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ncnn / src /layer /vulkan /binaryop_vulkan.cpp
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 // Tencent is pleased to support the open source community by making ncnn available.
//
// Copyright (C) 2019 THL A29 Limited, a Tencent company. All rights reserved.
//
// Licensed under the BSD 3-Clause License (the "License"); you may not use this file except
// in compliance with the License. You may obtain a copy of the License at
//
// https://opensource.org/licenses/BSD-3-Clause
//
// 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 "binaryop_vulkan.h"
#include "layer_shader_type.h"
#include <math.h>
namespace ncnn {
BinaryOp_vulkan::BinaryOp_vulkan()
{
support_vulkan = true;
support_image_storage = true;
pipeline_binaryop = 0;
pipeline_binaryop_pack4 = 0;
pipeline_binaryop_pack8 = 0;
pipeline_binaryop_broadcast[0] = 0;
pipeline_binaryop_broadcast[1] = 0;
pipeline_binaryop_broadcast_pack4[0] = 0;
pipeline_binaryop_broadcast_pack4[1] = 0;
pipeline_binaryop_broadcast_pack1to4[0] = 0;
pipeline_binaryop_broadcast_pack1to4[1] = 0;
pipeline_binaryop_broadcast_pack8[0] = 0;
pipeline_binaryop_broadcast_pack8[1] = 0;
pipeline_binaryop_broadcast_pack1to8[0] = 0;
pipeline_binaryop_broadcast_pack1to8[1] = 0;
}
static int get_reverse_op_type(int op_type)
{
if (op_type == BinaryOp::Operation_SUB) return BinaryOp::Operation_RSUB;
if (op_type == BinaryOp::Operation_DIV) return BinaryOp::Operation_RDIV;
if (op_type == BinaryOp::Operation_POW) return BinaryOp::Operation_RPOW;
if (op_type == BinaryOp::Operation_ATAN2) return BinaryOp::Operation_RATAN2;
if (op_type == BinaryOp::Operation_RSUB) return BinaryOp::Operation_SUB;
if (op_type == BinaryOp::Operation_RDIV) return BinaryOp::Operation_DIV;
if (op_type == BinaryOp::Operation_RPOW) return BinaryOp::Operation_POW;
if (op_type == BinaryOp::Operation_RATAN2) return BinaryOp::Operation_ATAN2;
return op_type;
}
int BinaryOp_vulkan::create_pipeline(const Option& opt)
{
const Mat& A_shape = bottom_shapes.empty() ? Mat() : bottom_shapes[0];
const Mat& B_shape = with_scalar ? A_shape : bottom_shapes.empty() ? Mat() : bottom_shapes[1];
const Mat& out_shape = top_shapes.empty() ? Mat() : top_shapes[0];
int A_elempack = 1;
if (A_shape.dims == 1) A_elempack = opt.use_shader_pack8 && A_shape.w % 8 == 0 ? 8 : A_shape.w % 4 == 0 ? 4 : 1;
if (A_shape.dims == 2) A_elempack = opt.use_shader_pack8 && A_shape.h % 8 == 0 ? 8 : A_shape.h % 4 == 0 ? 4 : 1;
if (A_shape.dims == 3 || A_shape.dims == 4) A_elempack = opt.use_shader_pack8 && A_shape.c % 8 == 0 ? 8 : A_shape.c % 4 == 0 ? 4 : 1;
int B_elempack = 1;
if (B_shape.dims == 1) B_elempack = opt.use_shader_pack8 && B_shape.w % 8 == 0 ? 8 : B_shape.w % 4 == 0 ? 4 : 1;
if (B_shape.dims == 2) B_elempack = opt.use_shader_pack8 && B_shape.h % 8 == 0 ? 8 : B_shape.h % 4 == 0 ? 4 : 1;
if (B_shape.dims == 3 || B_shape.dims == 4) B_elempack = opt.use_shader_pack8 && B_shape.c % 8 == 0 ? 8 : B_shape.c % 4 == 0 ? 4 : 1;
int out_elempack = 1;
if (out_shape.dims == 1) out_elempack = opt.use_shader_pack8 && out_shape.w % 8 == 0 ? 8 : out_shape.w % 4 == 0 ? 4 : 1;
if (out_shape.dims == 2) out_elempack = opt.use_shader_pack8 && out_shape.h % 8 == 0 ? 8 : out_shape.h % 4 == 0 ? 4 : 1;
if (out_shape.dims == 3 || out_shape.dims == 4) out_elempack = opt.use_shader_pack8 && out_shape.c % 8 == 0 ? 8 : out_shape.c % 4 == 0 ? 4 : 1;
size_t A_elemsize;
size_t B_elemsize;
size_t out_elemsize;
if (opt.use_fp16_storage)
{
A_elemsize = A_elempack * 2u;
B_elemsize = B_elempack * 2u;
out_elemsize = out_elempack * 2u;
}
else if (opt.use_fp16_packed)
{
A_elemsize = A_elempack == 1 ? 4u : A_elempack * 2u;
B_elemsize = B_elempack == 1 ? 4u : B_elempack * 2u;
out_elemsize = out_elempack == 1 ? 4u : out_elempack * 2u;
}
else
{
A_elemsize = A_elempack * 4u;
B_elemsize = B_elempack * 4u;
out_elemsize = out_elempack * 4u;
}
Mat A_shape_packed;
if (A_shape.dims == 1) A_shape_packed = Mat(A_shape.w / A_elempack, (void*)0, A_elemsize, A_elempack);
if (A_shape.dims == 2) A_shape_packed = Mat(A_shape.w, A_shape.h / A_elempack, (void*)0, A_elemsize, A_elempack);
if (A_shape.dims == 3) A_shape_packed = Mat(A_shape.w, A_shape.h, A_shape.c / A_elempack, (void*)0, A_elemsize, A_elempack);
if (A_shape.dims == 4) A_shape_packed = Mat(A_shape.w, A_shape.h, A_shape.d, A_shape.c / A_elempack, (void*)0, A_elemsize, A_elempack);
Mat B_shape_packed;
if (B_shape.dims == 1) B_shape_packed = Mat(B_shape.w / B_elempack, (void*)0, B_elemsize, B_elempack);
if (B_shape.dims == 2) B_shape_packed = Mat(B_shape.w, B_shape.h / B_elempack, (void*)0, B_elemsize, B_elempack);
if (B_shape.dims == 3) B_shape_packed = Mat(B_shape.w, B_shape.h, B_shape.c / B_elempack, (void*)0, B_elemsize, B_elempack);
if (B_shape.dims == 4) B_shape_packed = Mat(B_shape.w, B_shape.h, B_shape.d, B_shape.c / B_elempack, (void*)0, B_elemsize, B_elempack);
Mat out_shape_packed;
if (out_shape.dims == 1) out_shape_packed = Mat(out_shape.w / out_elempack, (void*)0, out_elemsize, out_elempack);
if (out_shape.dims == 2) out_shape_packed = Mat(out_shape.w, out_shape.h / out_elempack, (void*)0, out_elemsize, out_elempack);
if (out_shape.dims == 3) out_shape_packed = Mat(out_shape.w, out_shape.h, out_shape.c / out_elempack, (void*)0, out_elemsize, out_elempack);
if (out_shape.dims == 4) out_shape_packed = Mat(out_shape.w, out_shape.h, out_shape.d, out_shape.c / out_elempack, (void*)0, out_elemsize, out_elempack);
bool broadcast = true;
if (A_shape.dims == B_shape.dims && A_shape.w == B_shape.w && A_shape.h == B_shape.h && A_shape.d == B_shape.d && A_shape.c == B_shape.c)
{
broadcast = false;
}
// no broadcast
if (out_shape.dims == 0 || !broadcast)
{
std::vector<vk_specialization_type> specializations(3 + 15);
specializations[0].i = op_type;
specializations[1].i = with_scalar;
specializations[2].f = b;
specializations[3 + 0].i = A_shape_packed.dims;
specializations[3 + 1].i = A_shape_packed.w;
specializations[3 + 2].i = A_shape_packed.h * A_shape_packed.d;
specializations[3 + 3].i = A_shape_packed.c;
specializations[3 + 4].i = A_shape_packed.cstep;
specializations[3 + 5].i = B_shape_packed.dims;
specializations[3 + 6].i = B_shape_packed.w;
specializations[3 + 7].i = B_shape_packed.h * B_shape_packed.d;
specializations[3 + 8].i = B_shape_packed.c;
specializations[3 + 9].i = B_shape_packed.cstep;
specializations[3 + 10].i = out_shape_packed.dims;
specializations[3 + 11].i = out_shape_packed.w;
specializations[3 + 12].i = out_shape_packed.h * out_shape_packed.d;
specializations[3 + 13].i = out_shape_packed.c;
specializations[3 + 14].i = out_shape_packed.cstep;
Mat local_size_xyz;
if (out_shape_packed.dims == 1)
{
local_size_xyz.w = std::min(64, out_shape_packed.w);
local_size_xyz.h = 1;
local_size_xyz.c = 1;
}
if (out_shape_packed.dims == 2)
{
local_size_xyz.w = std::min(8, out_shape_packed.w);
local_size_xyz.h = std::min(8, out_shape_packed.h);
local_size_xyz.c = 1;
}
if (out_shape_packed.dims == 3)
{
local_size_xyz.w = std::min(4, out_shape_packed.w);
local_size_xyz.h = std::min(4, out_shape_packed.h);
local_size_xyz.c = std::min(4, out_shape_packed.c);
}
if (out_shape_packed.dims == 4)
{
local_size_xyz.w = std::min(4, out_shape_packed.w);
local_size_xyz.h = std::min(4, out_shape_packed.h * out_shape_packed.d);
local_size_xyz.c = std::min(4, out_shape_packed.c);
}
// pack1
if (out_shape.dims == 0 || out_elempack == 1)
{
pipeline_binaryop = new Pipeline(vkdev);
pipeline_binaryop->set_optimal_local_size_xyz(local_size_xyz);
pipeline_binaryop->create(LayerShaderType::binaryop, opt, specializations);
}
// pack4
if (out_shape.dims == 0 || out_elempack == 4)
{
pipeline_binaryop_pack4 = new Pipeline(vkdev);
pipeline_binaryop_pack4->set_optimal_local_size_xyz(local_size_xyz);
pipeline_binaryop_pack4->create(LayerShaderType::binaryop_pack4, opt, specializations);
}
// pack8
if ((opt.use_shader_pack8 && out_shape.dims == 0) || out_elempack == 8)
{
pipeline_binaryop_pack8 = new Pipeline(vkdev);
pipeline_binaryop_pack8->set_optimal_local_size_xyz(local_size_xyz);
pipeline_binaryop_pack8->create(LayerShaderType::binaryop_pack8, opt, specializations);
}
}
// broadcast
if (out_shape.dims == 0 || broadcast)
{
if (A_shape.dims > 0 && B_shape.dims > 0)
{
const bool a_rank_is_lower = A_shape.dims < B_shape.dims;
const bool a_rank_is_equal = A_shape.dims == B_shape.dims;
const bool a_pack_is_lower = A_elempack < B_elempack;
const bool a_pack_is_equal = A_elempack == B_elempack;
const bool a_size_is_lower = A_shape.w * A_shape.h * A_shape.d * A_shape.c < B_shape.w * B_shape.h * B_shape.d * B_shape.c;
if (a_rank_is_lower || (a_rank_is_equal && a_pack_is_lower) || (a_pack_is_equal && a_size_is_lower))
{
// swap AB
std::swap(A_shape_packed, B_shape_packed);
}
if (B_shape_packed.dims == 1 && ((A_shape_packed.dims == 2 && B_shape_packed.w * B_shape_packed.elempack != A_shape_packed.h * A_shape_packed.elempack) || ((A_shape_packed.dims == 3 || A_shape_packed.dims == 4) && B_shape_packed.w * B_shape_packed.elempack != A_shape_packed.c * A_shape_packed.elempack)))
{
B_shape_packed.dims = out_shape.dims;
B_shape_packed.w = B_shape_packed.w * B_shape_packed.elempack;
B_shape_packed.elempack = 1;
}
}
const int op_type_r = get_reverse_op_type(op_type);
std::vector<vk_specialization_type> specializations(1 + 18);
specializations[0].i = op_type;
specializations[1 + 0].i = A_shape_packed.dims;
specializations[1 + 1].i = A_shape_packed.w;
specializations[1 + 2].i = A_shape_packed.h;
specializations[1 + 3].i = A_shape_packed.d;
specializations[1 + 4].i = A_shape_packed.c;
specializations[1 + 5].i = A_shape_packed.cstep;
specializations[1 + 6].i = B_shape_packed.dims;
specializations[1 + 7].i = B_shape_packed.w;
specializations[1 + 8].i = B_shape_packed.h;
specializations[1 + 9].i = B_shape_packed.d;
specializations[1 + 10].i = B_shape_packed.c;
specializations[1 + 11].i = B_shape_packed.cstep;
specializations[1 + 12].i = out_shape_packed.dims;
specializations[1 + 13].i = out_shape_packed.w;
specializations[1 + 14].i = out_shape_packed.h;
specializations[1 + 15].i = out_shape_packed.d;
specializations[1 + 16].i = out_shape_packed.c;
specializations[1 + 17].i = out_shape_packed.cstep;
std::vector<vk_specialization_type> specializations_r(1 + 18);
specializations_r[0].i = op_type_r;
specializations_r[1 + 0].i = A_shape_packed.dims;
specializations_r[1 + 1].i = A_shape_packed.w;
specializations_r[1 + 2].i = A_shape_packed.h;
specializations_r[1 + 3].i = A_shape_packed.d;
specializations_r[1 + 4].i = A_shape_packed.c;
specializations_r[1 + 5].i = A_shape_packed.cstep;
specializations_r[1 + 6].i = B_shape_packed.dims;
specializations_r[1 + 7].i = B_shape_packed.w;
specializations_r[1 + 8].i = B_shape_packed.h;
specializations_r[1 + 9].i = B_shape_packed.d;
specializations_r[1 + 10].i = B_shape_packed.c;
specializations_r[1 + 11].i = B_shape_packed.cstep;
specializations_r[1 + 12].i = out_shape_packed.dims;
specializations_r[1 + 13].i = out_shape_packed.w;
specializations_r[1 + 14].i = out_shape_packed.h;
specializations_r[1 + 15].i = out_shape_packed.d;
specializations_r[1 + 16].i = out_shape_packed.c;
specializations_r[1 + 17].i = out_shape_packed.cstep;
Mat local_size_xyz;
if (out_shape_packed.dims == 1)
{
local_size_xyz.w = std::min(64, out_shape_packed.w);
local_size_xyz.h = 1;
local_size_xyz.c = 1;
}
if (out_shape_packed.dims == 2)
{
local_size_xyz.w = std::min(8, out_shape_packed.w);
local_size_xyz.h = std::min(8, out_shape_packed.h);
local_size_xyz.c = 1;
}
if (out_shape_packed.dims == 3)
{
local_size_xyz.w = std::min(4, out_shape_packed.w);
local_size_xyz.h = std::min(4, out_shape_packed.h);
local_size_xyz.c = std::min(4, out_shape_packed.c);
}
if (out_shape_packed.dims == 4)
{
local_size_xyz.w = std::min(4, out_shape_packed.w);
local_size_xyz.h = std::min(4, out_shape_packed.h * out_shape_packed.d);
local_size_xyz.c = std::min(4, out_shape_packed.c);
}
// pack1
if (out_shape.dims == 0 || (out_elempack == 1))
{
pipeline_binaryop_broadcast[0] = new Pipeline(vkdev);
pipeline_binaryop_broadcast[0]->set_optimal_local_size_xyz(local_size_xyz);
pipeline_binaryop_broadcast[0]->create(LayerShaderType::binaryop_broadcast, opt, specializations);
if (op_type_r != op_type)
{
// sub div pow ...
pipeline_binaryop_broadcast[1] = new Pipeline(vkdev);
pipeline_binaryop_broadcast[1]->set_optimal_local_size_xyz(local_size_xyz);
pipeline_binaryop_broadcast[1]->create(LayerShaderType::binaryop_broadcast, opt, specializations_r);
}
}
// pack4
if (out_shape.dims == 0 || (A_shape_packed.elempack == 4 && B_shape_packed.elempack == 4 && out_elempack == 4))
{
pipeline_binaryop_broadcast_pack4[0] = new Pipeline(vkdev);
pipeline_binaryop_broadcast_pack4[0]->set_optimal_local_size_xyz(local_size_xyz);
pipeline_binaryop_broadcast_pack4[0]->create(LayerShaderType::binaryop_broadcast_pack4, opt, specializations);
if (op_type_r != op_type)
{
// sub div pow ...
pipeline_binaryop_broadcast_pack4[1] = new Pipeline(vkdev);
pipeline_binaryop_broadcast_pack4[1]->set_optimal_local_size_xyz(local_size_xyz);
pipeline_binaryop_broadcast_pack4[1]->create(LayerShaderType::binaryop_broadcast_pack4, opt, specializations_r);
}
}
// pack1to4
if (out_shape.dims == 0 || ((A_shape_packed.elempack == 1 || B_shape_packed.elempack == 1) && out_elempack == 4))
{
pipeline_binaryop_broadcast_pack1to4[0] = new Pipeline(vkdev);
pipeline_binaryop_broadcast_pack1to4[0]->set_optimal_local_size_xyz(local_size_xyz);
pipeline_binaryop_broadcast_pack1to4[0]->create(LayerShaderType::binaryop_broadcast_pack1to4, opt, specializations);
if (op_type_r != op_type)
{
// sub div pow ...
pipeline_binaryop_broadcast_pack1to4[1] = new Pipeline(vkdev);
pipeline_binaryop_broadcast_pack1to4[1]->set_optimal_local_size_xyz(local_size_xyz);
pipeline_binaryop_broadcast_pack1to4[1]->create(LayerShaderType::binaryop_broadcast_pack1to4, opt, specializations_r);
}
}
// pack8
if ((opt.use_shader_pack8 && out_shape.dims == 0) || (A_shape_packed.elempack == 8 && B_shape_packed.elempack == 8 && out_elempack == 8))
{
pipeline_binaryop_broadcast_pack8[0] = new Pipeline(vkdev);
pipeline_binaryop_broadcast_pack8[0]->set_optimal_local_size_xyz(local_size_xyz);
pipeline_binaryop_broadcast_pack8[0]->create(LayerShaderType::binaryop_broadcast_pack8, opt, specializations);
if (op_type_r != op_type)
{
// sub div pow ...
pipeline_binaryop_broadcast_pack8[1] = new Pipeline(vkdev);
pipeline_binaryop_broadcast_pack8[1]->set_optimal_local_size_xyz(local_size_xyz);
pipeline_binaryop_broadcast_pack8[1]->create(LayerShaderType::binaryop_broadcast_pack8, opt, specializations_r);
}
}
// pack1to8
if ((opt.use_shader_pack8 && out_shape.dims == 0) || ((A_shape_packed.elempack == 1 || B_shape_packed.elempack == 1) && out_elempack == 8))
{
pipeline_binaryop_broadcast_pack1to8[0] = new Pipeline(vkdev);
pipeline_binaryop_broadcast_pack1to8[0]->set_optimal_local_size_xyz(local_size_xyz);
pipeline_binaryop_broadcast_pack1to8[0]->create(LayerShaderType::binaryop_broadcast_pack1to8, opt, specializations);
if (op_type_r != op_type)
{
// sub div pow ...
pipeline_binaryop_broadcast_pack1to8[1] = new Pipeline(vkdev);
pipeline_binaryop_broadcast_pack1to8[1]->set_optimal_local_size_xyz(local_size_xyz);
pipeline_binaryop_broadcast_pack1to8[1]->create(LayerShaderType::binaryop_broadcast_pack1to8, opt, specializations_r);
}
}
}
return 0;
}
int BinaryOp_vulkan::destroy_pipeline(const Option& /*opt*/)
{
delete pipeline_binaryop;
pipeline_binaryop = 0;
delete pipeline_binaryop_pack4;
pipeline_binaryop_pack4 = 0;
delete pipeline_binaryop_pack8;
pipeline_binaryop_pack8 = 0;
delete pipeline_binaryop_broadcast[0];
delete pipeline_binaryop_broadcast[1];
pipeline_binaryop_broadcast[0] = 0;
pipeline_binaryop_broadcast[1] = 0;
delete pipeline_binaryop_broadcast_pack4[0];
delete pipeline_binaryop_broadcast_pack4[1];
pipeline_binaryop_broadcast_pack4[0] = 0;
pipeline_binaryop_broadcast_pack4[1] = 0;
delete pipeline_binaryop_broadcast_pack1to4[0];
delete pipeline_binaryop_broadcast_pack1to4[1];
pipeline_binaryop_broadcast_pack1to4[0] = 0;
pipeline_binaryop_broadcast_pack1to4[1] = 0;
delete pipeline_binaryop_broadcast_pack1to8[0];
delete pipeline_binaryop_broadcast_pack1to8[1];
pipeline_binaryop_broadcast_pack1to8[0] = 0;
pipeline_binaryop_broadcast_pack1to8[1] = 0;
delete pipeline_binaryop_broadcast_pack1to8[0];
delete pipeline_binaryop_broadcast_pack1to8[1];
pipeline_binaryop_broadcast_pack1to8[0] = 0;
pipeline_binaryop_broadcast_pack1to8[1] = 0;
return 0;
}
int BinaryOp_vulkan::forward(const std::vector<VkMat>& bottom_blobs, std::vector<VkMat>& top_blobs, VkCompute& cmd, const Option& opt) const
{
const VkMat& A = bottom_blobs[0];
const VkMat& B = bottom_blobs[1];
const int outdims = std::max(A.dims, B.dims);
const bool a_rank_is_lower = A.dims < B.dims;
const bool b_rank_is_lower = B.dims < A.dims;
const bool a_rank_is_equal = A.dims == B.dims;
VkMat& top_blob = top_blobs[0];
if (a_rank_is_lower)
{
top_blob.create_like(B, opt.blob_vkallocator);
}
else if (b_rank_is_lower)
{
top_blob.create_like(A, opt.blob_vkallocator);
}
else
{
const int outw = std::max(A.w, B.w);
const int outh = std::max(A.h, B.h);
const int outd = std::max(A.d, B.d);
const int outc = std::max(A.c, B.c);
const int out_elempack = std::max(A.elempack, B.elempack);
const size_t out_elemsize = std::max(A.elemsize, B.elemsize);
if (outdims == 1)
{
top_blob.create(outw, out_elemsize, out_elempack, opt.blob_vkallocator);
}
if (outdims == 2)
{
top_blob.create(outw, outh, out_elemsize, out_elempack, opt.blob_vkallocator);
}
if (outdims == 3)
{
top_blob.create(outw, outh, outc, out_elemsize, out_elempack, opt.blob_vkallocator);
}
if (outdims == 4)
{
top_blob.create(outw, outh, outd, outc, out_elemsize, out_elempack, opt.blob_vkallocator);
}
}
if (top_blob.empty())
return -100;
// no broadcast
if (A.dims == B.dims && A.w == B.w && A.h == B.h && A.d == B.d && A.c == B.c && A.elempack == B.elempack)
{
std::vector<VkMat> bindings(3);
bindings[0] = A;
bindings[1] = B;
bindings[2] = top_blob;
std::vector<vk_constant_type> constants(15);
constants[0].i = A.dims;
constants[1].i = A.w;
constants[2].i = A.h * A.d;
constants[3].i = A.c;
constants[4].i = A.cstep;
constants[5].i = B.dims;
constants[6].i = B.w;
constants[7].i = B.h * B.d;
constants[8].i = B.c;
constants[9].i = B.cstep;
constants[10].i = top_blob.dims;
constants[11].i = top_blob.w;
constants[12].i = top_blob.h * top_blob.d;
constants[13].i = top_blob.c;
constants[14].i = top_blob.cstep;
const Pipeline* pipeline = top_blob.elempack == 8 ? pipeline_binaryop_pack8
: top_blob.elempack == 4 ? pipeline_binaryop_pack4
: pipeline_binaryop;
cmd.record_pipeline(pipeline, bindings, constants, top_blob);
return 0;
}
const bool a_pack_is_lower = A.elempack < B.elempack;
const bool a_pack_is_equal = A.elempack == B.elempack;
const bool a_size_is_lower = A.w * A.h * A.d * A.c * A.elempack < B.w * B.h * B.d * B.c * B.elempack;
if (a_rank_is_lower || (a_rank_is_equal && a_pack_is_lower) || (a_pack_is_equal && a_size_is_lower))
{
VkMat A2;
if (A.dims == 1 && ((B.dims == 2 && A.w * A.elempack != B.h * B.elempack) || ((B.dims == 3 || B.dims == 4) && A.w * A.elempack != B.c * B.elempack)))
{
vkdev->convert_packing(A, A2, 1, cmd, opt);
A2.dims = top_blob.dims;
}
else
{
A2 = A;
}
std::vector<VkMat> bindings(3);
bindings[0] = B;
bindings[1] = A2;
bindings[2] = top_blob;
std::vector<vk_constant_type> constants(18);
constants[0].i = B.dims;
constants[1].i = B.w;
constants[2].i = B.h;
constants[3].i = B.d;
constants[4].i = B.c;
constants[5].i = B.cstep;
constants[6].i = A2.dims;
constants[7].i = A2.w;
constants[8].i = A2.h;
constants[9].i = A2.d;
constants[10].i = A2.c;
constants[11].i = A2.cstep;
constants[12].i = top_blob.dims;
constants[13].i = top_blob.w;
constants[14].i = top_blob.h;
constants[15].i = top_blob.d;
constants[16].i = top_blob.c;
constants[17].i = top_blob.cstep;
const int ri = get_reverse_op_type(op_type) == op_type ? 0 : 1;
const Pipeline* pipeline = 0;
if (A2.elempack == 1 && top_blob.elempack == 1)
{
pipeline = pipeline_binaryop_broadcast[ri];
}
if (A2.elempack == 4 && top_blob.elempack == 4)
{
pipeline = pipeline_binaryop_broadcast_pack4[ri];
}
if (A2.elempack == 1 && top_blob.elempack == 4)
{
pipeline = pipeline_binaryop_broadcast_pack1to4[ri];
}
if (A2.elempack == 8 && top_blob.elempack == 8)
{
pipeline = pipeline_binaryop_broadcast_pack8[ri];
}
if (A2.elempack == 1 && top_blob.elempack == 8)
{
pipeline = pipeline_binaryop_broadcast_pack1to8[ri];
}
cmd.record_pipeline(pipeline, bindings, constants, top_blob);
}
else
{
VkMat B2;
if (B.dims == 1 && ((A.dims == 2 && B.w * B.elempack != A.h * A.elempack) || ((A.dims == 3 || A.dims == 4) && B.w * B.elempack != A.c * A.elempack)))
{
vkdev->convert_packing(B, B2, 1, cmd, opt);
B2.dims = top_blob.dims;
}
else
{
B2 = B;
}
std::vector<VkMat> bindings(3);
bindings[0] = A;
bindings[1] = B2;
bindings[2] = top_blob;
std::vector<vk_constant_type> constants(18);
constants[0].i = A.dims;
constants[1].i = A.w;
constants[2].i = A.h;
constants[3].i = A.d;
constants[4].i = A.c;
constants[5].i = A.cstep;
constants[6].i = B2.dims;
constants[7].i = B2.w;
constants[8].i = B2.h;
constants[9].i = B2.d;
constants[10].i = B2.c;
constants[11].i = B2.cstep;
constants[12].i = top_blob.dims;
constants[13].i = top_blob.w;
constants[14].i = top_blob.h;
constants[15].i = top_blob.d;
constants[16].i = top_blob.c;
constants[17].i = top_blob.cstep;
const Pipeline* pipeline = 0;
if (B2.elempack == 1 && top_blob.elempack == 1)
{
pipeline = pipeline_binaryop_broadcast[0];
}
if (B2.elempack == 4 && top_blob.elempack == 4)
{
pipeline = pipeline_binaryop_broadcast_pack4[0];
}
if (B2.elempack == 1 && top_blob.elempack == 4)
{
pipeline = pipeline_binaryop_broadcast_pack1to4[0];
}
if (B2.elempack == 8 && top_blob.elempack == 8)
{
pipeline = pipeline_binaryop_broadcast_pack8[0];
}
if (B2.elempack == 1 && top_blob.elempack == 8)
{
pipeline = pipeline_binaryop_broadcast_pack1to8[0];
}
cmd.record_pipeline(pipeline, bindings, constants, top_blob);
}
return 0;
}
int BinaryOp_vulkan::forward_inplace(VkMat& bottom_top_blob, VkCompute& cmd, const Option& /*opt*/) const
{
int elempack = bottom_top_blob.elempack;
std::vector<VkMat> bindings(3);
bindings[0] = bottom_top_blob;
bindings[1] = bottom_top_blob; // TODO use dummy buffer
bindings[2] = bottom_top_blob; // TODO use dummy buffer
std::vector<vk_constant_type> constants(15);
constants[10].i = bottom_top_blob.dims;
constants[11].i = bottom_top_blob.w;
constants[12].i = bottom_top_blob.h * bottom_top_blob.d;
constants[13].i = bottom_top_blob.c;
constants[14].i = bottom_top_blob.cstep;
const Pipeline* pipeline = elempack == 8 ? pipeline_binaryop_pack8
: elempack == 4 ? pipeline_binaryop_pack4
: pipeline_binaryop;
cmd.record_pipeline(pipeline, bindings, constants, bottom_top_blob);
return 0;
}
int BinaryOp_vulkan::forward(const std::vector<VkImageMat>& bottom_blobs, std::vector<VkImageMat>& top_blobs, VkCompute& cmd, const Option& opt) const
{
const VkImageMat& A = bottom_blobs[0];
const VkImageMat& B = bottom_blobs[1];
const int outdims = std::max(A.dims, B.dims);
const bool a_rank_is_lower = A.dims < B.dims;
const bool b_rank_is_lower = B.dims < A.dims;
const bool a_rank_is_equal = A.dims == B.dims;
VkImageMat& top_blob = top_blobs[0];
if (a_rank_is_lower)
{
top_blob.create_like(B, opt.blob_vkallocator);
}
else if (b_rank_is_lower)
{
top_blob.create_like(A, opt.blob_vkallocator);
}
else
{
const int outw = std::max(A.w, B.w);
const int outh = std::max(A.h, B.h);
const int outd = std::max(A.d, B.d);
const int outc = std::max(A.c, B.c);
const int out_elempack = std::max(A.elempack, B.elempack);
const size_t out_elemsize = std::max(A.elemsize, B.elemsize);
if (outdims == 1)
{
top_blob.create(outw, out_elemsize, out_elempack, opt.blob_vkallocator);
}
if (outdims == 2)
{
top_blob.create(outw, outh, out_elemsize, out_elempack, opt.blob_vkallocator);
}
if (outdims == 3)
{
top_blob.create(outw, outh, outc, out_elemsize, out_elempack, opt.blob_vkallocator);
}
if (outdims == 4)
{
top_blob.create(outw, outh, outd, outc, out_elemsize, out_elempack, opt.blob_vkallocator);
}
}
if (top_blob.empty())
return -100;
// no broadcast
if (A.dims == B.dims && A.w == B.w && A.h == B.h && A.d == B.d && A.c == B.c && A.elempack == B.elempack)
{
std::vector<VkImageMat> bindings(3);
bindings[0] = A;
bindings[1] = B;
bindings[2] = top_blob;
std::vector<vk_constant_type> constants(15);
constants[0].i = A.dims;
constants[1].i = A.w;
constants[2].i = A.h * A.d;
constants[3].i = A.c;
constants[4].i = 0; //A.cstep;
constants[5].i = B.dims;
constants[6].i = B.w;
constants[7].i = B.h * B.d;
constants[8].i = B.c;
constants[9].i = 0; //B.cstep;
constants[10].i = top_blob.dims;
constants[11].i = top_blob.w;
constants[12].i = top_blob.h * top_blob.d;
constants[13].i = top_blob.c;
constants[14].i = 0; //top_blob.cstep;
const Pipeline* pipeline = top_blob.elempack == 8 ? pipeline_binaryop_pack8
: top_blob.elempack == 4 ? pipeline_binaryop_pack4
: pipeline_binaryop;
cmd.record_pipeline(pipeline, bindings, constants, top_blob);
return 0;
}
const bool a_pack_is_lower = A.elempack < B.elempack;
const bool a_pack_is_equal = A.elempack == B.elempack;
const bool a_size_is_lower = A.w * A.h * A.d * A.c * A.elempack < B.w * B.h * B.d * B.c * B.elempack;
if (a_rank_is_lower || (a_rank_is_equal && a_pack_is_lower) || (a_pack_is_equal && a_size_is_lower))
{
VkImageMat A2;
if (A.dims == 1 && ((B.dims == 2 && A.w * A.elempack != B.h * B.elempack) || ((B.dims == 3 || B.dims == 4) && A.w * A.elempack != B.c * B.elempack)))
{
vkdev->convert_packing(A, A2, 1, cmd, opt);
A2.dims = top_blob.dims;
}
else
{
A2 = A;
}
std::vector<VkImageMat> bindings(3);
bindings[0] = B;
bindings[1] = A2;
bindings[2] = top_blob;
std::vector<vk_constant_type> constants(18);
constants[0].i = B.dims;
constants[1].i = B.w;
constants[2].i = B.h;
constants[3].i = B.d;
constants[4].i = B.c;
constants[5].i = 0; //B.cstep;
constants[6].i = A2.dims;
constants[7].i = A2.w;
constants[8].i = A2.h;
constants[9].i = A2.d;
constants[10].i = A2.c;
constants[11].i = 0; //A2.cstep;
constants[12].i = top_blob.dims;
constants[13].i = top_blob.w;
constants[14].i = top_blob.h;
constants[15].i = top_blob.d;
constants[16].i = top_blob.c;
constants[17].i = 0; //top_blob.cstep;
const int ri = get_reverse_op_type(op_type) == op_type ? 0 : 1;
const Pipeline* pipeline = 0;
if (A2.elempack == 1 && top_blob.elempack == 1)
{
pipeline = pipeline_binaryop_broadcast[ri];
}
if (A2.elempack == 4 && top_blob.elempack == 4)
{
pipeline = pipeline_binaryop_broadcast_pack4[ri];
}
if (A2.elempack == 1 && top_blob.elempack == 4)
{
pipeline = pipeline_binaryop_broadcast_pack1to4[ri];
}
if (A2.elempack == 8 && top_blob.elempack == 8)
{
pipeline = pipeline_binaryop_broadcast_pack8[ri];
}
if (A2.elempack == 1 && top_blob.elempack == 8)
{
pipeline = pipeline_binaryop_broadcast_pack1to8[ri];
}
cmd.record_pipeline(pipeline, bindings, constants, top_blob);
}
else
{
VkImageMat B2;
if (B.dims == 1 && ((A.dims == 2 && B.w * B.elempack != A.h * A.elempack) || ((A.dims == 3 || A.dims == 4) && B.w * B.elempack != A.c * A.elempack)))
{
vkdev->convert_packing(B, B2, 1, cmd, opt);
B2.dims = top_blob.dims;
}
else
{
B2 = B;
}
std::vector<VkImageMat> bindings(3);
bindings[0] = A;
bindings[1] = B2;
bindings[2] = top_blob;
std::vector<vk_constant_type> constants(18);
constants[0].i = A.dims;
constants[1].i = A.w;
constants[2].i = A.h;
constants[3].i = A.d;
constants[4].i = A.c;
constants[5].i = 0; //A.cstep;
constants[6].i = B2.dims;
constants[7].i = B2.w;
constants[8].i = B2.h;
constants[9].i = B2.d;
constants[10].i = B2.c;
constants[11].i = 0; //B2.cstep;
constants[12].i = top_blob.dims;
constants[13].i = top_blob.w;
constants[14].i = top_blob.h;
constants[15].i = top_blob.d;
constants[16].i = top_blob.c;
constants[17].i = 0; //top_blob.cstep;
const Pipeline* pipeline = 0;
if (B2.elempack == 1 && top_blob.elempack == 1)
{
pipeline = pipeline_binaryop_broadcast[0];
}
if (B2.elempack == 4 && top_blob.elempack == 4)
{
pipeline = pipeline_binaryop_broadcast_pack4[0];
}
if (B2.elempack == 1 && top_blob.elempack == 4)
{
pipeline = pipeline_binaryop_broadcast_pack1to4[0];
}
if (B2.elempack == 8 && top_blob.elempack == 8)
{
pipeline = pipeline_binaryop_broadcast_pack8[0];
}
if (B2.elempack == 1 && top_blob.elempack == 8)
{
pipeline = pipeline_binaryop_broadcast_pack1to8[0];
}
cmd.record_pipeline(pipeline, bindings, constants, top_blob);
}
return 0;
}
int BinaryOp_vulkan::forward_inplace(VkImageMat& bottom_top_blob, VkCompute& cmd, const Option& /*opt*/) const
{
int elempack = bottom_top_blob.elempack;
std::vector<VkImageMat> bindings(3);
bindings[0] = bottom_top_blob;
bindings[1] = bottom_top_blob; // TODO use dummy buffer
bindings[2] = bottom_top_blob;
std::vector<vk_constant_type> constants(15);
constants[10].i = bottom_top_blob.dims;
constants[11].i = bottom_top_blob.w;
constants[12].i = bottom_top_blob.h * bottom_top_blob.d;
constants[13].i = bottom_top_blob.c;
constants[14].i = 0; //bottom_top_blob.cstep;
const Pipeline* pipeline = elempack == 8 ? pipeline_binaryop_pack8
: elempack == 4 ? pipeline_binaryop_pack4
: pipeline_binaryop;
cmd.record_pipeline(pipeline, bindings, constants, bottom_top_blob);
return 0;
}
} // namespace ncnn