].y=polygon_primitive[i].point.y+offset.y; box_q[2].x=polygon_primitive[n].point.x-offset.x; box_q[2].y=polygon_primitive[n].point.y-offset.y; box_q[3].x=polygon_primitive[i].point.x-offset.x; box_q[3].y=polygon_primitive[i].point.y-offset.y; } if (fabs((double) (slope.p-slope.q)) < MagickEpsilon) { box_p[4]=box_p[1]; box_q[4]=box_q[1]; } else { box_p[4].x=(double) ((slope.p*box_p[0].x-box_p[0].y-slope.q*box_p[3].x+ box_p[3].y)/(slope.p-slope.q)); box_p[4].y=(double) (slope.p*(box_p[4].x-box_p[0].x)+box_p[0].y); box_q[4].x=(double) ((slope.p*box_q[0].x-box_q[0].y-slope.q*box_q[3].x+ box_q[3].y)/(slope.p-slope.q)); box_q[4].y=(double) (slope.p*(box_q[4].x-box_q[0].x)+box_q[0].y); } CheckPathExtent(6*BezierQuantum+360); dot_product=dx.q*dy.p-dx.p*dy.q; if (dot_product <= 0.0) switch (draw_info->linejoin) { case BevelJoin: { path_q[q++]=box_q[1]; path_q[q++]=box_q[2]; dot_product=(box_q[4].x-box_p[4].x)*(box_q[4].x-box_p[4].x)+ (box_q[4].y-box_p[4].y)*(box_q[4].y-box_p[4].y); if (dot_product <= miterlimit) path_p[p++]=box_p[4]; else { path_p[p++]=box_p[1]; path_p[p++]=box_p[2]; } break; } case MiterJoin: { dot_product=(box_q[4].x-box_p[4].x)*(box_q[4].x-box_p[4].x)+ (box_q[4].y-box_p[4].y)*(box_q[4].y-box_p[4].y); if (dot_product <= miterlimit) { path_q[q++]=box_q[4]; path_p[p++]=box_p[4]; } else { path_q[q++]=box_q[1]; path_q[q++]=box_q[2]; path_p[p++]=box_p[1]; path_p[p++]=box_p[2]; } break; } case RoundJoin: { dot_product=(box_q[4].x-box_p[4].x)*(box_q[4].x-box_p[4].x)+ (box_q[4].y-box_p[4].y)*(box_q[4].y-box_p[4].y); if (dot_product <= miterlimit) path_p[p++]=box_p[4]; else { path_p[p++]=box_p[1]; path_p[p++]=box_p[2]; } center=polygon_primitive[n].point; theta.p=atan2(box_q[1].y-center.y,box_q[1].x-center.x); theta.q=atan2(box_q[2].y-center.y,box_q[2].x-center.x); if (theta.q < theta.p) theta.q+=2.0*MagickPI; arc_segments=(size_t) ceil((double) ((theta.q-theta.p)/ (2.0*sqrt((double) (1.0/mid))))); CheckPathExtent(arc_segments+6*BezierQuantum+360); path_q[q].x=box_q[1].x; path_q[q].y=box_q[1].y; q++; for (j=1; j < (ssize_t) arc_segments; j++) { delta_theta=(double) (j*(theta.q-theta.p)/arc_segments); path_q[q].x=(double) (center.x+mid*cos(fmod((double) (theta.p+delta_theta),DegreesToRadians(360.0)))); path_q[q].y=(double) (center.y+mid*sin(fmod((double) (theta.p+delta_theta),DegreesToRadians(360.0)))); q++; } path_q[q++]=box_q[2]; break; } default: break; } else switch (draw_info->linejoin) { case BevelJoin: { path_p[p++]=box_p[1]; path_p[p++]=box_p[2]; dot_product=(box_q[4].x-box_p[4].x)*(box_q[4].x-box_p[4].x)+ (box_q[4].y-box_p[4].y)*(box_q[4].y-box_p[4].y); if (dot_product <= miterlimit) path_q[q++]=box_q[4]; else { path_q[q++]=box_q[1]; path_q[q++]=box_q[2]; } break; } case MiterJoin: { dot_product=(box_q[4].x-box_p[4].x)*(box_q[4].x-box_p[4].x)+ (box_q[4].y-box_p[4].y)*(box_q[4].y-box_p[4].y); if (dot_product <= miterlimit) { path_q[q++]=box_q[4]; path_p[p++]=box_p[4]; } else { path_q[q++]=box_q[1]; path_q[q++]=box_q[2]; path_p[p++]=box_p[1]; path_p[p++]=box_p[2]; } break; } case RoundJoin: { dot_product=(box_q[4].x-box_p[4].x)*(box_q[4].x-box_p[4].x)+ (box_q[4].y-box_p[4].y)*(box_q[4].y-box_p[4].y); if (dot_product <= miterlimit) path_q[q++]=box_q[4]; else { path_q[q++]=box_q[1]; path_q[q++]=box_q[2]; } center=polygon_primitive[n].point; theta.p=atan2(box_p[1].y-center.y,box_p[1].x-center.x); theta.q=atan2(box_p[2].y-center.y,box_p[2].x-center.x); if (theta.p < theta.q) theta.p+=2.0*MagickPI; arc_segments=(size_t) ceil((double) ((theta.p-theta.q)/ (2.0*sqrt((double) (1.0/mid))))); CheckPathExtent(arc_segments+6*BezierQuantum+360); path_p[p++]=box_p[1]; for (j=1; j < (ssize_t) arc_segments; j++) { delta_theta=(double) (j*(theta.q-theta.p)/arc_segments); path_p[p].x=(double) (center.x+mid*cos(fmod((double) (theta.p+delta_theta),DegreesToRadians(360.0)))); path_p[p].y=(double) (center.y+mid*sin(fmod((double) (theta.p+delta_theta),DegreesToRadians(360.0)))); p++; } path_p[p++]=box_p[2]; break; } default: break; } slope.p=slope.q; inverse_slope.p=inverse_slope.q; box_p[0]=box_p[2]; box_p[1]=box_p[3]; box_q[0]=box_q[2]; box_q[1]=box_q[3]; dx.p=dx.q; dy.p=dy.q; n=i; } path_p[p++]=box_p[1]; path_q[q++]=box_q[1]; /* Trace stroked polygon. */ stroke_polygon=(PrimitiveInfo *) AcquireQuantumMemory((size_t) (p+q+2UL*closed_path+2UL),sizeof(*stroke_polygon)); if (stroke_polygon != (PrimitiveInfo *) NULL) { for (i=0; i < (ssize_t) p; i++) { stroke_polygon[i]=polygon_primitive[0]; stroke_polygon[i].point=path_p[i]; } if (closed_path != MagickFalse) { stroke_polygon[i]=polygon_primitive[0]; stroke_polygon[i].point=stroke_polygon[0].point; i++; } for ( ; i < (ssize_t) (p+q+closed_path); i++) { stroke_polygon[i]=polygon_primitive[0]; stroke_polygon[i].point=path_q[p+q+closed_path-(i+1)]; } if (closed_path != MagickFalse) { stroke_polygon[i]=polygon_primitive[0]; stroke_polygon[i].point=stroke_polygon[p+closed_path].point; i++; } stroke_polygon[i]=polygon_primitive[0]; stroke_polygon[i].point=stroke_polygon[0].point; i++; stroke_polygon[i].primitive=UndefinedPrimitive; stroke_polygon[0].coordinates=(size_t) (p+q+2*closed_path+1); } path_p=(PointInfo *) RelinquishMagickMemory(path_p); path_q=(PointInfo *) RelinquishMagickMemory(path_q); polygon_primitive=(PrimitiveInfo *) RelinquishMagickMemory(polygon_primitive); return(stroke_polygon); }

program_evaluator.h

// Ceres Solver - A fast non-linear least squares minimizer // Copyright 2015 Google Inc. All rights reserved. // http://ceres-solver.org/ // // Redistribution and use in source and binary forms, with or without // modification, are permitted provided that the following conditions are met: // // * Redistributions of source code must retain the above copyright notice, // this list of conditions and the following disclaimer. // * Redistributions in binary form must reproduce the above copyright notice, // this list of conditions and the following disclaimer in the documentation // and/or other materials provided with the distribution. // * Neither the name of Google Inc. nor the names of its contributors may be // used to endorse or promote products derived from this software without // specific prior written permission. // // THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" // AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE // IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE // ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR CONTRIBUTORS BE // LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR // CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF // SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR BUSINESS // INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY, WHETHER IN // CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE OR OTHERWISE) // ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN IF ADVISED OF THE // POSSIBILITY OF SUCH DAMAGE. // // Author: keir@google.com (Keir Mierle) // // The ProgramEvaluator runs the cost functions contained in each residual block // and stores the result into a jacobian. The particular type of jacobian is // abstracted out using two template parameters: // // - An "EvaluatePreparer" that is responsible for creating the array with // pointers to the jacobian blocks where the cost function evaluates to. // - A "JacobianWriter" that is responsible for storing the resulting // jacobian blocks in the passed sparse matrix. // // This abstraction affords an efficient evaluator implementation while still // supporting writing to multiple sparse matrix formats. For example, when the // ProgramEvaluator is parameterized for writing to block sparse matrices, the // residual jacobians are written directly into their final position in the // block sparse matrix by the user's CostFunction; there is no copying. // // The evaluation is threaded with OpenMP or TBB. // // The EvaluatePreparer and JacobianWriter interfaces are as follows: // // class EvaluatePreparer { // // Prepare the jacobians array for use as the destination of a call to // // a cost function's evaluate method. // void Prepare(const ResidualBlock* residual_block, // int residual_block_index, // SparseMatrix* jacobian, // double** jacobians); // } // // class JacobianWriter { // // Create a jacobian that this writer can write. Same as // // Evaluator::CreateJacobian. // SparseMatrix* CreateJacobian() const; // // // Create num_threads evaluate preparers. Caller owns result which must // // be freed with delete[]. Resulting preparers are valid while *this is. // EvaluatePreparer* CreateEvaluatePreparers(int num_threads); // // // Write the block jacobians from a residual block evaluation to the // // larger sparse jacobian. // void Write(int residual_id, // int residual_offset, // double** jacobians, // SparseMatrix* jacobian); // } // // Note: The ProgramEvaluator is not thread safe, since internally it maintains // some per-thread scratch space. #ifndef CERES_INTERNAL_PROGRAM_EVALUATOR_H_ #define CERES_INTERNAL_PROGRAM_EVALUATOR_H_ // This include must come before any #ifndef check on Ceres compile options. #include "ceres/internal/port.h" #include <map> #include <string> #include <vector> #include "ceres/execution_summary.h" #include "ceres/internal/eigen.h" #include "ceres/internal/scoped_ptr.h" #include "ceres/parameter_block.h" #include "ceres/program.h" #include "ceres/residual_block.h" #include "ceres/scoped_thread_token.h" #include "ceres/small_blas.h" #include "ceres/thread_token_provider.h" #ifdef CERES_USE_TBB #include <atomic> #include <tbb/parallel_for.h> #include <tbb/task_scheduler_init.h> #endif namespace ceres { namespace internal { struct NullJacobianFinalizer { void operator()(SparseMatrix* jacobian, int num_parameters) {} }; template<typename EvaluatePreparer, typename JacobianWriter, typename JacobianFinalizer = NullJacobianFinalizer> class ProgramEvaluator : public Evaluator { public: ProgramEvaluator(const Evaluator::Options &options, Program* program) : options_(options), program_(program), jacobian_writer_(options, program), evaluate_preparers_( jacobian_writer_.CreateEvaluatePreparers(options.num_threads)) { #ifdef CERES_NO_THREADS if (options_.num_threads > 1) { LOG(WARNING) << "Neither OpenMP nor TBB support is compiled into this binary; " << "only options.num_threads = 1 is supported. Switching " << "to single threaded mode."; options_.num_threads = 1; } #endif // CERES_NO_THREADS BuildResidualLayout(*program, &residual_layout_); evaluate_scratch_.reset(CreateEvaluatorScratch(*program, options.num_threads)); } // Implementation of Evaluator interface. SparseMatrix* CreateJacobian() const { return jacobian_writer_.CreateJacobian(); } bool Evaluate(const Evaluator::EvaluateOptions& evaluate_options, const double* state, double* cost, double* residuals, double* gradient, SparseMatrix* jacobian) { ScopedExecutionTimer total_timer("Evaluator::Total", &execution_summary_); ScopedExecutionTimer call_type_timer(gradient == NULL && jacobian == NULL ? "Evaluator::Residual" : "Evaluator::Jacobian", &execution_summary_); // The parameters are stateful, so set the state before evaluating. if (!program_->StateVectorToParameterBlocks(state)) { return false; } if (residuals != NULL) { VectorRef(residuals, program_->NumResiduals()).setZero(); } if (jacobian != NULL) { jacobian->SetZero(); } // Each thread gets it's own cost and evaluate scratch space. for (int i = 0; i < options_.num_threads; ++i) { evaluate_scratch_[i].cost = 0.0; if (gradient != NULL) { VectorRef(evaluate_scratch_[i].gradient.get(), program_->NumEffectiveParameters()).setZero(); } } const int num_residual_blocks = program_->NumResidualBlocks(); ThreadTokenProvider thread_token_provider(options_.num_threads); #ifdef CERES_USE_OPENMP // This bool is used to disable the loop if an error is encountered // without breaking out of it. The remaining loop iterations are still run, // but with an empty body, and so will finish quickly. bool abort = false; #pragma omp parallel for num_threads(options_.num_threads) for (int i = 0; i < num_residual_blocks; ++i) { // Disable the loop instead of breaking, as required by OpenMP. #pragma omp flush(abort) #endif // CERES_USE_OPENMP #ifdef CERES_NO_THREADS bool abort = false; for (int i = 0; i < num_residual_blocks; ++i) { #endif // CERES_NO_THREADS #ifdef CERES_USE_TBB std::atomic_bool abort(false); tbb::task_scheduler_init tbb_task_scheduler_init(options_.num_threads); tbb::parallel_for(0, num_residual_blocks, [&](int i) { #endif // CERES_USE_TBB if (abort) { #ifndef CERES_USE_TBB continue; #else return; #endif // !CERES_USE_TBB } const ScopedThreadToken scoped_thread_token(&thread_token_provider); const int thread_id = scoped_thread_token.token(); EvaluatePreparer* preparer = &evaluate_preparers_[thread_id]; EvaluateScratch* scratch = &evaluate_scratch_[thread_id]; // Prepare block residuals if requested. const ResidualBlock* residual_block = program_->residual_blocks()[i]; double* block_residuals = NULL; if (residuals != NULL) { block_residuals = residuals + residual_layout_[i]; } else if (gradient != NULL) { block_residuals = scratch->residual_block_residuals.get(); } // Prepare block jacobians if requested. double** block_jacobians = NULL; if (jacobian != NULL || gradient != NULL) { preparer->Prepare(residual_block, i, jacobian, scratch->jacobian_block_ptrs.get()); block_jacobians = scratch->jacobian_block_ptrs.get(); } // Evaluate the cost, residuals, and jacobians. double block_cost; if (!residual_block->Evaluate( evaluate_options.apply_loss_function, &block_cost, block_residuals, block_jacobians, scratch->residual_block_evaluate_scratch.get())) { abort = true; #ifdef CERES_USE_OPENMP // This ensures that the OpenMP threads have a consistent view of 'abort'. Do // the flush inside the failure case so that there is usually only one // synchronization point per loop iteration instead of two. #pragma omp flush(abort) #endif // CERES_USE_OPENMP #ifndef CERES_USE_TBB continue; #else return; #endif // !CERES_USE_TBB } scratch->cost += block_cost; // Store the jacobians, if they were requested. if (jacobian != NULL) { jacobian_writer_.Write(i, residual_layout_[i], block_jacobians, jacobian); } // Compute and store the gradient, if it was requested. if (gradient != NULL) { int num_residuals = residual_block->NumResiduals(); int num_parameter_blocks = residual_block->NumParameterBlocks(); for (int j = 0; j < num_parameter_blocks; ++j) { const ParameterBlock* parameter_block = residual_block->parameter_blocks()[j]; if (parameter_block->IsConstant()) { continue; } MatrixTransposeVectorMultiply<Eigen::Dynamic, Eigen::Dynamic, 1>( block_jacobians[j], num_residuals, parameter_block->LocalSize(), block_residuals, scratch->gradient.get() + parameter_block->delta_offset()); } } } #ifdef CERES_USE_TBB ); #endif // CERES_USE_TBB if (!abort) { const int num_parameters = program_->NumEffectiveParameters(); // Sum the cost and gradient (if requested) from each thread. (*cost) = 0.0; if (gradient != NULL) { VectorRef(gradient, num_parameters).setZero(); } for (int i = 0; i < options_.num_threads; ++i) { (*cost) += evaluate_scratch_[i].cost; if (gradient != NULL) { VectorRef(gradient, num_parameters) += VectorRef(evaluate_scratch_[i].gradient.get(), num_parameters); } } // Finalize the Jacobian if it is available. // `num_parameters` is passed to the finalizer so that additional // storage can be reserved for additional diagonal elements if // necessary. if (jacobian != NULL) { JacobianFinalizer f; f(jacobian, num_parameters); } } return !abort; } bool Plus(const double* state, const double* delta, double* state_plus_delta) const { return program_->Plus(state, delta, state_plus_delta); } int NumParameters() const { return program_->NumParameters(); } int NumEffectiveParameters() const { return program_->NumEffectiveParameters(); } int NumResiduals() const { return program_->NumResiduals(); } virtual std::map<std::string, int> CallStatistics() const { return execution_summary_.calls(); } virtual std::map<std::string, double> TimeStatistics() const { return execution_summary_.times(); } private: // Per-thread scratch space needed to evaluate and store each residual block. struct EvaluateScratch { void Init(int max_parameters_per_residual_block, int max_scratch_doubles_needed_for_evaluate, int max_residuals_per_residual_block, int num_parameters) { residual_block_evaluate_scratch.reset( new double[max_scratch_doubles_needed_for_evaluate]); gradient.reset(new double[num_parameters]); VectorRef(gradient.get(), num_parameters).setZero(); residual_block_residuals.reset( new double[max_residuals_per_residual_block]); jacobian_block_ptrs.reset( new double*[max_parameters_per_residual_block]); } double cost; scoped_array<double> residual_block_evaluate_scratch; // The gradient in the local parameterization. scoped_array<double> gradient; // Enough space to store the residual for the largest residual block. scoped_array<double> residual_block_residuals; scoped_array<double*> jacobian_block_ptrs; }; static void BuildResidualLayout(const Program& program, std::vector<int>* residual_layout) { const std::vector<ResidualBlock*>& residual_blocks = program.residual_blocks(); residual_layout->resize(program.NumResidualBlocks()); int residual_pos = 0; for (int i = 0; i < residual_blocks.size(); ++i) { const int num_residuals = residual_blocks[i]->NumResiduals(); (*residual_layout)[i] = residual_pos; residual_pos += num_residuals; } } // Create scratch space for each thread evaluating the program. static EvaluateScratch* CreateEvaluatorScratch(const Program& program, int num_threads) { int max_parameters_per_residual_block = program.MaxParametersPerResidualBlock(); int max_scratch_doubles_needed_for_evaluate = program.MaxScratchDoublesNeededForEvaluate(); int max_residuals_per_residual_block = program.MaxResidualsPerResidualBlock(); int num_parameters = program.NumEffectiveParameters(); EvaluateScratch* evaluate_scratch = new EvaluateScratch[num_threads]; for (int i = 0; i < num_threads; i++) { evaluate_scratch[i].Init(max_parameters_per_residual_block, max_scratch_doubles_needed_for_evaluate, max_residuals_per_residual_block, num_parameters); } return evaluate_scratch; } Evaluator::Options options_; Program* program_; JacobianWriter jacobian_writer_; scoped_array<EvaluatePreparer> evaluate_preparers_; scoped_array<EvaluateScratch> evaluate_scratch_; std::vector<int> residual_layout_; ::ceres::internal::ExecutionSummary execution_summary_; }; } // namespace internal } // namespace ceres #endif // CERES_INTERNAL_PROGRAM_EVALUATOR_H_

CLHelper.h

//------------------------------------------ //--cambine:helper function for OpenCL //--programmer: Jianbin Fang //--date: 27/12/2010 //------------------------------------------ #ifndef _CL_HELPER_ #define _CL_HELPER_ #include <CL/cl.h> #include <vector> #include <iostream> #include <fstream> #include <string> using std::string; using std::ifstream; using std::cerr; using std::endl; using std::cout; //#pragma OPENCL EXTENSION cl_nv_compiler_options:enable #define WORK_DIM 2 //work-items dimensions struct oclHandleStruct { cl_context context; cl_device_id *devices; cl_command_queue queue; cl_program program; cl_int cl_status; std::string error_str; std::vector<cl_kernel> kernel; }; struct oclHandleStruct oclHandles; char kernel_file[100] = "Kernels.cl"; int total_kernels = 2; string kernel_names[2] = {"BFS_1", "BFS_2"}; int work_group_size = 512; int device_id_inused = 0; //deviced id used (default : 0) /* * Converts the contents of a file into a string */ string FileToString(const string fileName) { ifstream f(fileName.c_str(), ifstream::in | ifstream::binary); try { size_t size; char* str; string s; if(f.is_open()) { size_t fileSize; f.seekg(0, ifstream::end); size = fileSize = f.tellg(); f.seekg(0, ifstream::beg); str = new char[size+1]; if (!str) throw(string("Could not allocate memory")); f.read(str, fileSize); f.close(); str[size] = '\0'; s = str; delete [] str; return s; } } catch(std::string msg) { cerr << "Exception caught in FileToString(): " << msg << endl; if(f.is_open()) f.close(); } catch(...) { cerr << "Exception caught in FileToString()" << endl; if(f.is_open()) f.close(); } string errorMsg = "FileToString()::Error: Unable to open file " + fileName; throw(errorMsg); } //--------------------------------------- //Read command line parameters // void _clCmdParams(int argc, char* argv[]){ for (int i =0; i < argc; ++i) { switch (argv[i][1]) { case 'g': //--g stands for size of work group if (++i < argc) { sscanf(argv[i], "%u", &work_group_size); } else { std::cerr << "Could not read argument after option " << argv[i-1] << std::endl; throw; } break; case 'd': //--d stands for device id used in computaion if (++i < argc) { sscanf(argv[i], "%u", &device_id_inused); } else { std::cerr << "Could not read argument after option " << argv[i-1] << std::endl; throw; } break; default: ; } } } //--------------------------------------- //Initlize CL objects //--description: there are 5 steps to initialize all the OpenCL objects needed //--revised on 04/01/2011: get the number of devices and // devices have no relationship with context void _clInit() { int DEVICE_ID_INUSED = device_id_inused; cl_int resultCL; oclHandles.context = NULL; oclHandles.devices = NULL; oclHandles.queue = NULL; oclHandles.program = NULL; cl_uint deviceListSize; //----------------------------------------------- //--cambine-1: find the available platforms and select one cl_uint numPlatforms; cl_platform_id targetPlatform = NULL; resultCL = clGetPlatformIDs(0, NULL, &numPlatforms); if (resultCL != CL_SUCCESS) throw (string("InitCL()::Error: Getting number of platforms (clGetPlatformIDs)")); //printf("number of platforms:%d\n",numPlatforms); //by cambine if (!(numPlatforms > 0)) throw (string("InitCL()::Error: No platforms found (clGetPlatformIDs)")); cl_platform_id* allPlatforms = (cl_platform_id*) malloc(numPlatforms * sizeof(cl_platform_id)); resultCL = clGetPlatformIDs(numPlatforms, allPlatforms, NULL); if (resultCL != CL_SUCCESS) throw (string("InitCL()::Error: Getting platform ids (clGetPlatformIDs)")); /* Select the target platform. Default: first platform */ targetPlatform = allPlatforms[0]; for (int i = 0; i < numPlatforms; i++) { char pbuff[128]; resultCL = clGetPlatformInfo( allPlatforms[i], CL_PLATFORM_VENDOR, sizeof(pbuff), pbuff, NULL); if (resultCL != CL_SUCCESS) throw (string("InitCL()::Error: Getting platform info (clGetPlatformInfo)")); //printf("vedor is %s\n",pbuff); } free(allPlatforms); //----------------------------------------------- //--cambine-2: create an OpenCL context cl_context_properties cprops[3] = { CL_CONTEXT_PLATFORM, (cl_context_properties)targetPlatform, 0 }; oclHandles.context = clCreateContextFromType(cprops, CL_DEVICE_TYPE_GPU, NULL, NULL, &resultCL); if ((resultCL != CL_SUCCESS) || (oclHandles.context == NULL)) throw (string("InitCL()::Error: Creating Context (clCreateContextFromType)")); //----------------------------------------------- //--cambine-3: detect OpenCL devices /* First, get the size of device list */ oclHandles.cl_status = clGetDeviceIDs(targetPlatform, CL_DEVICE_TYPE_GPU, 0, NULL, &deviceListSize); if(oclHandles.cl_status!=CL_SUCCESS){ throw(string("exception in _clInit -> clGetDeviceIDs")); } if (deviceListSize == 0) throw(string("InitCL()::Error: No devices found.")); //std::cout<<"device number:"<<deviceListSize<<std::endl; /* Now, allocate the device list */ oclHandles.devices = (cl_device_id *)malloc(deviceListSize * sizeof(cl_device_id)); if (oclHandles.devices == 0) throw(string("InitCL()::Error: Could not allocate memory.")); /* Next, get the device list data */ oclHandles.cl_status = clGetDeviceIDs(targetPlatform, CL_DEVICE_TYPE_GPU, deviceListSize, \ oclHandles.devices, NULL); if(oclHandles.cl_status!=CL_SUCCESS){ throw(string("exception in _clInit -> clGetDeviceIDs-2")); } //----------------------------------------------- //--cambine-4: Create an OpenCL command queue oclHandles.queue = clCreateCommandQueue(oclHandles.context, oclHandles.devices[DEVICE_ID_INUSED], 0, &resultCL); if ((resultCL != CL_SUCCESS) || (oclHandles.queue == NULL)) throw(string("InitCL()::Creating Command Queue. (clCreateCommandQueue)")); //----------------------------------------------- //--cambine-5: Load CL file, build CL program object, create CL kernel object std::string source_str = FileToString(kernel_file); const char * source = source_str.c_str(); size_t sourceSize[] = { source_str.length() }; oclHandles.program = clCreateProgramWithSource(oclHandles.context, 1, &source, sourceSize, &resultCL); if ((resultCL != CL_SUCCESS) || (oclHandles.program == NULL)) throw(string("InitCL()::Error: Loading Binary into cl_program. (clCreateProgramWithBinary)")); //insert debug information //std::string options= "-cl-nv-verbose"; //Doesn't work on AMD machines //options += " -cl-nv-opt-level=3"; resultCL = clBuildProgram(oclHandles.program, deviceListSize, oclHandles.devices, NULL, NULL,NULL); if ((resultCL != CL_SUCCESS) || (oclHandles.program == NULL)) { cerr << "InitCL()::Error: In clBuildProgram" << endl; size_t length; resultCL = clGetProgramBuildInfo(oclHandles.program, oclHandles.devices[DEVICE_ID_INUSED], CL_PROGRAM_BUILD_LOG, 0, NULL, &length); if(resultCL != CL_SUCCESS) throw(string("InitCL()::Error: Getting Program build info(clGetProgramBuildInfo)")); char* buffer = (char*)malloc(length); resultCL = clGetProgramBuildInfo(oclHandles.program, oclHandles.devices[DEVICE_ID_INUSED], CL_PROGRAM_BUILD_LOG, length, buffer, NULL); if(resultCL != CL_SUCCESS) throw(string("InitCL()::Error: Getting Program build info(clGetProgramBuildInfo)")); cerr << buffer << endl; free(buffer); throw(string("InitCL()::Error: Building Program (clBuildProgram)")); } //get program information in intermediate representation #ifdef PTX_MSG size_t binary_sizes[deviceListSize]; char * binaries[deviceListSize]; //figure out number of devices and the sizes of the binary for each device. oclHandles.cl_status = clGetProgramInfo(oclHandles.program, CL_PROGRAM_BINARY_SIZES, sizeof(size_t)*deviceListSize, &binary_sizes, NULL ); if(oclHandles.cl_status!=CL_SUCCESS){ throw(string("--cambine:exception in _InitCL -> clGetProgramInfo-2")); } std::cout<<"--cambine:"<<binary_sizes<<std::endl; //copy over all of the generated binaries. for(int i=0;i<deviceListSize;i++) binaries[i] = (char *)malloc( sizeof(char)*(binary_sizes[i]+1)); oclHandles.cl_status = clGetProgramInfo(oclHandles.program, CL_PROGRAM_BINARIES, sizeof(char *)*deviceListSize, binaries, NULL ); if(oclHandles.cl_status!=CL_SUCCESS){ throw(string("--cambine:exception in _InitCL -> clGetProgramInfo-3")); } for(int i=0;i<deviceListSize;i++) binaries[i][binary_sizes[i]] = '\0'; std::cout<<"--cambine:writing ptd information..."<<std::endl; FILE * ptx_file = fopen("cl.ptx","w"); if(ptx_file==NULL){ throw(string("exceptions in allocate ptx file.")); } fprintf(ptx_file,"%s",binaries[DEVICE_ID_INUSED]); fclose(ptx_file); std::cout<<"--cambine:writing ptd information done."<<std::endl; for(int i=0;i<deviceListSize;i++) free(binaries[i]); #endif for (int nKernel = 0; nKernel < total_kernels; nKernel++) { /* get a kernel object handle for a kernel with the given name */ cl_kernel kernel = clCreateKernel(oclHandles.program, (kernel_names[nKernel]).c_str(), &resultCL); if ((resultCL != CL_SUCCESS) || (kernel == NULL)) { string errorMsg = "InitCL()::Error: Creating Kernel (clCreateKernel) \"" + kernel_names[nKernel] + "\""; throw(errorMsg); } oclHandles.kernel.push_back(kernel); } //get resource alocation information #ifdef RES_MSG char * build_log; size_t ret_val_size; oclHandles.cl_status = clGetProgramBuildInfo(oclHandles.program, oclHandles.devices[DEVICE_ID_INUSED], CL_PROGRAM_BUILD_LOG, 0, NULL, &ret_val_size); if(oclHandles.cl_status!=CL_SUCCESS){ throw(string("exceptions in _InitCL -> getting resource information")); } build_log = (char *)malloc(ret_val_size+1); oclHandles.cl_status = clGetProgramBuildInfo(oclHandles.program, oclHandles.devices[DEVICE_ID_INUSED], CL_PROGRAM_BUILD_LOG, ret_val_size, build_log, NULL); if(oclHandles.cl_status!=CL_SUCCESS){ throw(string("exceptions in _InitCL -> getting resources allocation information-2")); } build_log[ret_val_size] = '\0'; std::cout<<"--cambine:"<<build_log<<std::endl; free(build_log); #endif } //--------------------------------------- //release CL objects void _clRelease() { char errorFlag = false; for (int nKernel = 0; nKernel < oclHandles.kernel.size(); nKernel++) { if (oclHandles.kernel[nKernel] != NULL) { cl_int resultCL = clReleaseKernel(oclHandles.kernel[nKernel]); if (resultCL != CL_SUCCESS) { cerr << "ReleaseCL()::Error: In clReleaseKernel" << endl; errorFlag = true; } oclHandles.kernel[nKernel] = NULL; } oclHandles.kernel.clear(); } if (oclHandles.program != NULL) { cl_int resultCL = clReleaseProgram(oclHandles.program); if (resultCL != CL_SUCCESS) { cerr << "ReleaseCL()::Error: In clReleaseProgram" << endl; errorFlag = true; } oclHandles.program = NULL; } if (oclHandles.queue != NULL) { cl_int resultCL = clReleaseCommandQueue(oclHandles.queue); if (resultCL != CL_SUCCESS) { cerr << "ReleaseCL()::Error: In clReleaseCommandQueue" << endl; errorFlag = true; } oclHandles.queue = NULL; } free(oclHandles.devices); if (oclHandles.context != NULL) { cl_int resultCL = clReleaseContext(oclHandles.context); if (resultCL != CL_SUCCESS) { cerr << "ReleaseCL()::Error: In clReleaseContext" << endl; errorFlag = true; } oclHandles.context = NULL; } if (errorFlag) throw(string("ReleaseCL()::Error encountered.")); } //-------------------------------------------------------- //--cambine:create buffer and then copy data from host to device cl_mem _clCreateAndCpyMem(int size, void * h_mem_source) throw(string){ cl_mem d_mem; d_mem = clCreateBuffer(oclHandles.context, CL_MEM_READ_ONLY|CL_MEM_COPY_HOST_PTR, \ size, h_mem_source, &oclHandles.cl_status); #ifdef ERRMSG if(oclHandles.cl_status != CL_SUCCESS) throw(string("excpetion in _clCreateAndCpyMem()")); #endif return d_mem; } //------------------------------------------------------- //--cambine: create read only buffer for devices //--date: 17/01/2011 cl_mem _clMallocRW(int size, void * h_mem_ptr) throw(string){ cl_mem d_mem; d_mem = clCreateBuffer(oclHandles.context, CL_MEM_READ_WRITE | CL_MEM_COPY_HOST_PTR, size, h_mem_ptr, &oclHandles.cl_status); #ifdef ERRMSG if(oclHandles.cl_status != CL_SUCCESS) throw(string("excpetion in _clMallocRW")); #endif return d_mem; } //------------------------------------------------------- //--cambine: create read and write buffer for devices //--date: 17/01/2011 cl_mem _clMalloc(int size, void * h_mem_ptr) throw(string){ cl_mem d_mem; d_mem = clCreateBuffer(oclHandles.context, CL_MEM_WRITE_ONLY | CL_MEM_COPY_HOST_PTR, size, h_mem_ptr, &oclHandles.cl_status); #ifdef ERRMSG if(oclHandles.cl_status != CL_SUCCESS) throw(string("excpetion in _clMalloc")); #endif return d_mem; } //------------------------------------------------------- //--cambine: transfer data from host to device //--date: 17/01/2011 void _clMemcpyH2D(cl_mem d_mem, int size, const void *h_mem_ptr) throw(string){ oclHandles.cl_status = clEnqueueWriteBuffer(oclHandles.queue, d_mem, CL_TRUE, 0, size, h_mem_ptr, 0, NULL, NULL); #ifdef ERRMSG if(oclHandles.cl_status != CL_SUCCESS) throw(string("excpetion in _clMemcpyH2D")); #endif } //-------------------------------------------------------- //--cambine:create buffer and then copy data from host to device with pinned // memory cl_mem _clCreateAndCpyPinnedMem(int size, float* h_mem_source) throw(string){ cl_mem d_mem, d_mem_pinned; float * h_mem_pinned = NULL; d_mem_pinned = clCreateBuffer(oclHandles.context, CL_MEM_READ_ONLY|CL_MEM_ALLOC_HOST_PTR, \ size, NULL, &oclHandles.cl_status); #ifdef ERRMSG if(oclHandles.cl_status != CL_SUCCESS) throw(string("excpetion in _clCreateAndCpyMem()->d_mem_pinned")); #endif //------------ d_mem = clCreateBuffer(oclHandles.context, CL_MEM_READ_ONLY, \ size, NULL, &oclHandles.cl_status); #ifdef ERRMSG if(oclHandles.cl_status != CL_SUCCESS) throw(string("excpetion in _clCreateAndCpyMem() -> d_mem ")); #endif //---------- h_mem_pinned = (cl_float *)clEnqueueMapBuffer(oclHandles.queue, d_mem_pinned, CL_TRUE, \ CL_MAP_WRITE, 0, size, 0, NULL, \ NULL, &oclHandles.cl_status); #ifdef ERRMSG if(oclHandles.cl_status != CL_SUCCESS) throw(string("excpetion in _clCreateAndCpyMem() -> clEnqueueMapBuffer")); #endif int element_number = size/sizeof(float); #pragma omp parallel for for(int i=0;i<element_number;i++){ h_mem_pinned[i] = h_mem_source[i]; } //---------- oclHandles.cl_status = clEnqueueWriteBuffer(oclHandles.queue, d_mem, \ CL_TRUE, 0, size, h_mem_pinned, \ 0, NULL, NULL); #ifdef ERRMSG if(oclHandles.cl_status != CL_SUCCESS) throw(string("excpetion in _clCreateAndCpyMem() -> clEnqueueWriteBuffer")); #endif return d_mem; } //-------------------------------------------------------- //--cambine:create write only buffer on device cl_mem _clMallocWO(int size) throw(string){ cl_mem d_mem; d_mem = clCreateBuffer(oclHandles.context, CL_MEM_WRITE_ONLY, size, 0, &oclHandles.cl_status); #ifdef ERRMSG if(oclHandles.cl_status != CL_SUCCESS) throw(string("excpetion in _clCreateMem()")); #endif return d_mem; } //-------------------------------------------------------- //transfer data from device to host void _clMemcpyD2H(cl_mem d_mem, int size, void * h_mem) throw(string){ oclHandles.cl_status = clEnqueueReadBuffer(oclHandles.queue, d_mem, CL_TRUE, 0, size, h_mem, 0,0,0); #ifdef ERRMSG oclHandles.error_str = "excpetion in _clCpyMemD2H -> "; switch(oclHandles.cl_status){ case CL_INVALID_COMMAND_QUEUE: oclHandles.error_str += "CL_INVALID_COMMAND_QUEUE"; break; case CL_INVALID_CONTEXT: oclHandles.error_str += "CL_INVALID_CONTEXT"; break; case CL_INVALID_MEM_OBJECT: oclHandles.error_str += "CL_INVALID_MEM_OBJECT"; break; case CL_INVALID_VALUE: oclHandles.error_str += "CL_INVALID_VALUE"; break; case CL_INVALID_EVENT_WAIT_LIST: oclHandles.error_str += "CL_INVALID_EVENT_WAIT_LIST"; break; case CL_MEM_OBJECT_ALLOCATION_FAILURE: oclHandles.error_str += "CL_MEM_OBJECT_ALLOCATION_FAILURE"; break; case CL_OUT_OF_HOST_MEMORY: oclHandles.error_str += "CL_OUT_OF_HOST_MEMORY"; break; default: oclHandles.error_str += "Unknown reason"; break; } if(oclHandles.cl_status != CL_SUCCESS) throw(oclHandles.error_str); #endif } //-------------------------------------------------------- //set kernel arguments void _clSetArgs(int kernel_id, int arg_idx, void * d_mem, int size = 0) throw(string){ if(!size){ oclHandles.cl_status = clSetKernelArg(oclHandles.kernel[kernel_id], arg_idx, sizeof(d_mem), &d_mem); #ifdef ERRMSG oclHandles.error_str = "excpetion in _clSetKernelArg() "; switch(oclHandles.cl_status){ case CL_INVALID_KERNEL: oclHandles.error_str += "CL_INVALID_KERNEL"; break; case CL_INVALID_ARG_INDEX: oclHandles.error_str += "CL_INVALID_ARG_INDEX"; break; case CL_INVALID_ARG_VALUE: oclHandles.error_str += "CL_INVALID_ARG_VALUE"; break; case CL_INVALID_MEM_OBJECT: oclHandles.error_str += "CL_INVALID_MEM_OBJECT"; break; case CL_INVALID_SAMPLER: oclHandles.error_str += "CL_INVALID_SAMPLER"; break; case CL_INVALID_ARG_SIZE: oclHandles.error_str += "CL_INVALID_ARG_SIZE"; break; case CL_OUT_OF_RESOURCES: oclHandles.error_str += "CL_OUT_OF_RESOURCES"; break; case CL_OUT_OF_HOST_MEMORY: oclHandles.error_str += "CL_OUT_OF_HOST_MEMORY"; break; default: oclHandles.error_str += "Unknown reason"; break; } if(oclHandles.cl_status != CL_SUCCESS) throw(oclHandles.error_str); #endif } else{ oclHandles.cl_status = clSetKernelArg(oclHandles.kernel[kernel_id], arg_idx, size, d_mem); #ifdef ERRMSG oclHandles.error_str = "excpetion in _clSetKernelArg() "; switch(oclHandles.cl_status){ case CL_INVALID_KERNEL: oclHandles.error_str += "CL_INVALID_KERNEL"; break; case CL_INVALID_ARG_INDEX: oclHandles.error_str += "CL_INVALID_ARG_INDEX"; break; case CL_INVALID_ARG_VALUE: oclHandles.error_str += "CL_INVALID_ARG_VALUE"; break; case CL_INVALID_MEM_OBJECT: oclHandles.error_str += "CL_INVALID_MEM_OBJECT"; break; case CL_INVALID_SAMPLER: oclHandles.error_str += "CL_INVALID_SAMPLER"; break; case CL_INVALID_ARG_SIZE: oclHandles.error_str += "CL_INVALID_ARG_SIZE"; break; case CL_OUT_OF_RESOURCES: oclHandles.error_str += "CL_OUT_OF_RESOURCES"; break; case CL_OUT_OF_HOST_MEMORY: oclHandles.error_str += "CL_OUT_OF_HOST_MEMORY"; break; default: oclHandles.error_str += "Unknown reason"; break; } if(oclHandles.cl_status != CL_SUCCESS) throw(oclHandles.error_str); #endif } } void _clFinish() throw(string){ oclHandles.cl_status = clFinish(oclHandles.queue); #ifdef ERRMSG oclHandles.error_str = "excpetion in _clFinish"; switch(oclHandles.cl_status){ case CL_INVALID_COMMAND_QUEUE: oclHandles.error_str += "CL_INVALID_COMMAND_QUEUE"; break; case CL_OUT_OF_RESOURCES: oclHandles.error_str += "CL_OUT_OF_RESOURCES"; break; case CL_OUT_OF_HOST_MEMORY: oclHandles.error_str += "CL_OUT_OF_HOST_MEMORY"; break; default: oclHandles.error_str += "Unknown reasons"; break; } if(oclHandles.cl_status!=CL_SUCCESS){ throw(oclHandles.error_str); } #endif } //-------------------------------------------------------- //--cambine:enqueue kernel void _clInvokeKernel(int kernel_id, int work_items, int work_group_size) throw(string){ cl_uint work_dim = WORK_DIM; cl_event e[1]; if(work_items%work_group_size != 0) //process situations that work_items cannot be divided by work_group_size work_items = work_items + (work_group_size-(work_items%work_group_size)); size_t local_work_size[] = {work_group_size, 1}; size_t global_work_size[] = {work_items, 1}; oclHandles.cl_status = clEnqueueNDRangeKernel(oclHandles.queue, oclHandles.kernel[kernel_id], work_dim, 0, \ global_work_size, local_work_size, 0 , 0, &(e[0]) ); #ifdef ERRMSG oclHandles.error_str = "excpetion in _clInvokeKernel() -> "; switch(oclHandles.cl_status) { case CL_INVALID_PROGRAM_EXECUTABLE: oclHandles.error_str += "CL_INVALID_PROGRAM_EXECUTABLE"; break; case CL_INVALID_COMMAND_QUEUE: oclHandles.error_str += "CL_INVALID_COMMAND_QUEUE"; break; case CL_INVALID_KERNEL: oclHandles.error_str += "CL_INVALID_KERNEL"; break; case CL_INVALID_CONTEXT: oclHandles.error_str += "CL_INVALID_CONTEXT"; break; case CL_INVALID_KERNEL_ARGS: oclHandles.error_str += "CL_INVALID_KERNEL_ARGS"; break; case CL_INVALID_WORK_DIMENSION: oclHandles.error_str += "CL_INVALID_WORK_DIMENSION"; break; case CL_INVALID_GLOBAL_WORK_SIZE: oclHandles.error_str += "CL_INVALID_GLOBAL_WORK_SIZE"; break; case CL_INVALID_WORK_GROUP_SIZE: oclHandles.error_str += "CL_INVALID_WORK_GROUP_SIZE"; break; case CL_INVALID_WORK_ITEM_SIZE: oclHandles.error_str += "CL_INVALID_WORK_ITEM_SIZE"; break; case CL_INVALID_GLOBAL_OFFSET: oclHandles.error_str += "CL_INVALID_GLOBAL_OFFSET"; break; case CL_OUT_OF_RESOURCES: oclHandles.error_str += "CL_OUT_OF_RESOURCES"; break; case CL_MEM_OBJECT_ALLOCATION_FAILURE: oclHandles.error_str += "CL_MEM_OBJECT_ALLOCATION_FAILURE"; break; case CL_INVALID_EVENT_WAIT_LIST: oclHandles.error_str += "CL_INVALID_EVENT_WAIT_LIST"; break; case CL_OUT_OF_HOST_MEMORY: oclHandles.error_str += "CL_OUT_OF_HOST_MEMORY"; break; default: oclHandles.error_str += "Unkown reseason"; break; } if(oclHandles.cl_status != CL_SUCCESS) throw(oclHandles.error_str); #endif //_clFinish(); // oclHandles.cl_status = clWaitForEvents(1, &e[0]); // #ifdef ERRMSG // if (oclHandles.cl_status!= CL_SUCCESS) // throw(string("excpetion in _clEnqueueNDRange() -> clWaitForEvents")); // #endif } void _clInvokeKernel2D(int kernel_id, int range_x, int range_y, int group_x, int group_y) throw(string){ cl_uint work_dim = WORK_DIM; size_t local_work_size[] = {group_x, group_y}; size_t global_work_size[] = {range_x, range_y}; cl_event e[1]; /*if(work_items%work_group_size != 0) //process situations that work_items cannot be divided by work_group_size work_items = work_items + (work_group_size-(work_items%work_group_size));*/ oclHandles.cl_status = clEnqueueNDRangeKernel(oclHandles.queue, oclHandles.kernel[kernel_id], work_dim, 0, \ global_work_size, local_work_size, 0 , 0, &(e[0]) ); #ifdef ERRMSG oclHandles.error_str = "excpetion in _clInvokeKernel() -> "; switch(oclHandles.cl_status) { case CL_INVALID_PROGRAM_EXECUTABLE: oclHandles.error_str += "CL_INVALID_PROGRAM_EXECUTABLE"; break; case CL_INVALID_COMMAND_QUEUE: oclHandles.error_str += "CL_INVALID_COMMAND_QUEUE"; break; case CL_INVALID_KERNEL: oclHandles.error_str += "CL_INVALID_KERNEL"; break; case CL_INVALID_CONTEXT: oclHandles.error_str += "CL_INVALID_CONTEXT"; break; case CL_INVALID_KERNEL_ARGS: oclHandles.error_str += "CL_INVALID_KERNEL_ARGS"; break; case CL_INVALID_WORK_DIMENSION: oclHandles.error_str += "CL_INVALID_WORK_DIMENSION"; break; case CL_INVALID_GLOBAL_WORK_SIZE: oclHandles.error_str += "CL_INVALID_GLOBAL_WORK_SIZE"; break; case CL_INVALID_WORK_GROUP_SIZE: oclHandles.error_str += "CL_INVALID_WORK_GROUP_SIZE"; break; case CL_INVALID_WORK_ITEM_SIZE: oclHandles.error_str += "CL_INVALID_WORK_ITEM_SIZE"; break; case CL_INVALID_GLOBAL_OFFSET: oclHandles.error_str += "CL_INVALID_GLOBAL_OFFSET"; break; case CL_OUT_OF_RESOURCES: oclHandles.error_str += "CL_OUT_OF_RESOURCES"; break; case CL_MEM_OBJECT_ALLOCATION_FAILURE: oclHandles.error_str += "CL_MEM_OBJECT_ALLOCATION_FAILURE"; break; case CL_INVALID_EVENT_WAIT_LIST: oclHandles.error_str += "CL_INVALID_EVENT_WAIT_LIST"; break; case CL_OUT_OF_HOST_MEMORY: oclHandles.error_str += "CL_OUT_OF_HOST_MEMORY"; break; default: oclHandles.error_str += "Unkown reseason"; break; } if(oclHandles.cl_status != CL_SUCCESS) throw(oclHandles.error_str); #endif //_clFinish(); /*oclHandles.cl_status = clWaitForEvents(1, &e[0]); #ifdef ERRMSG if (oclHandles.cl_status!= CL_SUCCESS) throw(string("excpetion in _clEnqueueNDRange() -> clWaitForEvents")); #endif*/ } //-------------------------------------------------------- //release OpenCL objects void _clFree(cl_mem ob) throw(string){ if(ob!=NULL) oclHandles.cl_status = clReleaseMemObject(ob); #ifdef ERRMSG oclHandles.error_str = "excpetion in _clFree() ->"; switch(oclHandles.cl_status) { case CL_INVALID_MEM_OBJECT: oclHandles.error_str += "CL_INVALID_MEM_OBJECT"; break; case CL_OUT_OF_RESOURCES: oclHandles.error_str += "CL_OUT_OF_RESOURCES"; break; case CL_OUT_OF_HOST_MEMORY: oclHandles.error_str += "CL_OUT_OF_HOST_MEMORY"; break; default: oclHandles.error_str += "Unkown reseason"; break; } if (oclHandles.cl_status!= CL_SUCCESS) throw(oclHandles.error_str); #endif } #endif //_CL_HELPER_

mixed_tentusscher_myo_epi_2004_S1_3.c

// Scenario 1 - Mixed-Model TenTusscher 2004 (Myocardium + Epicardium) // (AP + max:dvdt) #include <stdio.h> #include "mixed_tentusscher_myo_epi_2004_S1_3.h" GET_CELL_MODEL_DATA(init_cell_model_data) { if(get_initial_v) cell_model->initial_v = INITIAL_V; if(get_neq) cell_model->number_of_ode_equations = NEQ; } SET_ODE_INITIAL_CONDITIONS_CPU(set_model_initial_conditions_cpu) { static bool first_call = true; if(first_call) { print_to_stdout_and_file("Using mixed version of TenTusscher 2004 myocardium + epicardium CPU model\n"); first_call = false; } // Get the mapping array uint32_t *mapping = NULL; if(extra_data) { mapping = (uint32_t*)extra_data; } else { print_to_stderr_and_file_and_exit("You need to specify a mask function when using a mixed model!\n"); } // Initial conditions for TenTusscher myocardium if (mapping[sv_id] == 0) { // Default initial conditions /* sv[0] = INITIAL_V; // V; millivolt sv[1] = 0.f; //M sv[2] = 0.75; //H sv[3] = 0.75f; //J sv[4] = 0.f; //Xr1 sv[5] = 1.f; //Xr2 sv[6] = 0.f; //Xs sv[7] = 1.f; //S sv[8] = 0.f; //R sv[9] = 0.f; //D sv[10] = 1.f; //F sv[11] = 1.f; //FCa sv[12] = 1.f; //G sv[13] = 0.0002; //Cai sv[14] = 0.2f; //CaSR sv[15] = 11.6f; //Nai sv[16] = 138.3f; //Ki */ // Elnaz's steady-state initial conditions real sv_sst[]={-86.3965119057144,0.00133824305081220,0.775463576993407,0.775278393595599,0.000179499343643571,0.483303039835057,0.00297647859235379,0.999998290403642,1.98961879737287e-08,1.93486789479597e-05,0.999599147019885,1.00646342475688,0.999975178010127,5.97703651642618e-05,0.418325344820368,10.7429775420171,138.918155900633}; for (uint32_t i = 0; i < NEQ; i++) sv[i] = sv_sst[i]; } // Initial conditions for TenTusscher epicardium else { // Default initial conditions /* sv[0] = INITIAL_V; // V; millivolt sv[1] = 0.f; //M sv[2] = 0.75; //H sv[3] = 0.75f; //J sv[4] = 0.f; //Xr1 sv[5] = 1.f; //Xr2 sv[6] = 0.f; //Xs sv[7] = 1.f; //S sv[8] = 0.f; //R sv[9] = 0.f; //D sv[10] = 1.f; //F sv[11] = 1.f; //FCa sv[12] = 1.f; //G sv[13] = 0.0002; //Cai sv[14] = 0.2f; //CaSR sv[15] = 11.6f; //Nai sv[16] = 138.3f; //Ki */ // Elnaz's steady-state initial conditions real sv_sst[]={-86.7781728901090,0.00123349870343949,0.784809889318744,0.784547392738085,0.000169596490364688,0.487274781980815,0.00289668567203959,0.999998415889729,1.86706803556251e-08,1.83887682327320e-05,0.999777287266349,1.00756607610598,0.999999160062542,3.39867729896090e-05,0.592251587252171,9.37662819093271,140.159936788276}; for (uint32_t i = 0; i < NEQ; i++) sv[i] = sv_sst[i]; } } SOLVE_MODEL_ODES_CPU(solve_model_odes_cpu) { // Get the mapping array uint32_t *mapping = NULL; if(extra_data) { mapping = (uint32_t*)extra_data; } else { print_to_stderr_and_file_and_exit("You need to specify a mask function when using a mixed model!\n"); } uint32_t sv_id; int i; #pragma omp parallel for private(sv_id) for (i = 0; i < num_cells_to_solve; i++) { if(cells_to_solve) sv_id = cells_to_solve[i]; else sv_id = (uint32_t )i; for (int j = 0; j < num_steps; ++j) { if (mapping[i] == 0) solve_model_ode_cpu_myo(dt, sv + (sv_id * NEQ), stim_currents[i]); else solve_model_ode_cpu_epi(dt, sv + (sv_id * NEQ), stim_currents[i]); } } } void solve_model_ode_cpu_myo (real dt, real *sv, real stim_current) { real rY[NEQ], rDY[NEQ]; for(int i = 0; i < NEQ; i++) rY[i] = sv[i]; RHS_cpu_myo(rY, rDY, stim_current, dt); for(int i = 0; i < NEQ; i++) sv[i] = rDY[i]; } void RHS_cpu_myo(const real *sv, real *rDY_, real stim_current, real dt) { // State variables real svolt = sv[0]; real sm = sv[1]; real sh = sv[2]; real sj = sv[3]; real sxr1 = sv[4]; real sxr2 = sv[5]; real sxs = sv[6]; real ss = sv[7]; real sr = sv[8]; real sd = sv[9]; real sf = sv[10]; real sfca = sv[11]; real sg = sv[12]; real Cai = sv[13]; real CaSR = sv[14]; real Nai = sv[15]; real Ki = sv[16]; //External concentrations real Ko=5.4; real Cao=2.0; real Nao=140.0; //Intracellular volumes real Vc=0.016404; real Vsr=0.001094; //Calcium dynamics real Bufc=0.15f; real Kbufc=0.001f; real Bufsr=10.f; real Kbufsr=0.3f; real taufca=2.f; real taug=2.f; real Vmaxup=0.000425f; real Kup=0.00025f; //Constants const real R = 8314.472f; const real F = 96485.3415f; const real T =310.0f; real RTONF =(R*T)/F; //Cellular capacitance real CAPACITANCE=0.185; //Parameters for currents //Parameters for IKr real Gkr=0.096; //Parameters for Iks real pKNa=0.03; // [!] Myocardium cell real Gks=0.062; //Parameters for Ik1 real GK1=5.405; //Parameters for Ito // [!] Myocardium cell real Gto=0.294; //Parameters for INa real GNa=14.838; //Parameters for IbNa real GbNa=0.00029; //Parameters for INaK real KmK=1.0; real KmNa=40.0; real knak=1.362; //Parameters for ICaL real GCaL=0.000175; //Parameters for IbCa real GbCa=0.000592; //Parameters for INaCa real knaca=1000; real KmNai=87.5; real KmCa=1.38; real ksat=0.1; real n=0.35; //Parameters for IpCa real GpCa=0.825; real KpCa=0.0005; //Parameters for IpK; real GpK=0.0146; real IKr; real IKs; real IK1; real Ito; real INa; real IbNa; real ICaL; real IbCa; real INaCa; real IpCa; real IpK; real INaK; real Irel; real Ileak; real dNai; real dKi; real dCai; real dCaSR; real A; // real BufferFactorc; // real BufferFactorsr; real SERCA; real Caisquare; real CaSRsquare; real CaCurrent; real CaSRCurrent; real fcaold; real gold; real Ek; real Ena; real Eks; real Eca; real CaCSQN; real bjsr; real cjsr; real CaBuf; real bc; real cc; real Ak1; real Bk1; real rec_iK1; real rec_ipK; real rec_iNaK; real AM; real BM; real AH_1; real BH_1; real AH_2; real BH_2; real AJ_1; real BJ_1; real AJ_2; real BJ_2; real M_INF; real H_INF; real J_INF; real TAU_M; real TAU_H; real TAU_J; real axr1; real bxr1; real axr2; real bxr2; real Xr1_INF; real Xr2_INF; real TAU_Xr1; real TAU_Xr2; real Axs; real Bxs; real Xs_INF; real TAU_Xs; real R_INF; real TAU_R; real S_INF; real TAU_S; real Ad; real Bd; real Cd; real TAU_D; real D_INF; real TAU_F; real F_INF; real FCa_INF; real G_INF; real inverseVcF2=1/(2*Vc*F); real inverseVcF=1./(Vc*F); real Kupsquare=Kup*Kup; // real BufcKbufc=Bufc*Kbufc; // real Kbufcsquare=Kbufc*Kbufc; // real Kbufc2=2*Kbufc; // real BufsrKbufsr=Bufsr*Kbufsr; // const real Kbufsrsquare=Kbufsr*Kbufsr; // const real Kbufsr2=2*Kbufsr; const real exptaufca=exp(-dt/taufca); const real exptaug=exp(-dt/taug); real sItot; //Needed to compute currents Ek=RTONF*(log((Ko/Ki))); Ena=RTONF*(log((Nao/Nai))); Eks=RTONF*(log((Ko+pKNa*Nao)/(Ki+pKNa*Nai))); Eca=0.5*RTONF*(log((Cao/Cai))); Ak1=0.1/(1.+exp(0.06*(svolt-Ek-200))); Bk1=(3.*exp(0.0002*(svolt-Ek+100))+ exp(0.1*(svolt-Ek-10)))/(1.+exp(-0.5*(svolt-Ek))); rec_iK1=Ak1/(Ak1+Bk1); rec_iNaK=(1./(1.+0.1245*exp(-0.1*svolt*F/(R*T))+0.0353*exp(-svolt*F/(R*T)))); rec_ipK=1./(1.+exp((25-svolt)/5.98)); //Compute currents INa=GNa*sm*sm*sm*sh*sj*(svolt-Ena); ICaL=GCaL*sd*sf*sfca*4*svolt*(F*F/(R*T))* (exp(2*svolt*F/(R*T))*Cai-0.341*Cao)/(exp(2*svolt*F/(R*T))-1.); Ito=Gto*sr*ss*(svolt-Ek); IKr=Gkr*sqrt(Ko/5.4)*sxr1*sxr2*(svolt-Ek); IKs=Gks*sxs*sxs*(svolt-Eks); IK1=GK1*rec_iK1*(svolt-Ek); INaCa=knaca*(1./(KmNai*KmNai*KmNai+Nao*Nao*Nao))*(1./(KmCa+Cao))* (1./(1+ksat*exp((n-1)*svolt*F/(R*T))))* (exp(n*svolt*F/(R*T))*Nai*Nai*Nai*Cao- exp((n-1)*svolt*F/(R*T))*Nao*Nao*Nao*Cai*2.5); INaK=knak*(Ko/(Ko+KmK))*(Nai/(Nai+KmNa))*rec_iNaK; IpCa=GpCa*Cai/(KpCa+Cai); IpK=GpK*rec_ipK*(svolt-Ek); IbNa=GbNa*(svolt-Ena); IbCa=GbCa*(svolt-Eca); //Determine total current (sItot) = IKr + IKs + IK1 + Ito + INa + IbNa + ICaL + IbCa + INaK + INaCa + IpCa + IpK + stim_current; //update concentrations Caisquare=Cai*Cai; CaSRsquare=CaSR*CaSR; CaCurrent=-(ICaL+IbCa+IpCa-2.0f*INaCa)*inverseVcF2*CAPACITANCE; A=0.016464f*CaSRsquare/(0.0625f+CaSRsquare)+0.008232f; Irel=A*sd*sg; Ileak=0.00008f*(CaSR-Cai); SERCA=Vmaxup/(1.f+(Kupsquare/Caisquare)); CaSRCurrent=SERCA-Irel-Ileak; CaCSQN=Bufsr*CaSR/(CaSR+Kbufsr); dCaSR=dt*(Vc/Vsr)*CaSRCurrent; bjsr=Bufsr-CaCSQN-dCaSR-CaSR+Kbufsr; cjsr=Kbufsr*(CaCSQN+dCaSR+CaSR); CaSR=(sqrt(bjsr*bjsr+4.*cjsr)-bjsr)/2.; CaBuf=Bufc*Cai/(Cai+Kbufc); dCai=dt*(CaCurrent-CaSRCurrent); bc=Bufc-CaBuf-dCai-Cai+Kbufc; cc=Kbufc*(CaBuf+dCai+Cai); Cai=(sqrt(bc*bc+4*cc)-bc)/2; dNai=-(INa+IbNa+3*INaK+3*INaCa)*inverseVcF*CAPACITANCE; Nai+=dt*dNai; dKi=-(stim_current+IK1+Ito+IKr+IKs-2*INaK+IpK)*inverseVcF*CAPACITANCE; Ki+=dt*dKi; //compute steady state values and time constants AM=1./(1.+exp((-60.-svolt)/5.)); BM=0.1/(1.+exp((svolt+35.)/5.))+0.10/(1.+exp((svolt-50.)/200.)); TAU_M=AM*BM; M_INF=1./((1.+exp((-56.86-svolt)/9.03))*(1.+exp((-56.86-svolt)/9.03))); if (svolt>=-40.) { AH_1=0.; BH_1=(0.77/(0.13*(1.+exp(-(svolt+10.66)/11.1)))); TAU_H= 1.0/(AH_1+BH_1); } else { AH_2=(0.057*exp(-(svolt+80.)/6.8)); BH_2=(2.7*exp(0.079*svolt)+(3.1e5)*exp(0.3485*svolt)); TAU_H=1.0/(AH_2+BH_2); } H_INF=1./((1.+exp((svolt+71.55)/7.43))*(1.+exp((svolt+71.55)/7.43))); if(svolt>=-40.) { AJ_1=0.; BJ_1=(0.6*exp((0.057)*svolt)/(1.+exp(-0.1*(svolt+32.)))); TAU_J= 1.0/(AJ_1+BJ_1); } else { AJ_2=(((-2.5428e4)*exp(0.2444*svolt)-(6.948e-6)* exp(-0.04391*svolt))*(svolt+37.78)/ (1.+exp(0.311*(svolt+79.23)))); BJ_2=(0.02424*exp(-0.01052*svolt)/(1.+exp(-0.1378*(svolt+40.14)))); TAU_J= 1.0/(AJ_2+BJ_2); } J_INF=H_INF; Xr1_INF=1./(1.+exp((-26.-svolt)/7.)); axr1=450./(1.+exp((-45.-svolt)/10.)); bxr1=6./(1.+exp((svolt-(-30.))/11.5)); TAU_Xr1=axr1*bxr1; Xr2_INF=1./(1.+exp((svolt-(-88.))/24.)); axr2=3./(1.+exp((-60.-svolt)/20.)); bxr2=1.12/(1.+exp((svolt-60.)/20.)); TAU_Xr2=axr2*bxr2; Xs_INF=1./(1.+exp((-5.-svolt)/14.)); Axs=1100./(sqrt(1.+exp((-10.-svolt)/6))); Bxs=1./(1.+exp((svolt-60.)/20.)); TAU_Xs=Axs*Bxs; // [!] Myocardium cell R_INF=1./(1.+exp((20-svolt)/6.)); S_INF=1./(1.+exp((svolt+20)/5.)); TAU_R=9.5*exp(-(svolt+40.)*(svolt+40.)/1800.)+0.8; TAU_S=85.*exp(-(svolt+45.)*(svolt+45.)/320.)+5./(1.+exp((svolt-20.)/5.))+3.; D_INF=1./(1.+exp((-5-svolt)/7.5)); Ad=1.4/(1.+exp((-35-svolt)/13))+0.25; Bd=1.4/(1.+exp((svolt+5)/5)); Cd=1./(1.+exp((50-svolt)/20)); TAU_D=Ad*Bd+Cd; F_INF=1./(1.+exp((svolt+20)/7)); //TAU_F=1125*exp(-(svolt+27)*(svolt+27)/300)+80+165/(1.+exp((25-svolt)/10)); TAU_F=1125*exp(-(svolt+27)*(svolt+27)/240)+80+165/(1.+exp((25-svolt)/10)); // Updated from CellML FCa_INF=(1./(1.+pow((Cai/0.000325),8))+ 0.1/(1.+exp((Cai-0.0005)/0.0001))+ 0.20/(1.+exp((Cai-0.00075)/0.0008))+ 0.23 )/1.46; if(Cai<0.00035) G_INF=1./(1.+pow((Cai/0.00035),6)); else G_INF=1./(1.+pow((Cai/0.00035),16)); //Update gates rDY_[1] = M_INF-(M_INF-sm)*exp(-dt/TAU_M); rDY_[2] = H_INF-(H_INF-sh)*exp(-dt/TAU_H); rDY_[3] = J_INF-(J_INF-sj)*exp(-dt/TAU_J); rDY_[4] = Xr1_INF-(Xr1_INF-sxr1)*exp(-dt/TAU_Xr1); rDY_[5] = Xr2_INF-(Xr2_INF-sxr2)*exp(-dt/TAU_Xr2); rDY_[6] = Xs_INF-(Xs_INF-sxs)*exp(-dt/TAU_Xs); rDY_[7] = S_INF-(S_INF-ss)*exp(-dt/TAU_S); rDY_[8] = R_INF-(R_INF-sr)*exp(-dt/TAU_R); rDY_[9] = D_INF-(D_INF-sd)*exp(-dt/TAU_D); rDY_[10] = F_INF-(F_INF-sf)*exp(-dt/TAU_F); fcaold= sfca; sfca = FCa_INF-(FCa_INF-sfca)*exptaufca; if(sfca>fcaold && (svolt)>-37.0) sfca = fcaold; gold = sg; sg = G_INF-(G_INF-sg)*exptaug; if(sg>gold && (svolt)>-37.0) sg=gold; //update voltage rDY_[0] = svolt + dt*(-sItot); rDY_[11] = sfca; rDY_[12] = sg; rDY_[13] = Cai; rDY_[14] = CaSR; rDY_[15] = Nai; rDY_[16] = Ki; } void solve_model_ode_cpu_epi (real dt, real *sv, real stim_current) { real rY[NEQ], rDY[NEQ]; for(int i = 0; i < NEQ; i++) rY[i] = sv[i]; RHS_cpu_epi(rY, rDY, stim_current, dt); for(int i = 0; i < NEQ; i++) sv[i] = rDY[i]; } void RHS_cpu_epi(const real *sv, real *rDY_, real stim_current, real dt) { // State variables real svolt = sv[0]; real sm = sv[1]; real sh = sv[2]; real sj = sv[3]; real sxr1 = sv[4]; real sxr2 = sv[5]; real sxs = sv[6]; real ss = sv[7]; real sr = sv[8]; real sd = sv[9]; real sf = sv[10]; real sfca = sv[11]; real sg = sv[12]; real Cai = sv[13]; real CaSR = sv[14]; real Nai = sv[15]; real Ki = sv[16]; //External concentrations real Ko=5.4; real Cao=2.0; real Nao=140.0; //Intracellular volumes real Vc=0.016404; real Vsr=0.001094; //Calcium dynamics real Bufc=0.15f; real Kbufc=0.001f; real Bufsr=10.f; real Kbufsr=0.3f; real taufca=2.f; real taug=2.f; real Vmaxup=0.000425f; real Kup=0.00025f; //Constants const real R = 8314.472f; const real F = 96485.3415f; const real T =310.0f; real RTONF =(R*T)/F; //Cellular capacitance real CAPACITANCE=0.185; //Parameters for currents //Parameters for IKr real Gkr=0.096; //Parameters for Iks real pKNa=0.03; // [!] Epicardium cell real Gks=0.245; //Parameters for Ik1 real GK1=5.405; //Parameters for Ito // [!] Epicardium cell real Gto=0.294; //Parameters for INa real GNa=14.838; //Parameters for IbNa real GbNa=0.00029; //Parameters for INaK real KmK=1.0; real KmNa=40.0; real knak=1.362; //Parameters for ICaL real GCaL=0.000175; //Parameters for IbCa real GbCa=0.000592; //Parameters for INaCa real knaca=1000; real KmNai=87.5; real KmCa=1.38; real ksat=0.1; real n=0.35; //Parameters for IpCa real GpCa=0.825; real KpCa=0.0005; //Parameters for IpK; real GpK=0.0146; real parameters []={13.8994716023310,0.000314898731878021,0.000156213524980972,0.000500074781915997,0.266864980659979,0.210551078794501,0.0657802089893208,2.85046969353601,0.0146506603832578,2.33945156719839,1099.72957852790,0.000431840298681176,0.479647775253583,0.0184750516443378,0.00580287376612870,1.67786611618970e-05}; GNa=parameters[0]; GbNa=parameters[1]; GCaL=parameters[2]; GbCa=parameters[3]; Gto=parameters[4]; Gkr=parameters[5]; Gks=parameters[6]; GK1=parameters[7]; GpK=parameters[8]; knak=parameters[9]; knaca=parameters[10]; Vmaxup=parameters[11]; GpCa=parameters[12]; real arel=parameters[13]; real crel=parameters[14]; real Vleak=parameters[15]; real IKr; real IKs; real IK1; real Ito; real INa; real IbNa; real ICaL; real IbCa; real INaCa; real IpCa; real IpK; real INaK; real Irel; real Ileak; real dNai; real dKi; real dCai; real dCaSR; real A; // real BufferFactorc; // real BufferFactorsr; real SERCA; real Caisquare; real CaSRsquare; real CaCurrent; real CaSRCurrent; real fcaold; real gold; real Ek; real Ena; real Eks; real Eca; real CaCSQN; real bjsr; real cjsr; real CaBuf; real bc; real cc; real Ak1; real Bk1; real rec_iK1; real rec_ipK; real rec_iNaK; real AM; real BM; real AH_1; real BH_1; real AH_2; real BH_2; real AJ_1; real BJ_1; real AJ_2; real BJ_2; real M_INF; real H_INF; real J_INF; real TAU_M; real TAU_H; real TAU_J; real axr1; real bxr1; real axr2; real bxr2; real Xr1_INF; real Xr2_INF; real TAU_Xr1; real TAU_Xr2; real Axs; real Bxs; real Xs_INF; real TAU_Xs; real R_INF; real TAU_R; real S_INF; real TAU_S; real Ad; real Bd; real Cd; real TAU_D; real D_INF; real TAU_F; real F_INF; real FCa_INF; real G_INF; real inverseVcF2=1/(2*Vc*F); real inverseVcF=1./(Vc*F); real Kupsquare=Kup*Kup; // real BufcKbufc=Bufc*Kbufc; // real Kbufcsquare=Kbufc*Kbufc; // real Kbufc2=2*Kbufc; // real BufsrKbufsr=Bufsr*Kbufsr; // const real Kbufsrsquare=Kbufsr*Kbufsr; // const real Kbufsr2=2*Kbufsr; const real exptaufca=exp(-dt/taufca); const real exptaug=exp(-dt/taug); real sItot; //Needed to compute currents Ek=RTONF*(log((Ko/Ki))); Ena=RTONF*(log((Nao/Nai))); Eks=RTONF*(log((Ko+pKNa*Nao)/(Ki+pKNa*Nai))); Eca=0.5*RTONF*(log((Cao/Cai))); Ak1=0.1/(1.+exp(0.06*(svolt-Ek-200))); Bk1=(3.*exp(0.0002*(svolt-Ek+100))+ exp(0.1*(svolt-Ek-10)))/(1.+exp(-0.5*(svolt-Ek))); rec_iK1=Ak1/(Ak1+Bk1); rec_iNaK=(1./(1.+0.1245*exp(-0.1*svolt*F/(R*T))+0.0353*exp(-svolt*F/(R*T)))); rec_ipK=1./(1.+exp((25-svolt)/5.98)); //Compute currents INa=GNa*sm*sm*sm*sh*sj*(svolt-Ena); ICaL=GCaL*sd*sf*sfca*4*svolt*(F*F/(R*T))* (exp(2*svolt*F/(R*T))*Cai-0.341*Cao)/(exp(2*svolt*F/(R*T))-1.); Ito=Gto*sr*ss*(svolt-Ek); IKr=Gkr*sqrt(Ko/5.4)*sxr1*sxr2*(svolt-Ek); IKs=Gks*sxs*sxs*(svolt-Eks); IK1=GK1*rec_iK1*(svolt-Ek); INaCa=knaca*(1./(KmNai*KmNai*KmNai+Nao*Nao*Nao))*(1./(KmCa+Cao))* (1./(1+ksat*exp((n-1)*svolt*F/(R*T))))* (exp(n*svolt*F/(R*T))*Nai*Nai*Nai*Cao- exp((n-1)*svolt*F/(R*T))*Nao*Nao*Nao*Cai*2.5); INaK=knak*(Ko/(Ko+KmK))*(Nai/(Nai+KmNa))*rec_iNaK; IpCa=GpCa*Cai/(KpCa+Cai); IpK=GpK*rec_ipK*(svolt-Ek); IbNa=GbNa*(svolt-Ena); IbCa=GbCa*(svolt-Eca); //Determine total current (sItot) = IKr + IKs + IK1 + Ito + INa + IbNa + ICaL + IbCa + INaK + INaCa + IpCa + IpK + stim_current; //update concentrations Caisquare=Cai*Cai; CaSRsquare=CaSR*CaSR; CaCurrent=-(ICaL+IbCa+IpCa-2.0f*INaCa)*inverseVcF2*CAPACITANCE; A=arel*CaSRsquare/(0.0625f+CaSRsquare)+crel; Irel=A*sd*sg; Ileak=Vleak*(CaSR-Cai); SERCA=Vmaxup/(1.f+(Kupsquare/Caisquare)); CaSRCurrent=SERCA-Irel-Ileak; CaCSQN=Bufsr*CaSR/(CaSR+Kbufsr); dCaSR=dt*(Vc/Vsr)*CaSRCurrent; bjsr=Bufsr-CaCSQN-dCaSR-CaSR+Kbufsr; cjsr=Kbufsr*(CaCSQN+dCaSR+CaSR); CaSR=(sqrt(bjsr*bjsr+4.*cjsr)-bjsr)/2.; CaBuf=Bufc*Cai/(Cai+Kbufc); dCai=dt*(CaCurrent-CaSRCurrent); bc=Bufc-CaBuf-dCai-Cai+Kbufc; cc=Kbufc*(CaBuf+dCai+Cai); Cai=(sqrt(bc*bc+4*cc)-bc)/2; dNai=-(INa+IbNa+3*INaK+3*INaCa)*inverseVcF*CAPACITANCE; Nai+=dt*dNai; dKi=-(stim_current+IK1+Ito+IKr+IKs-2*INaK+IpK)*inverseVcF*CAPACITANCE; Ki+=dt*dKi; //compute steady state values and time constants AM=1./(1.+exp((-60.-svolt)/5.)); BM=0.1/(1.+exp((svolt+35.)/5.))+0.10/(1.+exp((svolt-50.)/200.)); TAU_M=AM*BM; M_INF=1./((1.+exp((-56.86-svolt)/9.03))*(1.+exp((-56.86-svolt)/9.03))); if (svolt>=-40.) { AH_1=0.; BH_1=(0.77/(0.13*(1.+exp(-(svolt+10.66)/11.1)))); TAU_H= 1.0/(AH_1+BH_1); } else { AH_2=(0.057*exp(-(svolt+80.)/6.8)); BH_2=(2.7*exp(0.079*svolt)+(3.1e5)*exp(0.3485*svolt)); TAU_H=1.0/(AH_2+BH_2); } H_INF=1./((1.+exp((svolt+71.55)/7.43))*(1.+exp((svolt+71.55)/7.43))); if(svolt>=-40.) { AJ_1=0.; BJ_1=(0.6*exp((0.057)*svolt)/(1.+exp(-0.1*(svolt+32.)))); TAU_J= 1.0/(AJ_1+BJ_1); } else { AJ_2=(((-2.5428e4)*exp(0.2444*svolt)-(6.948e-6)* exp(-0.04391*svolt))*(svolt+37.78)/ (1.+exp(0.311*(svolt+79.23)))); BJ_2=(0.02424*exp(-0.01052*svolt)/(1.+exp(-0.1378*(svolt+40.14)))); TAU_J= 1.0/(AJ_2+BJ_2); } J_INF=H_INF; Xr1_INF=1./(1.+exp((-26.-svolt)/7.)); axr1=450./(1.+exp((-45.-svolt)/10.)); bxr1=6./(1.+exp((svolt-(-30.))/11.5)); TAU_Xr1=axr1*bxr1; Xr2_INF=1./(1.+exp((svolt-(-88.))/24.)); axr2=3./(1.+exp((-60.-svolt)/20.)); bxr2=1.12/(1.+exp((svolt-60.)/20.)); TAU_Xr2=axr2*bxr2; Xs_INF=1./(1.+exp((-5.-svolt)/14.)); Axs=1100./(sqrt(1.+exp((-10.-svolt)/6))); Bxs=1./(1.+exp((svolt-60.)/20.)); TAU_Xs=Axs*Bxs; R_INF=1./(1.+exp((20-svolt)/6.)); S_INF=1./(1.+exp((svolt+20)/5.)); TAU_R=9.5*exp(-(svolt+40.)*(svolt+40.)/1800.)+0.8; TAU_S=85.*exp(-(svolt+45.)*(svolt+45.)/320.)+5./(1.+exp((svolt-20.)/5.))+3.; D_INF=1./(1.+exp((-5-svolt)/7.5)); Ad=1.4/(1.+exp((-35-svolt)/13))+0.25; Bd=1.4/(1.+exp((svolt+5)/5)); Cd=1./(1.+exp((50-svolt)/20)); TAU_D=Ad*Bd+Cd; F_INF=1./(1.+exp((svolt+20)/7)); //TAU_F=1125*exp(-(svolt+27)*(svolt+27)/300)+80+165/(1.+exp((25-svolt)/10)); TAU_F=1125*exp(-(svolt+27)*(svolt+27)/240)+80+165/(1.+exp((25-svolt)/10)); // Updated from CellML FCa_INF=(1./(1.+pow((Cai/0.000325),8))+ 0.1/(1.+exp((Cai-0.0005)/0.0001))+ 0.20/(1.+exp((Cai-0.00075)/0.0008))+ 0.23 )/1.46; if(Cai<0.00035) G_INF=1./(1.+pow((Cai/0.00035),6)); else G_INF=1./(1.+pow((Cai/0.00035),16)); //Update gates rDY_[1] = M_INF-(M_INF-sm)*exp(-dt/TAU_M); rDY_[2] = H_INF-(H_INF-sh)*exp(-dt/TAU_H); rDY_[3] = J_INF-(J_INF-sj)*exp(-dt/TAU_J); rDY_[4] = Xr1_INF-(Xr1_INF-sxr1)*exp(-dt/TAU_Xr1); rDY_[5] = Xr2_INF-(Xr2_INF-sxr2)*exp(-dt/TAU_Xr2); rDY_[6] = Xs_INF-(Xs_INF-sxs)*exp(-dt/TAU_Xs); rDY_[7] = S_INF-(S_INF-ss)*exp(-dt/TAU_S); rDY_[8] = R_INF-(R_INF-sr)*exp(-dt/TAU_R); rDY_[9] = D_INF-(D_INF-sd)*exp(-dt/TAU_D); rDY_[10] = F_INF-(F_INF-sf)*exp(-dt/TAU_F); fcaold= sfca; sfca = FCa_INF-(FCa_INF-sfca)*exptaufca; if(sfca>fcaold && (svolt)>-37.0) sfca = fcaold; gold = sg; sg = G_INF-(G_INF-sg)*exptaug; if(sg>gold && (svolt)>-37.0) sg=gold; //update voltage rDY_[0] = svolt + dt*(-sItot); rDY_[11] = sfca; rDY_[12] = sg; rDY_[13] = Cai; rDY_[14] = CaSR; rDY_[15] = Nai; rDY_[16] = Ki; }

private.c

#include "private.h" static timer linsysTimer; static pfloat totalSolveTime; char * getLinSysMethod(Data * d, Priv * p) { char * tmp = scs_malloc(sizeof(char) * 64); sprintf(tmp, "sparse-direct, nnz in A = %li", (long) d->A->p[d->n]); return tmp; } char * getLinSysSummary(Priv * p, Info * info) { char * str = scs_malloc(sizeof(char) * 64); idxint n = p->L->n; sprintf(str, "\tLin-sys: nnz in L factor: %li, avg solve time: %1.2es\n", (long ) (p->L->p[n] + n), totalSolveTime / (info->iter + 1) / 1e3); totalSolveTime = 0; return str; } void freePriv(Priv * p) { if (p) { if (p->L) cs_spfree(p->L); if (p->P) scs_free(p->P); if (p->D) scs_free(p->D); if (p->bp) scs_free(p->bp); scs_free(p); } } cs * formKKT(Data * d) { /* ONLY UPPER TRIANGULAR PART IS STUFFED * forms column compressed KKT matrix * assumes column compressed form A matrix * * forms upper triangular part of [I A'; A -I] */ idxint j, k, kk; cs * K_cs; AMatrix * A = d->A; /* I at top left */ const idxint Anz = A->p[d->n]; const idxint Knzmax = d->n + d->m + Anz; cs * K = cs_spalloc(d->m + d->n, d->m + d->n, Knzmax, 1, 1); #ifdef EXTRAVERBOSE scs_printf("forming KKT\n"); #endif if (!K) { return NULL; } kk = 0; for (k = 0; k < d->n; k++) { K->i[kk] = k; K->p[kk] = k; K->x[kk] = d->RHO_X; kk++; } /* A^T at top right : CCS: */ for (j = 0; j < d->n; j++) { for (k = A->p[j]; k < A->p[j + 1]; k++) { K->p[kk] = A->i[k] + d->n; K->i[kk] = j; K->x[kk] = A->x[k]; kk++; } } /* -I at bottom right */ for (k = 0; k < d->m; k++) { K->i[kk] = k + d->n; K->p[kk] = k + d->n; K->x[kk] = -1; kk++; } /* assert kk == Knzmax */ K->nz = Knzmax; K_cs = cs_compress(K); cs_spfree(K); return (K_cs); } idxint LDLInit(cs * A, idxint P[], pfloat **info) { *info = (pfloat *) scs_malloc(AMD_INFO * sizeof(pfloat)); #ifdef DLONG return(amd_l_order(A->n, A->p, A->i, P, (pfloat *) NULL, *info)); #else return (amd_order(A->n, A->p, A->i, P, (pfloat *) NULL, *info)); #endif } idxint LDLFactor(cs * A, idxint P[], idxint Pinv[], cs **L, pfloat **D) { idxint kk, n = A->n; idxint * Parent = scs_malloc(n * sizeof(idxint)); idxint * Lnz = scs_malloc(n * sizeof(idxint)); idxint * Flag = scs_malloc(n * sizeof(idxint)); idxint * Pattern = scs_malloc(n * sizeof(idxint)); pfloat * Y = scs_malloc(n * sizeof(pfloat)); (*L)->p = (idxint *) scs_malloc((1 + n) * sizeof(idxint)); /*idxint Parent[n], Lnz[n], Flag[n], Pattern[n]; */ /*pfloat Y[n]; */ LDL_symbolic(n, A->p, A->i, (*L)->p, Parent, Lnz, Flag, P, Pinv); (*L)->nzmax = *((*L)->p + n); (*L)->x = (pfloat *) scs_malloc((*L)->nzmax * sizeof(pfloat)); (*L)->i = (idxint *) scs_malloc((*L)->nzmax * sizeof(idxint)); *D = (pfloat *) scs_malloc(n * sizeof(pfloat)); if (!(*D) || !(*L)->i || !(*L)->x || !Y || !Pattern || !Flag || !Lnz || !Parent) return -1; #ifdef EXTRAVERBOSE scs_printf("numeric factorization\n"); #endif kk = LDL_numeric(n, A->p, A->i, A->x, (*L)->p, Parent, Lnz, (*L)->i, (*L)->x, *D, Y, Pattern, Flag, P, Pinv); #ifdef EXTRAVERBOSE scs_printf("finished numeric factorization\n"); #endif scs_free(Parent); scs_free(Lnz); scs_free(Flag); scs_free(Pattern); scs_free(Y); return (n - kk); } void LDLSolve(pfloat *x, pfloat b[], cs * L, pfloat D[], idxint P[], pfloat * bp) { /* solves PLDL'P' x = b for x */ idxint n = L->n; if (P == NULL) { if (x != b) /* if they're different addresses */ memcpy(x, b, n * sizeof(pfloat)); LDL_lsolve(n, x, L->p, L->i, L->x); LDL_dsolve(n, x, D); LDL_ltsolve(n, x, L->p, L->i, L->x); } else { LDL_perm(n, bp, b, P); LDL_lsolve(n, bp, L->p, L->i, L->x); LDL_dsolve(n, bp, D); LDL_ltsolve(n, bp, L->p, L->i, L->x); LDL_permt(n, x, bp, P); } } void _accumByAtrans(idxint n, pfloat * Ax, idxint * Ai, idxint * Ap, const pfloat *x, pfloat *y) { /* y = A'*x A in column compressed format parallelizes over columns (rows of A') */ idxint p, j; idxint c1, c2; pfloat yj; #ifdef OPENMP #pragma omp parallel for private(p,c1,c2,yj) #endif for (j = 0; j < n; j++) { yj = y[j]; c1 = Ap[j]; c2 = Ap[j + 1]; for (p = c1; p < c2; p++) { yj += Ax[p] * x[Ai[p]]; } y[j] = yj; } } void _accumByA(idxint n, pfloat * Ax, idxint * Ai, idxint * Ap, const pfloat *x, pfloat *y) { /*y = A*x A in column compressed format this parallelizes over columns and uses pragma atomic to prevent concurrent writes to y */ idxint p, j; idxint c1, c2; pfloat xj; /*#pragma omp parallel for private(p,c1,c2,xj) */ for (j = 0; j < n; j++) { xj = x[j]; c1 = Ap[j]; c2 = Ap[j + 1]; for (p = c1; p < c2; p++) { /*#pragma omp atomic */ y[Ai[p]] += Ax[p] * xj; } } } void accumByAtrans(Data * d, Priv * p, const pfloat *x, pfloat *y) { AMatrix * A = d->A; _accumByAtrans(d->n, A->x, A->i, A->p, x, y); } void accumByA(Data * d, Priv * p, const pfloat *x, pfloat *y) { AMatrix * A = d->A; _accumByA(d->n, A->x, A->i, A->p, x, y); } idxint factorize(Data * d, Priv * p) { pfloat *info; idxint *Pinv, amd_status, ldl_status; cs *C, *K = formKKT(d); if (!K) { return -1; } amd_status = LDLInit(K, p->P, &info); if (amd_status < 0) return (amd_status); #ifdef EXTRAVERBOSE if(d->VERBOSE) { scs_printf("Matrix factorization info:\n"); #ifdef DLONG amd_l_info(info); #else amd_info(info); #endif } #endif Pinv = cs_pinv(p->P, d->n + d->m); C = cs_symperm(K, Pinv, 1); ldl_status = LDLFactor(C, NULL, NULL, &p->L, &p->D); cs_spfree(C); cs_spfree(K); scs_free(Pinv); scs_free(info); return (ldl_status); } Priv * initPriv(Data * d) { Priv * p = scs_calloc(1, sizeof(Priv)); idxint n_plus_m = d->n + d->m; p->P = scs_malloc(sizeof(idxint) * n_plus_m); p->L = scs_malloc(sizeof(cs)); p->bp = scs_malloc(n_plus_m * sizeof(pfloat)); p->L->m = n_plus_m; p->L->n = n_plus_m; p->L->nz = -1; if (factorize(d, p) < 0) { freePriv(p); return NULL; } totalSolveTime = 0.0; return p; } idxint solveLinSys(Data * d, Priv * p, pfloat * b, const pfloat * s, idxint iter) { /* returns solution to linear system */ /* Ax = b with solution stored in b */ tic(&linsysTimer); LDLSolve(b, b, p->L, p->D, p->P, p->bp); totalSolveTime += tocq(&linsysTimer); #ifdef EXTRAVERBOSE scs_printf("linsys solve time: %1.2es\n", tocq(&linsysTimer) / 1e3); #endif return 0; }

task_late_fulfill.c

// RUN: %libomp-compile -fopenmp-version=50 && env OMP_NUM_THREADS='3' \ // RUN: %libomp-run | %sort-threads | FileCheck %s // REQUIRES: ompt // Checked gcc 10.1 still does not support detach clause on task construct. // UNSUPPORTED: gcc-4, gcc-5, gcc-6, gcc-7, gcc-8, gcc-9, gcc-10 // clang supports detach clause since version 11. // UNSUPPORTED: clang-10, clang-9, clang-8, clang-7 // icc compiler does not support detach clause. // UNSUPPORTED: icc #include "callback.h" #include <omp.h> int main() { #pragma omp parallel #pragma omp master { omp_event_handle_t event; omp_event_handle_t *f_event; #pragma omp task detach(event) depend(out : f_event) shared(f_event) if (0) { printf("task 1\n"); f_event = &event; } #pragma omp task depend(in : f_event) { printf("task 2\n"); } printf("calling omp_fulfill_event\n"); omp_fulfill_event(*f_event); #pragma omp taskwait } return 0; } // Check if libomp supports the callbacks for this test. // CHECK-NOT: {{^}}0: Could not register callback 'ompt_callback_task_create' // CHECK-NOT: {{^}}0: Could not register callback 'ompt_callback_task_schedule' // CHECK-NOT: {{^}}0: Could not register callback 'ompt_callback_parallel_begin' // CHECK-NOT: {{^}}0: Could not register callback 'ompt_callback_parallel_end' // CHECK-NOT: {{^}}0: Could not register callback 'ompt_callback_implicit_task' // CHECK-NOT: {{^}}0: Could not register callback 'ompt_callback_mutex_acquire' // CHECK-NOT: {{^}}0: Could not register callback 'ompt_callback_mutex_acquired' // CHECK-NOT: {{^}}0: Could not register callback 'ompt_callback_mutex_released' // CHECK: {{^}}0: NULL_POINTER=[[NULL:.*$]] // CHECK: {{^}}[[MASTER_ID:[0-9]+]]: ompt_event_parallel_begin: // CHECK-SAME: parent_task_id=[[PARENT_TASK_ID:[0-9]+]], // CHECK-SAME: parent_task_frame.exit=[[NULL]], // CHECK-SAME: parent_task_frame.reenter=0x{{[0-f]+}}, // CHECK-SAME: parallel_id=[[PARALLEL_ID:[0-9]+]], // CHECK-SAME: requested_team_size=3, // CHECK: {{^}}[[MASTER_ID]]: ompt_event_implicit_task_begin: // CHECK-SAME: parallel_id=[[PARALLEL_ID]], // CHECK-SAME: task_id=[[IMPLICIT_TASK_ID:[0-9]+]] // The following is to match the taskwait task created in __kmpc_omp_wait_deps // this should go away, once codegen for "detached if(0)" is fixed // CHECK: {{^}}[[MASTER_ID]]: ompt_event_task_create: // CHECK-SAME: parent_task_id=[[IMPLICIT_TASK_ID]], // CHECK-SAME: has_dependences=yes // CHECK: {{^}}[[MASTER_ID]]: ompt_event_task_create: // CHECK-SAME: parent_task_id=[[IMPLICIT_TASK_ID]], // CHECK-SAME: parent_task_frame.exit=0x{{[0-f]+}}, // CHECK-SAME: parent_task_frame.reenter=0x{{[0-f]+}}, // CHECK-SAME: new_task_id=[[TASK_ID:[0-9]+]], // CHECK: {{^}}[[MASTER_ID:[0-9]+]]: ompt_event_task_schedule: // CHECK-SAME: first_task_id=[[IMPLICIT_TASK_ID]], // CHECK-SAME: second_task_id=[[TASK_ID]], // CHECK-SAME: prior_task_status=ompt_task_switch=7 // CHECK: {{^}}[[MASTER_ID:[0-9]+]]: ompt_event_task_schedule: // CHECK-SAME: first_task_id=[[TASK_ID]], // CHECK-SAME: second_task_id=[[IMPLICIT_TASK_ID]], // CHECK-SAME: prior_task_status=ompt_task_detach=4 // CHECK: {{^}}[[MASTER_ID:[0-9]+]]: ompt_event_task_schedule: // CHECK-SAME: first_task_id=[[TASK_ID]], // CHECK-SAME: second_task_id=18446744073709551615, // CHECK-SAME: prior_task_status=ompt_task_late_fulfill=6